r DEPARTMENT OP BOTAFT COLLEGE OE AGRICULTURE Laboratory Copy. Compliments of the Publishers COHMELL UNIVERSITY LIBRARY 924 089 570 414 Cornell University Library The original of this book is in the Cornell University Library. There are no known copyright restrictions in the United States on the use of the text. http://www.archive.org/details/cu31924089570414 LESSONS IN BOTANY GEORGE FRANCIS ATKINSON, Ph.B. Professor of Botanv in Cornell University NEW YORK HENRY HOLT AND COMPANY 1908 Copyright, 1900, BY HENRY HOLT & CO. ROBERT DRUMMOND COMPANY. l^iiNTKRS, N*.W YORK PREFACE. This abbreviated and simplified edition of my Elementary Botany has been prepared for the use of pupils in the secondary schools, where short, or half-year, courses in botany are given, and where, for one reason or another, my larger book cannot be adapted to such abbreviated courses. A large part of the matter has been rewritten, only the less technical descriptive portions being retained. The subject-matter is arranged for three different uses : exer- cises for the pupils, demonstrations by the teacher, and descrip- tive matter for reading and reference. To clearly set apart, for the convenience of the teacher and pupil, the work suggested for each, all the work outlined for the teacher is placed under the head of demonstration, whether the setting up of apparatus or an actual demonstration before the class ; so also all the prac- tical work of the pupils, whether an experiment or an ordinary exerpise, is put under the head of exercise. The demonstrations and the exercises each have their own consecutive numbering, so that the teacher can tell at a glance the subdivisions of the work. Where there are a sufficient number of microscopes, so that one can be allotted to two or three pupils, many of the demonstrations can be used as exercises, at the discretion of the teacher. All the paragraphs, whether descriptive, demonstration or exercise, have a separate and consecutive numbering. The first chapter in this abbreviated book is devoted to a study of how seedlings grow from the seed, and this is followed by a chapter on shoots, buds, etc., in order to give an oppor- tunity for some out-door work if the season is propitious, or for IV PREFA CE. the study of material easily collected. This emphasizes the de- sirability of supplementing the regular laboratory course with the out-door work, or with observations on material suitable to be employed in out-door work when conditions permit. The third chapter then treats of protoplasm (the living substance) in the root hairs of seedlings, followed by a similar study in spirogyra. In the following chapters much the same order is used as in the larger book, but there has been an attempt to simplify the treatment. Very much of the technical matter in the larger book has been omitted here, and in consequence much of the matter which is useful for reference to those who desire supple- mentary reading and explanations. For this matter the larger Elementary Botany should be consulted. The studies indicated in the part on ecology are not intended to be pursued as a distinct and separate piece of work, but they may be made the basis of excursions during the progress of the work on physiology and morphology. It is possible to indicate definitely where some of these out-door studies are applicable. At the same time the retention of the third part as a distinct subdivision of the book serves to emphasize the importance of ecological study, or perhaps rather of the study of plant life on a larger scale, and some of the interesting problems connected with the environmental influences on plant life and plant com- munities. It should be recognized that plant distribution, as well as many of the other important problems connected with ecological study, cannot be carried on in the secondary schools with the rigid system applicable in the college or university, or even with the precision which the student of ecology would desire, since a considerable previous technical knowledge of plants would be necessary. The chief importance of the study in the secondary schools is, I believe, to get the pupil interested in observing living plants, and in gaining a general impression of the fundamental laws, and in leading the pupil to realize, in a measure, the great influence which environment has on living beings. PREFACE. V It is suggested that the teacher, at the beginning of the work, take some account of the time to be allotted to the different subjects of the course. For example, in a 20-weeks' course, 7 to 8 weeks could be devoted to physiology, 5 or 6 weeks could be devoted to general morphology ; while 6 or 8 weeks could be devoted to the study of plant families. As the work progresses it can be easily seen whether or not all the exercises and demonstrations can be gotten in during the allotted time. If the time is too short in some cases, the teacher can then arrange to omit certain of the exercises in each chapter, so that as a whole the work can be completed in the desired time. Some of the chapters are intended for reading and reference only. These are indicated at the beginning of the chapters in question. They should not be taken into account when consid- ering the amount of practical work to be done by the pupil. Cornell University, January, 1900. MATERIAL FOR LABORATORY ILLUSTRATION. HIGH SCHOOL BOTANICAL SET. Special net price, $20. Express extra. Permanent Mounts. Those on cards are protected with fly-leaf arid placed together in a neat portfolio. Pond scum (Spirogyra) on card $ .20 Green felt (Vaucheria) on card 20 Wheat rust (Puccinia), three stages, on card 30 Carnation rust (Uromyces) on card 20 Dodder (Cuscuta) on card 20 Mildew (Uncinula) on card 20 Lichen thallus on card 20 Liverwort (Marchantia) thallus with gemmae and sexual organs on card 35 Liverwort — mature fruit (Sporogonia) carefully preserved in fluid for exhibition 75 Moss (Polytrichum) — male, female, and fruiting plant on card 35 Fern (Polypodium) — whole plant on card 10 Horsetail (Equisetum) — fertile and 'sterile plants on card 35 Quillwort (Isoetes) — whole plant on card 30 Quillwort (Isoetes) — plant in section preserved in fluid 45 Pine — male and female flowers and mature scale with seed on card .35 Trillium — mature plant on card 20 Toothwort (Dentaria) — plant on card 20 Microscopic Preparations. Corn — cross-section of stem showing bundles 40 Corn — longitudinal section of stem showing bundles 40 Sunflower — cross-section of stem showing bundles 40 Sunflower — longitudinal section of stem showing bundles 40 Caladium — cross-section of leaf stalk showing bundles 40 Celery — cross-section of leaf stalk showing bundles 40 Celery — longitudinal section of leaf stalk showing bundles 40 Ivy — cross-section of leaf 40 Begonia — cross-section of leaf 40 Pond scum. (Spirogyra) in fruit 40 Green felt (Vaucheria) in fruit 50 Green felt (Vaucheria) — sexual organs 50 Black mould (Rhizopus) — rhizoids, sporangia, and columella 50 Willow mildew (Uncinula) — perithecia crushed and stained to show asci and spores ,...., 50 Carnation rust — sections showing haustoria 40 Dodder (Cuscuta) — sections showing haustoria 40 Wheat rust (Puccinia) — sections of cluster cup 50 Wheat rust (Puccinia) — sections of red rust 50 Wheat rust (Puccinia) — spores of black rust 40 $14.60 MATERIAL FOR LABORATORY ILLUSTRATION. Vll Brought forward $14, Lichen (Peltigera) — section of thallus . Liverwort (Marchantia) — section of antheridia Liverwort (Marchantia) — section of archegonia Liverwort (Marchantia) — spores and elaters Moss (Mnium) — section of antheridia Moss (Mnium) — section of archegonia Moss capsule showing teeth (peristome) and spores Fern (Polypodium) — cross-section of stem Fern (Polypodium) — longitudinal section of stem Fern (Pteris) — cross-section of stem Fern (Pteris) — longitudinal section of stem Fern — sporangia and spores Fern — germinating spores Fern — prothallium with sexual organs * Fern — prothallium with attached embryo Horsetail (Equisetum) — spores and elaters Quillwort (Isoetes) — section of microsporangia Quillwort (Isoetes) — section of macrosporangia Pine — mature pollen Pine — fruiting scale at time of pollination Pine — prothallium with archegonia, and pollen tube in nucellus . . Trillium — pollen Trillium — section of anther Trillium — section of pistil showing Iocules and ovules Lilium — embryo-sac in section Dentaria — section of pistil showing Iocules and ovules 60 40 75 75 40 75 75 5° 40 40 40 40 40 5° 75 75 40 75 75 40 40 75 40 40 5° 75 5° $27.50 or the entire set for $20.00. Duplicate Material Free with Set. Pond scum (Spirogyra) in fruit. Green felt (Vaucheria) in fruit. Wheat rust — two stages on wheat and a cluster cup to represent the stage on barberry. Powdery mildew. Liverwort (Conocephalus). Moss (Polytrichum) — male, female, and fruiting plant. Fern (Polypodium) — pressed plants, and sporangia in formalin. Horsetail (Equisetum) — sterile and fertile plants. Quillwort (Isoetes) — plants in formalin. Pine — mature male and young female cones in formalin. These prepared slides, and other material, for laboratory work, can be obtained of the Ithaca Botanical Supply Co., Ithaca, N. Y. They are especially adapted to illustrate Lessons in Botany, as well as the author's larger "Elementary Botany.'' A supplementary list of supplies representing additional topics treated of in " Elementary Botany, " can be had on application to the Ithaca Botanical Supply Co. TABLE OF CONTENTS. PART I: PHYSIOLOGY. PAGES CHAPTER I. HOW THE SEEDLING GROWS FROM THE SEED 1-6 CHAPTER II. Winter buds, shoots, etc 1-H CHAPTER III. The living substance of plants 15-18 I. Protoplasm in root hairs of seedlings. CHAPTER IV. The living substance of plants, continued 19-23 II. Protoplasm in an alga: Spirogyra. CHAPTER V. The living substance of plants, concluded 24-27 III. Protoplasm in a fungus: Mucor. CHAPTER VI. HOW WATER MOVES IN AND OUT OF PLANT CELLS 2 8~33 Absorption, diffusion, osmose. ix X TABLE OF CONTENTS. CHAPTER VII. PAGES HOW PLANTS OBTAIN THEIR LIQUID FOOD 34~44 I . Water cultures 34-36 II. How plants obtain food from the soil 36-4 1 III. Strong solutions of plant food are injurious 4 I_ 44 CHAPTER VIII. HOW SOME PLANT PARTS REMAIN RIGID 45~49 CHAPTER IX. HOW WATER MOVES THROUGH THE PLANT 5°-55 I. Root pressure or osmotic pressure 50-51 II. The loss of water by plants (transpiration) 5 I_ 55 CHAPTER X. HOW WATER MOVES THROUGH THE PLANT, CONCLUDED.... 56-60 III. Part which the leaf plays in transpiration. CHAPTER XL Path of movement of liquids in plants 61-69 CHAPTER XII. How plants get their carbon food 70-73 I. The gases concerned. CHAPTER XIII. How plants get their carbon food, concluded 74-80 II. Starch formed by green plants. CHAPTER XIV. Rough analysis of plant substance 81-83 TABLE OF CONTENTS. XI CHAPTER XV. PAGES Some other ways in which certain plants obtain food... 84-93 CHAPTER XVI. Respiration 94-101 CHAPTER XVII. Growth 102-106 CHAPTER XVIII. 1 Movement in plants due to irritability 107-1 14 PART II: MORPHOLOGY AND LIFE HISTORY OF REPRESENTATIVE PLANTS. CHAPTER XIX. Spirogyra 115-119 CHAPTER XX. The green felt: Vaucheria 120-124 CHAPTER XXI. Fungi: The black mould * T-5-128 CHAPTER XXII. Fungi, continued : Wheat rust (Puccinia graminisI 129-133 CHAPTER XXIII. Fungi, concluded: The willow mildew (Uncinula sai.icis). 134-138 Xll TABLE OF CONTENTS. CHAPTER XXIV. PAGES Liverworts : Hepatic/E (Marchantia polymorpha) 139-148 CHAPTER XXV. Mosses : Musci (polvtrichum or mnium) 149-154 CHAPTER XXVI. Ferns: Filicine^ (the polypody or Christmas fern) I SS- I ^5 CHAPTER XXVII. Ferns, concluded: The sexual stage of ferns 166-173 CHAPTER XXVIII. Horsetails : Equisetine^ (the field equisetum) 174-179 CHAPTER XXIX. Quillworts: Isoetes 180-183 CHAPTER XXX. Gymnosperms : The white pine 184-193 CHAPTER XXXI. Morphology of the angiosperms : Trillium ; dentaria 194-202 CHAPTER XXXII. Prothallium and sexual organs of flowering plants .... 203-207 CHAPTER XXXIII. Seeds and seedlings 208 216 TABLE OF CONTENTS. XU1 CHAPTER XXXIV. PAGES The plant body and some of its modifications 217-220 CHAPTER XXXV. Arrangements of the parts of the flower 221-224 CHAPTER XXXVI. Relationships shown by flower and fruit 225-230 CHAPTER XXXVII. Classification (or taxonomy) 231-235 STUDIES ON PLANT FAMILIES. MONOCOTYLEDONES 236-249 CHAPTER XXXVIII. Topic I : Monocotyledones with conspicuous petals (peta- LOIDEjE) 236-242 Order Liliflorse : Family Liliacese ; the lily family. Order Gynandrae : Family Orchidaceae ; the orchid family. CHAPTER XXXIX. Topic II : Monocotyledones with flowers on a spadix (spa- dicifloRj«) 243-246 Family Aracese ; the arum family. CHAPTER XL. Topic III : Monocotyledones with a glume subtending the FLOWER (GLUMIFLOR/E) 247-249 Family Gramineae ; the grass family. XIV TABLE OF CONTENTS. FACES DICOTYLEDONES 250-283 CHAPTER XLI. Topic IV • Dicotyledones with distinct petals, flowers in CATKINS OR AMENTS ; OFTEN DEGENERATE 25O-254 Order Amentiferae : Family Salicaceae ; the willow family. Family Cupuliferse ; the oak family. CHAPTER XLII. Topic V : Dicotyledones with distinct petals and hypogy- NOUS FLOWERS 255-261 Order Urticiflorae : Family Ulmacese ; the elm family . Order Polycarpicse : Family Ranunculaceae ; the crowfoot family. Order Rhceadinae : Family Cruciferse ; the mustard family. Order Cistiflorse : Family Violacese ; the violet family. CHAPTER XLIII. Topic VI : Dicotyledones with distinct petals and perigy- nous or epigynous flowers 262-264 Order iEsculinae : Family Aceraceae ; the maple family. CHAPTER XLIV. Topic VI, continued 265-270 Order Rosiflorse : Family Rosacese ; the rose family. Family Amygdalaceae ; the almond family. Family Pomacese ; the apple family. Order Leguminosse : Family Papilionaceae ; the pea family. Topic VII : Dicotyledones with distinct petals and epigy- nous flowers 271-273 Order Myrtiflorae : Family Onograceae ; the evening-primrose family. SYMPETAL^E 274-282 CHAPTER XLV. Topic VIII : Dicotyledones with united petals, flower parts in five whorls 274 Order Bicornes : Family Vacciniacese ; the whortleberry family. TABLE OF CONTENTS. XV PAGES Topic IX : Dicotyledones with united petals, flower parts IS FOUR WHORLS 275-27^ Order Tubiflorse : Family Labiatse ; the mint family. Order Personate : Family Scrophulariacese; thefigwort family. CHAPTER XLVI. Topic IX, continued 278-282 Order Aggregatae : Family Compositae ; the composite family. PART III: ECOLOGY. Introduction 283-291 Suggestions for ecological study. CHAPTER XLVII. Seed distribution 292-299 CHAPTER XLVIII. Struggle for occupation of land 300-305 CHAPTER XLIX. Zonal distribution of plants 306-310 CHAPTER L. Soil formation in rocky regions and in moors 311-327 CHAPTER LI. Plant communities ; seasonal changes 328-336 CHAPTER LII. Adaptation of plants to climate 337-341 APPENDIX 343-353 GLOSSARY 3S5-36o BOTANY. PART I. PHYSIOLOGY. CHAPTER I. HOW THE SEEDLING GROWS FROM THE SEED. 1. Since the seedling plant is useful in illustrating several of the life processes of plants we may well begin with some studies of germinating seeds. We may take for the first example the pumpkin seedling, and then follow with several others in order to become familiar with the parts of the seedling plant before we study the life processes. THE PUMPKIN SEEDLING. Demonstration I. 2. To prepare seedB for germination. — Soal^a handful of seeds (or more if the class is large) in water for twelve to twenty -four hours. Take shallow crockery plates, or ordinary plates, or a germinator with a fluted bottom. Place in the bottom some sheets of paper, and if sphagnum moss is at hand scatter some over the paper. If the moss is not at hand, throw the upper layer of paper into numerous folds. Thoroughly wet the paper and moss, but do not have an excess of water. Scatter the seeds among the moss or the folds of the paper. Cover with some more wet paper and keep in a room where the temperature is about 20° C. to 25° C. The ger- minator should be looked after to see that the paper does not become dry. It may be necessary to cover it with another vessel to prevent the too rapid evaporation of the water. The germinator should be started about a week before the seedlings are wanted for study. Some of the soaked seeds should be planted in soil in pots and kept at the same temperature, for comparison with those grown in the germinator. BOTANY. 3. Structure of the pumpkin seed. — The pumpkin seed has a tough papery outer covering for the protection of the embryo plant within. This covering is made up of the seed coats. When the seed is opened by slitting off these coats there is seen within the ' ' meat ' ' of the pumpkin seed. This is nothing more than the embryo plant. The larger part of this embryo consists of two flattened bodies which are more prominent than any other part of the plantlet at this time. These two flattened bodies are the two first leaves, usually called cotyledons. If we spread these cotyledons apart we see that they are connected at one end. Lying between them at this point of attachment is a small bud. This is the plumule. The plumule consists of the very young leaves at the end of the stem which will grow as the seed germinates. At the other end where the cotyledons air. joined is a small projection, the young root, often termed the radicle. 4. How the embryo gets out of a pumpkin seed. — To see how the embryo gets out of the pumpkin seed we should examine seeds germinated in the folds of damp paper or on damp sphagnum, as well as some which have been germinated in earth. Seeds should be selected which represent several different stages of germination. Fig. i. Germinating seed of pumpkin, showing how the heel or " peg " catches on the seed coat to cast it off. 5. The peg helps to pull the seed coats apart. — The root pushes its way out from between the stout seed coats at the smaller end, and then turns downward unless prevented from so HOW THE SEEDLING GROWS FROM THE SEED. 3 doing by a hard surface. After the root is 2-\cm long, and the two halves of the seed coats have begun to be pried apart, if we look in this rift at the junction of the root and stem, we shall see that one end of the seed coat is caught against a heel, or "peg," which -has grown out from the stem for this purpose. Now if we examine one which is a little s-:. ,;v ;..ss«k>^ more ad- vance d, we shall see this heel more distinctly, and also that the stem is arching out away from the seed coats. As the stem arches up its back in this way it pries with the cotyledons against the upper seed coat, Escape of the pumpkin seedling from the seed coats. i , J 1 l j but the lower seed coat is caught against this heel, and the two are pulled gradually apart. In this way the embryo plant pulls itself out from be- tween the seed coats. In the case of seeds which are planted deeply in the soil we do not see this contrivance unless we dig down into the earth. The stem of the seedling arches through the soil, pulling the cotyledons up at one end. Then it straightens up, the green cotyledons part, and open out their inner faces to the sunlight, as shown in fig. 3. If we dig into the soil we shall see that this same heel is formed on the stem, and that the seed coats are cast off into the soil. 4 BOTANY. 6. Parts of the pumpkin seedling. — During the germination of the seed all parts of the embryo have enlarged. This in- crease in size of a plant is one of the peculiarities of growth. The cotyledons have elongated and expanded somewhat, though not to such a great extent as the root and the stem. The cotyledons also have become green on exposure to the light. Very soon after the main root has emerged from the seed coats, other lateral roots begin to form, so that the root soon becomes very much branched. The main root with its branches makes up the root system of the seedling. Be- tween the expanded cotyledons is seen the plumule. This has enlarged some- what, but not nearly so much as the root, or the part of the stem which extends below the cotyledons. This part of the stem, i. e. , that part below the cotyledons and extending to the beginning of the root, is called in all seedlings the hypocoiyl, which means ' ' below the cotyledon. ' ' Fig. 3. Pumpkin seedling rising from the ground. Exercise 1 . 7. Structure of a squash or pumpkin seed. — Sketch a squash or pumpkin seed, noting carefully the form and markings. Split off the tough papery seed coats (testa), from a seed which has been soaked in water, to observe the embryo. Note the large, flattened cotyledons. Spread them gently apart to see the attachment at the smaller ends, where they are attached to the short caulicle (stem). Sketch the embryo in this position showing the cotyledons, the plumule between them, and the short radicle projecting from the end where the cotyledons are attached; name the parts of the embryo. Make a cross-section of another seed through the middle, and observe the relation of the cotyledons to the seed coats; sketch. Make a cross-section HOW THE SEEDLING GROWS FROM THE SEED. 5 of a seed near the smaller end so that the section will cut across the plumule; sketch showing the positions of the different parts and the relation to the seed coats. Exercise 2. 8. Structure of the bean seed. — Take beans which have been soaked in ■water. Sketch a bean, showing the form, the scar (Jiilum) on the concave side, the minute pit (micropyle) by the side of the hilum. Remove the testa (seed coats) from one of the beans ; note the large thick cotyledons ; de- termine where the cotyledons are joined (or attache'd to the young caulicle). Along one side of this point of attachment note the young radicle ; at the ether end between the cotyledons note the plumule. Split open a bean along the line where the cotyledons meet ; sketch one half, showing the young plumule and the venation of the leaf, and at the other side the young radicle. Make a cross-section of a bean and sketch to show the relation of the cotyledons to the seed coats, and the plumule between the cotyledons. If there is time, compare a pea seed. Exercise 3. 9. Structure of the grain of corn. — Take grains of corn that have been soaked. Note the form, and the difference of the two sides. Sketch a grain of corn showing the depressed area near the smaller end. Make a longisection of a grain of corn through the middle line. (If neces- sary make several to obtain one which shows the structures well near the smaller end of the grain.) Sketch the section as shown by one half, observ- ing the following structures : ist, the hard outer "wall " (formed of the con- solidated wall of the ovary with the integuments of the ovules — see Chapters 32 and 33) ; 2d, the greater mass of starch and other plant food (the endosperm) in the centre ; 3d, a somewhat crescent-shaped body (the scutellum) lying next the endosperm and near the smaller end of the grain ; 4th, the remaining portion of the young embryo lying between the scutellum and the seed coat in the depression. When good sections are made one can make out the radicle at the smaller end of the seed, and a few successive leaves (the plumule) which lie at the opposite end of the embryo shown by sharply curved parallel lines. Observe the attach- ment of the scutellum to the caulicle at the point of junction of the plumule and the radicle. The scutellum is a part of the embryo and represents a cotyledon. Dissect out an embryo from another seed, and compare with that seen in the section. BOTANY. Exercise 4. 10. The squash (or pumpkin) seedling. — Take seedlings in different stages of germination which have been grown in a germinator. Make sketches of several different stages, showing the expanded cotyledons, the plumule between them, the main root, and the origin of the lateral roots, the hypocotyl (the portion of the stem between the root and the cotyledons). Note the "peg" on the hypocotyl and determine the way in which this organ assists the embryo in getting out of the seed coats. Compare seed- lings growing in the soil. 11. Other seedlings. — Make a. similar study of the bean, pea, and corn seedlings, both from seeds germinated in folds of damp paper, and from those grown in the soil. Sketch the different stages, and write a full descrip- tion and comparison, noting the points of agreement and disagreement between them, and the different ways in which the seedlings come up from the ground. (Consult Chapter 33). Material Seeds of the pumpkin or squash, beans, peas, and corn. These should be soaked in water for about twenty -four hours before they are wanted for the study of the seed. Seedlings of the same plants in different stages of germination. Some of the seeds should be germinated in folds of wet paper or in moss, and some of them should be planted in soil in pots. These should be started about a week in advance of the time when they are wanted for study by the student. The number of seeds and seedlings which should be prepared will depend on the number of students in the class. A surplus of material should be pro- vided for. CHAPTER II, WINTER BUDS, SHOOTS, ETC. 12. Season for study of shoots. — Either the autumn or the winter is an excellent time for some observations of the winter condition of plants, especially of the stems or shoots, as well as the leaves. While actual growth of the parts cannot then be observed, certain interesting and important peculiarities of the stems and leaves can then be easily studied. The exercises are also instructive for classes which have not had previous instruc- tion in nature studies. 13. Annuals, biennials, perennials.— One of the striking things which we observe during the winter season is the fact that certain plants, especially the herbs, like many weeds and culti- vated plants, are dead and dry. Where the plant makes its entire growth during the year or season, and ripens at the close, it is an annual. The bean, corn, squash, the ragweed, etc., are annuals. Other plants, like the thistle, mullein, etc., do not mature their fruit or seed until the second year. Such plants are biennials. Trees, shrubs, and many herbs as well, like the asters, goldenrods, etc., live from year to year, and are therefore peren- nials. In the goldenrods, in trillium, the toothwort, and other perennials of this kind, the larger part of the annual growth dies back at the close of the season, while the plant is carried over the winter by the shorter underground stem. 14. Annual growth of the horse-chestnut. — In figure 4 there is illustrated a shoot of the horse-chestnut. Near the middle portion of the shoot is a ring of numerous fine scars, and another ring of similar scars near the lower end. These rings of scars mark the positions of successive annual terminal buds, _ 7 BOTANY. so that the portion of the shoot between two such adjacent rings, or above the last one, rep- resents the growth in length of the shoot for one year. At the close of the season's growth the "bud" is formed. In the horse-chestnut the terminal bud is broader than the diameter of the shoot, and is ovate in form. 15. We notice that there are a number of scales which overlap each other somewhat as shingles do on a roof, only they are turned in the opposite direction. If we begin at the base of the bud, we can see that the two lowest scales are opposite each other, and that the two next higher ones are also opposite each other, and set at right angles to the position of the lower pair. In the same manner successive pairs of scales alternate, so that the third, fifth, seventh, etc., are exactly over the first, and the fourth, sixth, etc. , are exactly over the second. Aside from the fact that these brown scales fit closely together over the bud, we notice that they are covered with a sticky substance which helps to keep out the surface water. Thus a very complete armature is provided for the pro- tection of the young leaves inside. 16. Leaf scars. — -The number of leaves de- veloped during one season's growth in length of the shoot can be determined by counting the broad whitish scars which are situated just below each pair of lateral buds. Near the margin of these scars in the horse-chestnut are seen prominent pits arranged in a row. These Two-year old twig little pits in the leaf scar are formed by the or horse chestnut, r J showing buds and breaking away of the fibro-vascular bundles leaf scars. (A twig ° J with a terminal bud ( w hich run into the petiole of the leaf) as the should have been N r ' selected for this fig- i ea f f a n s j n the autumn. ure.) WINTER BUDS, SHOOTS, ETC. 17. Lateral buds. — The lateral buds, it is noticed, arise in the axils of the leaves. Each one of these by growth the next year, unless they remain dormant, will develop a shoot or branch. Just above the junction of the upper pair of branches we notice scars which run around the shoot in the form of slender rings, several quite close together. These are the scars of the bud scales of the previous year. By observing the location of these ring scars on the stem the age of the branch may be determined, as well as the growth in length each year. Small buds may be frequently seen arising in the axils of the bud scales, that is after the scales have fallen, so that four to ten small buds may be counted sometimes on these very nar- row zones of the shoot. 18. Bud leaves. — On re- moving the brown scales of the bud there is seen a pair of thin membranous scales which are nearly colorless. Underneath these are young leaves; successive pairs lie farther in the bud, in outline similar to the mature leaves, annual rings. and each pair smaller than the one just below it. They are very hairy, with long white woolly fibres. These woolly fibres serve also to protect the young leaves from the cold or from sudden changes in the temperature, since they hold the air in their meshes very securely. Fig. 5- Three-year-old twig of the American ash, with sections of each year's growth showing IO BOTANY. 19. Opening of the buds in the spring. — As the buds "swell" in the spring of the year, when the growth of the young leaves and of the shoot begins, the bud scales are thrown backward and soon fall away as the leaves unfold, thus leaving the "ring scar" which marks the start of the new year's growth in length of the shoot. 20. Variations in different shoots. — A study of a number of different kinds of woody shoots would serve to show us a series of very interesting variations in the color, surface markings, out- line of the branch, arrangement of the leaves and consequently different modes of branching, variations in the leaf scars, the form, size, color, and armature of the buds, as well as great variations in the character of the bud scales. There are striking differences between the buds of different genera, and with careful study differences can also be seen in the members of a genus. 21. Growth in thickness of woody stems. — In the growth of woody perennial shoots, the shoot increases in length each year at the end. The shoot also increases in diameter each year, though portions of the shoot one year or more old do not increase in length. We can find where this growth in diameter of the stem takes place by making a thin cross-section of a young shoot or branch of one of the woody plants. If we take the white ash, for example, in a cross-section of a one-year-old shoot we observe the following zones : A central one of whitish tissue the cells of which have thin walls. This makes a cylin- drical column of tissue through the shoot which we call the pith or medulla. Just outside of this pith is a ring of firmer tissue. The inner portion of this ring shows many woody vessels or ducts, and the outer portion smaller ducts, and a great many thick-walled woody cells or fibres. This then is a woody zone, or the zone of xylem. The outer ring is made up of the bark, as we call it. In this part are the bast cells. Between the bark and the woody zone is a ring of small cells distinguished from the bark and the woody inner portion by the finer texture of the cut surface. WINTER BUDS, SHOOTS, ETC. II This is the growing cylindrical layer of the shoot which lies between the bark and wood throughout the extent of the shoot and in fact the entire tree. It is the cambium. 22. Annual rings in woody stems. — If we now cut across a shoot of the ash which is several years old, we shall note, as shown in fig. 5, that there are successive rings which have a similar appearance to the woody ring in the one-year-old stem. This can well be seen without any magnification. The larger size of the woody ducts which are developed each spring, and the preponderance of the fibres at the close of each season's growth, mark well the growth in diameter which takes place each year. For further details consult Chapter XI, and also the author's larger ' ' Elementary Botany. ' ' 23. Phyllotaxy, or arrangement of leaves. — In examining buds on the winter shoots of woody plants, we cannot fail to be impressed with some peculiarities in the arrangement of these members on the stem of the plant. In the horse-chestnut, as we have already observed, the leaves are in pairs, each one of the pair standing opposite its partner, while the pair just below or above stand across the stem at right angles to the position of the former pair. In other cases (the common bed straw) the leaves are in whorls, that is, several stand at the same level on the axis, distributed around the stem. By far the larger number of plants have their leaves arranged alternately. A simple example of alternate leaves is presented by the elm, where the leaves stand successively on alternate sides of the stem, so that the distance from one leaf to the next, as one would measure around the stem, is exactly one half the distance around the stem. This arrangement is -J, or the angle of divergence of one leaf from the next is \. In the case of the sedges the angle of divergence is less, that is \. By far the larger number of those plants which have the alternate arrangement have the leaves set at an angle of diver- gence represented by the fraction -§. 12 BOTANY. 24. Other angles of divergence. — Other angles of divergence have been discovered, and much stress has been laid on what is termed a law in the growth of the stem with reference to the position which the leaves occupy. There are, however, numer- ous exceptions to this regular arrangement, which have caused some to question the importance of any theory like that of the ' ' spiral theory ' ' of growth propounded by Goethe and others of his time. 25. Adaptation in leaf arrangement. — As a result, however, of one arrangement or another we see a beautiful adaptation of the plant parts to environment, or the influence which environ- ment, especially light, has had on the arrangement of the leaves and branches of the plant. Access to light and air are of the greatest importance to green plants, and one cannot fail to be profoundly impressed with the workings of the natural laws in obedience to which the great variety of plants have worked out this adaptation in manifold ways. Exercise 5. 26. Shoots of the horse-chestnut — Select shoots with strong terminal buds, and with several ring scars indicating several years' growth. Sketch a shoot, showing the ring scars, the leaf scars, the lateral and terminal buds, the lenticels (small rough elevations scattered over the surface of the twig, made up of corky tissue through which air is admitted). Note that the lat- eral buds arise in the axils of leaves (above the leaf scars). Are there buds in the axils of all the leaf scars on the shoot ? How do they differ in size ? Note that the larger and longer ones, from which the lateral branches usually arise, are usually situated near the terminal portion of each year's growth of the shoot. There was not room for all of the buds to grow into branches because they would be too crowded, and would shut out light and air. In the struggle for existence some have outgrown others which remain dormant ready to start growth if by accident the main shoot should be broken just above them. Compare shoots which have borne flower-clusters for several years, and determine what effect this has had on the character of the branching. 27. Buds of the horse-chestnut. — Sketch in detail a large terminal bud. Note the color and texture of the outer scales of the bud. Is the texture of the outer bud scales such as to afford protection to the tender portion of the bud within ? Is there any other means for protection of the buds ? WINTER BUDS, SHOOTS, ETC. 13 Remove the scales one by one, determining the number, and their ar- rangement on the axis, as well as the difference in texture and form. Make a longitudinal section of the bud, and sketch one half to show the relation of the scales in the bud. Make a cross-section and sketch. 28. Annual growth in thickness as shown by the " annual rings. " — With a sharp knife make cross-sections of the shoots of different ages, and from the number of annual rings determine the age of the shoot. Compare the annual rings with the number of ring scars on the shoot and see if the age of the shoot determined by both means is the same. Exercise 6. 29. Comparative study of other shoots. — Study in a similar way other shoots, taking for example the walnut or butternut, the birch, elm, dog- wood, peach, apple, etc. The selection may be- made from trees or shrubs which are accessible, and for the purpose of illustrating several different types. Sketch the form of the shoot, the position of the leaf scars, of the ring scars, of the buds, lenticels, etc. Make careful notes upon these characters, as well as on the different col- ors, surface markings, etc. Determine the age of the shoots, and of the branches, the relation of the dormant buds to those which have developed into the lateral shoots or branches. Determine the effect which fruit buds have had on the branching of the different species. Make cross-sections and determine the age by the annual rings. Exercise 7. 30. Comparative study of other buds. — Study the buds of several different shoots of trees and shrubs, for the purpose of determining the variations in the form of the bud scales, and the different means for the protection of the delicate scales within. Examples suggested are as follows : walnut or butternut, hickory, cur- rant, etc. Sketch the form and surface characters of the buds, and note the color, or other characters. Remove the scales one by one, note their arrangement on the shoot, their relation one to another in the bud. Determine the number of scales in a bud of the different kinds. Sketch the different forms of bud scales in each differ- ent kind of bud, arranging the sketches to represent the number of the scales, their form, and relative position on the axis, but far enough separated to show the details of each. 14 BOTANY. Exercise 8. 13. Comparison of leaf arrangement. — Study the arrangement of the leaves on several different shoots, by an examination of the leaf scars or by the buds. The teacher can select shoots which represent several different systems of phyllotaxy, for example the opposite and the alternate ; among the alternate let the pupil determine those which have the angles of divergence repre- sented by the fractions \, \, §, §, etc. Exercise 9. 32. Field observations on trees and shoots. — If the weather is favorable an excursion to the woods, fields, or to some park or garden would be an ap- propriate conclusion to these exercises. The result can be made the basis of a short paper by each student. For example, let the pupil observe the habit (that is, the general form, character of branching, etc. ) of different trees ; the character of the bark ; any further peculiarities of buds and shoots ; the dif- ferences between deciduous trees (those which shed all their leaves in the autumn, or whose leaves die), and evergreens. (In the evergreens the leaves remain green and attached to the trees for more than a. year, for example in the pines for about three years. In this way while new leaves are formed each year, and old leaves are shed each year, there are green leaves on the tree at all seasons.) Material (for exercises 5-8). — Shoots showing two or three years' growth of the following species (or others which may be more convenient in some localities) : horse-chestnut, birch, dogwood, apple, peach, etc., a selection to represent several different types. In selecting some of the shoots it will be well to collect some which have borne fruit and which have fruit buds, in order to compare the different type of branching induced on the fruit-bearing shoots. (If some of the material can be collected when the leaves are present and preserved, such leafy shoots will be interesting for comparison, especially shoots of the birch, which have short lateral branches bearing only two leaves each year.) CHAPTER III. THE LIVING SUBSTANCE OF PLANTS. I. Protoplasm in Root Hairs of Seedlings. 33. Importance of studying protoplasm. — Now that we have become familiar with the parts of the seedling, have studied the germination of the seed, and have observed the increase in size and elongation of its parts we are impressed with the fact that it is a living thing. It is now time to inquire into the nature of the living substance of plants. Plant growth as well as some of the other life processes which we are about to study are at bottom dependent on this living matter. It is evident, then, that we should know something abqut it, how it appears, and how it acts. For with this knowledge it is easier to comprehend how the plant does its work as a living being. This living sub- stance of plants is protoplasm. The student should now observe protoplasm in several plants. If there are not a sufficient num- ber of microscopes to enable the students to make and study their own preparations, let the teacher prepare a demonstration for the members of the class. Demonstration 2. 34. To prepare seedlings with clean root hairs. — Begin to prepare the seeds several days or a week before they are wanted for study. Soak a handful of corn or beans, radishes, etc. (or more if there is a large class) in an abundance of water for 24 hours. Prepare a moist chamber by placing a layer of moss (sphagnum) or cotton in the bottom of a wide vessel (a crockery plate or a germinator with a fluted bottom). Upon this place a layer of filter paper. Have the sphagnum and filter paper well wetted, but not with a sur- 15 l6 BOTANY. plus of water. Remove the seeds from the water and scatter them over the paper. Place another sheet of wet filter paper over them, and if it is necessary, in order to keep the seeds moist, scatter among them a little damp absorbent cotton. Cover with a glass or with an inverted vessel to pre- vent too rapid evaporation of the moisture. Set aside in a warm place, about 22° C. to 25° C. (about 70°-8o° Fahr.). Look at the culture Fig. 6. every day to see that there is just the right Seedling of radish, showing root . hairs, amount of water to keep the seeds from drying, and also to see that there is not a surplus of water or the seeds will rot. When the roots have begun to appear from the seeds remove the upper layer of paper and moss so that the root hairs can develop without interfer- ence. When the young roots just back of the tip are covered with a downy growth of colorless hairs, as in figure 6, they are ready for use. Demonstration 3. 35. To prepare the root hairs for examination with the microscope. — Hold the root between the thumb and finger (or in this position between two thin pieces of elder pith to give it support). Then with a sharp razor, the blade resting on the forefinger and the edge against the root in the region of the root hairs, make a sliding cut across the root. Make several successive similar cuts in such a way as to get thin cross-sections of the root with the root hairs attached. Mount these sections in a drop of water on a glass slip and cover with a clean circle cover glass. Or with the needles tease out a small portion of the root with the root hairs attached. Tease apart the tissues in a drop of water, being careful not to break off the root hairs, and mount in water on a glass slip. Place the slip under the microscope and focus the microscope on suitable root hairs for demonstration of the protoplasm. Let each pupil be seated at the microscope for a few moments to observe the protoplasm in the root hairs. Demonstration 4. 36. Protoplasm in the root hairs. — Examining this preparation with the aid of the microscope we see that each thread or root hair is a continuous tube. It is a single plant cell which has become very much elongated and free by pushing out its free end some distance from the other cells of the outer portion of the root. Observe the boundary wall of the thread. This is the cell wall. Within this the protoplasm is seen. It is colorless and very granular, that is, numerous fmall granules of different sizes lie quite closely together in a colorless slimy liquid. This is the protoplasm. It does not THE LIVING SUBSTANCE OF PLANTS. 17 ntirely fill the root hair. But here and there are seen strands of this sub- :ance which cross the thread leaving clear spaces between. Or the clear paces appear as rounded vacuoles of different sizes, r the vacuoles are more or less elongated. These lear spaces in the root hair are occupied by a watery ibstance known as the cell sap. Demonstration 5. 87. Test for protoplasm. — Draw off the water from nder the cover glass by the use of filter paper, and t the same time add some of the solution of iodine ith a medicine dropper. Observe that the proto- lasm is stained a yellowish-brown color. This is le reaction of protoplasm in the presence of iodine. Exercise 1 O. 38. Study root hairs of seedlings. — Some of the :edlings prepared in demonstration 2 can be used f the members of the class for a study of the gross Dpearance of the root hairs. Make a sketch of the seedling showing what por- Dn of the root is covered by the root hairs. Why e not the root tips covered with the root hairs? fhy are the root hairs absent from the older portions : the roots ? As to strength and firmness how do ie root hairs and rcots compare ? Test this by indling. Immerse the portion of the root covered by the iot hairs for a few moments in a solution of iodine, o they take the stain ? Will the stain all wash out water when immersed for a few moments ? Take a fresh seedling with uninjured root hairs id immerse the root for a few moments in a 1% [ueous solution of eosin. Rinse in water. Do the root hairs hold the ain ? Immerse the root for a few moments in strong alcohol, or in 2% rmalin. and then immerse the root hairs in eosin. Rinse in water. Do the ot hairs hold the stain now ? Why ? Write out a complete account of your experiments and observations. Fig. 7. Root hairs of corn be- fore and after treatment with 5% salt solution. 18 BOTANY. Synopsis. — The root hairs are formed near the growing end of the young root. The root hair is a single plant cell, very long and narrow. The root hair is formed by the elongation of one of the outer cells of the root. Cell wall, the enclosing cellulose membrane to protect and hold the cell contents. Protoplasm. Nucleus. The root- Granular protoplasm, arranged differently from that in spiro- hair cell. ] gyra ; a wall layer, and then stout strands and masses which reach across with clear rounded spaces between (the vacuoles). Cell sap, in the vacuoles. Chlorophyll absent. Reactions of the protoplasm ; is killed, and stained yellowish brown with iodine; a 1% aqueous solution of eosin does not stain it; it does stain with the eosin when first killed with alcohol. Materials. — Young seedlings of radish, corn, squash, or other plants, with clean root hairs, grown in a germinator (see Demonstration 2). A solution of iodine. A 1% aqueous solution of eosin. 9S% alcohol (commercial strength). Watch glasses to receive small quantities of these solutions when the pupils are engaged in exercise 10. Medicine droppers. For the demonstrations : Micros .ope, razor, glass slips, cover-glass circles, dissecting needles. (Hereafter the microscope and accessories will not be listed in each case for the demonstrations ; microscope, etc. , will be inserted instead.) CHAPTER IV. THE LIVING SUBSTANCE OF PLANTS— Continued. II. Protoplasm in an Alga: Spirogyra. 39. The plant spirogyra.* — There are a number of algse which would serve the purpose quite as well as spirogyra, but we shall want to employ this plant again at a later time, and it is well now to become familiar with it. It is found in the water of pools, ditches, ponds, or in streams of slow-running water. It is green in color, and occurs in loose mats, usually floating near the surface. The name " pond scum " is some- times given to this plant, along with others which are more or less closely related. If we lift a portion of it from the water, we see that the mat is made up of a great tangle of green silky threads. Each one of these threads is a plant, so that the number contained in one of these floating mats is very great. Demonstration 6. 40. To prepare spirogyra for study under the microscope. — Lift up a bit of this thread tangle with a needle and place it in a drop of water on a " glass slip." With the needles tease apart the threads so that they will be scattered in the water. Now place over these threads in the water a clean, thin, glass circle. Place the preparation on the stage of the microscope and adjust for observation of a thread. Let the pupils first examine the plant under the low power of the microscope, and then under the high power. They should e * If spirogyra is in fruit some of the threads will be lying parallel in pairs, and connected by short tubes. In some of the cells may be found rounded or oval bodies known as zygospores. These may be seen in figure 93 and will be described in another part of the book. 19 20 BOTANY. •T first observe certain things about the plant enumerated in paragraphs^ and 42, so that they will be able to tell it from other minute green algse. When these things have been observed the protoplasm can be demonstrated. At one sitting each pupil can ob- serve the things called for in paragraphs 41-44 ; make sketches and notes. 41. Chlorophyll bands in spirogyra. — We first observe the presence of bands, green in color, the edges of which are usually very irregularly notched. These bands course along in a spiral manner near the surface of the thread. There may be one or several of these spirals, according to the species which we happen to select for study. This green coloring matter of the band is chlorophyll, and this substance, which also oc- curs in the higher green plants, will be considered in a later chapter. At quite regular intervals in the chlorophyll band are small starch grains, grouped in a rounded mass. 42. T,he spirogyra thread consists of cylind- rical cells end to end. — Another thing which attracts our attention, as we examine a thread of spirogyra under the microscope, is that the thread is made up of cylindrical segments or compartments placed end to end. We can see a distinct separating line between the ends. Each one of these segments or compartments of the thread is a cell, and the boundary wall is in the form of a cylinder with closed ends. 43. Protoplasm. — Having distinguished these parts of the plant we can look for the proto- Fig. 8. gyra, showing 1 k>ng plasm. It occurs within the cells. It is color- rells, chlorophyll ,. , ,. . . band, nucleus, less (i.e., hyaline) and consequently requires plasm, and the close observation. Near the centre of the cell orprotopiasm ayer can be seen a rather dense granular body of an elliptical or irregular form, with its long diameter transverse to THE LIVING SUBSTANCE OF PLANTS. 21 the axis of the cell in some species; or triangular, or quadrate in others. This is the nucleus. Around the nucleus is a granular layer from which delicate threads of a shiny granular substance radiate in a star-like manner, and terminate in the chlorophyll band by one of the groups cf starch grains. A granular layer of the same substance lines the inside of the cell wall, and can be seen through the microscope if it is properly focussed. This granular substance in the cell is protoplasm. 44. Cell-sap in spirogyra. — The greater part of the interior space of the cell, that between the radiating strands of proto- plasm, is occupied by a watery fluid, the " cell-sap." Demonstration 7. 45. Test for protoplasm in spirogyra. — Mount a few threads of spirogyra in a drop of weak solution of iodine for microscopic examination. Fig. 9. Cell of spirogyra before treat- ment with iodine. Fig. 10. Cell of spirogyra after treatment with iodine. The iodine gives a yellowish-brown color to the protoplasm, and it can be more distinctly seen. The nucleus is also much more prominent since it colors deeply, and we can perceive within the nucleus one small rounded body, sometimes more, 22 BOl^ANY. the nucleolus. The iodine here has killed and stained the protoplasm. 46. Living protoplasm resists the action of some reagents. — If a few living threads are placed in a i$ aqueous solution of eosin, and after a time washed, the protoplasm remains un- colored. This teaches that protoplasm in a living condition resists for a time the action of some reagents. (The iodine and eosin here used are called reagents.) But let us place these threads for a short time, two or three minutes, in strong alcohol, which kills the protoplasm. Then mount them in the eosin solution. The protoplasm now takes the eosin stain. After the protoplasm has been killed the nucleus is no longer elliptical or angular in outline, but is rounded. The strands of protoplasm are no longer in tension as they were when alive. Exercise 1 1 . 47- The alga epirogyra. — Place some of the threads in a shallow vessel of water. Note the appearance of the threads, their length. Determine if branches are present or not. If a small hand lens is convenient, spread some of the threads out between two glass slips, and holding the preparation toward a lighted window look at it through the lens. Describe what is seen. Lift some of the threads with the aid of a needle, and notice how long and delicate they are. Feel of some between the thumb and finger. Pinch some of the threads and again place them in the water. Write an account of the observations. Place some threads in a small quantity of alcohol and let remain for several minutes. Does the alcohol become colored green ? Why ? Place some of the threads in a solution of iodine for a few moments. Rinse them in water. Do the threads hold the color ? What is the color ? Place some fresh threads in a l% solution of eosin for a few moments. Rinse in water. Do the threads hold , the stain ? Why ? Place the same threads for a few moments in strong alcohol, and then in the eosin. Rinse in water. Do the threads now hold the color ? Why ? Write out a complete account of your experiments and observations in this study of the gross characters of the ^lant spirogyra. THE LIVING SUBSTANCE OF PLANTS. 23 Synopsis. — The spirogyra plant occurs in quiet water. f A single cell, cylindrical, is a section of a long thread. Cell wall of cellulose. Chlorophyll band, flattened, coiled spirally around the inner side of the wall, colored green by the chlorophyll substance. Nucleus, granular, near centre of cell. Spirogyra Small nucleolus within nucleus. cell. Protoplasm proper (cytoplasm) radiating in strands rrotoplasm. \ from the nucleus ; thin wall layer next the cell wall. Cell-sap (watery substance) occupying the spaces between the strands of protoplasm. (Starch masses in the chlorophyll band.) The spirogyra thread is made up of many of these cells lying end to end. Reactions of protoplasm in spirogyra: Stains yellowish brown with iodine. A 1% aqueous solution of eosin does not stain the living protoplasm. Alcohol kills the protoplasm, so that eosin will then stain it. Materials. — Fresh mats of the pond-scum spirogyra, either freshly collected from ponds or ditches, or from an aquarium where it may be kept for a week or more in a fresh condition. A solution of iodine. A 1% aqueous solution of eosin. 95$ alcohol. Watch glasses for receiving the solutions when the pupils are engaged in exercises II. Microscope, etc. CHAPTER V. THE LIVING SUBSTANCE OF PLANTS— Concluded. III. Protoplasm in a Fungus : Mucor. Note. — Omit or read this chapter, or where there is time, if the teacher so desires, it may be studied in addition to spirogyra, or as an alternate if spiro- gyra cannot be obtained. Demonstration 8. 48. To obtain the black mould — If stock cultures of the black mould are not at hand it is well for the teacher to make some preparation several weeks beforehand for securing the mould for the cultures. To do this take an orange or lemon, cut in halves, and squeeze out the juice. Let it lie exposed in the room for a day. Then place this with some old bread in a moist chamber and set aside in a warm room for several days. In this time several moulds will appear. Some may have a blue color, others white, and some will probably become black. The black one is quite likely to be the black mould. New cultures of the black mould should now be made on fresh bread, or on the cut surface of baked potatoes. If they are made on potatoes the following method will answer; if on bread put the pieces in a moist chamber and sow the spores as described here for the potato cultures. Demonstration 9. 49. To make cultures of the black mould. — Take some freshly baked potatoes. Make a cut about i«ra deep entirely around them. Break them into halves and place these in moist chambers on damp paper with the cut surfaces uppermost. If a platinum needle which can be flamed is not at hand, take a dissecting needle, thrust it for a moment into strong alcohol. Hold it in the air until it is dry. Touch the moist surface of the potato with the needle, then touch the black heads of the fungus on the bread or fruit to catch some of the spores. Then touch the potato surface again, repeating this sev- eral times until spores have been put in a number of spots. Close the moist 24 THE LIVING SUBSTANCE OF PLANTS. 2-, chamber and set aside in a warm place. For several days observe the growth. First there appear small spots of delicate white threads. This tuft of threads increases in size, the threads elongate and branch. Demonstration lO. 50. To prepare the mycelium of the black mould for study of th^ proto- plasm. — These white threads of the mould are fungus threads. They are called the mycelium. The mycelium is the vegetative or growing portion of the mould, while the black heads are the fruiting portion. With a nee le carefully lift a small tuft of these threads grown in the moist chamber, place them in a drop of water on the glass slip and carefully tease them apart so that individual threads can be seen. Prepare for study under the microscope. When the microscope has been focussed on a suitable group of threads each pupil can then observe the things noted in paragraphs 51-53. 51. Mycelium of the black mould. — Under the microscope we see only a small portion of the branched threads. There is no chlorophyll as in spirogyra. This is one of the important characters of the group of plants to which the black mould belongs. In addition to the absence of chlorophyll, we see that the mycelium is not divided at short intervals into cells, but appears like a delicate tube with branches, which become successively smaller toward the ends. Fig. 11. Thread of mucor, showing protoplasm and vacuoles. 52. Appearance of the protoplasm. — Within the tube-like thread now note the protoplasm. It has the same general appearance as that which we noted in spirogyra. It is slimy, or semi-fluid, partly hyaline, and partly granular, the granules consisting of minute particles (the microtomes). While in 26 BOTANY. mucor the protoplasm has the same general appearance as in spirogyra, its arrangement is very different. In the first place it is plainly continuous throughout the tube. We do not see the prominent radiations of strands around a large nucleus, but still the protoplasm does not fill the interior of the threads. Here and there are rounded clear spaces termed vacuoles, which are filled with the watery fluid, cell-sap. The nuclei in mucor are very minute, and cannot be seen except after careful treat- ment with special reagents. 53. Movement of the protoplasm in mucor. — While examin- ing the protoplasm in mucor we are likely to note streaming movements. Often a current is seen flowing slowly down one side of the thread, and another flowing back on the other side, or it may all stream along in the same direction. Exercise 1 2. 54. Study of mycelium. — Use portions of the mould which have not become black. These portions are the mycelium, mats of the fine colorless threads. Note the color of the threads, the absence of chlorophyll. To test this place some of the threads in strong alcohol, let stand for some time. Does the alcohol become colored ? Take some fresh threads and place them in the iodine solution. Remove and rinse in water. What is the color ? Place fresh threads in some of the \% aqueous solution of eosin, and rinse in water. Do the threads hold the color? Now immerse the same threads in strong alcohol, then rinse in water, and place in the eosin solution for a moment. Rinse in water. Do the threads now hold the stain? Why? Write out a complete account of the experiments and observations. Exercise 1 3. 55. To obtain the mould from fruits. — This may be made a home exercise if preferred. It is well whenever possible to get the pupils to do some of the work of preparation. Let each pupil take half an orange or lemon, squeeze out the juice, and leave it exposed in his living room through the day. At night place it along with some pieces of bread in a glass tumbler, first putting a wet piece of paper in the bottom of the tumbler. Cover the vessel with a piece of glass. Keep in a warm room. Each day observe what appears, keeping notes, and describing the appearance of the mycelium. Observe if the black mould appears when the growth comes to fruit. THE LIVING SUBSTANCE OF PLANTS. 2? 56. Protoplasm occurs in the living parts of all plants. — The substance we have found in the alga spirogyra, in the root hairs of the corn seedling, in the threads of the black mould, is essentially alike in all. It may be arranged differently in the different plants, but its general appearance is the same. It moves quite rapidly in the cells of some plants, but so slowly in others that we may not see the movement. Yet when we treat the protoplasm with well-known reagents the reaction in general is the same. It has been found by the experience of different investigators that the substance in plants which shows these reactions under given conditions is protoplasm. We have demonstrated to our satisfaction then that we have seen protoplasm in the simple alga spirogyra, in the root hairs of the seedling, and in the threads of the black mould. If we chose to make sections of the stems and leaves of the seedling, or of the living parts of other higher plants, we should find that protoplasm is present in all these living cells. We then con- clude that protoplasm occurs in the living parts of all plants. 57. Summary of observations on protoplasm. — While we have by no means exhausted the study of protoplasm, we can, from this study, draw certain conclusions as to its occurrence and appearance in plants. Protoplasm is found in the living and growing parts of all plants. It is a semi-fluid, or slimy, granular, substance; in some plants, or parts of plants, the protoplasm exhibits a streaming or gliding movement of the granules. It is irritable. In the living condition it resists more or less for some time the absorption of certain coloring substances. The water may be withdrawn by glycerine. The protoplasm may be killed by alcohol. When treated with iodine it acquires a yellowish-brown color. Material. — Freshly formed mycelium of the common black mould (see demonstration 8, which also see for culture material and vessels). A solution of iodine. A l% aqueous solution of eosin. 95$ alcohol. Watch glasses to receive small quantities of the solutions when the pupils are engaged in exercise 12. Microscope, etc. CHAPTER VI. HOW WATER MOVES IN AND OUT OF PLANT CELLS. Absorption, Diffusion, Osmose. Demonstration 1 1 . 58. Osmose in spirogyra. — Mount a few threads of the alga spirogyra in a drop of the 5$ salt solution on a glass slip, and place on a cover glass for microscopic examination. Let each pupil examine the preparation to ob- serve the protoplasm contracted away from the cell wall. The protoplasmic layer contracts slowly from the cell wall, and the movement of the mem- brane can be watched by looking through the microscope. The membrane contracts in such a way that all the contents of the cell are finally collected into a rounded or oval mass which occupies the centre of the cell. Now add fresh water and draw off the salt solution. The protoplasmic membrane expands again, or moves out in all directions, and occupies its former position against the inner surface of the cell wall. This indicates that there is some pressure from within, while this process of absorption is going on, which causes the membrane to move out against the cell wall. The salt solution draws water from the cell-sap. There is thus a ten- dency to form a vacuum in the cell, and the pressure on the outside of the protoplasmic membrane causes it to move toward the centre of the cell. When the salt solution is removed and the thread of spirogyra is again bathed with water, the movement of the water is inward in the cell. This would suggest that there is some substance dissolved in the cell-sap which does not readily filter out through the membrane, but draws on the water outside. It is this which produces the pressure from within and crowds the membrane out against the cell wall again. 59. Turgescence. — Were it not for the resistance which the cell wall offers to the pressure from within, the delicate proto- plasmic membrane would stretch to such an extent that it would «8 WATEK IN PLANT CELLS. i 2 9 be ruptured, and the protoplasm therefore would be killed. If we examine the cells at the ends of the threads of spirogyra we will see in most cases that the cell wall at the free end is arGhed outward. This is brought about by the pressure from within upon the protoplasmic membrane which itself presses against the cell wall, and causes it to arch outward- This is beautifully Fig. 14. Spirogyra from salt solution into water. Tig. 12. Spirogyra before placing in salt solu- tion. Fig. 13. Spirogyra in 5$ salt solution shown in the case of threads which are recently broken. The cell wall is therefore elastic; it yields to a certain extent to the 3o BOTANY. pressure from within, but a point is soon reached beyond which it will not stretch, and an equilibrium then tends to be established between the pressure from within on the protoplas- mic membrane, and the pressure from without by the elastic cell wall. This state of a cell is turgescence, or such a cell is said to be turgescenl, or turgid. Demonstration 12. 60. Experiment to show diffusion through an animal membrane. — For this experiment use a thistle tube, across the larger end of which should be stretched and tied tightly a piece of bladder mem- brane. A strong sugar solution (three parts sugar to one part water) is now placed in the tube so that the bulb is filled and the liquid extends part way in the neck of the tube. This is immersed in water within a wide-mouth bottle, the neck of the tube being supported in a perforated cork in such a way that the sugar solution in the tube is on a level with the water in the bottle or jar. In a short while the liquid begins to rise in the thistle tube, in the course of several hours having risen several centimeters. The diffusion current is thus stronger through the membrane in the direction of the sugar solution, so that this gain? more water than it loses. 61 . How diffusion takes place. — We have here two liquids separated by an animal membrane, water on the one hand which diffuses readily through the membrane, while on the other is a solution of sugar which dif- fuses through the animal membrane with difficulty. The water, therefore, not contain- ing any solvent, according to a general law which has been found to obtain in such cases, diffuses more readily through the membrane into the sugar solution, which thus increases in volume, and also becomes more dilute. The bladder membrane is what is sometimes called a diffusion mem- brane, since the diffusion currents travel through it. In this ex- periment then the bulk of the sugar solution is increased, and the Fig. 15. WATER IN PLANT CBLLS. 3 J liquid rises in the tube by this pressure above the level of the water in the jar outside of the thistle tube. The diffusion of liquids through a membrane is osmosis. 62. Importance of these physical processes in plants. — Now if we recur to our experiment with spirogyra we find that exactly the same processes take place. The proptoplasmic membrane is the diffusion membrane, through which the diffusion takes place. The salt solution which is first used to bathe the threads of the plant is a stronger solution than that of the cell- sap within the cell. Water, therefore, is drawn out of the cell- sap, but the substances in solution in the cell-sap do not readily move out. As the bulk of the cell-sap diminishes the pressure from the outside pushes the protoplasmic membrane away from the wall. Now when we remove the salt solution and bathe the thread with water again, the cell-sap, being a solution of certain substances, diffuses with more difficulty than the water, and the diffusion current is inward, while the protoplasmic membrane moves out against the cell wall, and turgidity again results. Also in the experiments with salt on the tissues and cells of the beet (see exercise 14), the same processes take place. These experiments not only teach us that in the protoplasmic membrane, the cell wall, and the cell-sap of plants do we have structures which are capable of performing these physical processes, but they also show that these processes are of the utmost importance to the plant, in giving the plant the power to take up solutions of nutriment from the soil. Exercise 14. 63. To test the effect of a 5% salt solution on a portion of the tissues of a beet. — Select a red beet. Cut several slices about \cm in diameter and about $mm thick. Grasp the slices between the thumb and forefinger and attempt to bend them by light pressure. They are quite rigid and bend but little. Immerse a few of the slices in fresh water and a few in a 5$ salt solu- tion. In the course of an hour or less, examine the slices again. Those in the water remain as at first quite rigid, while those in the salt solution are more or less flaccid or limp. They readily bend by pressure between the fingers. The salt solution, we judge after our experiment with spirogyra, with- 32 BOTANY. draws some of the water from the cell-sap, the cells thus losing their turgid, ity and the tissues becoming limp or flaccid from the loss of water. 64. The beet slice becomes rigid again in water. — Now remove some of the slices of the beet from the salt solutions, wash them with water and then immerse them in fresh water. In the course of thirty minutes to one hour, if we examine them again, they will be found to have regained, partly or completely, their rigidity. Here again we infer from the former experiment with spirogyra that the substances in the cell-sap now draw water inward ; that is, the diffusion current is inward through the cell walls and the proto- plasmic membrane, and the tissue becomes turgid again. Exercise 1 5. 65. Turgor is lost when the protoplasm is dead. — Place some slices of a red beet in alcohol ; also some in hot water near the boiling point. Do the alcohol and the the hot water become colored ? Why ? Determine the condition of the Fig- 16. Fig. 17. Fig. 18. Rigid condition of fresh beet Limp condition after lying in Rigid again after lying section. salt solution, in water. Figs. 16-18. — Turgor and osmosis in slices of beet. slices by pressure between the fingers. Are they rigid or flaccid? Why? Place them now in fresh cold water. After a quarter of an hour or longer does any change take place as regards their resistance to pressure between the fingers ? What is the reason for their remaining in this condition? In what condition must protoplasm be in order to perform the work of a diffusion membrane ? Exercise 1 6. 66. Osmose experiments with leaves. — Take leaves of various plants, like the geranium, coleus, or seedlings of the squash, pea, or bean, etc. WATER IN PLANT CELLS. 33 Movement of water in a single cell. Immerse the leaves of some in water, and of another set in a 5$ salt solution. The petioles of the leaves should not be immersed, for it is desirable to keep the cut ends out of the water or salt solution. In fifteen minutes to half an hour, lift the leaves and seedlings from the water and note the result, and :ompare. Those which were in the salt solution now rinse in fresh water ind immerse for a time in water. Now note the result. Explain the results 3f this experiment from the results obtained in the previous experiments. Synopsis. ' A strong salt solution draws water out of the cell-sap, and the protoplasmic membrane is pushed inward. The cell becomes flabby. Remove the salt and surround the cell with water, and ^ the cell-sap draws water inside again, so that the pro- toplasmic membrane moves out and presses strongly against the cell wall and the cell becomes rigid ("turgid") again. The cell-sap then is a solution of certain salts. The beet slice is a cell mass, or a mass of tissue. Placed in salt solution some of the water is drawn out of the cell-sap of all the cells by the salt solution ; the mass of cells, or the slice, becomes flabby. { Placed in water it becomes rigid, or turgid, again. The action is the same as in the single cell, but all the cells act in concert. The action is the same with leaves, and other soft cell masses, or plant parts. When water and a salt, or sugar, solution are separated by an animal membrane, the current of water is stronger toward the salt, or sugar, solu- ;ion. The membrane holds back for a time the substance dissolved in the water. So the protoplasmic membrane acts in the same way when it sepa- rates two different liquids, where one is a stronger salt than the other, or where one is a salt and the other is water. When the protoplasm is killed it cannot act as a diffusion membrane. Material. — Fresh material of spirogyra. Fresh beets, dark red ones (winter-stored beets are good). Leafy shoots of some succulent plants, in a fresh condition, or seedlings. Common table salt, a. $% solution in water. 95$ alcohol, and hot water for exercise 15. Wide-mouth bottle, thistle tube, small piece of bladder membrane, and sugar, for demonstration 12. Microscope, etc. Movement of water in cell masses. CHAPTER VII. HOW PLANTS OBTAIN THEIR LIQUID FOOD. I. Water Cultures. 67. How constituents of plant food are determined. — We are now ready to inquire how plants obtain food from the soil or water. Chemical analysis shows that certain mineral sub- stances are common constituents of plants. By growing plants in different solutions of these various substances it has been possible to determine what ones are necessary constituents of plant food. While the proportion of the mineral elements which enter into the composition of plant food may vary con- siderably within certain limits, the concentration of the solutions should not exceed certain limits. A very useful solution is one recommended by Sachs, and is as follows : 68. Formula for solution of nutrient materials. — The pro- portions of the ingredients are here given. A larger quantity than iooocc may be needed. Water iooo cc. Potassium nitrate o. 5 gr. Sodium chloride 0.5 " Calcium sulphate 0.5 " Magnesium sulphate 0.5 " Calcium phosphate 0.5 " The calcium phosphate is only partly soluble. The solution which is not in use should be kept in a dark cool place to prevent the growth of minute algse. Demonstration 13. 69. To prepare the seedlings in water cultures. — Several different plants are useful for experiments in water cultures ; peas, corn, or beans are very 34 HOfV PLANTS OBTAIJV THEIR LIQUID FOOD. 35 good. The seeds of these plants may be germinated, after soaking them for several hours in warm water, by placing them between the folds of wet paper on shallow trays, or in the folds of wet cloth (see demonstration I). At the same time that the seeds are placed in damp paper or cloth for germination, one lot of the soaked seeds should be planted in good soil and kept under the same temperature conditions, for control. When the plants have germinated one series should be grown in distilled water, which possesses no plant food ; another in the nutrient solution, and still another in the nutrient solution to which has been added a few drops of a solution of iron chloride or ferrous sulphate. There would then be four series of cultures which should be carried out with the same kind of seed in each series so that the comparisons can be made on the same species under the different conditions. The series should be numbered and recorded as follows : No. I, soil. No. 2, distilled water. No. 3, nutrient solution. No. 4, nutrient solution with a few drops of iron solution added. 70. How to set up tj_e experiment. — Small jars or wide-mouth bottles, or crockery jars, can be used for the water cultures, and the cultures are set up as follows : A cork which will just fit in the mouth of the bottle, or which can be supported by pins, is perforated so that there is room to insert the seedling, with the root projecting below into the liquid. The seed can be fastened in position by inserting a pin through one side, if it is a large one, or in the case of small seeds a cloth of a coarse mesh can be tied over the mouth of the bottle instead of using the cork. After properly setting up the experiments the cultures should be arranged in a suitable place, and observed from time to time during several weeks. In -order to obtain more satisfactory results several duplicate series should be set up to guard against the error which might arise from variation in individual plants and from accident. Where there are several students in a class, a single series set up by several will act as checks upon one an- other. If glass jars are used for the liquid cultures they should be wrapped with black paper or cloth to exclude the light from the liquid, otherwise numerous minute algse are apt to grow and interfere with the experiment. If crockery jars are used they will not need covering. Fig. 19. Culture cylinder to show position of corn seedling (Hansen). 3 6 BOl^ANY. 71. Result of the experiment. — For some time all the plants grow equally well, until the nutriment stored in the seed is exhausted. The numbers I, 3 and 4, in soil and nutrient solutions, should outstrip number 2, the plants in the distilled water. No. 4 in the nutrient solution with iron, having a perfect food, compares favorably with the plants in the soil. Exercise 1 7. 72. Notes on the water cultures. — When the water cultures are set up the members of the class can take notes on them. Then from time to time for several months the plants should be inspected and the members of the class should keep a record of the results, and should not only compare the plants in Fig. 20. Fig. 21. Fig. 22. Fig. 23. In soil. Nutrient solu- Nutrient solu- In distilled tion with iron. t i o n without water, iron. Figures 20-23. — Comparison of growth of pumpkin seedlings, all started at the same time. the different jars, but should compare them with the plants growing in the soil which were planted at the same time. From these records let each pupil write a complete account of the experiment. II. How Plants obtain Food from the Soil. 73. Plants take liquid food from the soil. — From these experiments then we judge that such plants take up the food they receive from the soil in the form of a liquid, the elements being in solution in water. HOW PLANTS OBTAIN THEIR LIQUID FOOD. 37 If we recur now to the experiments which were performed with the salt solution on the cells of spirogyra, in the cells of the beet, and the way in which these cells become turgid again when the salt solution is removed and they are again bathed with water, we will have an indication of the way in which plants take up nutrient solutions of food material through their roots. It should be understood that food substances in solution during absorption diffuse through the protoplasmic membrane independently of each other and also independently of the rate of movement of the water from the soil into the root hairs and cells of the roots. When the cell-sap is poor in certain sub- stances which are dissolved in the surrounding water of the soil, these substances diffuse inwardly more rapidly. But as the cell-sap becomes richer in that particular food substance its further absorption is correspondingly diminished until the cell- sap becomes poorer again, as by diffusion this substance passes on into other cells. 74. How food solutions are carried into the plant. — We can see how the root hairs are able to take up solutions of plant food, and we must next turn our attention to the way in which these solutions are carried further into the plant. We should make a section across the root of a seedling in the region of the root hairs and examine it with the aid of a microscope. We here see that the root hairs are formed by the elongation of certain of the surface cells of the root. These cells elongate perpendicularly to the root, and become $mm to 6mm long. They are flexuous or irregular in outline and cylindrical, as shown in fig. 24. The end of the hair next the root fits in between the adjacent superficial cells of the root and joins closely to the next deeper layer of cells. In studying the section of the young root we see that the root is made up of cells which lie closely side by side, each with its wall, its protoplasm, and cell-sap, the protoplasmic membrane lying on ♦he inside of each cell wall. 33 BOTANY. Demonstration 1 4. 75. To ihow the relation of the root hairs to the other cells of the root. — The teacher can make thin sections of young roots, with a razor, through the region of the root hairs, and mount them for microscopic study for demon- Kig. 24. Section of corn root, showing rhizoids formed from elongated epidermal cells. stration before the class. Let each member of the class sketch a portion of the section, to show the root hairs, their relation to the other cells of the root, as well as some of the characters of the tissues of the root. 76. Action of the cell-sap. — In the absorption of the watery solutions of plant food by the root hairs, the cell-sap, being a more concentrated solution, gains some of the former, since the liquid of less concentration flows through the protoplasmic membrane into the more concentrated cell-sap, increasing the bulk of the latter. This makes the root hairs turgid, and at the same time dilutes the cell-sap so that the concentration is not so great. The cells of the root lying' inside and close to the base of HOW PLANTS OBTAIN THEIR LIQUID FOOD. 39 the root hairs have a cell-sap which is now more concentrated than the diluted cell-sap of the hairs, and consequently gain some of the food solutions from the latter, which tends to lessen the content of the root hairs and also to increase the concentration of the cell-sap of the same. This makes it possible for the root hairs to draw on the soil for more of the food solutions, and thus, by a variation in the concentration of the substances in solution in the cell-sap of the different cells, the food solutions are carried along until they reach the vascular bundles, through which the solutions are carried to distant parts of the plant. In this way a pressure is produced which causes the liquid to rise in the plant. 77. How the root hairs get the watery solutions from the soil. — If we examine the root hairs of a number of seedlings which are growing in the soil under normal conditions, we shall Fig. 25. Root hairs of corn seedling with soil particles adhering closely. see that a large quantity of soil readily clings to the roots. We should note also that unless the soil has been recently watered there is no free water in it; the soil is only moist. We are curious to know how plants can obtain water from soil which is not wet. If we attempt to wash off the soil from the roots, being careful not to break 4° BOTANY. away the root hairs, we find that small particles cling so tenaciously to the root hairs that they are not removed. Placing a few such root hairs under the microscope it appears as if here and there the root hairs were glued to the minute soil particles. In soil most suitable for the growth of land plants the water is not in excess. It is in the form of a thin film surrounding the soil particles. Some of the soil particles being "glued" to the root hairs, this portion of the water film is brought into close contact with the root hairs so that it can be absorbed. Plants cannot remove all the water from the soil. Note. — Some plant food is in solution in the water of the soil, but much of it is in an insoluble form (minute particles, or rocks, containing mineral substances), or in the form of organic matter (as leaves, stems, or other plant parts, or animal matter). The organic matter in the soil is in process of decay because certain microscopic fungi, and especially bacteria, feed upon it and change some of it into a form which can be taken up as food by the higher plant. The insoluble particles, containing mineral substances, are constantly being corroded by the action of certain acids, especially carbonic acid, which is constantly being formed in the soil. The walls of the root hairs are also saturated with this acid, and thus they are able to dissolve some of these mineral substances. This corroding action of the roots can be well shown by placing a small marble plate in a pot; then plant beans or peas on the plate, and cover with earth. In lieu of the marble plate the peas may be planted in clam, or oyster, shells, which are then buried in the soil of the pot, so that the roots from the seedlings will come in contact with the smooth surface of the shell, or of the marble if that is used. After the plants have been growing two or three weeks, remove the soil, and wash the surface of the marble or shell. Hold the surface now toward the window in such a way as to see the light reflected from the surface. The surface has been etched by the action of the roots. Demonstration 1 5 (or Exercise). 78. Plants can obtain water from soil which appears dry. — Use small pots with well-grown seedlings. Place the pots in a dry room. Supply no water to the soil. From day to day observe the condition of the soil, and feel of it to note the condition of dryness. Can plants live and grow in a soil which looks and feels dry ? When the plants have wilted remove them from the soil. Weigh the pot of soil. Then place it in an oven and bake it. Weigh again. Has it lost HOW PLANTS OBTAIN THEIR LIQUID FOOD. 41 weight ? Can plants remove all the moisture from the soil by absorption through their roots ? Demonstration 1 5a (or Exercise). 78a. To demonstrate the action of a root hair. — Take a long potato, cutoff the ends squarely, and bore a smooth hole from one end nearly through to the other end, being careful not to split the potato. Now pare off the sides to make a tube closed at one end. Rest the closed end in a vessel of water, as shown in fig. 25a, after having filled the tube with sugar. After five or six hours examine. The sugar inside of the potato tube draws water inward from the vessel, imitating the action of a root hair. Exercise 1 8. 79. Salt particles cling to root hairs.- ^ Potato J^'^al cavity con- Have at hand small pots of seedlings the taining sugar, standing in vessel of ., r .... t, it i- water. B, section of potato tube SOll of which IS not wet. Full, Or dig, up a showing cavity only partly filled with seedling. Observe the soil clinging to the su S ar - < After MacDougal.) roots. Agitate it to remove as much of the soil as possible. Wash the roots by rinsing in water. Are all the soil particles removed ? To what portions of the roots does most of the soil cling ? Why ? Compare with seedlings grown in a germinator free from soil. III. Strong Solutions of Plant Food are Injurious. Exercise 1 9 (or Demonstration). 80. To show the eftect on plants of food solutions which are too strong. — Potassium nitrate is one of the food substances used in the water cultures. It is also one of the necessary food substances from which nitrogen is obtained for the plant. Take strongly concentrated solutions, say a 5$, a io#, and a 20$ solution. Label three pots of seedlings to correspond with the solutions. Pour in enough of each solution to the corresponding pots to saturate the soil. In the course of three or four hours (or later) observe the result. Observe the condition of the stems at the surface of the ground. Explain the result in each case. Permit these to remain without watering for a day to see if they will revive. Pour in water and wash through to remove as much of the salt as possible. Set them aside for a day or two. Do they revive ? Why ? 42 BOTANY. 81. Food solutions which are too strong injure plants instead of benefiting them. — In figures 27 to 33 are shown the results of some experiments with strongly concentrated food solutions. In this case the food substance is potas- sium nitrate. Solutions of this salt of 2f , yfo, \of, and 20$ were prepared. Three pots of pumpkin seedlings were employed. In one the soil (which was already quite moist in all of the pots) was saturated with the 2$, one with the 10$, and the other with the 20$ solution. In a few hours the seedlings in pots 31 and 32 had collapsed, while those in pot 30 were still rigid. The salt in 31 and 32, being, even when diluted with the water in the soil, stronger than the salts in the cell-sap, withdrew water Pumpkin seedling removed from soil to show from the TOOt hairs, TOOtS, and earth clinging to roots. frQm tfae j ower part of thg stems, so that the plants lost their rigidity. The lower part of the stems was flabby. The plants were then photographed as shown in figures 30-32. Some of the 5$ solution was then added to pot 30. In four hours (at 6 p.m.) two of the seed- lings showed signs of collapse. On the following morning these two had collapsed, and the photograph of the result is shown in figure ^^. Synopsis. — Plants obtain their food either in a liquid or a gaseous form. Plants obtain their liquid food (mostly certain mineral and nitrogenous substances) by absorption. HOW PLANTS OBTAIN THEIR LIQUID FOOD. 43 Fig. 27. 2% solution potassium nitrate. Fig. 28. io# solution potassium nitrate. Fig. 29. ■zq'/c solution potassium nitrate. Figures 27-29. — Pumpkin seedlings, soil watered with solution of potassium nitrate of [ifferent strengths. Photographed immediately after the application of the solution to he soil. Fig. 30. 2% solution potassium Fig- 3i- 10% solution potassium Fig. 32. 20% solution potassium nitrate. nitrate. nitrate. Figures 30-32. — Pumpkin seedlings, soil watered with solution of potassium nitrate of different strengths. Photographed four hours after application of the solution to the soil. 44 BOTANY. Plants having a root system in comparatively dry ground absorb their liquid food through root hairs and roots. Aquatic plants (plants in water) absorb liquid food through nearly the entire surface in contact with the water. The plant food must be in a very dilute solution; a strong solution injures the plant, and, if too strong, will kill the plant, because by the law of diffusion the water in the plant is removed to such an extent that the plant becomes flabby, and if turgor is not restored, the plant will die. Soil which is not saturated with water, i.e., that which is only moist, or even which may seem dry, still contains water which forms a thin film (capillary film) around the soil particles. The root hairs become firmly fixed to certain of the soil particles and are thus brought in close contact with the water film which contains mineral and nitrogenous food in solution. This film is con tinuous from one soil particle to another in soil of the right texture and physical properties, and thus as the root hairs absorb that portion of the film in contact with them, by capil- larity the film draws more water through the soil from moist places. Materials:— Potassium nitrate, sodium chloride, calcium sulphate, mag- nesium sulphate, calcium phosphate, for nutrient solution as per paragraph 68. A larger amount of potassium nitrate (saltpetre) for exercise 19. Wide-mouth bottles, or small crockery jars, with perforated corks to fit, for the water culture. Seedlings started in a germinator. Seedlings, grown in pots, two or three weeks old, for exercises 17 and 18. One or more long potatoes ; sugar. Microscope, etc. Razor. Fig- 33- Pot in which the 2% solution was poured. After four hours a 556 solution of potassium ni- trate was added. This caused two of the seed- lings to collapse after about ten hours. Photo- graphed eighteen hours after last application. CHAPTER VIII. , HOW SOME PLANT PARTS REMAIN RIGID. 82. Turgidity of plant parts. — In Chapter VI we found that ;he turgescence of a cell depends on the absorption of water by Fig. 34. F'g- 35- ndian turnip plant just removed from the Same plant half an hour later. It is be- soil. It is rigid. coming limp. Drotoplasm. The protoplasm permits the cell-sap to draw the ivater inward by diffusion, but the protoplasmic membrane does lot permit the water to filter out readily, and the outward pressure 45 4 6 BOTANY. of the protoplasm on the elastic cell wall makes the cell turgid. So we found in the experiments with the slices of beet in the salt solution and water that the partial removal of the water from the beet leaves the slices limp, while they regain their rigidity if the salt solution is removed and the slices are placed in water. We should now endeavor to see if water plays any part in the rigidity of plant parts, as in the case of shoots, leaves, etc., and in what way this rigidity may be lost and regained. Exercise 20. 83. Loss of turgidity in out shoots. — From a living geranium, balsam, coleus, or other plant, cut a leafy shoot i§cm to 20cm long. Leave it in a dry room for a short while until it partly wilts. Grasp the shoot at the cut end and attempt to hold it erect. How does it now compare with its condition when first cut from the plant ? 84. Restoration of turgidity in shoots. — Take the leafy shoot used in paragraph 83. (It should not be so wilted that any portion of it is dry.) Cut the, end fresh again and place it in a vessel of water, and if the room is dry, cover the vessel and shoot with '"'::_ a tall glass cylinder or bell jar. Observe the result in a few hours, or on the following day. 85. Longitudinal tissue tension. — For this in early summer one may use the young and succulent shoots of the elder (sambucus) ; or the petioles of rhubarb during the summer and early autumn ; or the petioles of richardia. Petioles of caladium are Fig. 36. Same plant photographed four hours late has revived. BOW SOME PLANT PA UTS REMAIN RIGID. 47 excellent for this purpose, and these may be had at almost any season of the year from the greenhouses, and are thus especially advantageous for work during late autumn or winter. The tension is so strong that a portion of such a petiole 10- i ^cm long is ample to demon- strate it. As we grasp the lower end of the petiole of a caladium, or rhubarb leaf, we observe how rigid it is, and how well it sup- ports the heavy expanded lam- ina of the leaf. Exercise 21 . 86. To demonstrate the tissue ten- sion. — Take a portion of the petiole of a caladium, or of celery, or other plant, about 15OTZ long. Cut the ends off squarely. With a knife strip off a layer from the outside about 2-ynm in thick- „. „. „ _. Fig. 37. Fig. 38. Fig. 39. ness, and the full length of the piece. Centre of Outside Outside strip Now attempt to replace it, comparing the petiole. strip. attached to length of each part. Remove another Figures 37-39. Showing longitudinal strip lying next this one, and so on tissue tension, until all the outer portion has been removed. Describe what takes place as the successive strips are removed. When all are removed, compare an outside strip with the central portion. What has happened ? Is there now a greater difference in length between the outside strip and the central portion ? What is the cause of this ? Describe the tensions in the outside and inner portion of the petiole. Cut a section of the petiole about 8cm long, remove strips on two opposite sides and split the remainder down the middle, securing two pieces with the center and outside portion attached. Place one of these in fresh water and the other in a 5 per cent salt solution and note the result. If convenient treat celery petioles in the same way. The flower stems of dandelions split into quarters are .excellent objects to compare when placed in water, and in a 5 per cent salt solution. 4 8 BOTANY. Exercise 22. 87. Transverse tissue tension. — To show this take a willow shoot 3-5«rc in diameter and saw off sections about 2cm long. Cut through the bark on one side, and peel off the bark in one piece carefully. Now attempt to re- place it. What has happened ? Describe the tension. Demonstration 16. 88. Importance of tissue tension. — To demonstrate the efficiency of this tension in giving support, let us take a long petiole of caladium or of rhubarb. Hold it by one end in a hori- zontal position. It is firm and rigid, and does not droop, or but little. Re- move all of the outer portion of the tissues, as described above, leaving only the central portion. Now attempt to hold it in a horizon- tal position by one end. It is flabby and Fig. 40. S' B \ droops down- Caladium leaf petiole rigid from longitudi- nal tensions. ward because the longitudinal ten- sion is removed. (See figs. 40, 41.) Synopsis. — When plants are re- moved from the soil, or plant parts are removed from the shoot, they soon become flabby and limp. Fig. 41. When these partly wilted plants Same leaf, longitudinal tension partly removed are placed with the stems in water, h ? the loss of two °««ide strips, they may become rigid again by the absorption of water and the restora- tion of the rigidity of the cells. HOW SOME PLANT PARTS REMAIN RIGID. 49 Longitudinal tissue tension. Succulent stems and petioles are often kept rigid be- cause of a pull, or tension, of different layers of cells in opposite directions. The outer layers of cells tend to shorten, while the inner cells tend to lengthen. These opposite tensions, or pulls, make the shoot rigid. The cells of the shoots must be turgid with water or the tension is not present. Transverse tissue ( This occurs where the outer layers of tissue are tension. ( stretched transversely instead of longitudinally. Material. — If fresh plants cannot be obtained out-doors, use leafy shoots of rather succulent plants from the green-house, like the coleus plant, garden balsam, or leaves with long petioles like the caladium of the green- house, or stored celery. The shoots should not be cut from the plant until the pupil is ready to begin the exercise. Wide-mouthed bottles, filled with water, and if necessary some bell jars (one large bell jar will answer for several students). CHAPTER IX. HOW WATER MOVES THROUGH THE PLANT. I. Root Pressure, or Osmotic Pressure. 89. Flow of water from pruned vines. — It is a very common thing to note, when certain shrubs or vines are pruned in the spring, the exudation of a watery fluid from the cut surfaces. In the case of the grape vine this has been known to continue for a number of days, and in some cases the amount of liquid, called " sap," which escapes is considerable. In many cases it is directly traceable to the activity of the roots, or root hairs, in the absorption of water from the soil. For this reason the term root pressure is used to denote the force exerted in supply- ing the water from the soil. 90. Root pressure may be measured. — It is possible to measure not only the amount of water which the roots will raise in a given time, but also to measure the force exerted by the roots during root pressure. It has been found that root pressure in the case of the nettle is sufficient to hold a column of water about 4.5 meters (15 ft.) high (Vines), while the root pressure of the vine (Hales, 1721) will hold a column of water about 10 meters (36.5 ft.) high, and the birch (Betula lutea) (Clark, 1873) has a root pressure sufficient to hold a column of water about 25 meters (84.7 ft.) high. Demonstration 1 7. 91. To demonstrate root pressure. — Use a potted begonia or balsam, the latter being especially useful. The plants are usually convenient to obtain from the greenhouses, to illustrate this phenomenon. Cut off rather close to 5° HOW WATER MOVES THROUGH THE PLANT. 5 1 u e soil and attach a long glass tube to the cut end of the stem, still con- :cted with the roots, by the use of rubber tubing as shown in figure 42. A :ry small quantity of water may be poured in to mois- n the cut end of the stem. In a few minutes the water :gins to rise in the glass tube. In some cases it rises lite rapidly, so that the column of water can readily ; seen to extend higher and higher up in the tube hen observed at quite short intervals. The height : this column of water is a measure of the force exerted f the roots. The pressure force of the roots may be easured also by determining the height to which it ill raise a column of mercury. Exercise 23. 92. To make records of the experiment. — The pupils in take notes on the experiment at the time it is set up. hen for several days let them keep a record of the :ight of the liquid in the tube, taken at several times day if possible. 93. Variation in root pressure, — In either ise where the experiment is continued for :veral days it is noticed that the column of water or of mercury ses and falls at different times during the same day, that is, the ilumn stands at varying heights; or in other words the root ressure varies during the day. With some plants it has been mnd that the pressure is greatest at certain times of the day, or at attain seasons of the year. Such variation of root pressure ex- ibits what is termed a periodicity, and in the case of some plants tere is a daily periodicity; while in others there is in addition an inual periodicity. With the grape vine the root pressure is ■eatest in the forenoon, and decreases from 12-6 p.m., while ith the sunflower it is greatest before 10 a.m. , when it begins to gcrease. Temperature of the soil is one of the most important eternal conditions affecting the activity of root pressure. Fig. 43. Experiment to show root pressure. (Detmer.) II. The Loss or Water by Plants (Transpiration). 94. Wilting of cut shoots. — We should now inquire if all the ater which is taken up in excess of that which actually suffices 52 &OTANY. for turgidity is used in plant growth and in the increase of plant substance. We notice when a leaf or shoot is cut away from a plant, unless it is kept in quite a moist condition, or in a damp, cool place, that it becomes flaccid, and droops. It wilts, as we say. The leaves and shoot lose their turgidity. This fact suggests that there has been a loss of water from the shoot or leaf. It can be readily seen that this loss is not in the form of drops of water which issue from the cut end of the shoot or petiole. What then becomes of the water in the cut leaf or shoot ? Exercise 24. 95. Loss of water from excised leaves. — Take a handful of fresh, green, rather succulent leaves, which are free from water on the surface, and place them under a 'glass bell jar, which is tightly closed below but which contains Fig- 43- Leafy shoots just covered with dry bell jar. Fig. 44. The same after four hours ; mist shows on inside of jar. Figures 43, 44. — Experiment to show transpiration from leaves on cut shoots. no water. Place this in a brightly lighted window, or in sunlight. In the course of fifteen to thirty minutes notice that a thin film of moisture is ac- cumulating on the inner surface of the glass jar. After an hour or more the moisture has accumulated so that it appears in the form of small drops of condensed water. . Set up at the same time a bell jar in exactly the same way but which contains no leaves. In this jar there will be no condensed moisture on the inner surface. We thus are justified in concluding that the moisture in the former jar comes from the leaves. Since there is no visible HOW WATER MOVES THROUGH THE PLANT. S3 'ater on the surfaces of the leaves, or at the cut ends, before it may have ondensed there, we infer that the water escapes from the leaves in the form f water -vapor, and that this water vapor, when it comes in contact with the Fig. 45. Fig. 46. Leaves removed to show drops of water Photographed after the water has been on inside of jar. wiped from inside of jar. lrface of the cold glass, condenses and forms the moisture film, and later le drops of water. The leaves of these cut shoots therefore lose water in le form of water vapor, and thus a loss of turgidity results. Demonstration 18. 96. Loss of water from growing plants. — Suppose we now take a small nd actively growing plant in a pot, and cover the pot and the soil with a leet of rubber cloth which fits tightly around the stem of the plant (or the ot and soil may be enclosed in a hermetically sealed vessel) so that le moisture from the soil cannot escape. Then place a bell jar over the lant, and set in a. brightly lighted place, at a temperature suitable for rowth. In the course of a few minutes on a dry day a moisture film forms 1 the inner surface of the glass, just as it did in the case of the glass jar mtaining the cut shoots and leaves. Later the moisture has condensed so lat it is in the form of drops. If we have the same leaf surface here as we id with the cut shoots, we will probably find that a larger amount of ater accumulates on the surface of the jar from the plant that is still at- ched to its roots. 97. Water escapes from the surfaces of living leaves in the irm of water vapor. — This living plant then has lost water, hich also escapes in the form of water vapor. Since here there 54 BOTANY. are no cut places on the shoots or leaves, we infer that the loss of water vapor takes place from the surfaces of the leaves and from the shoots. It is also to be noted that, while this plant is losing water from the surfaces of the leaves, it does not wilt or lose its turgidity. The roots by their activity and osmotic pressure supply water to take the place of that which is given off in the form of water vapor. This loss of water in the form of water vapor by plants is transpiration. Synopsis. As a result of the law of diffusion by which water from the soil is drawn inside the root hairs forcibly by the cell- sap, and is passed on through the cells of the root by the same law of diffusion, a pressure occurs which causes the liquid plant food to rise to some extent in the roots and stems of plants. The height to which water can be lifted by root pressure varies in different plants. Root pressure is not constant throughout the day in a given plant, but varies. Root pressure is usually lower at night and higher toward midday. Plants then show a daily periodicity in the strength of the root pressure, but the periods are not coincident in all plants ; that is, the time of day when one plant shows the greatest root pressure is not necessarily the same for another plant. Some plants also show an annua! periodicity in the strength of the root pressure. , Living plants are constantly losing water by evaporation (or transpiration) from the surface, unless the air is sat- urated with moisture. If plants are removed from the soil, or shoots are cut away, they "wilt," or become flabby, because of the loss of water. This loss of water from plants, or plant parts, can be dem- onstrated by placing the plant under a glass receiver. The water escapes in the form of invisible water vapor. When the plant is growing normally, the roots by absorp- tion of water from the soil supply water to take the place of that evaporated from the exposed plant surface. Root pressure or osmotic pressure. Transpiration. HOW WATER MOVES THROUGH THE PLANT. 55 Material For root pressure : One or more potted plants like a begonia, garden balsam, etc. A long glass tube about the same diameter as that of the plant stem ; some rubber tubing to connect the glass with the stem, and to connect sections of tubing if necessary. For transpiration : Some succulent leaves and leafy shoots, like gera- nium, coleus, balsam, etc. Some small glass bell jars. A potted coleus plant (or balsam), some sheet rubber to cover the pot and earth closely, and a bell jar to cover the plant. CHAPTER X. HOW WATER MOVES THROUGH THE PLANT— Concluded. III. Part which the Leaf plays in Transpiration. Demonstration 1 9. 98. Structure of a leaf. — We are now led to inquire why it is that a living leaf loses water less rapidly than dead ones, and why less water escapes from a given leaf surface than from an equal surface of water. To understand this it will be necessary to examine the minute structure of a leaf. For this purpose we will select the leaf of an ivy, though many other leaves will answer equally well. From a por- tion of the leaf we should make very thin cross-sections with a razor or other sharp in- strument. These sections should be perpen- dicular to the surface of the leaf, and should be then mounted in water for microscopic examination. * Let the pupils examine the preparations and make sketches of the structure of the leaf, naming the different kinds of cells, and de- scribing the function of the different groups of cells. (See paragraphs 99-101.) 99. Epidermis of the leaf. — In this Fig. 47. . , , Section through ivy leaf show- section we see that the green part of ing communication between sto- , , . . , , mate and the large intercellular the leat is bordered on what are its spaces of the leaf ; stoma closed. upper and lower surfaces by a row of cells which possess no green color. The walls of the cells of each row have nearly parallel sides, and the cross walls are perpendicular. These cells form a single layer over both sur- * Demonstrations may be made with prepared sections of leaves. 56 HOW WATER MOVES THROUGH THE PLANT. 57 Fig. 48. Fig 49. Stoma open. Stoma closed. Figures 48, 49. - Section through stomata of ivy leaf. faces of the leaf and are termed the epidermis. Their walls are quite stout and the outer walls are culicularized. 100. Soft tissue of the leaf. — The cells which contain the green chlorophyll bodies are arranged in two different ways. Those on the upper side of the leaf are usually long and pris- matic in form and lie closely parallel to each other. Because of this arrangement of these cells they are termed • the palisade cells, and form what is called the palisade layer. The other green cells, lying below, vary greatly in size in different plants and to some extent also in the same plant. Here we notice that they are elongated, or oval, or somewhat irregular in form. The most striking peculiarity, however, in their arrange- ment is that they are not usually packed closely together, but each cell touches the other adjacent cells only at certain points. This arrangement of these cells forms quite large spaces between them, the intercellular spaces. If w e should examine such a sec- tion of a leaf before it is mounted in water we Portion of epidermis of ivy, showing irregular epidermal cells, stoma WOUlQ See and guard cells. , , . , , that the in- tercellular spaces are not filled with water or cell-sap, but are filled with air or some gas. Within the cells, on the other hand, we find the cell-sap and the protoplasm. Fig. 50. 58 BOTANY. 101. Stomata. — If we examine carefully the row of epidermal cells on the under surface of the leaf, we will find here and there a peculiar arrangement of cells shown at figs. 47-49. This opening through the epidermal layer is a stoma. The cells which immediately surround the openings are the guard cells. The form of the guard cells can be better seen if we tear a leaf in such a way as to strip off a short piece of the lower epidermis, and mount this in water. The guard cells are nearly crescent shaped, and the stoma is elliptical in outline. The epidermal cells are very irregular in outline in this view. We should also note that while the epidermal cells contain no chlorophyll, the guard cells do. 102. The living protoplasm retards the evaporation of water from the leaf. — If we now take into consideration a few facts which we have learned in a previous chapter, with refer- ence to the physical properties of the living cell, we will be able to give a partial explanation of the comparative slowness with which the water escapes from the leaves. The inner surfaces of the cell walls are lined with the membrane of protoplasm, and within this is the cell-sap. These cells have become turgid by the absorption of the water which has passed up to them from the roots. While the protoplasmic membrane of the cells does not readily permit the water to filter through, yet it is saturated with water, and the elastic cell wall with which it is in contact is also saturated. From the cell wall the water evaporates into the intercellular spaces. But the water is given up slowly through the protoplasmic membrane so that the water vapor cannot be given off as rapidly from the cell walls as it could if the protoplasm were dead. The living protoplasmic membrane then, which is only slowly permeable to the water of the cell- sap, is here a very important factor in checking the too rapid loss of water from the leaves. 103. Communication through intercellular spaces. — By an examination of our leaf section we see that the intercellular HOW WATER MOVES THROUGH THE PLANT. 59 spaces are all connected, and that the stomata, where they occur, open also into intercellular spaces. There is here an opportunity for the water vapor in the intercellular spaces to escape when the stomata are open. 104. Action of the stomata. — Besides permitting the escape of the water vapor when the stomata are open they serve a very important office in regulating the amount of transpiration. During normal transpiration the stomata remain open, that is, when the amount of transpiration from the leaf is not in excess of the supply of water to the leaves. But when the transpiration from the leaves is in excess, as often happens, and the air becomes very dry, the stomata close, and thus the rapid trans- piration is checked. For further discussion of transpiration and root pressure see the author's larger " Elementary Botany." Synopiis. Structure of a leaf (cross-section). Epidermis. The epidermal cells usually lack chloro- phyll. Upper epidermis, a layer of cells over the upper surface of the leaf. Lower epidermis, a layer of cells over the lower surface of the leaf. Guard cells of the stomates (openings in the epidermis) contain chlorophyll. (Hairs of various kinds on different leaves are often present: see synopsis of tissues at close of Chapter XL) Mesophyll (the cells of the leaf between the upper and lower epidermis) 1. Palisade layer o£ cells, usually next the upper epidermis. Contains chlorophyll. 2. Loose parenchyma cells, with large inter- cellular spaces where the air and water vapor can circulate. Cells contain chloro- phyll. (Vascular bundles are present in the "veins'' oi the leaf : see Chapter XI.) 6o BOTANY. Function of the leaf in transpiration. The living protoplasm retards the evaporation of water somewhat from the cells. The water escapes from the cells of the middle part of the leaf into the intercellular spaces. From here it passes out through the openings (sto- mates). When transpiration is in excess of root pressure, the guard cells close together and shut the open- ing, and thus greatly retard the loss of water. The cuticle, a thin deposit on the outer surface of the epidermal cells, also retards more or less transpiration. Material. — Fresh leaves of some plant like begonia, ivy, or other leaf which is easy to section. Where preferred, permanently mounted slides of sections of leaves may be used. CHAPTER XL V PATH OF MOVEMENT OF LIQUIDS IN PLANTS. 105. Course of the liquids through the stems. — In our study of root pressure and transpiration we have seen that large quan- tities of water or solutions move upward through the stems of plants. We are now led to inquire through what part of the stems the liquid passes in this upward movement, or in other words, what is the path of the " sap " as it rises in the stem. This we can readily see by the following trial. Demonstration 20. 106. To show the tracts through which the liquids rise. — Cut off leafy shoots of various plants and insert the cut ends in a vessel of water to which has been added a few crystals of the dye known as fuchsin to make a deep red color (other red dyes may be used, but this one is especially good). If the study is made during the summer, the "touch-me-not" (impatiens) will be found a very useful plant, or the garden balsam, which may also be had in the winter from conservatories. Almost any plant will do, however, but we should also select one like the corn plant (Zea mays) if in the summer. 107. These solutions color the tracts in the stem and leaves through which they flow. — After a few hours in the case of the impatiens, or the more tender plants, we can see through the stem that certain tracts are colored red by the solution, and after 12 to 24 hours there may be seen a red coloration of the leaves of some of the plants used. After the shoots have been standing in the solution for a few hours, if we cut them at various places we shall note that there are several points in the section where the tissues are colored red. In the impatiens 61 62 BOTANY. perhaps from four to five, in the sunflower a larger number. In these plants the colored areas on a cross-section of the stem are situated in a concentric ring which separates more or less completely an outer ring of the stem from the central portion. If we now split portions of the stem lengthwise we see that these colored areas continue throughout the length of the stem, in some cases even up to the leaves and into them. 108. Arrangement of the tracts in the corn stalk. — If we cut across the stem of a corn plant which has been in the solu- Fig. 51. Broken corn stalk, showing fibro-vascular bundles. tion, we see that instead of the colored areas being in a con- centric ring they are irregularly scattered, and on splitting the stem we see here also that these colored areas extend for long distances through the stem. Exercise 25. 109. To demonstrate the tracts in stems and petioles. — Take leaves of a calla lily, or of a caladium, which grow in conservatories, and good leaves of stored celery, with long petioles. Other leafy shoots which are more accessible may be used, if desired. Place the ends of the petioles, or the shoots, in a solution of fuchsin, or in red ink. in the course of an hour (they may be left in a longer time if necessary) observe the petioles and leaves. Can any of the color be seen without cutting into the stem ? (Where the PART OF MOVEMENT OF LIQUIDS IN PLANTS. 63 shoots remain in the colored liquid for a day, or even for a less time, portions of the leaves will show the color.) Cut across the stems, and describe the location of the colored areas. Split the petioles or stems and trace the colored tracts. Compare their location in the calla and the celery petiole. 110. To observe the texture of these areas in a celery petiole. — Take fresh but rather old celery leaves (from stored celery if in the winter). Break the petiole apart. Is the broken part ragged ? Is there any difference in the texture or toughness of the petiole shown by any portions " stringing " out ? Describe the location of these strands. What are they ? Have they any re- lation to the colored areas or tracts in the petiole which was in the red ink ? Break apart in a similar way a petiole which has been in the red ink. Compare. The celery represents a dicotyledenous plant. 111. The strands in a dead corn stalk. — Take a dead corn stalk (they are easily obtained in the autumn or winter from the fields). Cut through the outer harder portion of the stem. Break it. Compare carefully with the broken celery petiole. The corn stem represents a monocotyledonous plant. 112. There are definite courses through which the liquids rise. — We thus see that instead of the liquids passing through the entire stem they are confined to definite courses. Now that we have discovered the path of the upward movement of water in the stem, we are curious to see what the structure of these definite portions of the stem is. Demonstration 21. 113. Structure of the fibrovascular bundle. — Make quite thin cross-sec- tions of the stem it is desired to study, and mount in water for microscopic examination. Permanent mounts may be made in Canada balsam by those who understand the method. Or mounted preparations may be obtained, which will preserve for future use. Let each pupil examine cross and longi- tudinal sections of a dicotyledon and of a monocotyledon, making out clearly the different groups of tissues, and the kinds of cells composing them. Paragraphs 114-123 may be used as a guide. The description is here made from the castor-oil bean, and the illustration from the sunflower to represent the dicotyledon, while the corn stem is used to illustrate the monocotyledon. It will be no disadvantage for the teacher to use other plants than those em- ployed here for the demonstration. 114. The bundles in a dicotyledon.— To illustrate the structure of the bundle in one type we may take the stem of the castor-oil bean. On examin- ing these cross-sections we see that there are groups of cells which are denser than the ground tissue. These groups correspond to the colored areas in the former experiments, and are the vascular bundles cut across. These groups 6 4 BOTANY. are somewhat oval in outline, with the pointed end directed toward the centre of the stem. If we look at the section as a whole we see that there is a nar- Fig. 52. Xylem portion of bundle. Cambium portion of bundle. East portion of bundle. Section of vascular bundle of sunflower stem, row continuous ring * of small cells situated at the same distance from the centre of the stem as the middle part of the bundles, and that it divides the bundles into two groups of cells. 115. Woody portion of the bundle. — In that portion of the bundle on the inside of the ring, i.e., toward the "pith," we note large, circular, or angu- lar cavities. The walls of these cells are quite thick and woody. They are therefore called wood cells, and because they are continuous with cells above and below them in the stem in such a way that long tubes are formed, they are called woody vessels. Mixed in with these are smaller cells, some of which also have thick walls and are wood cells. Some of these cells may have thin walls. This is the case with all when they are young, and they are then classed with the fundamental tissue or soft tissue (parenchyma). This part of the bundle, since it contains woody vessels and fibres, is the wood portion of the bundle, or technically the xylem. * This ring and the bundles separate the stem into two regions, an outer one composed of large cells with thin walls, known as the cortical cells, or collectively the cortex. The inn"r portion, corresponding to what is called the pith, is made up of the same kind of cells and is called the medulla, or pilk. When the cells of the cortex, as well as of the pith, remain thin-walled the tissue is called parenchyma. Parenchyma belongs to the group of tis- sues called fundamental. PART OF MOVEMENT OF LIQUIDS IN PLANTS. 65 116. Bast portion of the bundle. — If our section is through a part of the stem which is not too young, the tissues of the outer part of the bundle will show either one or several groups of cells which have white and shiny walls, that are thickened as much or more than those of the wood vessels. These cells are bast cells, and for this reason this part of the bundle is the bast portion, or the phloem. Intermingled with these, cells may often be found which have thin walls, unless the bundle is very old. Nearer the centre of the bundle and stil^within the bast portion are cells with thin walls, angular and irregularly arranged. This is the softer portion of the bast, and some of these cells are what are called sieve tubes, which can be better seen and studied in a longitudinal section of the stem. 117. Cambium region of the bundle. — Extending across the centre of the bundle are several rows of small cells, the smallest of the bundle, and we can see that they are more regularly arranged, usually in quite regular rows, like bricks piled upon one another. These cells have thinner walls than any others of the bundle, and they usually take a deeper stain when treated with a solution of some of the dyes. This is because they are younger, and are therefore richer in protoplasmic contents. This zone of young cells across the bundle is the cambium. Its cells grow and divide, and thus in- crease the size of the bundle. By this increase in the number of the cells of the cambium layer, the outermost cells on either side are continually passing over into the phloem, on the one hand, and into the wood portion of the bundle, on the other hand. 118. Longitudinal section of the bundle. — If we make thin longisections of the vascular bundle of the castor-oil seedling (or other dicotyledon) so that we have thin ones running through a bundle radially, as shown in fig. 53, we can see the structure of these parts of the bundle in side view. We see here that the form of the cells is very different from what is presented in a cross-section of the same. The walls of the various ducts have peculiar markings on them. These markings are caused by the walls being thicker in some places than in others, and this thickening takes place so regularly in some instances as to form regular spiral thickenings. Others have the thick- enings in the form of the rounds of a ladder, while still others have pitted walls or the thickenings are in the form of rings. 119. Vessels or ducts. — One way in which the cells in side view differ greatly from an end view, in a cross-section in the bundle, is that they are much longer in the direction of the axis of the stem. The cells have become elongated greatly. If we search for the place where two of these large cells with spiral, or ladder-like, markings meet end to end, we shall see that the wall which formerly separated the cells has nearly or quite disappeared. In other words the two cells have now an open communication at the ends. This is so for long distances in the stem, so that long columns of these large 66 BOTANY. cells form tubes or vessels through which the water rises in the stems of plants. 120. Bast fibres. — In the bast portion of the bundle we detect the cells of the bast fibres by their thick walls. They are very much elongated and the .*"«• S3- Longitudinal section of vascular bundle of sunflower stem; spiral, scalariform and pitted vessels at left; next are wood libers with oblique cross walls; in middle are cambium cells with straight cross walls, next two sieve tubes, then phloem or bast cells. ends taper out to thin points so that they overlap. In this way they serve to strengthen the stem. 121. Sieve tubes. — Lying near the bast cells, usually toward the cambium, are elongated cells standing end to end, with delicate markings on their cross- walls which appear like finely punctured plates or sieves. The protoplasm in such cells is usually quite distinct, and sometimes contracted away from the side walls, but attached to the cross-walls, and this aids in the detection of the sieve tubes (fig. 53). The granular appearance which these plates present is caused by minute perforations through the wall so that there is a communication between the cells. The tubes thus formed are there- fore called sieve tubes, and they extend for long distances through the bundle so that there is communication throughout the entire length of the stem. (The function of the sieve tubes is supposed to be that for the down- ward transportation of substances elaborated in the leaves. ) 122. Bundle in the sunflower stem. — In like manner a section of the stem of the sunflower shows similar bundles, but the number is greater than eight. In the garden balsam the number is from four to six in an ordinary stem 3-4*k/» diameter. Here we can see quite well the origin of the vascular bundle. Between the larger bundles especially in free-hand sections of stems PART OF MOVEMENT Of LIQUIDS IN PLANTS. 67 irough which a colored solution has been lifted by transpiration, we can le small groups of the minute cells in the cambial ring which are col- red. These groups of cells which form strands running through the stem are rocambium strands. The cells divide and increase just like the cambium :11s, and the older ones thrown off on either side change, those toward the :ntre of the stem to wood vessels and fibres, and those on the outer side to ast cells and sieve tubes. 123. Fibrovascular bundles in the Indian corn. — In fig. 54 is repre- ssed a. fibrovascular bundle of the stem of the Indian corn. The large :11s are those of the spiral and reticulated id -annular vessels. This is the woody artion of the bundle, or xylem. Oppo- te. this is the bast portion or phloem, arked by the lighter colored tissue at i. he larger of these cells are the sieve bes, and intermingled with them are nailer cells with thin walls. Surround- g the entire bundle are small cells with ick walls. These are elongated and the pering ends overlap. They are thus :nder and long and form fibres. In eh a bundle all of the cambium has .ssed over into permanent tissue and the indie is said to be closed. 124. Rise of water in the vessels. — uring the movement of the water or Fig- 54- Transection of fibrovascular bundle of Indian corn, a, toward periphery of stem ; g-, large pitted vessels ; j, spiral Ltrient solutions upward in the stem the vessel ; r, annular vessel ; /, air cavity . r ,. , ,. j. . . formed by breaking apart of the cells; ssels of the wood portion of the bundle i, so ft bast, a form of sieve tissue ; p, certain plants are nearly or quite filled, ^in-walled parenchyma. (Sachs.) root pressure is active and transpiration is not very rapid. If, however, on y days transpiration is in excess of root pressure, as often happens, the ssels are not filled with the water, but are partly filled with certain gases cause the air or other gases in the plant become rarefied as a result of the cessive loss of water. There are then successive rows of air or gas bub- ;s in the vessels separated by films of water which also line the walls of ; vessels. The condition of the vessel is much like that of a glass tube rough which one might pass the " froth" which is formed on the surface soapy water. This forms a chain of bubbles in the vessels. This chain s been called Jamin's chain because of the discoverer. 125. Rise of water in the bundles is not we'l understood. — Why water or id solutions can be raised by the plant to the height attained by some trees s never been satisfactorily explained. There are several theories pro- 68 BOTANY. Epidermal system. Trichomes (hairs). Xylem. pounded which cannot be discussed here. It is probably a very complex process. Root pressure and transpiration both play a part, or at least can be shown, as we have seen, to be capable of lifting water to a considerable height. 126. Synopsis of tissues. Epidermis. Simple hairs. Many-celled hairs. Branched hairs, often stellate. Clustered, tufted hairs. Glandular hairs. . Root hairs. Guard cells of stomates. Spiral vessels. Pitted vessels. Scalariform vessels. Annular vessels. Wood fibres. . Wood parenchyma. Cambium (fascicular). f Sieve tubes. Phloem. \ Bast fibres. [_ Bast parenchyma. Cork. Parenchyma. Ground tissue. Interfascicular cambium. Medullary rays. Bundle sheath. Sclerenchyma (thick-walled cells, in nuts, etc.). Collen- chyma (thick-angled cells, under epidermis of succulent stems). Fibrovascular system. Fundamental system. Demonstration 22.* 127. If it is desired that the pupils examine under the microscope the dif- ferent elements of the epidermal and fundamental system, the teacher can make or procure sections to illustrate them. The pupils can then study and make sketches to illustrate the structures. Material. — Leaves of stored celery, the older ones with rather tough petioles, and considerable leaf surface ; or caladium leaves with long petiole This demonstration may well be omitted. PART OF MOVEMENT OF LIQUIDS IN PLANTS. 6g rom the conservatory; old dead corn-stalks. Shoots of the garden balsam impatiens) are good. A solution of fuchsin (add a few crystals to water), or use red ink. For study of the vascular bundles, sections may be made of the stems or letioles of the same plants, or of fresh corn stalks, of the stem of the sun- lower, or castor-oil bean. The teacher can make these sections either free land, or with a microtome; or if preferred, permanent slides to illustrate he structure of the vascular bundles may be obtained. If the pupils are to make their own sections for study, sharp razors will .Iso be required. Microscope, etc., for demonstration 21. CHAPTER XII. HOW PLANTS GET THEIR CARBON FOOD. I. The Gases Concerned. Exercise 26. 128. Gas given off by green plants in the sunlight. — Take some green alga, like spirogyra or vaucheria, which is in a fresh condition, place one lot in a beaker or tall glass vessel of water and set this in the direct sunlight or in a well lighted place. At the same time cover a similar vessel of spirogyra with black cloth so that it will be in the dark, or at least in very weak light. 129. The gas is shown in the form of bub- bles. — In a short time we that in the first vessel small bubbles of gas are accumulating on the surface of the threads of the spirogyra, and now and then some free themselves and rise to the surface of the water. Where there is quite a tangle of the threads the gas is apt to become caught and held back in larger bubbles, which on agitation of the vessel are freed. Examine the vessel which was covered to exclude the light, or which was placed in the dark. Are bubbles of gas given off here? Place the vessel in the light and note how soon bubbles begin to pass off. Fig- 55- Oxygen gas given off by spirogyra. Exercise 27. 130. Experiment with elodea. — Take one of the higher green plants, an aquatic plant like elodea, callitriche, etc. Place the plant in the water with the cut end of the stem uppermost, but still immersed, the plant being weighed down by a glass rod or other suitable object. If we place the vessel of water 70 HOW PLANTS GET THEIR CARBON FOOD. 71 containing these leafy stems in the bright sunlight, in a short time bubbles of gas will pass off quite rapidly from the cut end of the stem. In the stem from which the leaves have been cut are there as many bub- bles ? What is the reason ? What part of the leafy shoot gives rise to the greater part of the gas ? Demonstration 23. 131. To determine the kind of gas given off by green plants in the sun- light. — Take quite a quantity oi the plants of elodea and place them under an inverted funnel which is immersed in water: the gas will be given off in quite large quantities and will rise into the narrow exit of the funnel. The funnel should be one with a short tube, or the vessel one which is quite deep so that a small test tube which is filled with water may in this condition be inverted over the opening of the funnel tube. Place in the bright sun- light for several days. With this arrangement of the experiment the gas will rise in the inverted test tube, slowly displace a portion of the water, and become collected in a suffi- cient quantity to afford us a test. When a. considerable Fig. 5 6. Bubbles of oxygen gas given off from elodea in presence of sunlight. (Oels ) Fig. 57- Apparatus for col- lecting quantity of oxygen from elodea. (Detmer.) quantity has accumulated in the test tube, we may close the end of the tube in the water with the thumb, lift it from the water and invert. The gas will rise against the thumb. A dry soft pine splinter should be then lighted, and after it has burned a short time, extinguish the flame by blowing upon it, when the still burning end of the splinter should be brought into the mouth of the tube as the thumb is quickly moved to one side. The glowing of the splinter shows that the gas is oxygen. 182. Oxygen given off by green land plants also. — If we should extend our experiments to land plants we should find that oxygen is given off by them under these conditions of light. Land plants, however, will not do this when they are immersed in water, but it is necessary to set up rather com- plicated apparatus and to make analyses of the gases at the beginning and at the close of the experiments. This has been done, however, in a suffi- ciently large number of cases so that we know that all green plants in the sunlight, if temperature and other conditions are favorable, give off oxygen. 7% BOTANY. 133. Absorption of carbon dioxide. — We have next to inquire where the oxygen comes from which is given off by green plants when exposed to the sunlight, and also to learn something more of the conditions necessary for the process. We know that water which has been for some time exposed to the air and soil, and has been agitated, like running water of streams, or the water of springs, has mixed with it a consider- able quantity of oxygen and carbon dioxide. Demonstration 24. 134. To show the result in boiled water. — Boil spring water or hydrant water which comes from a stream containing oxygen and carbon dioxide, for about 20 minutes, to drive off these gases. Set this aside where it will not be agitated, until it has cooled sufficiently to receive plants without injury. Now place some spirogyra or vaucheria, and elodea, or other green water plant, in this boiled water and set the vessel in the bright sunlight under the same conditions which were employed in the experiments for the evolution of oxygen. No oxygen is given off. Note. — It can be demonstrated that carbon dioxide is absorbed by the plant while the oxygen is passing off. In the case of aquatic plants the carbon dioxide is mixed with the water, while in the case of the land plants the carbon dioxide comes from the air. In the study of respiration we shall find that carbon dioxide is formed within the plant. Some of the carbon dioxide then which plants use when they are giving jff oxygen comes from within the plant itself. For some simple experiments to demonstrate the absorption of carbon dioxide during this process see paragraphs 1 19-124 of the author's larger "Elementary Botany." 135. A chemical change of the gas takes place within the plant cell. — Since oxygen is given off while carbon dioxide, a different gas, is necessary, it would seem that a chemical change takes place in the gases within the plant. Since the process takes place in such simple plants as spirogyra as well as in the more bulky and higher plants, it appears that the changes go on within the cell, in fact within the protoplasm. We should remember also that this chemical' change of the gases in plants pan only take place in the presence of light. HOW PLANTS GET THEIR CARBON FOOD. 73 Synopsis. — At temperatures suitable for growth, green plants in the sun- ght are constantly giving off a gas. In the case of water plants this gas can be seen in the form of bubbles. This gas is oxygen. At the same time that oxygen is being given off by green plants carbon ioxide (carbon and oxygen) is being absorbed by the plant. A chemical change in the carbon dioxide takes place in the plant and Dme of the oxygen is thus liberated. Material. — Fresh mats of some alga, either spirogyra, zygnema, or vau- heiia. Fresh shoots of one of the higher water plants like elodea (found in the aallow water of ponds, lakes, or streams near low ground). Beakers with fresh spring or hydrant water to hold the plants. A funnel nd large test tube for demonstration 23. The demonstration should be :arted several days in advance. CHAPTER XIII. HOW PLANTS GET THEIR CARBON FOOD. Concluded. II. Starch formed by Green Plants. Exercise 28. 136. To test for the presence of starch in green leaves. — Take green leaves which have been for several hours in the bright sunlight. J3oil them in alcohol, using great care not to set the alcohol on fire. This removes the chlorophyll. If it is desired not to use the alcohol, boil the leaves in water for a short time. Then place them in alcohol, changing the alcohol occa- sionally. The green color is extracted slowly by this process, It may be extracted more rapidly if the preparation is placed in the sunlight. When the leaves are decolorized, place them in a solution of iodine in potassium iodide. In place of this solution, a. tincture of iodine purchased at drug- stores answers fairly well. Observe the color of the leaves. This color is due to the presence of starch, the starch becoming dark blue or nearly black when treated with iodine. 137. Starch is formed only in the green parts of variegated leaves. — If we test for starch in variegated leaves like the leaf of a coleus plant, we shall have an interesting demonstration of the fact that the green parts of plants only form starch. We may take a leaf which is partly green and partly white, from a plant which has been standing for some time in bright light. Fig. 58 is from a photograph of such a leaf. We should first boil it in alcohol to remove the green color. Now immerse it in the potassium iodide of iodine solution for a short time. The parts which were formerly green are now dark blue or nearly black, showing the presence of starch in those portions 74 HOW PLANTS GET THEIR CARBON FOOD. 75 of the leaf, while the white part of the leaf is still uncolored. This is well shown in fig. 59, which is from a photograph of another coleus leaf treated with the iodine solution. 138. Green parts of plants form starch when exposed to light. — Thus we find that in the case of all the green plants we Fig. 58. Leaf of coleus showing green and white areas, before treatment with iodine. Fig. 59. Similar leaf treated with iodine, the starch re- action only showing where the leaf was green. have examined, starch is present in the green cells of those which have been standing for some time in the sunlight where the process of the absorption of C0 2 and the giving off of oxygen can go on, and that in the case of plants grown in the dark, or in leaves of plants which have stood for some time in the dark, starch is absent. We reason from this that starch is the product of the chemical change which takes place in the green cells under these conditions. Because CO, is absorbed during this process, and because of the chemical changes which take place in the formation of starch, by means of which the carbon 7 6 BOTANY. is changed from its attraction in the molecule of carbon dioxide to its attraction in the molecule of starch, the process has been termed carbon assimilation. But since it is not truly an assimilatory process, and because sunlight is necessary in the first step of the conversion, it has also been recently termed photosyntax ox photosynthesis. These terms, however, seem in- appropriate, since the synthetic part of the process is not known to be due to the action of light. In the presence of chlorophyll light reduces the carbon dioxide, while the synthetic part of the process may not be influenced by light. For popular treatment the term carbon conversion was proposed in the author's larger " Elementary Botany." But this is also an unfortunate term, and he would now propose the simple term, starch formation. But there should be no objection to the use of the term carbon assimilation, or photosynthesis. 139. Fungi cannot form starch.- — If we should extend our experiments to the fungi, which lack the green color so charac- teristic of the majority of plants, we should find that starch formation does not take place even though the plants are exposed to direct sunlight. These plants then obtain carbo- hydrates for food from other sources, as parasites from living plants, and as saprophytes from dead Dlants, or from certain plant products. III. Chlorophyll and Chlorophyll Bodies. 140. Form of the chlorophyll bodies. — This green substance of plants, the presence of which is necessary in the formation of starch, is chlorophyll. It usually occurs in definite bodies, the chlorophyll bodies. Chlorophyll bodies vary in form in some different plants, especially in some of the lower plants. This we have already seen in the case of spirogyra, where the chlorophyll body is in the form of a very irregular band, which courses around the inner side of the cell wall in a spiral manner. In zygnema, which is related to spirogyra, the chlorophyll bodies are star-shaped. In the desmids the form varies greatly. HO W PLANTS GET THEIR CARBON FOOD. 77 In vaucheria, a branched thread-like alga, the chlorophyll bodies are oval in outline. This form of the chlorophyll body is that which is common to many of the green algae, and also occurs in the mosses, liverworts, ferns, and the higher plants. It is a more or less rounded, oval, flattened body. Demonstration 25. 141. Chlorophyll bodies in leaves. — If it is desired to demonstrate the chlorophyll bodies the teacher can make free-hand sections from fresh leaves of a begonia, or from some other plant. In figure 60 are shown the chloro- phyll bodies in the leaf of the ivy. Fig. 60. Section of ivy leaf, palisade cells above, loose parenchyma, with large intercellular spaces in centre. Epidermal cells on either edge, with no chlorophyll bodies. 142. Chlorophyll. — The chlorophyll is a coloring substance which resides in the chlorophyll body. It can be extracted from the body by the use of alcohol. The body is a plastid of a proteid nature, widely distributed in many plants. The plastid when not exposed to light is usually colorless, when exposed to light it often becomes green; while in the roots of the carrot and in the petals of some flowers it possesses other colors. When it is colorless it is called a leucoplast, when green a chloroplast, and when yellow, red, etc., a chromoplast. 143. Where starch is first formed. — The starch is first formed in the chlorophyll bodies. The chlorophyll absorbs 78 BOTANY. certain of the rays of light. The absorbed light is transformed into energy which assists in the chemical changes taking place in the carbonic acid (when the carbon dioxide of the air meets the water in the cell it forms carbonic acid) in the cell by which starch is built up. By mounting leaves of some mosses, or the prothallia of ferns in water, for microscopic examination, the starch grains can be seen within the chlorophyll bodies. They can often be seen in the chlorophyll bodies in the leaf of begonias when thin sections are made for observation under the microscope. 144. Starch in other parts of plants than the leaves. — While the larger part of the starch is formed in the green leaves, it is often found stored in large quantities in parts of plants not exposed to the light. It is formed in the leaves during the day, and at night it is dissolved and transported to other parts of the plant where it may be needed for the manufacture of other substances used in plant growth, or it may be stored in special receptacles in the form of starch grains again, as in the potato tuber, the roots of the sweet potato, or in the thick leaves of the onion, etc. Exercise 29. 145. To test for the presence of starch in parts of the plant where it is stored. — Cut a potato tuber, scrape some of the potato at the cut surface into a pulp. Apply a small quantity of a solution of iodine to this pulp. Describe the result. The color produced is the reaction for what substance ? Where was the starch first formed in the potato plant ? How is it that later it is found in the tubers which are underground stems ? What function for the potato plant does this stored starch serve ? If it is desired the pupils may test for starch in the enlarged roots of the sweet potato, the grains of corn, or in the leaves of the onion. Place a small quantity of corn starch (as much as will be lifted on the point of a small knife blade) in a test tube. Add water to the depth of two inches and warm over a flame, then cool by moving the end in cold water or by holding it under the water tap. Add to the starch water a drop or two of a tincture of iodine (iodine crystals dissolved in alcohol). Observe the blue color. Now heat over the flame; the color disappears because the warm water extracts the iodine from the starch grains. Now cool again. The blue color reappears since the starch again takes up the iodine. HOW PLANTS GET THEIH CARBON FOOD. 79 Demonstration 26. 146. Form of starch grains. — Where starch is stored as a reserve mate- rial it occurs in grains which usually have certain characters peculiar to the species of plant in which they are found. They vary in size in many dif- ferent plants, and to some extent in form also. Scrape some of the cut sur- face of the potato tuber into a pulp and mount a small quantity in water, or make a thin section for microscopic examination. We find large starch grains of a beautiful structure. The grains are oval in form and more or less irregular in outline. But the striking peculiarity is the presence of what seem to be alternating dark and light lines in the starch grain. The lines form irregu- lar rings, which are smaller and smaller until we come to the small central spot termed the " hilum " of the starch grain. It is supposed that these ap- parent lines in the starch grain are caused by the starch substance being deposited in alternating dense and dilute layers, the dilute layers containing more water than the dense ones ; others think that the successive layers from the hilum outward are regularly of diminishing density, and that this gives the appearance of alternating lines. 147. Necessity of carbon food for plants. — The starch formed by plants is one of the organic substances manufactured by plants. It is the basis for the formation of other organic sub- stances. Starch contains carbon, hydrogen, and oxygen, in the proportion of 6 molecules of carbon, io molecules of hydrogen, and 5 molecules of oxygen (C 8 H ln 5 ). The water in the starch is in the proportion of 2 molecules of hydrogen to i molecule of oxygen (H,0). For this reason it is called a carbohydrate. The most important carbohydrates in plants are starch, the sugars, and cellulose, the latter substance, or modifications of it, forming the cell walls of plants. Without carbon-food green plants cannot make any appreciable increase in plant substance, though a considerable increase in size of the plant may take place (see paragraph 194). Chlorophylless plants, like the fungi and certain parasitic or saprophytic (as the Indian- pipe, certain of the orchids, etc.) angiosperms, derive their carbon-food from the carbohydrates manufactured by the green plants. Animals also derive their carbohydrates through the medium of the green plants, either directly or indirectly. Note. For further experiments and discussion of this subject see the author's larger "Elementary Botany." 8o BOTANY. Starch formation, by- green plants. Synopsis. Carbon dioxide is absorbed by the green parts of plants. In the presence of chlorophyll in the cell, and under the influence of sunlight, a. chemical change takes place in the carbonic acid (carbon dioxide united with the water in the plant-cell). As a result of this chemical change starch is formed by the union of carbon, hydrogen, and oxygen ; but all of the oxygen brought in by the carbon dioxide is not needed in the manufacture of starch. This portion of the oxygen is set free. Fungi, or other plants which lack chlorophyll cannot form starch. Parts of leaves, or parts of plants, which lack chlorophyll cannot form starch. Chlorophyll is the green pigment in the chlorophyll bodies (chloroplasts). Starch is first formed in the chlorophyll bodies, and then dissolved and carried to other parts of the plant, for food, or to be stored. Material. — Fresh leaves of ordinary plants which have been for a few hours in daylight (some of the seedlings which have been grown, or plants from the greenhouse will answer); some variegated leaves of the coleus plant if possible. For study of chlorophyll, leaves of begonia to section are good. For study of starch, potato tubers ; and if other objects are wanted, sweet pota- toes, onions, etc. If the pupils make their own sections of the begonia leaves, sharp razors will be necessary. Chemicals needed in the test for starch : a solution of iodine in potassium iodide (see appendix for formula), or an ordinary tincture of iodine ob- tained at drugstores ; alcohol. Microscope, etc., if it is desired to demonstrate the structure of starch grain. CHAPTER XIV. ROUGH ANALYSIS OF PLANT SUBSTANCE. 148. Some simple experiments to indicate the nature of plant substance. — After these building-up processes of the plant, it is instructive to perform some simple experiments which indi- cate roughly the nature of the plant substance, and serve to • show how it can be separated into other substances, some of them being reduced to the form in which they existed when the plant took them as food. For exact experiments and results it would be necessary to make chemical analyses. Exercise 30. 149. The water in tlie plant. — Take fresh leaves or leafy shoots or other fresh plant parts. Weigh. Permit them to remain in a dry room until they are what we call "dry." Now weigh. The plants have lost weight, and from what we have learned in studies of transpiration this loss in weight we know to result from the loss of water from the plant. Exercise 31. 150. The dry plant material contains water. — Take dry leaves, shavings, or other dry parts of plants. Place them in a test-tube. With a holder rest the tube in a nearly horizontal position, with the bottom of the tube in the flame of a bunsen burner. Very soon, before the plant parts begin to "burn," note that moisture is accumulating on the inner surface of the test-tube. This is water driven cff which could not escape by drying in air, without the addition of artificial heat, and is called " hygroscopic water." 151. Water formed on burning the dry plant material. — Light a soft-pine or bass-wood splinter. Hold a thistle tube in one hand with the bulb down- ward and above the flame of the splinter. Carbon will be deposited over the inner surface of the bulb. After a time hold the tube toward the window and look through it above the carbon. Drops of water have accumulated on 8l 82 BOTANY. on the inside of the tube. This water is formed by the rearrangement of some of the hydrogen and oxygen, which is set free by the burning of the plant material, where they were combined with carbon, as in the cellulose, and with other elements. Exercise 32. 152. Formation of charcoal by burning. — Take dried leaves, and shav- ings from some soft wood. Place in a porcelain crucible, and cover about ym deep with dry fine earth. Place the crucible in the flame of a Bunsen burner and let it remain for about 15 minutes. Remove and empty the con- tents. If the flame was hot the plant material will be reduced to a good quality of charcoal. The charcoal consists largely of carbon. 153. The ash of the plant. — Place in the porcelain crucible dried leaves and shavings as before. Do not cover with earth. Place the crucible in the flame of the Bunsen burner, and for a moment place on the porcelain cover ; then remove the cover, and note the moisture on the under surface from the escaping water. Permit the plant material to burn ; it may even flame for a time. In the course of 15 minutes it is reduced to a whitish powder, much smaller in bulk than the charcoal in the former experiment. This is the ash of the plant. What has become of the carbon? In this experiment the air was not ex- cluded from the plant material, so that oxygen combined with the carbon as the water was freed, and formed carbon dioxide, passing off into the air in this form. This it will be remembered is the form in which the plant took the carbon-food in through the leaves. Here the carbon dioxide met the water coming from the soil, and the two united to form, ultimately, starch, cellulose, and other compounds of carbon ; while with the addition of nitro- gen, sulphur, etc., coming also from the soil, still other plant substances were formed. Note. — The ash of the plant contains, usually, potash, soda, lime, mag- nesium, ferric oxide, phosphoric acid, sulphuric acid, silica, chlorine. (See page 64 of the author's larger " Elementary Botany," 2d Ed., revised.) Synopsis. The living plant contains a large amount of water. When the plant is dried in the air it still contains a considerable amount of water. This water of air-dried plants can only be driven off by artificial heat (at a temperature of ioo° F. for some time). When all of the water is dried out of the plant, if the plant is burned so that the plant substance is disorganized, several different substances are formed. ROUGH ANALYSIS OF PLANT SUBSTANCE. 83 1. Water is formed by the uniting of hydrogen and oxygen as these elements are freed from the plant substance by the burning. 2. Certain gases, one of them is carbon dioxide, formed by the carbon from the disorganized plant substance uniting with oxygen of the air during the burning. If the dried plant material is burned while oxygen from the air is ex- cluded, the carbon cannot unite with oxygen to form carbon dioxide, but remains in the form of charcoal, which is almost pure carbon. When plant material is burned with access of oxygen the residuum is a whitish-gray powder called the ash. (See page 64 of the author's larger "Elementary Botany," 2d Ed., revised.) Material. — Leafy shoots fresh; air-dried leaves, and some soft dry wood irhite pine wood, bass wood, or some similar soft wood). Apparatus. — Bunsen burner to supply gas-flame ; small porcelain cruci- £s with covers; supports to hold crucibles in the flame; test tubes; thistle ibes; some dry earth. CHAPTER XV. SOME OTHER WAYS IN WHICH CERTAIN PLANTS OBTAIN FOOD. (This chapter is for reading, or the teacher may make demon- strations before the class if there is time. ) 154. Nutrition of moulds. — Start some growths of the black mould as described in paragraph 49. Then for several days observe the growth. First there appear small spots of delicate white threads. This tuft of threads increases in size, the threads elongate and branch. Finally upright threads appear which bear the black heads (sporangia, sing, sporangium) and spores again. Break the potatoes open through several of these tufts. The threads of the mould enter the potato also. The mycelium in the potato or in the bread absorbs food solutions from these substances in the same way that root hairs absorb food solu- tions. The potato and the bread are largely made up of starch from green plants. This demonstration serves excellently to show how the fungi which lack chlorophyll obtain their carbo- hydrate food from the products of green plants (see paragraph 147)- 155. Nutrition of the larger fungi. — If we select some one of the larger fungi, the majority of which belong to the mush- room family and its relatives, which is growing on a decaying log or in the soil, we shall see on tearing open the log, or on removing the bark or part of the soil, as the case may be, that the stem of the plant, if it have one, is connected with whitish strands. During the spring, summer, or autumn months, examples of the mushrooms connected with these strands may usually be found readily in the fields or woods, but during the HOW PLANTS OBTAIN FOOD. 8$ winter and colder parts of the year often they may be seen in forcing houses, especially those cellars devoted to the propaga- tion of the mushroom of commerce. 156. The fungus strands. — These strands are. made up of numerous threads of the mycelium which are closely twisted and interwoven into a cord or strand, which is called a myce- 'ium strand, or rhizomorph. These are well shown in fig. 61, which is from a photograph of the mycelium strands, or "spawn" as the grower of mushrooms calls it, of Agaricus campestris. The little knobs or enlargements on the strands are the young fruit bodies, or ' ' buttons. ' ' 157. Mats of mycelium are sometimes very extensive. — While these threads or strands of the mycelium in the decaying wood or in the decaying organic matter of the soil are not true roots, they function as roots, or root hairs, in the absorption of food materials. In old cellars and on damp soil in moist places we sometimes see fine examples of this vegetative part of the fungi, the mycelium. But most magnificent examples are to be seen in abandoned mines where timber has been taken down into the tunnels far below the surface of the ground to support the rock roof above the mining operations. I have visited some of the coal mines at Wilkesbarre, Pa., and here on the wood props and doors, several hundred feet below the surface, and in blackest darkness, in an atmosphere almost completely saturated at all times, the mycelium of some of the wood-destroying fungi grows in a profusion and magnificence which is almost beyond belief. 158. Form of the mushroom. — A good example for this study is the common mushroom (Agaricus campestris). This occurs from July to November in lawns and grassy fields. The plant is somewhat umbrella-shaped, as shown in fig. 62, md possesses a cylindrical stem attached to the under side of the convex cap or pileus. On the under side of the pileus are thin radiating plates, shaped somewhat like a knife blade. These are the gills, or lamellae, and toward the stem they are 86 BOTANY. HOW PLANTS OBTAIN FOOD. 87 rounded on the lower angle and are not attached to the stem. The longer ones extend from near the stem to the margin of the pileus, and the V-shaped spaces between them are occupied by successively shorter ones. Around the stem a little below the gills is a collar, termed the ring or annulus. Fig. 62. Agaricus campestris. View of under side showing stem, annulus, gills, and margin of pileus. 159. nutrition of parasitic fungi. — Certain of the fungi grow on or- within the higher plants and derive their food materials from them and at their expense. Such ,a fungus is called a parasite, and there are a large number of these plants, which are known as parasitic fungi. The plant at whose expense they grow is called the ' ' host. ' ' One of these parasitic fungi, which it is quite easy to obtain in greenhouses or conservatories during the autumn and winter, is the carnation rust (Uromyces caryophyllinus), since it breaks out in rusty dark brown patches on the leaves and stems of the carnation (see fig. 63). If we make thin cross-sections through one of these spots on a leaf, and place them for a few minutes in a solution of chloral hydrate, portions of the tissues of the leaf will be dissolved. After a few minutes we wash the sec- tions in water on a glass slip, and stain them with a solution of eosin. If the sections were carefully made, and thin, the threads of the mycelium will be seen coursing between the cells of the leaf as slender threads. Here and there will be seen short branches of these threads which penetrate the cell wall of the host and project into the interior of the cell in the form of an irregular knob. Such a branch is a haustorium. By means of this haustorium, which is here only a short branch of the mycelium, nutritive substances are taken by the fungus from the proto- plasm or cell-sap of the carnation. From here it passes to the threads of the mycelium. These in turn supply food material for the development of the dark brown gonidia, which we see form the dark-looking powder on the spots. Many other fungi form haustoria, which take up nutrient matters in the way described for the carnation rust. 160. Nutrition of the dodder. — The dodder (cuscuta) is an example of one of the higher plants that is parasitic. The stem twines around the stems of other plants, sending short conical processes termed haustoria in their tissues. By means of these the nutriment is absorbed from the host. The means of absorb- Fig. 63. Carnation rust on leaf and flower stem. From photograph. HOW PLANTS OBTAIN FOOD. 8 9 ing nutriment maybe demonstrated by making sections through both parasite and host at a point where the haustoria enter the stem. These should then be mounted for examination with the microscope. Fig. 64. Several teleutospores, showing the variations in form. 161. Carnivorous plants, or insectivorous plants. — Examples of these are the well-known Venus fly-trap (Dionaea muscipula) and the sundew (Drosera rotundifolia). These are illustrated in figures 67 and 68. The lamina of the leaf of the Venus Fig. 65. Cells from the stem of a rusted carnation, showing the intercellular mycelium and haus- toria. Object magnified thirty times more than the scale. fly-trap resembles a steel trap, as shown open in figure 67. When an insect alights on the leaf and touches one of the hairs (there are three prominent hairs on the upper surface of each 9° BOTANY. half of the leaf), the leaf suddenly closes and captures it. It has been found that when the hair is touched the first time no movement of the leaf takes place, but when it is touched the second time the leaves close up suddenly. There are small glands on the surface of the leaf which excrete a substance that digests the insect, when the digested portions are absorbed by the leaf and are assimilated bv the plant as food. The leaf of the sundew is quite different in form and action. In the species Fig. 66. Dodder. illustrated here the lamina of the leaf is rotund, and the upper surface is covered with numerous long glandular hairs. The gland is on the end of the hair, and a sticky substance is HOW PLANTS OBTAIN FOOD. 9' excreted by the cells of the gland, which glistening in the sun- light reminds one of drops of dew. For this reason the plant is called the sundew. When an insect alights on a leaf the viscid substance clings to it and holds it firmly so that it cannot escape. The glandular hairs then begin slowly to curve inward toward the centre of the 'leaf as shown in figure 68. Finally the margins of the leaf become inrolled also, so that the insect is held fast and close to the upper surface of the leaf. , Excretions from the leaf surface act as a digestive ferment upon the insect. 162. Nutrition of bacteria. — Bacteria are very minute plants, in the form, of short rods, which are either straight or spiral, while some are minute spheres. They are widely distributed; some cause dis- eases of plants- and animals, others cause decay of organic matter, while still others play an important role in con- verting certain nitrogen com- pounds into an available form for plant food. They absorb their food through, the sur- face of their body. They may be obtained in abund- ^ h ™ d n *3d ance for study in infusions lobes ' of plants or of meats. To demonstrate bacteria in infusions take a small quantity of hay or of meat. Place it in water and heat at about 60° C. for an hour. Then set the vessel containing the infusion aside in a warm room for several days., Numbers of bacteria will be developed, some of them probably motile. With a good micro- scope they may be demonstrated by mounting a drop of the infusion on a glass slip and preparingfor examination with the microscope. Fig. 67. Leaf of Venus fly- trap (Dionaea musci- Fig. 68. Leaf of Drosera ro- tundifolia, some of the glandular hairs fold- ing inward as a result of a stimulus. Fig. 6g. Root of the common vetch showing root tubercles, Nitrogen gatherers. 163. How clovers, peas, and other legumes gather ni- trogen. — It has long been known that clover plants, peas, beans, and many other leguminous plants are often able to thrive in soil where the cereals do but poorly. Soil poor in nitro- genous plant food becomes richer in this substance where clovers, peas, etc., are grown, and they are often planted for the purpose of enriching the soil. Leguminous plants, especially in poor soil, are almost certain to have enlargements, in the form of nodules, or ' ' root tubercles. ' ' A root of the common vetch with some of these root tubercles is shown in fig. 69. 163a. A fungal or bacterial organism in these root tubercles. — If we cut one of these root tubercles open, and mount a small portion of the interior in water for examination with the microscope, we shall find small rod-shaped bodies, some of which resemble bacteria, while others are more or less forked into forms like the letter Y, as shown in fig. 70. These bodies are rich in nitrogenous substances, or proteids. They are portions of a minute organ- ism, of a fungous or bacterial nature, which attacks the roots of leguminous plants and causes these nodular outgrowths. The organism (Phytomyxa leguminosarum) exists in the soil and is widely distributed where legumes grow. 164. How the organism gets into the roots of the legumes. — This minute organism in the soil makes its way through the wall of a root hair near the end. It then grows down the interior of the root hair in the form of a thread. When it reaches the cell walls it makes' a minute perforation, through which it grows to enter the adjacent cell, when it enlarges again. In this way it passes from the root hair to the cells of HOW PLANTS OBTAIN FOOD. 93 the root and down to near the centre of the root. As soon as it begins to enter the cells of the root it stimulates the cells of that portion to greater activity. So the root here develops a large lateral nodule, or ' ' root tubercle. ' ' As this ' ' root Fig. 70, Fig. 71. Root-tubercle organism from vetch, old con- Root-tubercle organism from Medicago dition. denticulata. tubercle" increases in size, the fungus threads branch in all directions, entering many cells. The threads are very irregular in form, and from certain enlargements it appears that the rod- like bodies are formed, or the thread later breaks into myriads of these small " bacteroids. " 165. The root organism assimilates free nitrogen for its host. — This organism assimilates the free nitrogen from the air in the soil, to make the proteid substance which is found stored in the bacteroids in large quantities. Some of the bacteroids, rich in proteids, are dissolved, and the proteid substance is made use of by, the clover or pea, as the case may be. This is why such plants can thrive in soil with a poor nitrogen content. Later in the season some of the root tubercles die and decay. In this way some' of the proteid substance is set free in the soil. The soil thus becomes richer in nitrogenous plant food. The forms of the bacteroids vary. In some of the clovers they are oval, in vetch they are rod-like or forked, and other forms occur in some of the other genera. CHAPTER XVI. RESPIRATION. Exercise 33. 166. Simple experiment to demonstrate the evolution of C0 a during germination. — Where there are a number of students and a number of large cylinders are not at hand, take bottles of a pint capacity, place in the bottom some peas soaked for 12 to 24. hours. Cover with a glass plate which has been smeared with vaseline to make a tight joint with the mouth of the bottle. Set aside in. a moderately warm place for 24 hours. Then slide the glass plate a little to one side and quickly pour in a little baryta water so • that it will run down on the inside of the bottle. Cover the bottle again. Note the precipitate of barium carbonate which demonstrates the presence of C0. 2 in the bottle. Lower a lighted taper. It is extinguished because of the great quantity of CO a . Exercise 34. 167. Comparison of respiration in plants and ani- mals — Take some of the baryta water and breathe upon it. The same film is formed. The carbon diox- ide which we exhale is absorbed by the baryta water and forms barium carbonate, just as in the case of the peas. In the case of animals the process by which ( Sacl >s.) oxygen is taken into the body and carbon dioxide is given off is respiration. The process in plants which we are now studying is the same, and also is respiration. The oxygen in the vessel was partly used up in the process and carbon dioxide was given off. (It will be seen that this process is exactly the opposite of that which takes place in starch formation.) Exercise 35 (or Demonstration). 168. Respiration is necessary for growth. — After we have performed the experiment in paragraph 166, if the vessel has not been open too long so 94 Fig. 72. Test for presence of carbon dioxide in vessel with germinating peas. RESPIRA TION. 95 hat oxygen has entered, we may use the vessel for another experiment, >r set up a new one to be used in the course of 12 to 24 hours, after the oxy- gen has been consumed. Place some folded damp filter paper on the ger- minating peas in the jar. Upon this place one-half dozen peas which have ust been germinated, and in which the roots are about 2Q-2$mm long. See igures 73, 74. The vessel should be covered tightly again and set aside in a Fiff. 73- Fig- 74- Fig. 74*. Fig. 73a. Fig. 73.— Seedlings in vessels containing an excess of carbon dioxide, and very little >xygen. No growth takes place. Fig. 74. — Vessel with normal air used as a check. No excess of carbon dioxide, usual .mount of oxygen. Normal growth takes place. Figures 73d and 74*2 represent the condition of the peas in the experiment shown in figs. 3 and 74, a month later. The cylinders as set up for that experiment were left for a nonth and then photographed^ The peas in the cylinder containing normal air have ;rown, producing stems which reach to the top of the cylinder, while in fig-. 730;, where he oxygen wasabsent, the peas have died. At this time a test was made with a lighted aper ; it burned brightly in the cylinder 74^, but was quickly extinguished in the cylinder 3«. The peas having died in this jar, decomposition had taken place and other gases than arbon dioxide were present, but there was not sufficient oxygen to support combustion. rarm room. A second jar with water in the bottom instead of the gcrminat- ng peas should be set up as a check. Damp folded filter paper should be upported above the water, and on this should be placed one-half dozen peas pith roots of the same length as those in the jar containing carbon dioxide. 9 6 BOTANY. 169. Oxygen is necessary for growth. — In 24 hours examine and note how much growth has taken place. It will be seen that the roots have elon- gated but very little or none in the first jar, while in the second one we see that the roots have elongated considerably, if the experiment has been carried on carefully. Therefore in an atmosphere devoid of oxygen or an excess of carbon dioxide, very little growth will take place, which shows that normal respiration with access of oxygen is necessary for growth. 170. Energy set free during respiration. — From what we have learned of the exchange of gases during respiration we infer that the plant loses carbon during this process. If the process of respira- tion is of any benefit to the plant, there must be some gain in some direction to compensate the plant for the loss of carbon which takes place. It can be shown by an experiment that during respiration there is a slight elevation of the temperature " in the plant tissues. The plant then gains some heat during respiration. We have also seen in the attempt to grow seedlings in the absence of oxygen that very little growth takes place. But when oxygen is admitted growth takes place rapidly. The process of respiration, then, also sets free energy which is manifested in one direction, by growth. Fig. 75- Pea seedlings ; the one at the left had no oxygen and little growth took place; the one at the right in oxygen and growth was evident. Demonstration 27. 171. To set np the apparatus for demonstrating respiration. — Soak a double handful of peas for 12 to 24 hours in an abundance of cool water. Prepare a small quantity of baryta water, a saturated solution, and filter some into a short wide vial. Take a glass cylinder about 35«re high by ^cm in diameter. Select a perforated rubber cork to fit very tightly when crowded part way in the open end of the cylinder. Prepare a long S manometer by bending a glass tube which is about one and one-half meters long by (mfm inside diameter, into the form shown in figure 76. Put mercury into one end of the manometer as shown in the figure, and if it is desired to show the RESPIRA TION. 97 experiment at a distance in the classroom, place a small quantity of a solu- tion of eosin r.bove each column of mercury. Insert the other end of the manometer through the preforation in the rubber cork. It must fit very tightly. If there is another perforation plug it with a glass rod. Take a wide-mouthed small glass jar — a small glycerine jelly jar is good — which will go inside the cylinder. Break a few sticks of caustic potash and drop in it. Nearly fill with water and tie a string around the top so that it can be lowered into the upper part of the cylinder without spilling any of the potash solution. Prepare a sup- port for this by inserting a glass rod about lym long into a cork. Have all the parts of the apparatus and the ma- terial ready, and the baryta water in the open vial, so that the apparatus may be set up quickly. Have the cylin- der warm and set the apparatus up in a room where the temperature is about 2o° C. (about 68° Fahr.). Place a small quantity of damp paptr (not wet) in the bottom of the cylinder. Place in the soaked peas to fill about 8cm to locm. Upon these place the small vial of baryta water. Drop in the support and press the glass rod down far enough so that the jar of potash solution will enter and pass far enough below the mouth of the cylinder to be out of the way of the rubber cork. Insert the rubber cork containing the S manometer of mercury, placing be- tween it and the side of the cylinder a stout needle to allow the escape of air Fig. 76. Fig. 77. Experiment to demonstrate respiraton. Fig. 76. — At beginning" of experiment ; while the cork is pressed in tightly, mercury in each arm equal No oxygen has T-. ■ T1 .t t . been consumed in vessel. This allows the mercury to remain at Fig . 77 ._ At close of experiment ; mer- the same level in both arms of the tube J^y in inner arm has risen. Some oxygen has been consumed. Now remove the needle and set the apparatus aside where the temperature will remain at about 20° C. , and let g8 BOTANY. stand for about 24 hours. The apparatus should be set up quickly so that forming carbon dioxide will not displace the air. 172. Carbon dioxide given off during germination while oxygen from the air is con- sumed. — In a short while there can be seen a whitish film on the baryta water in the vial. In less than an hour this film may become so thick that with a little agitation it breaks and settles as a white precipitate: This white pre- cipitate is barium carbonate. Some of the carbon dioxide given off by the peas is ab- sorbed by the baryta water forming the insoluble barium carbonate. Carbon dioxide is also absorbed by the caustic potash solution in the bottom of the cylinder. Owing to the slowness with which the carbon dioxide diffuses from between the peas into the potash solution an excess may be formed. This excess of carbon dioxide in the cylinder produces a pressure which is shown by the rise of the mer- cury in the outer arm of the tube.* In about 24 hours observe Fig. 78. Fig. 79. Experiment to demonstrate respiration. Fig. 78. — At beginning of experiment; mer- cury in each arm equal. No oxygen has been consumed in vessel. Fig. 79.— At close of experiment ; mercury „,.„. : c c +ill nio-n^r in t-no n „tpr in inner arm has risen. Some oxygen has been ^.ury IS bllll nigner in me OUtcr c ° nsumed ' arm it shows that there is still * When this inside pressure is produced it shows that more CO, is the experiment. If the mer- RES P If! A TION. 9£ in excess of C0 2 in the cylinder. At any rate lift the cylinder with the hands in such a way as to hold firmly at the same time the glass tube. Lift it up and down in such a way as to spill a portion of the baryta water over against the wall of the cylinder, ind to dash the potash solution into a spray. Be careful not to toss the mercury out of either arm of the tube. .-■ If the open irm of the' glass tube is closed with the finger (should the apparatus be set up as indicated in fig. 78), the cylinder may be inclined so as to let a portion of the potash solution run, up imong the peas to come directly in contact with t-he C<3\ remaining there. Now rest the cylinder on the table and Dbserve the result. The mercury now, if it did not before, stands higher in the inner arm of the S tube, showing that some :onstituent of the air within the cylinder was consumed during :he formation of the C0 2 . This constituent of the air must be Dxygen, since the carbon can only come from the plant. Where :he baryta water was spilled over an abundance of the white precipitate of the barium carbonate is formed. If desired the experiment can be set up as shown in figure 78, with the potash solution in the bottom of the cylinder, and :he peas supported on a circular piece of wire netting held in Diace between two small corks inserted in a glass rod. At the :lose of the experiment when the cylinder is being agitated the escaping baryta water forms a large quantity of the whitish precipitate as it washes down the side of the cylinder. >eing set free than oxygen is being consumed. This feature of the ex- jeriment demonstrates what is known as intramolecular respiration, a kind )f respiration which can go on independently of the entrance of the oxygen, jee the author's larger " Elementary Botany " page 58. 100 BOTANY. Demonstration 28. 17SL Respiration in a leafy plant. — We may take a potted plant which has a well-developed leaf surface and place it under a tightly fitting bell jar. Under the bell jar there also should be placed a small vessel containing baryta water. A similar apparatus should be set up, but with no plant, to serve as a check. The experiment must be set up in a room which is not frequented by persons, or the carbon dioxide in the room from respiration will vitiate the experiment. The bell jar containing the plant should be covered with a black cloth to prevent starch formation. In the course of ten or twelve Test for' g 'lib°ration of hours . if everything has worked properly, the baryta carbon dioxide from leafy wa t e r under the jar with the plant will shew the film giant during respiration. ■* * .,, , aryta water in smaller of barium carbonate, while the other one will show vessel. (Sachs.) none Respiration, therefore, takes place in a leafy plant as well as in germinating seeds. Synopsis. — Respiration (taking in oxygen and giving off carbon dioxide) occurs in all plants during growth. Respiration takes place actively in germinating seeds and opening buds and flowers. Respiration without access of oxygen (intramolecular respiration) takes place, in germinating seeds for example, in addition to normal respiration. Respiration in plants is the same process as in animals. The carbon dioxide from respiration may be detected by testing the air in the vessel where the plant is growing with a lighted taper (the taper is ex- tinguished), or by baryta water (the baryta water absorbs carbon dioxide, forming the insoluble barium carbonate), or by lime water (the lime water absorbs carbon dioxide, forming the insoluble calcium carbonate = chalk). Access of oxygen is necessary for the growth of most plants. (Some bac- teria will only grow in the absence of oxygen. ) Respiration is a breaking-down process. (Changes take place in the pro- toplasm, the entering oxygen uniting with some of the carbon and oxygen of the protoplasm and forming CO a .) Compare this with the burning of plant substance. Respiration transforms energy in the plant, which is manifested by an elevation of the temperature of the plant substance, so that the plant gains some heat ; it is also manifested by growth. KESPIKA TION. IOI Starch formation or Photosynthesis. Respiration. Comparison of respiration and starch formation. Carbon dioxide is taken in by the plant and oxygen is liberated. Starch is formed as a result of the metabolism, or chemical change. The process takes place only in green plants, and in the green parts of plants, that is, in the presence of the chlorophyll. (Exception in purple bacte- rium. ) The process only takes place under the influence oi sunlight. It is a building-up process, because new plant sub- stance is formed. Oxygen is taken in by the plant and carbon dioxide is liberated. Carbon dioxide is formed as a result of the meta- bolism, or chemical change. The process takes place in all plants whether they possess chlorophyll or not (exceptions in anaerobic bacteria). The process takes place in the dark as well as in the sunlight. It is a breaking-down process, because combustion of plant substance occurs. Material and apparatus. — Peas soaked for 24 hours in cold water (enough for class and for demonstration). Peas germinated, and with roots about 20mm long. A few should be started 4 or 5 days in advance of the time they are wanted. Wide-mouthed bottles, or cylinders, with glass plates and vaseline, to close them, or corks (glass plates are better). Tapers, or soft wood splinters for flaming. Baryta water (saturated solution of barium hydrate in water) in tightly stoppered bottle. Watch glasses for baryta water. For demonstration 27: glass cylinder about 3$cm high by $cm in diameter ; perforated rubbor cork to fit very tightly ; S manometer made from glass tubing about 6mm diameter ; mercury ; small glass jar and vial ; support as indicated in demonstration 27 ; some sticks of caustic potash ; baryta water ; a stout needle. For demonstration 28: potted plant ; bell jar to cover ; baryta water. CHAPTER XVII. GROWTH. 174. Meaning of growth. — By growth is usually meant an increase in the bulk of the plant accompanied generally by an increase in plant substance. Among the lower plants growth is easily studied in some of the fungi. 175. Growth of roots — For the study of the growth of roots we may take any one of many different plants. The seedlings of such plants as peas, beans, corn, squash, pumpkin, etc., serve excellently for this purpose. Exercise 36. 176. To study growth of roots. — The seeds, a handful or so, are soaked in water for about 12 hours, and then placed between layers of paper or between the folds of cloth, which must be kept quite moist but not very wet, and should be kept in a warm place. (See demonstration 2.) The primary or first root (radicle) of the embryo pushes its way out between the seed coats at the small end. When the seeds are well germi- nated, select several which have the root 4-$i-m long. With a crow-quill pen we may now mark the terminal portion of the root off into very short sections as in fig. 8i. The first mark should be not more than \mm from the tip, and the others not more than I mm apart. Now place the seedlings down on damp filter paper, and cover with a bell jar so that they will re- main moist, and if the season is cold place them in a warm room. At intervals of 8 or io hours, if convenient, observe them and note the further growth of the root. Sketch the root with the marks at the beginning of the experiment, and at the different times the observations are taken. Where does the elongation take place ? Determine this by the marks on the root which separate. Where is the region of greatest elongation ? Does the region of greatest elongation rl-an^e ? 102 GRO WTH. IO3 177. The region of elongation.— While the root has elon- gated, the region of elongation is not at the tip of the root. It lies a little distance back from the tip, beginning at about 2mm from the tip and extending over an area represented by from 4 to 5 of the millimeter marks. The root shown in fig. 66 was marked at 10 a.m. on July 5. At 6 p.m. of the same day, 8 hours later, growth had taken place as shown in the Root of germinating pumpkin, showing region of elongation just back of the tip. middle figure. At 9 a. m. on the following day, 1 5 hours later, the growth is represented in the lower one.' Similar experiments upon a number of seedlings gives the same result : the region of elongation in the growth of the root is situated a little distance back from the tip. Further back very little or no elongation takes place, but growth in diameter continues for some time, as we should discover if we examined the roots of growing pumpkins, or other plants, at different periods. 178. Movement of region of greatest elongation. — In the region of elongation the areas marked off do not all elongate equally at the same time. The middle spaces elongate most rapidly and the spaces marked off by the 6, 7, and 8 mm marks elongate slowly, those farthest from the tip more slowly than the others, since elongation has nearly ceased here. The spaces marked off between the 2-\mm marks also elongate slowly, but soon begin to elongate more rapidly, since that region is becom- ing the region of greatest elongation. Thus the region of greatest elongation moves forward as the root grows, and remains approximately at the same distance behind the tip. 104 BOTANY. Exercise 37. 179. Growth of the stem. — We may use a bean seedling growing in the soil. At the junction of the leaves with the stem there are enlargements. These are the nodes, and the spaces on the stem between successive nodes are the internodes. We should mark off several of these internodes, espe- cially the younger ones, into sections about $mm long. Now observe these at several times for two or three days, or more. The region of elongation is greater than in the case of the roots, and extends back further from the end of the stem. In some young garden bean plants the region of elonga- tion extended over an area of \omm in one internode. 180. Force exerted by growth. — One of the marvellous things connected with the growth of plants is the force which is exerted by various members of the plant under certain condi- tions. Observations on seedlings as they are pushing their way through the soil to the air often show us that considerable force is required to lift the hard soil and turn it to one side. A very striking illustration may be had in the case of mushrooms which sometimes make their waythrough the hard and packed soil of walks or roads. That succulent and tender plants should be capable of lifting such comparatively heavy weights seems incredible until we have witnessed it. Very striking illustrations of the force of roots are seen in the case of trees which grow in rocky situations, where rocks of considerable weight are lifted, or Lever auxanometer (Oels) for measuring elongation of email n'-ffc in lai-o-^ vc^rArc the stem during growth. Mlld,n Hits 111 large TOCKS are widened by the lateral pressure exerted by the growth of a root, which entered when it was small and wedged its way in. Fig. 82. GRO WTH. I05 If the season of the year is one that will permit, make some observations on the force exerted by seedlings in coming through the hard earth; of mushrooms coming up through dry and hard earth; of the wedging of roots in the crevices of rocks. Or recall and note any observations of this/ kind made in the past. One has only to note the immense size and weight of some trees to understand the force which must have been ex- pended during their growth in lifting up the food materials for these massive objects. 181. Energy of growth. — This is manifested in the compara- tive size of the members of a given plant. To take the sun- flower for example, the lower and first leaves are comparatively small. As the plant grows larger the leaves are larger, and this increase in size of the leaves increases up to a maximum period, when the size decreases until we reach the small leaves at the top of the stem. The zone of maximum growth of the leaves corresponds with the maximum size of the leaves on the stem. The rapidity and energy of growth of the stem is also correlated with that of the leaves, and the zone of maximum growth is coincident with that of the leaves. It would be instructive to note it in the case of other plants. Exercise 38. 182. To study zone of maximum growth. — Study the zone of maximum growth in several plants which may be at hand. Some plants may be ob- :ained for use from conservatories. Other plants may be collected during the 'rowing season and preserved for this purpose. Corn plants, for example, :an be gathered at maturity in the early autumn or late summer. They nay be carefully pressed entire, and mounted on large sheets, or on paste- board. The zones of maximum growth of the stem as well as of the leaves ;an be studied from these preserved plants. The plants in this condition will serve this purpose for several years. For other experiments and studies on growth see the author's arger " Elementary Botany." io6 BOTANY. Growth. Synopsis. An increase in the bulk or size of the plant. (Parts of the plant become longer and stouter.) Growth in length of the root takes place most actively a few millimeters back from the tip. The region of elongation of the root changes as the root be- comes longer. Growth in length is the result of the elongation of the newly formed cells [the formative region (i.e., where new cells are formed) is in the root tip] . The stem grows in a similar way, but the region of elongation extends over a greater area than in the root. As a result of the increase in the size of plants by growth, great force is exerted, sufficient to move considerable amounts of hard earth ; or, in the case of trees, to even split rocks, or to lift up during growth the entire plant material in trunk and branches. The energy of growth during the season, or during the life of an annual, varies. It is low at first, as manifested by the small size of the members, then it increases to a maximum, then decreases. material and apparatus. — Seedlings of squash, or pumpkin, or peas, etc., grown in a germinator free from earth. The seeds should be started a week to ten days before they are wanted, so that the roots will be about ym to 4«7z long. (See demonstration 2 for preparing seedlings.) Sev- eral moist chambers ; large corks upon which some of the seedlings can be pinned. India ink and crow-quill pen for marking the roots. Seedlings grown in soil in pots with the stems just appearing above the soil. Potted begonias; entire corn plants (may be pressed and preserved dry); or small but mature sunflower plants (also may be preserved dry). CHAPTER XVIII. MOVEMENT IN PLANTS DUE TO IRRITABILITY. 183. Movement in response to stimulus. — Beside the growth movements which take place in plant parts, the parts of plants show certain movements which are due to irritability. In this kind of movement the plant is influenced by some exciting cause, called a stimulus. The stimulus acts upon the irritable part of the plant, and in response to this movement occurs. We can easily study the effect of several different kinds of stimuli. 184. Influence of the earth on the direction of growth. — In the germination of the seeds which we have used in some of the earlier experiments it has probably been observed that the direc- tion which the root and stem take upon germination is not due to the position in which the seed happens to lie. Under normal conditions we have seen that the root grows downward and the stem upward. Exercise 39. 185. To study the influence of the earth on roots. — Take seedlings grown in a germinator which are free from the soil. Pin several seedlings to a cork in such a way that the stems and roots of different ones will be lying in different directions. Mark off the tip of the root of several with ink, as in paragraph 176. Cut off the extreme tip from a few of the roots. Place the cork in a moist chamber, with an abundance of water or saturated paper in the bottom. On the following day observe the positions of the roots and stems. Sketch and annotate. In the case of the roots marked into millimeter spaces determine the motor zone (region of curvature) of the root. Comparing these with the roots from which the tip was cut determine the perceptive zone (the zone which receives the stimulus). Now turn the cork in another posi- tion, leave for a day and note the result. 107 I08 BOTANY. Exercise 40. 186. Influence of the earth on stems and leaves.— Place rapidly growing potted plants horizontally. Seedlings in pots, or young plants, or potted hyacinths are good ones to use. In the course of a day observe the positions of the stems and leaves. Sketch some of them. 187. Gravity acts as a stimulus. — Knight found that the stimulus which influences the root to turn downward is the force of gravity. The reaction of the root in response to this stimulus is geotropism, a turning influenced by the earth. This term is applied to the growth movements of plants influenced by the earth with regard to direction. While the motor zone lies back of the root tip, the latter receives the stimulus, and is the per- ceptive zone. If the root tip is cut off the root is no longer geotropic, and will not turn downward when placed in a hori- zontal position. Growth toward the earth is progeotropism. The lateral growth of secondary roots is diageotropism. 188. The result with stems. — The stem, on the other hand, which was placed in a horizontal position has become again erect. Fig. 83. Fig. 84. Germinating pea placed in a hori- In twenty-four hours gravity has caused the zontal position. root to turn downward. Figures 83, 84. — Progeotropism of the pea root. This turning of the stem in the upward direction takes place in the dark as well as in the light, as we can see if we start the experiment at nightfall, or place the plant in the dark. This upward growth of the stem is also influenced by the earth, and therefore is a case of geotropism. The special designation in the case of upright stems is negative geotropism, or apogeotropism, or the stems are said to be apogeotropic. Place a rapidly growing potted plant in a horizontal position by laying the pot on its side. The ends MOVEMENT IN PLANTS DUE TO IRRITABILITY. IOQ of the shoots will soon turn upward again. Young bean plants growing in a pot began within two hours to turn the ends of the shoots upward. Horizontal leaves and shoots can be shown to be subject to the same in- fluence, and are therefore diageolropic. 189. Influence of light. — Not Pumpkin seedling showing apogeotropism. Seedling at the left placed hori zontally. In twenty-four hours the stem has become erect. only is light a very important factor for plants during starch formation, it exerts great influence on plant growth and movement. Demonstration 29. 190. To prepare plants grown in the dark — Three or four weeks be- fore these plants are wanted for study the teacher may plant a sufficient number of seeds (radish or other seeds) in small pots for the class to study. Several different kinds of seeds may be used for comparison if desired. Place one lot of the pots in a warm but very dark place. They may be put in a box, and the box can be then covered with two or three layers of black cloth, sufficient to shut out all light. Keep the box in a warm room, and oc- casionally open it to water the plants if necessary. The lot kept in the light should have the same temperature conditions. If preferred the pupils can plant the seeds, and place those to be grown in the dark in a common box. This is preferable if it is convenient for the pupils to do it. Exercise 41 . 191. Influence of light on the growth of plants. — When the plants have grown for about two weeks they will be ready for study. Compare the plants grown in the dark with those grown in the light. Which lot have the longer stems? What influence then does light have on growth in no BOTANY. length ? Which plants have the larger leaves ? What influence does light have on the development of leaves ? What is the difference in color of the plants ? What is the cause of this ? Which lot of plants have the firmer tissues ? What is the cause of the difference in the firmness of the tissues ? Sketch a plant grown in the dark ; sketch one to the same scale grown in the light. Exercise 42. 192. Influence of light on the direction of growth. — Take potted seed- lings and place them near a window so that they will. have a one-sided illu- mination. Or place them in a box which has a small opening at one side. After a day or two observe the position of the seedlings. Does light have an influence on the direction of growth ? What is the direction with refer- ence to the source of light ? Sketch one of the plants, and indicate on the sheet the direction of the fl'lt Fig 86 ' * * ' Radish seedlings, grown in the 193. Influence Of dark, long, slender, not green. light on the position of leaves. — Take potted plants with a number of leaves, and place them near a window for several days or a week. Ob- serve the position of the leaves at the beginning Fig. 87. of the experiment, and after a week's time. What , R ?. di . sh seedlings grown in the light, shorter, stouter, and is the position of the leaves with reference to the green in color. Growth re- source of light ? Can you tell why the leaves take tar e y lg "■• this position ? 194. Retarding influence of light on growth. — We have only to return to the experiments performed in growing plants in the dark to see one of the influences which light exerts on plants. The plants grown in the dark were longer and more MOVEMENT IN PLANTS DUE TO IRRITABILITY. Ill slender than those grown in the light. Light then has a retard- ing influence on the elongation of the stem. 195. Influence of light on direction of growth. — While we are growing seed- lings, the pots or boxes., of some of them should be placed so that the plants will ' have a one- sided Mu- ni i n a tion. This oan be done by placing them near an open win- dow, in a room with a one-sided illumi- nation, or they may be placed in a box closed on all sides but one which is facing the window or light. In 1 2-24 hours, or even in a much shorter time in some cases, the stems of the seedlings will be directed toward the source of light. This influence exerted by the rays of light is helioiropism, a turning influenced by the sun or sun- light. 196. Diaheliot- ropism. — Horizon- ;al leaves and ihoots are diahe- * ' ' ' Dark chamber with opening at one side to show heliotropism. iiageotropic. The < After Schieichert.) general direction which leaves assume under this influence is hat of placing them with the upper surface perpendicular to 112 BOTANY. the rays of light which fall upon them. Leaves, then, exposed to the brightly lighted sky are, in general, horizontal. This position is taken in direct response to the stimulus of light. Fig. 91. Sunflower plant removed from darkness, leaves extending under influence of light (diaheliotro- pism). The leaves of plants with a one-sided illumination, as can be seen by trial, are turned with their upper surfaces toward the source of light, or per- pendicular to the incidence of the light rays. In this way light over- comes for the time being the direc- tion which growth gives to the leaves. The so-called " sleep" of plants is of course not sleep, though the leaves f '£■ 9°- ' ' nod, ' ' or hang downward, in many Sunflower plant. Epinastic _,, condition of leaves induced dur- cases. 1 here are many plants in ine the day in darkness. .... . which we can note this drooping of the leaves at nightfall, and in order to prove that it is not determined by the time of day we can resort to a well-known experiment to induce this condition during the day. The plant which has been used to illustrate this is the sunflower. Some of these plants, which were grown in a box, when they were fOVEMENT IN PLANTS DUE TO IRRITABILITY. 1 13 bout 35cm high were covered for nearly two days, so that the ght was excluded. At midday on the second day the box was amoved, and the leaves on the covered plants are well repre- ^nted by fig. 90, which was made from one of them. The ;aves of the other plants in the box which were not covered rere horizontal, as shown by fig. 91. Now on leaving these ilants, which had exhibited induced "sleep" movements, xposed to the light they gradually assumed the horizontal losition again. Synapsis. Irritability. Plants are irritable, that is, they respond to certain stimuli. The force of gravity stimulates the tip of the root, and causes the root to turn downward. The "motor zone," in response to this stimulus, is co- incident with the region of elongation of the root. The perceptive zone is in the root tip. The force of gravity stimulates the stem to turn upwards (or away from the earth). I Progeotropism (in first root). Geotropism. -J Diageotropism (in lateral roots). ( Apogeotropism (in stems). Stems( horizontal stems are diahelio- tropic) grow towards the light (heli- otropic). Leaves turn so as to face the light (un- less the light is very strong, when they may turn their edge toward the light). Light retards growth of stems, since Influence of light, j stems grown in the dark are longer. Plants do not "sleep"; when the leaves turn downward at night it is because the influence of light is re- moved and the leaf is free to turn in the direction caused by growth, the growth being more active usually on the upper side of the leaf after it pushes out from the bud. 114 BOTANY. Material and apparatus. — Seedlings, moist chambers, corks and pins, as in Chapter XVII. Seedlings in pots (beans, squash or pumpkin), \ocm to l$cm high. Potted hyacinths if they can be obtained. Seedlings grown in pots in the dark (about three weeks old), others of the same age grown in the light. Some dark boxes with small opening at one side, to receive some of the pots of seedlings. If possible some sunflower plants grown in pots, plants about 20cm to ■yacm high, and tall dark boxes to cover them when desired. Sunflower plants should be started two or three months in advance. Potted oxalis, which is often grown in conservatories, is better to show in- duced "sleep" movements. PART II: MORPHOLOGY AND LIFE HIS- TORY OF REPRESENTATIVE PLANTS. CHAPTER XIX. SPIROGYRA. 197. Convenience in studying spirogyra. — In our study of protoplasm and some of the processes of plant life we became acquainted with the general appearance of the plant spirogyra. It is now a familiar object to us. And in taking up the study of representative plants of the different groups, we shall find that in knowing some of these lower plants the difficulties of understanding methods of reproduction and relationship are not so great as they would be if we were entirely ignorant of any members of the lower groups. 198. Form of spirogyra. — We have found that the plant spirogyra consists of simple threads, with cylindrical cells attached end to end. We have also noted that each cell of the thread is exactly alike, with the exception of certain ' ' hold- fasts " on some of the species. If we should examine threads in different stages of growth we should find that each cell is capable of growth and division, just as it is capable of perform- ing all the functions of nutrition and assimilation. The cells of spirogyra then multiply by division. Not simply the cells at the ends of the threads but any, and all of the cells divide as they grow, and in this way the threads increase in length. 199. Conjugation of spirogyra. — Under certain conditions, when vegetative growth and multiplication cease, a process of reproduction takes place which is of a kind . termed sexual "5 Ii6 BOTANY. reproduction. Fig. 92. Thread of spiro- gyra, showing long cells, chlorophyll band, nucleus, strands of proto- plasm, and the granular wall layer of protoplasm. If we select mats of spirogyra which have lost their deep green color, we are likely to find differ- ent stages of this sexual process, which in the case of spirogyra and related plants is called conjugation. Demonstration 30. 200. To demonstrate the conjugation of spiro- gyra. — From a tangle of the threads on a glass slip, which are conjuga- ting, mount a few in water, tease the threads apart, place on a cover glass, and prepare for observation under the microscope. Let the pupils sketch conju- gating cells, and make notes upon the different stages of the passage of the protoplasm, and on the other characters of the fruiting threads, as outlined below. 201. Conjugation. — If the material is in the right condition we will see in certain of the cells an oval or elliptical body. If we note carefully the cells in which Fig. 93. Zygospores of spirogyra. these oval bodies are situated, there will be seen a tube at one side which connects with an emptycell of a thread which lies near as shown in fig. 93. If SPIROGYRA. 117 we search through the material we may see other threads con- nected in this ladder fashion, in which the contents of the cells are in various stages of collapse from what we have seen in the growing cell. In some the protoplasm and chlorophyll band have moved but little from the wall ; in others they form a mass near the centre of the cell, and again in others we will see that the content of the cell of one of the threads has moved partly through the tube into the cell of the thread with which it is connected. This suggests to us that the oval bodies found in the cells of one thread of the ladder, while the cells of the other thread were empty, are formed by the union of the contents of the two cells. In fact that is what does take place. This kind of union of the contents of two similar or nearly similar cells is conjugation. The oval bodies which are the result of this con- jugation are zygotes, or zygospores. When we are examining living material of spirogyra in this stage it is possible to watch this process of conjugation. Fig. 94 represents the different stages of conjugation of spirogyra. 202. How the threads conjugate, or join. — The cells of two threads lying parallel put out short processes. The tubes from two opposite cells meet and join. The walls separating the contents of the two tubes dissolve so that there is an open communication between the two cells. Each one of these cells corresponds to a sexual organ. This process of conjugation is a sexual process. The process here is a very simple one be- cause any cell of the thread without any particular change in size or form may become a sexual organ. The cell which loses its protoplasm is the supplying cell, while the one in which th e zygospore is formed is the receiving cell. Before the movement of the protoplasm begins we cannot tell which is to be the sup- plying cell or the receiving cell. The passage of the protoplasm from one cell to another can only be seen under the most favorable conditions, and then with living material. It is possible, howevei, in preserved material n8 BOTANY. to find cells which have the protoplasm in some of these different stages. When the zygospores are being studied one should look for some cells in these stages. \=\ ]— Fig. t)4. Conjugation in spirogyra; from left to right beginning in the upper row is shown the gradual passage of the protoplasm from the supplying cell to the receiving cell. 203. The zygospore. — This zygospore now acquires a thick wall which eventually becomes brown in color. The chlorophyll color fades out, and a large part of the protoplasm passes into an oily substance which makes it more resistant to conditions which would be fatal to the vegetative threads. The zygospores are capable therefore of enduring extremes of cold and dry- ness which would destroy the threads. They pass through a " resting'' period, in which the water in the pond may be frozen, or dried, and with the oncoming of favorable conditions for growth in the spring or in the autumn they germinate and produce the green thread again. For further reading on spirogyra and its relatives see the author's larger " Elementary Botany," Chapter XV. SPIKOG YRA. II 9 Synopsis. Vegetative stage ; single unbranched threads, composed of cylindrical cells end to end. Cells all alike. Grows by division and elongation of all the cells. Spirogyra. -j s exua l stage ; conjugation of like cells. Receiving and supplying cells, not differentiated. Result of conjugation, a zygospore. The zygospore after a period of rest produces the spirogyra thread again. Material. — Spirogyra in conjugation, showing different stages, as well as the zygospores. The material may be collected fresh, or it may be preserved in 2% formalin collected in advance or purchased from supply companies. Microscope, etc. CHAPTER XX. THE GREEN FELT: VAUCHERIA. 204. Description of vaucheria. — The plant vaucheria usually occurs in dense mats floating on the water or lying on the damp soil. The texture and feeling of one of these mats reminds one of" felt," and the species are sometimes called the " green felts. " The threads are quite jSHHk coarse and are branched. Upon exami- i|?w$*| nation with the mi- croscope we find that the isBllHlr threads are contin- uous, that is, there are MW'W'm no cross-walls as in spirogyra dividing the m/$PW& thread up into short cells. The chlorophyll is JkM in small oval bodies scattered over the inside BSmB °* tne wa ^ °f tne tube. These are the char- §?$*$& acters of the vegeta- tive threads. A portion of m%^m a vegetative thread is shown m fig. 95. Cross- fp|&OT|# walls are formed only where reproductive fflMxM cells or organs are formed, which cut their gM&klji off from the re- Fig. 95. Portion of branched thread of vaucheria. mainder of the vegetative thread. This plant multiplies in several ways which would be too tedious to detail here. The sexual reproduction,* however, should be studied if possible, * Oedogonium may be studied in place of vaucheria if preferred and if material is more easily obtained. Vaucheria is usually more abundant and 120 THE GREEN FELT: VAUCHERIA. 121 since the organs of reproduction can be readily seen, usually much easier to study than in any of the plants belonging to the higher groups. If fresh material is not at hand, that which has been preserved in alcohol or formalin will serve very well. Often excellent material is to be found in greenhouses growing on the soil of pots during the winter, especially if one obtains from outside in the autumn some bulbs of arisaema (jack-in-the- pulpit) with soil near them for potting. Fresh material of vaucheria in fruit is found easily during the autumn or spring. At this time a quantity should be preserved. The sexual organs are usually more abundant when the threads appear somewhat yellowish or yellow green. Exercise 43. 205. Gross characters of vaucheria. — If fresh material is at hand which was growing in water, note how firmly the threads are tangled together ; compare with spirogyra in this respect. Can you make out in this condition that the threads are branched? This branched condition of vaucheria is one of the reasons for the dense tangle of threads. Note the coarse feeling ; compare with spirogyra in this respect. If material on the soil is at hand, note that it is not necessary that all species grow in water. Note here also the dense tangle of threads. Lift up a tuft with the needle ; compare the effect on the threads with that of spiro- gyra when a. tuft of the latter is lifted in the same way. Compare the " feeling " of the threads with that of spirogyra. Demonstration 31. 206. Sexual reproduction in vaucheria. — Mount a few threads of fruiting vaucheria in water for microscopic study. If prepared slides are at hand they will answer for the demonstration. Let each pupil make a sketch of the sexual organs, and make notes of the form of the same ; also note the con- tinuity of the threads, cross-walls* only being formed in connection with the reproductive organs. Let them compare the different stages found in the formation of the ripe egg. both kinds of the sexual organs are more easily found and understood, those of oedogonium being more complicated. See Chapters XVI and XVII of the author's larger "Elementary Botany." 122 BOTANY. 207. Vaucheria sessilis; the sessile vaucheria. — In this plant the sexual organs are sessile, that is they are not borne on. a stalk as in some other species. The sexual organs usually occur several in a group. Fig. 96 represents a portion of a fruiting plant. 208. Sexual organs of vaucheria. Antheridium. — The antheridia are]short, slender, curved branches Fig. 96. Young antheridium and oogonium of Vaucheria , , . , t sessilis, before separation from contents of thread by from a main thread. A a sep um. septum is formed which separates an end portion from the stalk. This end cell is the antheridium. Frequently it is collapsed or empty as shown in fig. 97. The protoplasm in the antheridium forms numerous small oval bodies each with two slender lashes, the cilia. When these are formed the antheridium opens at the end and they Fig. 97. Vaucheria sessilis, one antheridium between two oogonia. escape. It is after the escape of these spermatozoids that the antheridium is collapsed. Each spermatozoid is a male gamete. 209. Oogonium. — The oogonia are short branches also, but they become large and somewhat oval. The septum which separates the protoplasm from that of the main thread is as we see near the junction of the branch with the main thread. The THE GREEN FELT: VAUCHERIA. 1 23 oogonium, as shown in the figure, is usually turned somewhat to one side. When mature the pointed end opens and a bit of the protoplasm escapes. The remaining protoplasm forms the large rounded /M^^li egg cell which fills the wall of the oogonium. In some of the o< igonia which ^MS^¥ « \ we examine this egg is sur- rounded by a thick brown „ . . .,. Flg - ' 8 ; . . . J Vauchena sessilis ; oogonium opening and emit- wall, with Starchy and oily ting a bit of protoplasm ; spermatozoids ; sperma- J J tozoids entering oogonium. (After Pringsheim and contents. This is the fer- Goebei.) tilized egg (sometimes called here the oospore). It is freed from the oogonium by the disintegration of the latter, sinks into the mud and remains here until the following autumn or spring, when it grows directly into a new plant. The spermatozoids are very difficult to see and one should not expect to study them here. Fertilization is brought about by the spermatozoids swimming in at the open end of the oogonium, when one of them makes its way down into the egg and fuses with the nucleus of the latter. 210. Vaucheria compared with spirogyra. — In vaucheria we have a plant which is very interesting to compare with spirogyra in several respects. In spirogyra growth takes place in all cells, that is in all parts of the thread, while in vaucheria growth is confined to the ends of the threads and the ends of the branches. This is a distinct advance on spirogyra. Again in spirogyra any part of the thread (any cell) may become one of the sexual organs. In vaucheria the sexual organs are special branches, which are short, and further, the two organs are different in size so that they can readily be distinguished long before the time for fertilization. Then in vaucheria the supplying cell does not give all its content to the receiving cell, but only a bit of the protoplasm in the form of a minute body, the spermatozoid. > 124 BOTANY. Vaucheria. Sexual organs differentiated. Synopsii. Vegetative stage ; branched threads, continuous, growth con- fined to the ends of the threads and ends of the branches. Sexual stage ; fertilization of an egg by a minute sperm nu- cleus. Antheridium (male organ). Contains num- bers of small spermatozoids. Oogonium (female organ). Contains one egg. Result of fertilization is the formation of a fertilized egg (oospore), which after a period of rest grows into the vau- cheria plant again. Material. — Freshly collected material of one of the species of vaucheria which is in fruit. It can be obtained from the water of ponds or ditches, or it is very often found growing on soil of pots in greenhouses. If preferred it may be collected in advance and be preserved in 2% formalin, or it may be purchased of supply companies. Microscope, etc. CHAPTER XXL FUNGI: THE BLACK MOULD. Demonstration 32. 211. To grow the mould. — This plant maybe grown byplacing old bread, or partly decaying fruits, as bananas, or the peelings of lemons or oranges in a moist chamber. Set this in a warm place for about one week. Then the plant may be grown on potatoes as described in paragraph 49, or one may take the material for study directly from the bread. It should be studied before it becomes very old. Exercise 44. 212. Mycelium. — Before the black heads of the fungus appear, note the delicate fluffy white tufts of threads which appear on the surface of the bread or other substance on which the fungus is growing. These threads are the mycelium, and a single thread is a mycelium thread, or " hypha." Search on the margins of old cultures where the threads come in contact with paper (some sheets of paper should be placed by the sides of the cul- tures) or the sides of the vessels for " runners," long threads of mycelium which touch the place of support here and there. Are there tufts of upright threads at the points of contact which bear black heads ? Try to find the connection of the black threads with the creeping mycelium. If the mycelium has not been studied in a previous chapter the teacher can mount some here for demonstration. Let the pupils note the branched, colorless threads, and that there are no cross-walls. Note the granular protoplasm. At the microscope let each pupil note the long dark-colored stalks which bear the rounded "heads" ; the latter are the sporangia. If the spores are mature the sporangium wall is perhaps broken and the spores more or less scattered. If so, note the remnant of the wall as a small collar below the enlarged end of the stalk. The enlarged end of the stalk is the ' ' colu- mella." In the younger stages of the sporangium, note the columella arched up within the sporangium. Trace the stalks down to their attach. i«5 126 BOTANY. ment with the mycelium. Is there only one at this point of attachment, or are there several? Are there any rhizoids present at the point of attach- ment ? Sketch the different stages. 213. Description of the mucor fruit. — We shall probably note at once that the stalks or upright threads which support the heads are stouter than the threads of the mycelium. These upright threads soon have formed near the end a cross- Fig. 99. Portion of banana with a mould (Rhizopus nigricans) growing on one end. wall which separates the protoplasm in the end from the remainder. This end cell now enlarges into a vesicle of con- siderable size, the head as it appears, but to which is applied the name of sporangium (sometimes called gonidangium, because it encloses the gonidia). At the same time that this end cell is enlarging the cross^wall is arching up into the interior. This forms the columella. All the protoplasm in the sporangium now divides into gonidia. FUNGI; THE BLACK MOULD. 127 Fig. too. Group of sporangia of a mucor (Rhizopus nigricans) showing rhizoids and the stolon extending from an older group. These are small rounded or oval bodies. The wall of the sporangium becomes dissolved, except a small collar around the stalk which remains attached be- low the columella (fig. 101). By this means the gonidia are freed. These gonidia germinate and produce the mycelium again'. Fig. 101. A mucor (Rhizopus nigricans) ; at left nearly mature sporangium with columella show- ing within ; in the middle is ruptured sporangium with some of the gonidia clinging to the columella ; at right two ruptured sporangia with everted columella. 128 BOTANY. 214. To show the "runners" of the black mould. — If some filter paper is placed by the side of the bread or other substance in the moist chamber, some of the threads of the fungus may be induced. to grow over on to it. If the mould is the species illustrated in fig. ioo there may be seen " runners " like those in the figure with clusters of the sporangia at certain points. Certain threads of the mycelium grow along on the paper like a strawberry ' ' runner ' ' does over the ground. Here and there the mycelium touches the paper and forms little rootlets, and also a group of the sporangia. It is because of this character that the plant is called Mucor stolonifer, the stolon bearing mould. Or the other name of " rhizopus " is given because it is " root- footed. ' ' The black mould. Synopsis. Grows on old bread, decaying fruits, vegetables, etc. Vegetative part ; delicate whitish threads, which branch, and form a cottony-like mat, called the my- celium. Fruiting part ; upright stout threads bear black heads, called sporangia. Several fruiting threads in a cluster, with rhizoids at base. Sporangium. Sporangium wall. Columella. Spores (or gonidia). L Sexual stage not treated of here. Material. — Cultures of the black mould on bread or baked potatoes. See paragraph 49 for making the cultures. Microscope, etc. If conjugation of a mould is desired, it may be purchased of supply com. panies. Fruiting part. ■ CHAPTER XXII. FUNGI (Continued): WHEAT RUST. (Puccinia graminis.) 215. Importance of the rusts. — The fungi known as ' ' rusts " are very important ones to study, since all the species are para- sitic, and many produce serious injuries to crops. Exercise 45. 216. Black rust of wheat. — Dried stalks of wheat or oats with the black spots of this stage of the rust are excellent for the study. Sketch a portion of an affected stalk, showing the spots in natural size and form. With, a hand lens examine the spots more carefully. Observe that the black mass of color has burst through the epidermis of the wheat. Describe the appearance. 217. Bed rust of wheat. — This stage is found abundantly on the leaves of the wheat and oats, etc. Dried leaves which have been pressed are good for the study. Observe the color of the spots, and compare with that of the black-rust spots. Compare the size also. Examine with a hand lens, and determine whether the mass of spores making up the rust color, break through the epidermis. Sketch a portion of the leaf showing the characters observed. 218. Cluster-cup stage on the barberry. — Leaves of the barberry maybe pressed dry and preserved for study. Sketch a leaf showing the location and character of the spots. Describe the form and character of the spots. Ex- amine the spots on both sides of the leaves with a hand lens. Describe what you see. If leaves of the barberry with the cluster cups cannot be obtained some other cluster-cup fungus may be used, but it should be understood that the others are not connected with the wheat rust (except some growing on shrubs closely related to the barberry). Demonstration 33. 219. To demonstrate the different stages of the wheat rust under the micro- scope.— Black rust : with a knife scrape out the material from a few black spots, tease out in water on a glass slip, and mount as usual. Red rust : pre- 129 '3° BOTANY. pare in the same way from the yellow spots. To demonstrate the cluster cups, good cross-sections of the leaf through a spot should be made, or prepared slides should be obtained. Let the pupils sketch the form of the different spores, and other characters, and make notes of the observations. To demonstrate mycelium in the tissues, use the carnation rust which can be obtained in winter in greenhouses where the carnations are grown (see Chapter XV, paragraph 159), or fresh wheat leaves may be preserved in alcohol for making sections. 220. Wheat rust (Puccinia graminis). — The wheat rust is one of the best known of these fungi, since a great deal of study has been given to it. One form of the plant occurs in long \ Fig. 102. "Wheat leaf with red rust, natural size. Mg. 106 Single sorus. Fig. 103. Fig. 104. Fig. 105. Portion of leaf Black rust. Enlarged, enlarged to show Natural size, sori. Figures 102, 103. — Puccinia graminis, red rust stage (uredo stage). Figures 104-106. — Black rust of wheat, showing son of teleutospores. reddish-brown or reddish pustules, and is known as the " red rust" (figs. 102, 103). Another form occurs in elongated black pustules, and this form is the one known as the " black rust" (figs. 104-107). These two forms occur on the stems, blades, etc., of the wheat, also on oats, rye, and some of the grasses. 221. Teleutospores of the black-rust form. — Scrape off some portion of one of the black pustules (sori), tease it out in water on a slide, and examine with a microscope, to see numer- FUNGI: WHEAT KUST, 131 ous spores, composed of two cells, and having thick, brownish walls as shown in fig. 108. Usually there is a slender brownish stalk on one end. These spores are called ieleutospores. They are somewhat oblong or elliptical, a little constricted where the septum separates the two cells, and the end cell varies from ovate Fig. 107. Head of wheat showing black .rust spots on the chaff and awns. Fig. 108. Teleutospores of wheat rust, Showing two cells and the pedicel. Fig. iog. Uredospores of wheat rust, one showing remnants of the pedicel. to rounded. The mycelium of the fungus courses between the cells, just as is found in the case of the carnation rust, which belongs to the same family (see Chapter XV). 222. Uredospores of the red-rust form. — If we make a similar preparation from the pustules of the red-rust form we shall see that instead of two-celled spores they are one-celled. 132 BOTANY. The walls are thinner and not so dark in color, and they are covered with minute spines. They have also short stalks, but •e^gj^ these fall away very easily. These one- MSwIiSl^ celled spores of the red-rust form are called ' ' uredospores. ' ' The uredospores and teleutospores are sometimes found in the same pustule. It was once supposed that these two kinds of spores belonged to different plants, but now it is known that the one-celled form, the uredospores, is a form developed earlier in the season than the teleu- tospores. 223. Cluster- cup form on the barberry. — On the bar- berry is found still another of the Fig. no. Barberry leaf with two diseased spots, natural size. Figures 153-135. Fig. in. Single spot showing cluster cups enlarged. split margin -Cluster-cup stage of "wheat rust. Two cluster form cups more en- larged, showing w heat rust, the sniit marcrin. ' cluster cup ' ' stage. The pustules on the under side of the barberry leaf are cup-shaped the cups being partly sunk in the tissue of the leaf, while the rim is more or less curved backward against the leaf, and split at several places. These cups occur in clusters on the affected spots of the barberry leaf as shown in fig. 1 1 1. Within the cups numbers of one-celled spores (orange in color, called aecidiospores) are borne in chains from short branches of the mycelium, which fill the base of the cup. In fact the wall of the cup (peridium) is formed of similar rows of cells, which, instead of separating into spores, remain united to form a wall. These cups are usually borne on the under side of the leaf. FUNGI: WHEAT RUST. 133 For a fuller study of the wheat rust and of other fungi see the author's larger " Elementary Botany," Chapters XX, XXI. Wheat rust. Fig. 113- Section through leaf of barberry at point affected with the cluster-cup stage of the wheat rust; spermagonia above, aecidia below. (After Marshall- Ward.) Synopsis. A parasite on grains, grasses, and on the barberry. Vegetative part of plant ; mycelium growing within the tissues of the host. Fruiting part of the plant. 1st. Red rust (one-celled spores in pustules on blades and stems of the wheat). 2d. Black rust (two-celled spores in pustules on the blades and stems of the wheat). F f rm J 3^* Cluster cup (one-celled spores in chains within a structure called a peridium, or cup on leaves and stems of barberry). 4th. Spermagonia (small flask-shaped bodies accompanying the cluster cups, of un- known function). Material. — Dried stalks of wheat or oats with the black -rust spots ; dried leaves with the red-rust spots ; leaves of the barberry with the cluster cups. (If the barberry leaves cannot be obtained, another species of cluster cup may be used to illustrate the tecidial stage, but it should be remembered that other cluster cups are not connected with the life history of the wheat rust. ) For satisfactory studies of the cluster-cup stage, sections through the cup should be made from fresh material, or sections already made may be pur- chased from the supply companie$. ^ Microscope, etc. CHAPTER XXIII. FUNGI (Concluded): THE WILLOW MILDEW. (Uncinula salicis.) 224. Description of the mildew. — The willow mildew belongs to a very interesting group of the fungi known as the powdery mildews. These mildews are very common on the leaves, and even stems, flowers, and fruits, of various plants. It is a very easy matter to find them during the summer or late autumn and to press a number of the leaves to preserve for future study. The mycelium grows on the outside of the parts of the host, so that it gives a whitish, "mildewed" appearance to the affected places. Very short branches (haustoria) from the mycelium enter the epidermal cells of the host and draw nutri- ment from ihe leaves or other parts, and supply the fungus with the materials for growth. This nutriment is taken at the expense of the host, and often considerable injury to it is thus done, which results in a sickly appearance of the host, or even in a deformity, the leaves or stems being curled or dwarfed. Immense numbers of small, colorless spores (gonidia) are borne in chains on some of the threads, and these piled up on the surface of the leaf give it a powdered appearance. After this powdery stage of the fungus has formed, another kind of fruit of the fungus is developed. This may be detected by numerous minute black specks seated on the white mycelium, as shown in fig. 114. Each one of these black specks is a fruit body. 134 FUNGI: THE WILLOW MILDEW. *35 Exercise 46. 225. The Willow Mildew. — Take dried leaves, or those freshly collected, which show some of the whitish mycelium, and numerous black fruit bodies- Fig. 114. ^ Leaves of willow showing willow mildew. The black dots are the fruit bodies (perithecia) seated on the white mycelium. Observe the white mycelium. • Is it scattered unevenly over the surface of the leaf, or does it form more or less circular spots? Is there any difference in I36 BOTANY. the color or appearance of the leaf in the spots where the mycelium is seated ? * Try to remove some of the mycelium with a needle, to see that it consists of threads which are on the surface of the leaf. Fruit bodies. Observe the minute black specks seated on the mycelium. Are all of them black, or dark in color ? If there are any yellowish ones how do they compare with the dark ones as to size ? How do they compare as to age ? With a hand lens examine them more carefully. Can you see any dark-colored threads extending out from the fruit body ? Can you see their form ? Demonstration 34. 226. The fruit bodies.— Place a drop of water on a glass slip. Touch the point of a scalpel or knife to the water and then scrape the surface of the leaf gently where there are a number of the black bodies. The capillarity of the water will hold some of the fruit bodies to the point of the knife. From this tease off the fruit bodies with * needle into the drop of water on the slip. Separate them well and put on the cover glass. Let each pupil examine the fruit bodies under the microscope. Note the form of surface markings and the appendages. Sketch. 227. The asci and spores which they contain. — Take this same prep- aration, crush the fruit bodies by gently pressing on the cover glass above them, until the fruit bodies are cracked open, and some of the sacs containing the spores are pressed out (see fig. 116). Let the pupils examine and sketch them. The gonidia may be demonstrated by using leaves where the fruit bodies are not abundant, but which possess an abundance of the mycelium (see fig. IIS). 228. Fruit bodies of the willow mildew. — On the mycelium there appear numerous black specks scattered over the affected places of the leaf. These are the fruit bodies (perithecia). When examined with a low power of the microscope, each one is seen to be a rounded body, from which radiate numerous * If the leaves are not old the portions where the mycelium is seated may be more or less yellow, showing an injury ; but if the leaves are quite old and nearly ready to fall, the green color may have disappeared more rapidly from the unaffected parts of the leaf, for the fungus gives some stimulus to the leaf, and often this is manifested by the green color remaining longer in the affected parts of the old leaves. FUNGI: THE WILLOW MILDEW. 137 filaments, the appendages. Each one of these appendages is coiled at the end into the form of a little hook. Because of these hooked appendages this genus is called uncinula. This rounded body is the perithecium. 229. Asoi and ascospores. — While we are looking at a few of these through the microscope with the low power, we should press on the cover glass with a needle until we see a few of the Fig. 116. Fig. 117. Willow mildew ; bit of mycelium with erect conidiophores, bearing chain of gonidia ; ' gonidium at left germinating. Fruit of willow mildew, showing hooked ap- Fruit body of an- pendages. Genus uncinula. other mildew with Figures 116, 117— Perithecia (perithecium) dichotomousappen- of two powdery mildews, showing escape of dages. Lrenus asci containing the spores from the crushed microspna^ra. fruit bodies. perithecia rupture. If this is done carefully we see several small ovate sacs issue, each containing a number of spores, as shown in fig. 116. Such a sac is an ascus, and the spores are ascospores. 138 BOTANY. Synopsis. — Vegetative part of the plant : mycelium on the surface of the host sends suckers (haustoria) into the cells of the host. Propagative stage of the plant: short erect threads which Willow mildew. \ bear chains of spores (gonidia). Fruiting part of the plant (perfect stage). Perithecium with hooked appendages. Perithecium contains sacs (asci). The sacs contain the spores (ascospores). Uaterial. — Dried and pressed leaves of willow with the white mildew, also older stages showing the numerous black ' ' specks, ' ' the fruit bodies, of the mildew. Other species of the mildew may be used if preferred. Microscope, etc. , CHAPTER XXIV. LIVERWORTS (HEPATICyE). {Marchantia polymorpha.') 230. Form of marchantia. — The marchantia (M. polymorpha) has been chosen for study because it is such a common and easily obtained plant, and also for the reason that with com- parative ease all stages of development can be obtained. It illustrates also very well certain features of the structure of the liverworts. , The plants are of two kinds, male and female. The two different organs, then, are developed on different plants. In appearance, however, before the beginning of the structures which bear the sexual organs they are practically the same. The plant forms a flattened, green, leaf-like body which lies on the damp soil or clings closely to wet rock. It is shaped somewhat like an irregular ribbon, the margins more or less wavy, and the plant is branched in a forked manner as shown in fig. 1 1 8. Upon the under side are numerous hair-like bodies, the "rhizoids, " which serve the purpose of root hairs in absorbing food solutions, and they also attach the plant to the substratum. The growing point of the thallus is in the little depression at the free end. For fuller studies of the liverworts and for the sexual organs see the author's larger " Elementary Botany," Chapters XXII and XXIII. Exercise 47. 231. Male plants. — Examine both surfaces of the "thallus" as the leaf- like body of the liverwort is called. Note where the rhizoids are attached. Sketch the plant, showing the rhizoids, the form of the thallus, and the urn- 139 14° BOTANY. brella-shaped bodies on the upper surface. Note that the expanded part of this umbrella-shaped structure is crenate on the margin, giving it a lobed appearance, and that these lobes radiate from the centre. Search for little pits opening on the upper surface of these structures ; these are the opening of the chambers where the antheridia are borne. With a hand lens examine the upper surface of the thallus. Can you see that it is marked oft into diamond-shaped areas, with a minute opening in the centre of each ? These openings are the stomates of the thallus. Observe that the central line of the thallus is thicker than the margins. This is the midrib. Exercise 48. 232. Female plants. — Study these in a similar way, and compare. The thallus is very similar, the greater point of difference being in the umbrella- shaped structures. Note that the expanded portion is more deeply lobed, forming prominent rays. On the under surface observe the delicate hanging fringes. Underneath these the archegonia are borne. If material with ripe fruit is at hand preserved in formalin, observe the rounded capsules on short stalks which protrude from beneath these curtains. Sketch and describe all parts of the plant. Exercise 49. 233. Sterile plants hearing, cups and gemmae. — Study these in a similar way. Note that the umbrella-shaped structures are absent. Observe the minute cups on the upper surface. With a hand lens note the minute flat- tened green bodies within the cups. These are the gemmae, or buds, and serve as one means of propagating the plant. Demonstration 35. (May be omitted. ) 234. Sexual organs. — The teacher may make demonstrations to show the sexual organs, and the- spores and elaters. For the antheridia section the antheridial receptacle, and for the archegonia section the archegonial recep- tacle. Unless one is familiar with methods of sectioning these structures, it would be better to purchase prepared sections of these organs for the demon- stration. See fig. 123. Demonstration 36. 235. Spores and elaters. — When the fruit is ripe (see fig. 125) and the spores and elaters are escaping some may be mounted. They may be mounted in glycerine jelly. Such mounts will keep for a long time if cared LIVERWORTS. 141 for, and will serve for successive years' study. Mounts may also be made from material preserved in formalin. Tease out a few of the spores and elaters from the capsule with needles, in a drop of alcohol on the glass slip. Melt a bit of glycerine jelly on a cover glass and just as the alcohol is evap- orating from the slide lower the glycerine with the cover over them. See figure 126. Spores and elaters from some other liverwort may be used if more convenient. 236. Antheridial plants. — One of the male plants is figured at 118. It bears curious structures, each held aloft by a short stalk. These are the antheridial re- ceptacles. Each one is circular, thick, and shaped somewhat like a bi-convex lens. The upper surface is marked by radiating furrows, and the margin is crenate. Then we note, on careful examination of the upper surface, that there are numerous minute open- ings. If we make a thin section of this structure per- pendicular t o its surface we shall be able to unravel the mys- tery of its in- terior. Here we see, as shown in fig. 1 1 9, that each one of these little openings on the surface is an entrance to quite a large cavity. Within each cavity there is an oval or elliptical body, supported from the base of the cavity on a short stalk. This is an antheridium, and one of them is shown still more enlarged in fig. 120. This shows the structure of the anther- idium, and that there are within several angular areas, which are divided by numerous straight cross-lines into countless tiny cuboidal cells, the sperm mother cells. Each of these Fig. 118. Male plant of marchantia bearing antheridiophores. 142 BOTANY. changes into a swiftly moving body resembling a serpent with two long lashes attached to its tail. F,g. i 9. Section of antheridial receptacle from male plant of Marchantia polymorpha, showing cavities where the antheridia are borne. 237. Archegonial plants. — In fig. 122 we see one of the female plants of marchantia. Upon this there are also very curious structures, which remind one of miniature umbrellas. Fig. 120. Section of antheridium of mar- chantia, showing the groups of sperm mother cells. Fig. 12 1. Spermatozoids of marchantia, uncoiling and one extended, showing the two cilia. The general plan of the archegonial receptacle is similar to that 01 the antheridial receptacle, but the rays are more pronounced, LIVERWORTS. 143 and the details of structure are quite different, as we shall see. Underneath the arms there hang down delicate fringed curtains. If we make sections of this in the same direction as we did of the antheridial receptacle, we .shall be able to find what is Fig. 122. Marchantia polymorpha, female plants bearing archegoniophores. secreted behind these curtains. Here we find the archegonia, but instead of being sunk in cavities their bases are attached to the under surface, while the delicate, pendulous fringes afford them protection from drying. 144 BOTANY. 238. Sporogonium of liverworts. — If the sporogonium (spore-case) of marchantia cannot be obtained those of any other liverwort may be used. 239. Sporogonium of marchantia. — If we examine the plant shown in fig. 124 we shall see oval bodies which stand out between the rays of the female receptacle, supported on short stalks. These are the sporogonia, or spore-cases. We can see that some of the spore-cases have opened, the wall splitting., down from the apex in several lines. This is caused by the drying of the wall. These toothlike divisions of the wall now curl backward, and we can see the yellowish mass of the spores in slow motion, falling here and there. It appears also as if there were twisting threads which aided the spores , ; in becoming freed from the capsule. Marchantia poiymorpha, 240. Spores and elaters. — If we take archegonium with egg ; p, curtain which hangs down a bit of this mass of spores and mount around the archegonia; „e, egg; v, venter of archego- it in water for examination with the mum; », neck of .archego- nium. . ■■> microscope, we shall see that, besides the spores, there are very peculiar thread-like bodies, the mark- ings of which remind one of a Hwisted rope. These are very long cells froni the' inner ;; part of the spore-case, and their walls are marked'Iby spiral thickenings. • This causes them in drying, and also when they absorb moisture, to twist and curl in all sorts of ways. They thus aid in pushing the spores out of the capsule as it is drying. 241. How marchantia multiplies. — New plants of mar- chantia are formed by the germination of the spores, and growth of the same to the thallus. The plants may also be multiplied by parts of the old ones breaking away by the action of strong currents of water, and when they lodge in suitable LIVERWORTS. 145 places grow into well-formed plants. As the thallus lives from year to year and continues to grow and branch the older por- tions die off, and thus separate plants may be formed from a former single one. 242. Buds, or gemmae, of marchantia. — But there is an- other way in which marchantia multiplies itself. If we exam- 124. Archegonial receptacles of marchantia bearing ripe sporo- gonia. The capsule of the sporogonium projects outside, while the stalk is attached to the receptacle underneath the curtain. In the left figure two of the capsules have burst and the elaters and spores are escaping. Fig 125. Section of archegonial receptacle of Marchantia polymorpha ; ripe sporogonia One is open, scattering spores and elaters; two are still enclosed in the wall of the archegonium. The junction of the stalk of the sporogonium with the receptacle is the point of attach- ment of the sporophyte of marchantia with the gametophyte. ine the upper surface of such a plant as that shown in fig. 127, we shall see that there are minute cup-shaped or saucer-shaped 146 BOTANY. vessels, and within them minute green bodies. When these green buds free themselves from the cups they come to lie on one side and develop into new plants. It does not matter on Fig. 126. Elater and spore of marchantia. j/, spore ; rnc, mother cell of sporesj showing partly formed spores. what side they lie, for whichever side it is, that will develop into the lower side of the thallus, and will form rhizoids, while the upper surface will develop the stomates. LIVERWORTS. H7 ^mm. Fig. 127. Marchantia plant with cupules and gemma? ; rhizoids below. Synopsis. Plant body ; flattened ribbon-like, green, with rhizoids on under surface ; grows in moist situations. 'ist. Plant with buds in little cups. The buds escape and propagate the plant. 2d. Male plants. Antheridial receptacle. Vegetative part. Antheridial cavities. \fls\ rpliantia Three forms. "" Antheridium. rJLcLl *- HlX 1 1 LI CL (A liver- ' Spermatozoids. wort). 3d- Female plants. Archegonial receptacle. Archegonium. Egg. * 1 Capsule wall. Fruit capsule. -1 Spores. Fruiting part. , ( Elaters. Short stalk attaching fruit body to archego- nial receptacle. I4§ BOTANY. Material and apparatus. — Freshly collected plants, or if these cannot be had, plants preserved in 2% formalin, or in alcohol, may be used. Some plants dry are often useful if they are not to be had in any other condition. Plants with the cups and gemmae; male plants; and female plants. For the study of the fruit bodies plants must be had either fresh (but this is quite impossible since they ripen in June and July) or better, plants with ripe fruit bodies may be preserved in 2% formalin. For the demonstration of the sexual organs, and of the spores and elaters, the teacher may make sections, or purchase sections of supply companies. Hand lenses, or simple dissecting microscopes. Microscope, etc., for demonstrations 35 and 36. CHAPTER XXV. MOSSES (MUSCI). (Polytricbum, or mnium.) 243. The moss plant. — We are now ready to take up the more careful study of the moss plant. There are a great many kinds of mosses, and they differ greatly from each other in the finer details of structure. Yet there are certain general re- semblances which make it convenient to take for study almost any one of the common species in a neighborhood, which forms abundant fruit. Some, however, are more suited to a first study than others. Those mosses in which there is a marked difference between the male* and female plants, like polytrichum, bryum, mnium, etc., are most suitable for the purpose. The male plants of these genera have the leaves at the end of the stem in a broad rosette. Both male and female plants should be collected, and the fruiting plants also. The latter bear above the leafy portion a stalked capsule. Polytrichum (known as pigeon wheat moss) is suggested here for the practical study, while mnium is here used to illustrate the mosses. It will be found useful occa- sionally to study a plant that is different from the one fully illustrated in the book, since it givas the student an opportunity for more independent work. The Pigeon Wheat Moss (Polytrichum). Exercise 50. 244. The fruiting plant. — Take entire plants, those with leafy stems bearing the stalked capsule. Sketch the entire plant. Note the stem (axis) and the three rows of leaves. Search for the rhizoids at the lower end of the stem. What is their color ? Observe the capsule, its form. 149 15° BOTANY. Among the material search for those capsules representing several different ages. Very young ones are often collected when there appears to be nothing but a slender stalk, the capsule not yet being fully developed. Search on the capsule for the hairy hood, known as a calyptra. Remove this ; note its form. Now at the end of the capsule note the conic lid (the operculum). Remove this, or examine older capsules where the lid has fallen away. Note the numerous teeth. When the lid is removed, are there any small granules (the spores) escaping ? Compare the shape of the capsules of different ages. Exercise 5 1 . 245. The male plants Note the broad rosette of leaves at the end of the stem. Compare the arrangement of the leaves here with those lower down on the stem. Sketch. The antheridia (sing, antheridium) are borne in the centre of the rosette. 246. The female plants. — Compare with the male plants : what is the difference in the arrangement of the leaves? Can you suggest why the leaves are arranged differently in the two plants ? Demonstration 37. (May be omitted when necessary. ) 247. Demonstration of spores, etc. — The teacher can prepare mounts of the spores, and of a portion of the mouth (peristome) of the capsule for study. If it is desired also leaves may be examined under the microscope. The leaves are made up of a single layer of cells, except at the middle line where the cells are several layers thick, and long and narrow. The cells in the middle line form the "midrib" of the leaf. The teacher can also make sections through the ends of the male and female plants to demonstrate the sexual organs, or prepared slides representing these may be purchased for demonstration. Description of the Moss, Mnium. 248. Mnium. — We will select here the plant shown in fig. 128. This is known as a mnium (M. affine), and one or another of the species of mnium can be obtained without much difficulty. The mosses, as we have already learned, possess an axis (stem) and leaf-like expansions, so that they are leafy- stemmed plants. Certain of the branches of the mnium stand upright, or nearly so, and the leaves are all of the same size at any given point on the stem, as seen in the figure, MOSSES. IS! There are three rows of these leaves, and this is true of most of the mosses. 249. Habit of milium. — The mnium plants usually form quite extensive and pretty mats of green in shady moist woods or ravines. Here and there among the erect stems are prostrate ones, with two rows of prominent leaves so arranged that they remind one of some of the leafy-stemmed liverworts. If we examine some of the leaves of the mnium we will see that the greater part of the leaf consists of a single layer of green cells, just as is the case in the leafy-stemmed liverworts. But along the middle line is a thicker layer, so that it forms a dis- tinct midrib. This is characteristic of Fig. 128. Portion of moss plant of Mnium affine, showing two sporogonia from one branch. Capsule at left has just shed the cap or operculum ; capsule at right is shedding spores, and the teeth are bristling at the mouth. Next to the right is a young capsule with calyptra still attached; next are two spores enlarged. the leaves of mosses, and is one way in which they are sepa- rated from the leafy-stemmed liverworts, the latter never having a midrib. 152 BOTANY. 250. The fruiting moss plant. — In fig. 128 is a moss plant " in fruit," as we say. Above the leafy stem a slender stalk bears the capsule, and in this capsule are borne the spores. 251. Sporogonium of the moss. — The sporogonium (spore- case) of a moss is illustrated in fig. 128. The sporo- gonium is the portion repre- sented above the leafy part, and consists of a stalk and capsule. This was devel- oped from the fertilized egg. Fig. 129. Female plant (gametophyte) of a moss (mnium), showing rhizoids below, and the tuft of leaves above which protect the archegonia. Fig. 130. Male plant (gametophyte) of a moss (mnium) showing rhizoids below and the antheridia at the. centre above surrounded by the rosette of leaves. The capsule is nearly cylindrical, bent downward, and supported on a long slender stalk. MOSSES. 153 Upon the capsule is a peculiar cap, shaped like a ladle or spatula, the calyptra. 252. Structure of the moss capsule. — At the free end on the moss capsule as shown in the case of mnium in fig. 128, after the remnant of the archegonium falls away, there is seen a conical lid which fits closely over the end. When the capsule is ripe this lid easily falls away, and can be brushed off, so that it is necessary to handle the plants with care if is desired to preserve this for study. 253. Opening of the capsule. — When the lid is brushed away as the capsule dries more, we see that the end of the capsule covered by the lid appears " frazzled. " If we examine this end with the microscope we will see that the tissue of the capsule here is torn with great regularity, so that there are two rows of narrow, sharp teeth which project outward in a ring around the opening. If we blow our " breath " upon these teeth they will be seen to move, and as the moisture disappears and reappears in the teeth, they close and open the mouth of the capsule, so sensitive are they to the changes in the humidity of the air. In this way all of the spores are prevented to some extent from escaping from the capsule at one time. 254. The male and female moss plants. — The two plants of mnium, shown in figs. 129, 130, are quite different, as one can easily see, and yet they belong to the same species. One is a female plant, while the other is a male plant. The sexual organs, then, in mnium, as in many others of the mosses, are borne on separate plants. The archegonia are borne at the end of the stem, and are protected by somewhat narrower leaves which closely overlap and are wrapped together. They are similar to the archegonia of the liverworts. The male plants of mnium are easily selected, since the leaves at the end of the stem form a broad rosette with the antheridia, and some sterile threads packed closely together in the centre. The ends of the mass of antheridia can be seen with the naked eye, as shown in fig. 130. 154 BOTANY. Synopsis. Moss plant (Polytrichum or other moss). Plant body, a. small leafy stem, with rhizoids. Protonema (branched green threads which precede the leafy stem). Male plants with a rosette of leaves at the end. Antheridia. Spermatozoids. Female plants, leaves closed together at the end. Archegonia. Archegonium contains egg. Capsule wall. Fruit capusule. Vegetative part of plant. Three forms. Fruiting part. Stalk. Lid. Teeth at mouth. Spores. (The hood is not a part of the capsule, but is the remains of the archegonium.) Material and apparatus. — The pigeon wheat moss (polytrichum) is an ex- cellent one to study, but one should not be confined to this if it is easier to collect other species which show strong differences between male and female plants. Male and female plants, as well as plants with fruit, some of which should possess the "hood," should be preserved dry, or in 2% formalin. Free hand, or prepared, sections of the sexual organs. Apparatus, the same as in Chapter XXIV. CHAPTER XXVI. FERNS (FILICINEyE). {The polypody, or Christmas fern.) 255. Importance of study of ferns. — In taking up the study of the ferns we find plants which are very beautiful objects of nature and thus have always attracted the interest of those who love the beauties of nature. But they are also very interesting to the student, because of certain remarkable peculiarities of the structure of the fruit bodies, and especially because of the intermediate position which they occupy within the plant king- dom, representing in the two phases of their development the primitive type of plant life on the one hand, and on the other the modern type. We will begin our study of the ferns by tak- ing that form which is the more prominent, the fern plant itself. 256. Selection of fern for study. — There are several ferns which answer equally well for study. It is important to have the entire plant, underground stem, roots, and leaves, and what is of especial importance, some of the leaves should have the "fruit dots." The common polypody (Polypodium vulgare) is widely distributed, and will be useful for the practical study, even though the Christmas fern here is used to illustrate the descriptive part. There should, however, be no necessity for limiting the study to a certain species, since in one locality one species can be more easily obtained, while in another locality another species may be more convenient to study. Exercise 52. 257. The fern plant. — Take entire plants, if the common polypody, note the creeping stem (root-stock or rhizome), the numerous brown scales cov- 155 156 BOTANY. ering it, the bud at the anterior end covered also with brown scales. Ob- serve the numerous dark slender roots. Note the leaves, some of them perhaps plain (sterile) on the under side, while others have numerous circular brown or blackish dots, the fruit dots where the sporangia (spore-cases) and spores are borne. Describe the form of the leaf. Name the different parts. Sketch the entire plant. Sketch a portion of the under side of the spore-bearing leaf, to show the fruit dots. Compare the polypody with several other species of ferns if possible. Exercise 53. 258. The scattering of the spores. — If the study is made at a time when the ferns with spores just ripe cannot be collected out doors, get some leaves from greenhouses. Take those leaves where the fruit dots appear quite black, and under the lens the sporangia appear like shiny rounded black bodies. Place a leaf on white paper in a dry room, with the under side uppermost. In the course of an hour or earlier watch for showers of spores which are scattered around the leaf, Sometimes in a dry room these begin to scatter in the course of a few minutes. The success of this exercise will depend on the material being in the right condition. After a little experi- ence in collecting it is not difficult to get the right material. Demonstration 38. 259. To show the sporangia. — These can be shown from sporangia which are just ripe, or from older material which has been dried, or pre- served in formalin or alcohol. Scrape off a few of the sporangia from the "fruit dot." Mount them in water for examination under the microscope. Let each student examine the form and structure. Sketch a sporan- gium seen from the side. Name the different parts, the slender stalk, the enlarged spore-case. In the spore-case make out a prominent row of cells over the back and upper part (the annulus), note the "lip cells" in front, one each side of the place where the sporangium opens. If there are any spores in this preparation note and describe them ; sketch one also. If there are none to be seen in the preparation made for the study of the sporangium the teacher can mount some for study if desired. To see the snapping of the sporangium fresh ripe material may be mounted in water ; then draw under the cover glass some glycerine and watch the result. 260. The Christmas fern. — One of the ferns which is very common in the Northern States, and occurs in rocky banks and woods, is the well-known Christmas fern (Aspidium acrosti- FERN'S. 157 choides) shown in fig. 131. The leaves are the most prominent part of the plant, as is the case with most if not all our native ferns. The stem is very short and for the most part under the surface of the ground, -while the leaves arise very close together, and thus form a rosette as they rise and gracefully bend outward. The leaf is elongate and re- minds one somewhat of a plume with the pinnae ex- tending in two rows on oppo- site sides of the midrib. These pinnae alternate with one another, and at the base of each pinna is a little spur which projects upward from the upper edge. Such a leaf is said to be pinnate. While all the leaves have the same general outline, we notice that certain ones, especi- ally those toward the centre of the rosette, are much narrower from the middle portion toward the end. This is because of the shorter pinnae here. 261. Fruit "dots" (sorus, indusium). — If we examine the under side of such short pinnse of the Christmas fern we see that Fig. 131. Christmas fern (Aspidium acrostichoides). i 5 8 BOTANY. there are two rows of small circular dots, one row on either side of the pinna. These are called the ' ' fruit dots, ' ' or sori (a single one is a sorus). If we examine it with a low power of the microscope, or with a pocket lens, we will see that there is a circular disk which covers more or less completely very minute objects, usually the ends of the latter projecting just beyond the edge if they are mature. This circular disk is what is called the indusium, and it is a special outgrowth of the epidermis of the leaf here for the pro- tection of the spore-cases. These minute objects un- derneath are the fruit bodies, which in the case of the ferns and their allies are called sporangia. This in- dusium in the case of the Christmas fern, and also in some others, is attached to the leaf by means of a short slender stalk which is fast- ened to the middle of the under side of this shield. 262. Sporangia. — If we i, section through the leaf at Rhizome with bases_ of leaves, and roots of the one of the fruit dots, Or if Christmas fern. we tease off some of the sporangia so that the stalks are still attached, and examine them with the microscope, we can see the form and structure of these peculiar bodies. Different views of a sporangium are shown in fig. 137. The slender portion is the stalk, and the larger part is the spore-case proper. We should examine the FERNS. f§9 structure of this spore-case quite carefully, since it will help us to understand better than we otherwise could the remarkable operations which it performs in scattering the spores. 263. Structure of a sporangium. — If we examine one of the sporangia in side vkw as shown in fig. 137, we note a promi- nent row of cells which extend around the margin of the dorsal edge from near the attachment of the stalk to the upper front angle. The cells are prominent because of the thick inner walls, and the thick radial walls which are perpendicular to the inner walls. The walls on the back of this row and on its sides are very thin and membranous. We should make this one Fig- '33- Rhizome of sensitive fern (Onoclea sensibilis\ carefully, for the structure of these cells is especially adapted to a special function which they perform. This row of cells is termed the annulus, which means a little ring. While this is not a complete ring, in some other ferns the ring is nearly com- plete. 264. The lip cells. — In the front of the sporangium is another peculiar group of cells. Two of the longer ones resemble the lips of some creature, and since the sporangium opens between them they are sometimes termed the lip cells. These lip cells i6o BOTANY. are connected with the upper end of the annulus on one side and with the upper end of the stalk on the other side by thin-walled cells, which may be termed connec- tive cells, since they hold each lip cell to its part of the opening sporangium. The cells on the side of the sporangium are also thin-walled. If we now ex- amine a sporangium from the back, or dorsal edge as we say, it will appear as in the left-hand figure. Here we can see how very prominent the annu- lus is. It projects beyond the surface of the other cells of the sporangium. The spores are contained inside this case. 265. Opening of the sporangium and dispersion of the spores. — If we take some fresh fruiting leaves of the Christmas Fig Under side dium spinulosum showing dots (sori). of pinna of Aspi- fruit Fig- '35- Four pinnjE of adiantum, showing recurved margins which cover the sporangia. fern, or of any one of many of the species of the true ferns just at the ripening of the spores, and place a portion of a leaf on a piece of white paper in a dry room, in a very short time we shall see that the paper is being dusted with minute brown objects which fly out from the leaf. Now if we take a portion of the same FERN'S. 161 leaf and place it under the low power of the microscope, so that the full rounded sporangia can be seen, in a short time we note that the sporangium opens, the upper half curls backward as shown in fig. 138, and soon it snaps quickly, to near its former position, and the spores are at the same time thrown for a considerable distance. This movement can sometimes be seen with the aid of a good hand lens. 266. How does this opening and snapping of the sporan- gium take place ? — We are now more curious than ever to see just how this opening and how the snapping of the sporangium takes place. We should now mount some of the fresh sporangia in water and cover with a cover glass for microscopic examination. A drop of glycerine should be placed it one side of the cover ^lass on the slip so that the edge of the glycerine will come in touch with the water. Now as one looks through the micro- scope to watch the sporan- gia, the water should be drawn from under the cover glass with the aid of some bibulous paper, like filter Fig. 136. n ,„ pr nlnrpH ^MceHular capitate Eair. opposite side from the glycerine. As the glycerine takes the place of the water around the sporangia it draws the water out of the cells of the annulus, just as it took the water out of the cells of the spirogyra as we learned some time ago. As the water is 1 62 BOTANY. drawn out of these cells there is produced a pressure from with- out, the atmospheric pressure upon the glycerine. This causes the walls of these cells of the annulus to bend inward, because, as we have already learned, the glycerine does not pass through the walls nearly so fast as the water comes out. 267. "Working of the annulus. — Now the structure of the cells of this annulus, as we have seen, is such that the inner walls and the perpendicular walls are stout, and consequently they do not Fig. 137. Rear, side, and front views of fern sporangium, d, tion, about natural size. t h e terminal portion begins to assume the ap- G YMNOSPERMS. I 9 I pearance of a young female cone or flower. These young female cones, at about the time that the pollen is escaping from the anthers, are long ovate, measuring about 6-10 mm long. They stand upright as shown in fig. 170. 313. Form of a "scale" of the female flower. — If we remove one of the scales from the cone at this stage we can better study it in detail. It is flattened, and oval in outline, with a stout " rib," if it may be so called, running through the middle line and terminating in a point. The scale is in two parts as shown in fig. 173, which is a view of the under side. The small " outgrowth " which appears as an appendage is the cover scale, for while it is smaller in the pine than the other portion, in some of the relatives of the pine it is larger than its mate, and being on the out- side, covers it. (The inner scale is some- times called the ovuliferous scale, because it bears the ovules.) 314. Ovules, or macrosporangia, of the Fig. 171. rig. 172. * ■&• -/J* Section of female cone Scale of white pine with the Scale of white pine seen of white pine, showing two ovules at base of ovulif- from the outside, showing the from the outside, showing the cover scale. UI WI1ILC pine, MlUWllIg LWU U.UI&3 . young ovules (macrospo- erous scale, rangia) at base of the ovu- liferous scales. pi ne , — At each of the lower angles of the scale is a curious oval body with two curved, forceps-like processes at the lower and 192 BOTANY. smaller end. These are the macrosporangia, or, as they are called in the higher plants, the ovules. These ovules, as we see, are in the positions of the seeds on the mature cones. In fact the wall of the ovule forms the outer coat of the seed, as we will later see. 315. Pollination. — At the time when the pollen is mature the female cones are still erect on the branches, and the scales, which during the earlier stages of growth were closely pressed against one another around the axis, are now spread apart. As the Fig. 174. Branch of white pine showing young female cones at time of pollination on the ends of the branches, and one-year-old cones below, near the time of fertilization. clouds of pollen burst from the clusters of the male cones, some of it is wafted by the wind to the female cones. It is here caught in the open scales, and rolls down to their bases, where some of it falls between these forceps-like processes at the lower end of the ovule. At this time the ovule has exuded a drop of G YMNOSPERMS. 1 93 a sticky fluid in this depression between the curved processes at its lower end. The pollen sticks to this, and later, as this viscid substance dries up, it pulls the pollen close up in the depression against the lower end of the ovule. This depression is thus ; known as the pollen chamber. Now the open scales on the young female cone close up again, so tightly that water from rains is excluded. What is also very curious, the cones, which up to this time have been standing erect, so that the open scale could catch the pollen, now turn so that they hang downward. This more certainly excludes the rains, since the overlapping of the scales forms a shingled surface. Quantities of resin are also formed in the scales, which exudes and makes the cone practically impervious to water. The female cone now slowly grows during the summer and autumn, increasing but little in size during this time. During the winter it rests, that is, ceases to grow. With the coming of spring, growth commences again and at an accelerated rate. The increase in size is more rapid. The cone reaches maturity in September. We thus see that nearly eighteen months elapse from the beginning of the female flower to the maturity of the cone, and about fifteen months from the time that pollination takes place. * material. — Several branches of the pine showing the long shoots and whorls of branches. (These should be had in the laboratory if the tree can- not be studied in the open. If fresh branches cannot be had, preserve them dry.) Mature cones collected in August just before the seeds fall away. Branches with the female cones, collected from the top of the tree, in early summer (June), preserve in alcohol. Branches with the clusters of male cones collected late in May or early in June just before the pollen is scattered. Preserve in alcohol. Sections to show the female prothallium, archegonium, and fertilization can be made by the teacher, or they may be purchased of supply companies. Dissecting microscope, or tripod lens ; dissecting needles. • CHAPTER XXXI. MORPHOLOGY OF THE ANGIOSPERMS : TRILLIUM; DENTARIA. Exercise 60. 316. Trillium. — Note the general habit of the plant ; the short, thick, underground stem, which is perennial ; the roots attached to this ; the scale leaves at the anterior end around the base of the flowering stem. Note the flowering stem ; the whorl of three green leaves on it, and the terminal flower. Observe that there are no roots attached to the flowering stem. Is the flowering stem perennial ? Exercise 61. 317. Flower of trillium. — Observe the difference in the parts of the flower ; two whorls of leaf-like parts on the outside. Take these up in order, beginning at the outside. Outer whorl (calyx) ; note the resemblance of each member of the calyx to the leaf. How do they compare in number with the whorl of leaves on the stem ? Sketch one. Each one is a sepal. 318. Corol'a the second whorl. — Is there any resemblance between the parts of the corolla and a leaf of trillium ? How do the parts compare as to form and number with the leaves ? Sketch one. Each part of the corolla is a fetal. 319. Third and fourth whorl (andrcecium). — Note here that there are six members composing these two whorls, three in each. Is there any resem- blance between these and the leaves ? Did you ever see any of these mem- bers (stamens) partly changed to petals or leaves in trillium? Did you ever see any of them partly changed in other flowers ? in the water lily for ex- ample. Examine, a water lily when you have an opportunity. Look for these changes in other plants when you have an opportunity. Sketch a stamen, and name the parts, the slender stalk (filament), the more expanded part (anther) with four long sacs (anther locules, or sacs) ; 194 ANGIOSPERMS. 195 if they have just opened observe the great quantity of yellow "dust." These are the pollen grains, or the small spores. (The anther sacs Ihen must be the small sporangia.) 320. The inner whorl (gynoecium). — Note that the structure in the centre of the trillium flower ends in three slender points ; cut across the larger part of this object below. Nole that it has three chambers. What does this suggest? What do you find attached to the inner walls of these chambers ? They are the ovules. Sketch a cross-section. Is there any relation be- tween the three parts of this structure (pistil) and leaves ? What is this relation ? Compare the mature fruit of trillium (if at hand) with the pistil and ovules. Description of Trillium. 321. General appearance. — As one of the plants to illustrate this group we may take the wake-robin, as it is sometimes called, or trillium. There are several species of this genus in the United States; the commonest one in the eastern part is the " white wake-robin " (Trillium grandiflorum). This occurs in or near the woods. A picture of the plant is shown in fig. 175. There is a thick, fleshy, underground stem, or rhizome as it is usually called. This rhizome is perennial, and is marked by ridges and scars. The roots are quite stout and possess coarse wrinkles. From the growing end of the rhizome each year the leafy, flowering stem arises. This is 20-30 cm. (8-12 inches) in height. Near the upper end is a whorl of three ovate leaves, and from the centre of this rosette rises the flower stalk, bearing the flower at its summit. 322. Parts of the flower. Calyx. — Now if we examine the flower we shall see that there are several leaf-like structures. These are arranged also in threes just as are the leaves. First there is a whorl of three, pointed, lanceolate, green, leaf-like members, which make up the calyx in the higher plants, and the parts of the calyx are sepals, that is, each leaf-like member is a sepal. But while the sepals are part of the flower, so called, we easily recognize them as belonging to the leaf series. 323. Corolla. — Next above the calyx is a whorl of white or pinkish members, in Trillium grandiflorum, which are also leaf- I96 BOTANY. like in form, and broader than the sepals, being usually some- what broader at the free the corolla in the higher the corolla is a petal. the flower, and are not would suggest that they 324. Androecium. — of the corolla is found bers which do not at first They are known in the seen in fig. 176 each filament), and extending greater part of the length side. This part of the ridges form the anther flower is opened, these in the wall along the edge see quantities of yellow- escaping from the Tup- les. If we place some microscope we see that it ute bodies which resem- rounded in form, and the end. These make up what is plants, and each member of But while they are parts of green, their form and position also belong to the leaf series. Within and above the insertion another tier, or whorl, of mem- sight resemble leaves in form, higher plants as stamens. As stamen possesses a stalk (= along on either side for the are four ridges, two on each stamen is the anther, and the sacs, or lobes. Soon after the anther sacs open also by a split of the ridge. At this time we ish powder or dust tured anther locu- of this under the is made up of min- Fj , I7 ,. ble spores; they are outer wall is spiny. Trillium grandiflorum. ANGIOSPERMS. 197 They are in fact spores, the microspores of the trillium, and here, as in the gymnosperms, are better known as pollen. 325. The stamen a sporophyll. — Since these pollen grains are the spores, we would infer, from what we have learned of the ferns and gymnosperms, that this Fig. 176. Sepal, petal, stamen, and pistil of Trillium grandiflorum. member of the flower which bears them is a sporophyll ; and this is the case. It is in fact what is called the micro- sporophyll. Then we see also that the anther sacs, since they enclose 'lie spores, would be the sporangia (microsporangia). From this it is now quite clear that the stamens belong also to the leaf series. They are just six in number, twice the number found in a whorl of leaves, or sepals, or corolla. It is believed, therefore, that there are two whorls of stamens in the flower of trillium. 326. Gynoecium. — Next above the stamens and at the centre of the flower is a stout, angular, ovate body which terminates in three long, slender, curved points. This is the pistil, and at Fig. 177. Trillium grand- diflorum, with the compound pistil expanded into three leaf- like members. At the right these three are shown in detail. 198 BOTANY. present the only suggestion which it gives of belonging to the leaf series is the fact that the end is divided into three parts, the number of parts in each successive whorl of members of the flower. If we cut across the body of this pistil and examine it with a low power we see that there are three chambers or cavi- ties, and at the junction of each the walls suggest to us that this body may have been formed by the infolding of the margins of three leaf- like members, the places of contact having then become grown together We see also that from the incurved margins of each division of the pistil there stand out in the cavity oval bodies. These are the ovules. Now the ovules, we have learned from our study of the gymnosperms, are the sporangia (here the macrosporangia). It is now more evident that this curious body, the pistil, is made up of three leaf-like mem- bers which have fused together, each member being the equivalent of a sporophyll (here the macrosporo- phyll). This must be a fascinating observation, that plants of such widely different groups and of such different grades of complexity should have members formed on the same plan and belonging to the same series of members, devoted to similar functions, and yet carried out with such great modifications that at first we do not see this common meeting ground which a comparative study brings out so clearly. 327. Transformations of the flower of trillium. — If anything more were needed to make it clear that the parts of the flower Fig. 178. Abnormal trillium. The nine parts of the perianth are green, and the outer whorls of stamens are expanded into petal-like mem- bers. Fig. 179. Transformed stamen of tril- lium showing anther locules on the margin. TRILLIUM. 199 of trillium belong to the leaf series we could obtain evidence from the transformations which the flower of trillium sometimes presents. In fig. 178 is a sketch of a flower of trillium, made from a photograph. One set of the stamens has expanded into petal-like organs, with the anther sacs on the margin. In fig. 177 is shown a plant of Trillium grandiflorum in which the pistil has separated into three distinct and expanded leaf-like structures, all green except portions of the margin. Exercise 62. 328. Toothwort (dentaria). — Note the general habit of the plant ; the rather long, slender, smooth, fleshy, underground, perennial root stock (stem) ; the rudimentary leaves ; the roots ; the growing end some distance ahead of the point where the annual flowering shoot arises ; compare with trillium in this respect. The flowering annual shoot ; note the slender, smooth stem, the two opposite leaves which are three divided (trifoliate), the open raceme of flowers terminating the shoot. Exercise 63. 329. The flower. — Compare the parts of the flower with the leaves. The flowers should be collected before all of them are open, since the sepals fall away quite easily. Note that the flower parts are in twos or multiples of two, while in trillium the parts are in threes or multiples of three. In each case the number of parts in a whorl is the same as the number of leaves in a whorl, so that this strengthens the view of the parts of the flower being homologous with the leaves. Illustrate and describe the different members of the flower. The pistil here is also a compound pistil. If there is time compare with other flowers like the toothwort, as the shepherd's purse, mustard, etc. Description of the Toothwort. 330. General appearance. — For another study we may take a plant which belongs to another division of the higher plants, the common "pepper root," or "toothwort" (Dentaria di- phylla) as it is sometimes called. This plant occurs in moist 200 BOTANY. woods during the month of May, and is well distributed in the northeastern United States. A plant is shown in fig. 1 80. It has a creeping underground rhizome, whitish in color, fleshy, and with a few scales. Each spring the annual flower - bearing stem rises from one of the buds of the rhizome, and after the ripening of the seeds, dies down. The leaves are situated a little above the middle point of the stem. They are opposite and the num- ber is two, each one Fig. 180. Toothwort (Dentaria diphylla). TOOTHWORT. 201 being divided into three dentate lobes, making what is called a compound leaf. 331. Parts of the flower. — The flowers are several, and they are borne on quite long stalks (pedicels) scattered over the terminal portion of the stem. We should now examine the parts of the flower, beginning with the calyx. This we can see, looking at the under side of some of the flowers, possesses four scale-like sepals, which easily fall away after the opening of the flower. They do not resemble leaves so much as the sepals of trillium, but they belong to the leaf series, and there are two pairs in the set of four. The corolla also possesses four petals, which are more expanded than the sepals and are whitish in color. The stamens are six in number, one pair lower than the others, and also shorter. The filament is long in propor- tion to the anther, the latter consisting of two lobes or sacs, instead of four as in trillium. The pistil is composed of two carpels, or leaves fused together. So we find in the case of the pepper root that the parts of the flower are in twos, or multiples of two. Thus they agree in this respect with the leaves ; and while we do not see such a strong resemblance between the parts of the flower here and the leaves, yet from the presence of the pollen (microspores) in the anther sacs (microsporangia) and of ovules (macrosporangia) on the margins of each half of the pistil, we are, from our previous studies, able to recognize here that all the members of the flower belong to the leaf series. 332. In trillium and in the pepper root we have seen that the parts of the flower in each apparent whorl are either of the same number as the leaves in a whorl, or some multiple of that number. This is true of a large number of other plants, but it is not true of all. The trillium and the dentaria were selected as being good examples to study first, to make it very clear that tlie members of the flower are fundamentally leaf structures, or rather that they belong to the same series. of members as do the leaves of the plant. 202 BOTANY. Material. — Entire plants of trillium and dentaria in flower, with root stock. Specimens either fresh or dried. Entire flowers of both plants when they cannot be obtained at the right season, may be preserved in ad- vance in formalin. A sufficient number should be prepared, depending on the number of pupils in the class. Mature fruit may also be preserved in formalin or alcohol. It will be useful to have entire plants of trillium col- lected in late autumn, in the winter, or early spring before the flower stalk rises above the ground, in order to see the condition in which the flower passes the winter. CHAPTER XXXII.* PROTHALLIUM AND SEXUAL ORGANS OF FLOWERING PLANTS. 333. The stamens and pistils are not the sexual organs. — Before the sexual organs and sexual processes in plants were properly understood it was customary for botanists to speak of the stamens and pistils of flowering plants as the sexual organs. Some of the early botanists, a century ago, found that in many plants the seed would not form unless first the pollen from the stamens came to be deposited on the stigma of the pistil. A little further study showed that the pollen germinated on the stigma and formed a tube which made its way down through the pistil and into the ovule. .This process, including the deposition of the pollen on the stigma, was supposed to be fertilization, the stamen was looked on as the male sexual organ, and the pistil as the female sexual organ. We have found out, however, by further study, and especially by a comparison of the flowering plants and the lower plants, that the stamens and pistils are not the sexual organs of the flower. 334. The stamens and pistils are spore-bearing leaves. — The stamen is the spore-bearing leaf, and the pollen grains are not un- like spores; in fact they are the small spores of the angiosperms. The pistil is also a spore-bearing leaf, the ovule the sporangium, which contains the large spore called an embryo sac. In the ferns we know that the spore germinates and produces the green heart-shaped prothallium. The prothallium bears the sexual * This chapter is for reading and reference, but if the teacher desires to give demonstrations of the germinating pollen grain, and of the embryo sac, the following memorandum on material will be found of assistance. 203 204. BOTANY. organs. Now the fern leaf bears the spores and the spore forms the prothallium. So it is in the flowering plants. The stairen bears the small spores — pollen grains — and the pollen grain Fig- 182. Diagrammatic section of a flower. Ke, calyx ; K, corolla ; A the filament, and „•• ii ~-.. . •a-*'/ lit' ' ' ''•; ;• ^ T' , P .:\V +*"' / ■ ■■■• ?■■'■■ .i- '■■:■<■ a *■■«■• -UV^ )'' ■- '' - : » ■■ ■■ > < 240 PLANT FAMILIES: MONOCOTYLEDONS. But after the flower perishes, the bulb, deep in the soil, slowly builds the next season's flower, which is kept through the autumn and winter, much of the time encased in ice, waiting for springtime that it may rise and unfold. Order Gynandr^:. 391. The orchid family (orchidaceae). — Among the orchids are found the most striking departures from the arrangement of the flower found in the simpler monocotyle- dons. An example of this is seen in the lady- slipper (cypripedium, shown in fig. 208). The ovary appears to be below the calyx and corolla. This is brought about by the adhesion of the lower part of the Fig. 206. calyx to the wall of the Flower of an orchid (epipactis), the inferior ovary nV o rv Thp nvarv tripn twisted as in all orchids so as to bring the upper part of uv*y Men the flower below. j g in f erior ^ while the calyx and corolla are epigynous. The stamens • are united with the style by adhesion, two lateral perfect ones and one upper imperfect one. The stamens are thus gynandrous. The sepals and petals are each three in number. One of the petals, the "slipper," is large, nearly horizontal, and forms the " lip " or " labellum " of the orchid flower. The labellum is the platform or landing place for the insect in cross-pollina- tion. Above the labellum stands one of the sepals more showy than the others, the " banner. " The two lateral " strings " of the slipper are the two other petals. The stamens are still more reduced in some other genera, while in several tropical orchids three normal stamens are present. There are thus four striking modifications of the orchid ORCHIDACEM. 241 flower: 1st, the flower is irregular (the parts of a set are differ- ent in size and shape); 2d, adnation of all parts with the pistil; 3d, reduction and suppression of the stamens; 4th, the ovary is twisted half way around so that the posterior side of the flower becomes anterior. Floral dia- grams in fig. 207 show the posi- tion of the stamens in two dis- tinct types. The number of orchid species is very large, and the majority are found in tropical countries. 392. Pollination of orchids. — Some of the most marvellous adaptations for cross-pollination by insects are found in the Fig. 207. Diagrams of orchid flowers. A , the usual type ; B, of cypripedium. (Vines.) Fig. 209. Section of flower of cypripedium. j/, stigma : a , at the left stamen. The insect enters the labellum at the centre, passes under and against the stigma, and out through the opening l>, where it rubs against the pollen. In passing through another flower this pollen is rubbed off on the stigma. orchids, or members of the orchis family. The larger number of the members of this family grow in the tropics. Many of these in the forests are supported on lofty trees where they are brought near the sunlight, and such are called "epiphytes." Fig. 208. Cypripedium. 242 PLANT FAMILIES: MONOCOTYLEDONS. A number of species of orchids are distributed in temperate regions. 393. Cypripedium or lady-slipper. — One species of the lady- slipper is shown in fig. 208. The labellum in this genus is shaped like a shoe, as one can see by the section of the flower in fig. 209. The stigma is situated at st, while the anther is situated at a, upon the style. The insect enters about the middle of the boat-shaped labellum. In going out it passes up and out at the end near the flower-stalk. In doing this it passes the stigma first and the anther last, rubbing against both. The pollen caught on the head of the insect will not touch the stigma of the same, but will be in a position to come in contact with the stigma of the next flower visited. Exercise 65. 394. The orchid. — Take one of the orchids, the lady-slipper (cypripedium) for example, and make out the parts of the flower, and the relation of the different members. Study the structure of the flower with reference to the pollination by insects, with the aid of the text, and determine the course which the insect takes to effect cross-pollination. Material. — Entire plants in flower, including the bulb. This is usually buried deep in the soil, and should be collected fresh if possible. Some of the smaller plants, not in flower, should also be at hand. The plant flowers during May in the northeastern United States. It is represented in other sections by different species. In sections where a species of this genus cannot be obtained another of the orchis family may be employed. {Apparatus. Dis- secting microscopes, or tripod lenses (the former are better), dissecting nee- dles, scalpel. The apparatus will not be repeated for the following exercises.) CHAPTER XXXIX. MONOCOTYLEDONS (Continued). Topic II : Monocotyledons with flowers on a Spadix (Spadiciflorae). 395. Lesson II. The arum family (araceae). — This family is well represented by several plants. The skunk's cabbage (Spathyema foetida), the " jack-in-the-pulpit, " also called " Indian-turnip " (Arisaema triphyllum), shown in fig. 210, the water arum (Calla palustris), and the sweet flag (Acorus cala- mus) are members of this family, as also are the callas and caladiums grown in conservatories. The parts of several of the species of this family, especially the corm of the Indian turnip, are very acrid to the taste. The floral parts are more or less reduced. 396. Relatives of the arum family. — Related to the arum family are the ' ' duckweeds. ' ' Among the members of this family are the most diminutive of the flowering plants, as well as the most reduced floral structures. Other related families are the cat-tails and palms. In the latter the spathe and spadix are of enormous size. The cocoa- nut is the fruit of the cocoanut palm. Exercise 66. Indian -turnip. 397. Staminate plants (sometimes called male plants). — Sketch an entire plant showing the corm (the thickened perennial stem), the annual shoot with leaves and spathe. Cut away one side of the spathe to expose the long com- pact cluster of staminate (spadix) flowers within. Sketch the spadix, showing the mass of stamens as well as the sterile part of the shoot above. Dissect off from the axis feveral of the stamens. Note that the filament is very short, and that the anther is irregularly lobed. 243 244 PLANT FAMILIES: MONOCOTYLEDONS. 398. The pistillate plants (sometimes called female plants). — Compare with the staminate plant. How many leaves are there ? Is the number of leaves constant on all the pistillate plants ? Cut away one side of the spathe and expose the spadix of pistillate flowers. Sketch. Observe that each flower consists of a single flask-shaped pistil, and that these are packed closely together. Note the delicate brush-like stigma. Search for plants which show both stamens and pistils on the same spadix. Where both kinds of flowers, are present on the same spadix, on what part of the spadix does each kind appear ? On the corm of different plants search for lateral buds, which are young plants. Observe that they usually arise on directly opposite sides of the corm ; that they easily become freed from the old conns ; that they are young corms. Do they arise in the axils of the leaves or scale leaves which have fallen away ? Cut off a portion of the corm. Do not eat any portion but touch the tongue to the cut surface. The flesh of the corm is very acrid. Description of the Indian-turnip. 399. Indian-turnip. — The " Indian -turnip, " or " jack-in- the-pulpit " (Arisaema triphyllum), loves the cool, shady, rich, alluvial soil of low grounds, or along streams, or on moist hillsides. A group of the jacks is shown in figure 210 as they occur in the rich soil on dripping rocks in one of our glens. At their feet is a carpet of moss. Often the violet sits humbly underneath its spreading three-parted leaves. The thin, strap- shaped spathe, unfolded at its base, bends gracefully over the spadix, the sterile end of which stands solitary in the pulpit thus formed. The flowers are very much reduced, i.e., the number of members in the sets is reduced so that they do not appear in threes as in the typical monocotyledons. Some of the members are also often reduced in size or are rudimentary. The plants are " dimorphic " usually. 400. Female plants. — The large plants usually bear the pistillate flowers, which are clustered around the base of the spadix, each flower consisting of a single pistil, oval in form, terminating in a brush-like stigma. The stigma consists of numerous spreading, delicate hairs. The open cavity of the short style is hairy also, and a brush of hairs extends into the cavity of the ovary. Into this brush of internal hairs the necks ARACEM. 245 of the several ovules crowd their way to the base of the style near its opening. Even when the stigma is not pollinated the Fig. 2io. A group of jacks. ovary continues to grow in size, and the stigmatic brush remains fresh for a long time. 246 PLANT FAMILIES: MONOCOTYLEDONS. 401. Male plants. — Excepting some of the intermediate sizes, one can usually select on sight the male and female plants. The smaller ones which have a spathe are nearly all male and bear a single leaf, though a few have two leaves. The male flowers are also clustered at the base of the spadix, and are very much reduced. Each flower consists only of stamens, and singularly the stamens of each flower are joined into one com- pound stamen, the anther-sacs forming rounded lobes at the end of the short consolidated filaments. 402. The female plants require more food than the male plants. — In some plants both male and female flowers occur on a single spadix, the lower flowers being female, while the upper ones are male. The larger plants are nearly all female, and many, though not all, bear two leaves. In this dimorphism of the plant there is a division of labor apportioned to the destiny and needs of each, and in direct correspondence with the capacity to supply nutriment. The staminate flowers, being short-lived, need comparatively a small amount of nutriment, and after the escape of the pollen (dehiscence of the anthers) the spathe dies, while the leaf remains green to assimilate food for growth of the fleshy short stem (corm), where also is stored nutriment for the growth in the autumn and spring when the leaf is dead. The female plants have more work to do in providing for the growth of the embryo and seed, in addition to the growth of the corm and next season's flower. The smaller female plants thus sometimes exhaust themselves so in seed bearing that the corm becomes small, and the following season the plant is reduced to a male one. 403. Growth and death of the corm. — The new roots each year arise from the upper part of the corm. The stored sub- stances in the base of the corm are used in the early season's growth, and the old tissue sloughs off as the new corm is formed above upon its remains. Material. — Freshly collected plants should be used, the entire plant ; small ones as well as large ones. CHAPTER XL. MONOCOTYLEDONS (Concluded). Topic III: Monocotyledons with a glume subtending the flower (Glumiflorse). 404. Lesson III. Grass family (graminefle). Oat. — As a representative of the grass family (gramineae) one may take the oat plant, which is widely cultivated, and also can be grown w Fig. 2ii. Fig. 212. Fig. 213. Fig. 214. Spikelet of One glume re- Flower opened Section show- oat showing moved showing showing two palets, ing ground plan two glumes. fertile flower. three stamens, and of flower, a, axis. two lodicules at base of pistil. Fig. 215. Flower of oat, showing the upper palet behind, and the two lodicules in front. readily in gardens, or perhaps in small quantities in greenhouses in order to have material in a fresh condition for study. Or we 247 248 PLANT FAMILIES: MONOCOTYLEDONS. may have recourse to material preserved in alcohol for the dissection of the flower. The plants grow usually in stools; the stem is cylindrical, and marked by distinct nodes as in the corn plant. The leaves possess a sheath and blade. The flowers form a loose head of a type known as a panicle. Each little cluster as shown in fig. 211 is a spikelet, and consists usually here of one or two fertile flowers below and one or two undeveloped flowers above. We see that there are several series of overlapping scales. The two lower ones are " glumes," and because they bear no flower in their axils are empty glumes. Within these empty glumes and a little higher on the axis of the spike is seen a boat-shaped body, formed of a scale, the margins of which are folded around the flowers within, and the edges inrolled in a peculiar manner when mature. From the back of this glume is borne usually an awn. If we carefully remove this scale, the " flower glume," we find that there is another scale on the opposite (inner) side, and much smaller. This is the " palet. " Next above this we have the flower, and the most prominent part of the flower, as we see, is the short "pistil with the. two plume-like styles, and the three stamens at fig. 213. But if we are careful in the dissection of the parts we shall see, on look- ing close below the pistil on the side of the flower- ing glume, that there are two minute scales (fig. 215). These are what are termed the lodicules, considered by some to be merely bracts, by others to represent a perianth, that is two of the Fig. 216. Diagram of oak spikelet. Gl, glumes ; 2?, palets A , abortive flower. GRAMINE&. 249 sepals, the third sepal having entirely aborted. Rudiments of this third sepal are present in some of the gramineae. 405. Other members of the grass family. — To the gramineae belong also the wheat, barley, corn, the grasses, rice, etc. It is one of the most important families from an economic stand- point, furnishing a great variety of food for man and other animals. The gramineae, while belonging to the class mono- cotyledons, are less closely allied to the other families of the class than these families are to each other. For this reason they are regarded as a very natural group. Exercise 67. 406. The wheat (Triticum sativum vulgare). — The wheat plant may be studied as an alternate for the oat plant. The entire wheat plant. — Study the entire wheat plant, and compare with the oat plant. Are the stems of the wheat single or are stools formed? Since a germinating grain of wheat forms at first but a single stem, how are the stools formed ? Examine young wheat plants to determine this. The inflorescence. — The " head " of wheat forms a single spike: Sketch a spike. Remove a few of the spikelets, and note the jointed and zigzag char- acter of the axis (rachis) of the spike ; note the attachment of the spikelets. The spikelets. — Note the empty glumes at the .base • ^determine how many flowers there are in a spikelet. How many flowering glumes and palets are there to each flower ? In a mature head of wheat determine how many of the flowers in a spikelet ripen grain, and how, many are sterile? Are there any of the spikelets which are completely sterile? Where are they located? Using a head of wheat at the time of flowering, .spread apart the members of a flower with the aid of dissecting needles, and sketch the parts of the flower, showing the glume, palet, -the three stamens, and the t pistil with the plumose styles. Endeavor to find the lodicules. (See the description of the oat flower for comparison.) Sketch an empty and a flowering glume to show the " nerves" and awns. Compare the grain of wheat with a grain of corn. (See paragraph g.) Material. — Entire stools of young, fresh plants (may be obtained at any time during autumn, winter, or spring) ; mature plants in flower (if they can- not be obtained fresh they may be dried, preserving at the same time some of the flowering heads in alcohol or formalin) ; ripe heads of wheat. CHAPTER XLI. DICOTYLEDONS. Topic IV: Dicotyledons with distinct petals, flowers in catkins, or aments; often degenerate. Order Amentifer^:. 407. Lesson IV. The willow family (salicaceae). — The wil- lows represent a very interesting group of plants in which the Fig. 217. Spray of willow leaves, pistillate and staminate catkins (Salix discolor). flowers are greatly reduced. The flowers are crowded on a more or less elongated axis forming a catkin, or ament. The 250 salicacejE. 251 ament is characteristic of several other families also. The willows are dioecious, the male and female catkins being borne on different plants. The catkins appear like great masses of either stamens or pistils. But if we dissect off several of the flowers from the axis, we find that there are many flowers, each one subtended by a small bract. In the male or ' ' sterile ' ' catkins the flower consists of two to eight stamens, while in the female or ' ' fertile ' ' catkins the flower consists of a single pistil. The poplars and willows make up the willow family. Exercise 68. 408. The willow (Salix discolor). The leafy shoot. — Determine the arrangement of the leaves of the willow ; sketch a leaf showing its form, 1 the character of the margin, and of- the vena- tion. If different willows are at hand compare the color of the twigs, as well as the character of the twigs as to brittleness or litheness. The inflorescence. — What is the kind of inflorescence? Are both kinds of flowers borne on the same ament (catkin), or on different aments ? The staminate catkins. — Determine what constitutes a flower by dissect- ing some of them off from the axis of the catkin. What parts of the flower are present ? How many stamens in a flower ? If a hand lens is convenient use it in making out the form of the pari s. Sketch a flower in its position on the axis of the catkin, showing also the bract at the base of the flower. De- scribe the character of the bract as seen under the lens. The pistillate catkin. — What parts of the flower are present? Compare with the staminate flower. Sketch a pistillate flower with the subtending bract to show the form of the ovary, with the divided stigma. Is the pistil sessile or stalked ? How many carpels make up the pistil ? Is there a small gland (nectary) present near the base of the ovary which represents the peri- anth ? Is there a nectary on the staminate flower ? The fruit. — Examine ripe pods of the willow. Determine what parts of the flower unite to form the fruit. What difference between a fruit and seed in the willow? What means is provided for the dissemination of the seeds ? Field observations on the willows. — At what time do the catkins of the willow appear ? Do they flower before the leaves appear ? At time of flow- ering note the character and abundance of the pollen from the stamens. Is it in the form of "dust," or is it adhesive? How are the willows pollinated? Do insects visit the willow flower ? Are willows easily propagated by shoots ? What happens if a willow branch is stuck into damp soils ; when it is left in the water for some time ? 252 PLANT FAMILIES: DICOTYLEDONS. Material. — Shoots of the willow, some with leaves, some with the catkins (the two kinds of catkins occur on different plants). If material cannot be obtained fresh when wanted for study, the leafy shoots may be preserved dry, and the catkins in alcohol or formalin, or dry. Ripe fruit should also be at hand ; this may be preserved dry. Order AmentiferjE. 409. Lesson V. The oak family (cupuliferse). — A small branch of the red oak (Quercus rubra) is illustrated in fig. 218. Fig. 218. Spray of oak leaves and flowers. Below at right is staminate flower, at left pistillate flower. This is one of the rarer oaks, and is difficult for the beginner to distinguish from the scarlet oak. The white oak is perhaps CUPULIFER&. 253 in some localities a more convenient species to study. But for the general description here the red oak will serve the purpose. Just as the leaves are expanding in the spring, the delicate sprays of pendulous male catkins form beautiful objects. The petals are wanting in the flower, and the sepals form a united calyx, with several lobes, that is, the parts of the calyx are coherent. In the male flowers the calyx is bell-shaped and deeply lobed. The pendent stamens, variable in number, just reach below its margin. The pistillate or female flowers are not borne in catkins, but stand on short stalks, either singly or a few in a cluster. The calyx here is urn-shaped with short lobes. The ovary consists of three united (coherent) carpels, and there are three stigmas. Only one seed is developed in the ovary, and the fruit is an acorn. The numerous scales at the base of the ovary form a scaly involucre, the cup. The beech, chestnut, and oak are members of the oak family. 410. Other anient bearers. — The following additional fam- ilies among the ament bearers are represented in this country : the birch family (birch, alder), the hazelnut family (hazelnut, hornbeam, etc.), walnut family (hickory, walnut), and the sweet-gale family (myrica). Exercise 69. 411. The oak. — (The white oak or any common one in the neighborhood.) The leaves. — Determine the arrangement of the leaves on the shoot. Sketch a leaf showing the form, outline, and venation. Compare the young leaves with the old ones as to texture, surface characters, etc. The inflorescence. — What is the kind of inflorescence ? Are both kinds of flowers in the same inflorescence or in different inflorescences ? The staminate inflorescence. — Note the cluster of staminate aments. De- termine a single flower and sketch it to show the parts. What parts of the flower are present ? Determine the number of parts of each set present. The pistillate inflorescence. — How does it differ from the staminate in- florescence? Sketch a pistillate flower, showing the parts. What parts of the flower are present ? The fruit (an acorn with the cup). — Sketch an acorn in the "cup." 254 PLANT FAMILIES: DICOTYLEDONS. What is the homology of the cup ? i.e., to what part or series of members of the plant does it belong ? Could the pistillate flower of the ancestors of the oak have been in the form of aments, and if so could the cup of the acorn represent the degraded and consolidated ament ? If so, what part of the ament would now be represented in the cup ? (It has also been suggested that the scales of the involucre which make up the cup are adventitious growths accompanying the development of the fruit. ) (If the acorn has not been studied under the paragraph dealing with seeds and fruits, and if there is time now, remove the wall of the acorn and deter- mine the parts of the embryo. Are any parts of the embryo green while still enclosed within the acorn ? Field observations on the oaks. — Compare the time of appearance of the flowers and leaves of the oak. What about the abundance of the pollen ? How are the oaks pollinated ? The ament-bearing plants are usually wind pollinated, and for this reason there is an abundance of pollen, and always in the form of dust. Is there an exception to this general rule ? How long after the flowers are formed before the acorn is ripe ? If there is time during excursions note other ament-bearing plants. Material. — Mature leaves, leafy shoots, sprays of the flowers, both pistillate and staminate ; fruit (the acorn in the cups). CHAPTER XLII. DICOTYLEDONS (Continued). Topic V : Dicotyledons with distinct petals and hypogynous flowers. Order UrticiflorjE. 412. Lesson VI. The elm family (ulmacese). — The elm tree belongs to this family. The leaves of our American elm (Ulmus americana) are ovate, pointed, deeply serrate, and with an oblique base as shown in fig. 219. The narrow stipules Fig. 219. Spray of leaves and flowers of the American elm ; at the left above is section of flower, next is winged seed (a samara). which are present when the leaves first come from the bud soon fall away. The flowers are in lateral clusters, which arise from 255 256 PLANT FAMILIES: DICOTYLEDONS. the axils of the leaves, and appear in the spring before the leaves. They hang by long pedicels, and the petals are absent. The calyx is bell-shaped, and 4-9-cleft on the margin. The stamens vary also in number in about the same proportion. A section of the flower in fig. 219 shows the arrangement of the parts, the ovary in the centre. The ovary has either one or two Iocules, and two styles. The mature fruit has one locule, and is margined with two winged expansions as shown in the figure. This kind of a seed is a samara. Exercise 70. 413. The elm (TJlmus americana). Leaves. — What is the arrangement of the leaves on the shoot? Sketch a leaf showing its attachment to the shoot, and the relation of the stipules ; note how easily the stipules fall away. The inflorescence. — Describe the inflorescence ; a single flower ; sketch a single flower in the position in which it stands on the tree. Cut away the floral envelope on one side ; determine the number of stamens ; the number of pistils ; are the pistils single or compound ? Of how many carpels is it composed ? Sketch a flower with the front part of the envelope and the front stamens removed. What part of the floral envelope is present ? What is its character and form ? What are the relations of the sets of the flower to each other ? In time of appearance how do the flowers compare with the leaves ? Describe the mature fruit; how many seed are present? What parts of the flower are united in the fruit ? What is the fruit called ? Materials. — Spray of leaves and flowers; it maybe necessary to collect them at different times. Leafy shoots should be collected while some of the leaves are still young in order to preserve some with the stipules, and they may be preserved dry and pressed. Fruits collected at the time of maturity may be preserved dry. Order Polycarpic^:. 414. Lesson VII. The crowfoot family (ranunculacese). — The marsh-marigold (Caltha palustris) is a member of this family. The leaves are heart-shaped or kidney-shaped, and the edge is crenate. The bright golden-yellow flowers have a single whorl of petal-like envelopes, and according to custom in such cases they are called sepals. The number is not RANUNCULA CE&. 257 definite, varying from five to nine usually. The stamens are more numerous, as is the general rule in the members of the family, but the number of the pistils is small. Each one is separate, and forms a little pod when the seed is ripe. The marsh-marigold, as its name implies, occurs in marshy or wet places and along the muddy banks of streams. It is one of the common flowers in April and May. Exercise 7 1 . 415. The Buttercup. — If preferred, a species of buttercup may be studied instead of the marsh-marigold, but a comparison with the latter is de- sirable. The entire plant. — Describe form and habit of the plant ; the character of the stem ; branching ; the form and arrangement of the leaves ; the character of the roots (these characters will depend on the species). The inflorescence. — What kind of in- florescence ? What parts of the flower are present? Describe the color and form of members of the different sets of the flower. Determine the number of members in each set (approximately if not ac- curately). Sketch a sepal, a petal (is a nectar gland pres- ent?), a stamen, and a pistil, noting carefully the characters of each. Do the stamens all ripen their pollen at the same time ? Is there any ad- vantage as regards the time of ripening of the stamens ? What is the relation of the members of a set among themselves ? What is the relation of the sets to each other ? Is the flower perfect or imperfect ; complete or incomplete ? Is it regular or irregular ; hypogynous, perigynous, or epigynous ? Are the parts of the flower free and distinct, or adherent, or coherent? Fig. 221. Diagram of marsh-marigold 258 PLANT FAMILIES: DICOTYLEDONS. If fruit is present determine the number of seed in a ripe fruit ; and also what parts of the flower make up the fruit. If there is time a comparison of the flowers, fruit, and leaves of different species of the ranunculus will be found interesting, especially species from dry and wet ground as well as some of the species which grow in the water. Construct the formula for the buttercup flower ; also construct the floral diagram. Material. — Entire plants, some flowering stems with flowers, some with fruit. Fresh material when possible. The Buttercup (ranunculus). 416. Other crowfoots. — Many of the crowfoots or buttercups (ranunculus) with bright yellow flowers grow in similar situa- tions. The " wood anemone" (anemone), small plants with white flowers, and the rue anemone (anemonella), which resem- bles it, both flower in woods in early spring. The common virgin's bower (Clematis virginiana) occurs along streams or on hillsides, climbing over shrubs or fences. The vine is some- what woody. The leaves are opposite, petioled, and are com- posed of three leaflets, which are ovate, three-lobed, and usually strongly toothed, and somewhat heart-shaped at the base. The flower clusters are borne in the axils of the leaves, and therefore may also be opposite. The clusters are much branched, form- ing a convex mass of beautiful whitish flowers. The sepals are colored and the petals may be absent, or are very small. The stamens are numerous, as in the members of the crowfoot family. The pistils are also numerous, and the achenes in fruit are tipped with the long plumose style, which aids them in floating in the air. 417. Character of the ranunculaceae. — Some of the charac- ters of the ranunculaceae we recognize to be the following: The plants are mostly herbs, the petals are separate, and when the corolla is absent the sepals are colored like a corolla. The stamens are numerous, and the pistils are either numerous or few, but they are always separate from each other, that is they are not fused into a single pistil (though sometimes there is but cruciferm. 259 one pistil). All the parts of the flower are separate from each other, and make up successive whorls, the pistils terminating the series. When the seeds are ripe the fruit is formed, and may be in the form of a pod, or achene, or in the form of a berry, as in the baneberry (actaea). Order Rhceadinje. 418. Lesson VIII. The mustard family (cruciferae). — This is well represented by the toothwort (dentaria), which we studied in a former chapter. (If the toothwort has been studied, the shepherd 's-purse may be omitted.) Exercise 72. 419. The Shepherd's purse (Capsella bursa-pastoris). — If it is desired to study a species besides the toothwort the shepherd' s-purse will answer It is a common and widely distributed species, found in waste places and in fields. The entire plant. — Note and describe the habit and character of the plant, i.e., the size, character of branching, character of the root, position and ar- rangement of the leaves. Compare the "radicle" (lower) leaves with the " cauline " (stem) leaves as to form, and insertion. The radicle leaves are more or less deeply lobed or pinnatifid (pinnately cut), while the stem leaves are slender, lanceolate, toothed, and often auricled (with little ears) at the base. The inflorescence. — What is the kind of inflorescence? Determine the parts of the flower present, as well as the number and arrangement of the members of the flower. What figure do the petals make in the flower, which suggests the name of the family to which the shepherd's purse and the tooth- wort belong ? The fruit. — What parts of the flower are united in the fruit ? Compare the plant with the toothwort. Construct the floral diagram of the toothwort or shepherd's purse, or of other cruciferous plant studied. material. — Entire plants with flowers and fruit. The plant occurs from early spring to autumn, and can be usually obtained in a fresh condition when wanted. The exercise on the violet may be omitted unless it is desired to study it in connection with some field observations, and for the purpose of observing " cleistogamous " flowers, when the outline here given will answer. 260 PLANT FAMILIES : DICOTYLEDONS. Order CistifloRj. stand- ard ; IV, wings ; A", two petals forming keel. of the five petals. The petals have received distinct names here because of the position and form in the flower. At fig. 232 the petals are separated and shown in their corresponding positions, and the names are there given. The flower is irregular and the parts are in fives, except the carpel, which is single. The calyx is gamosepalous (coherent), the corolla poly- petalous (distinct). The ten stamens are in two groups, one separate stamen and nine united; they are thus diadelphous (two brotherhoods). The fruit forms a pod or legume, and at maturity splits along both edges. There are three families in the legume- bearing plants : 1st, including the locusts, cassias, etc. ; 2d, the pea family, including peas, beans, clovers, ground-nuts, or peanuts, vetches, desmodium, etc. ; 3d, in- cluding the sensitive plants like mimosa. Exercise 78. 433. The pea (Pisum sativum). The entire plant. — Describe the entire plant, the branching, the means for support (compare different cultivated varieties in respect to size, habit, and means for support if practicable). The leaf. — Sketch a leaf; name the different parts; what kind of a leaf is it ? Does the leaf serve any purpose for the mechanical support of the plant ? How ? The inflorescence. — What is the kind of inflorescence ? The flower. — Is it regular or irregular ? The calyx. — Describe the calyx. How many sepals are indicated? Are the sepals distinct or coherent ? What name is applied to this kind of a calyx ? The corolla. —What are the relations of the petals to each other? What term is applied to indicate this relation ? Sketch a flower, and name the differ- ent parts of the corolla ; what name is given to such a flower ? The stamens (remove the corolla) ; how many stamens are there ? What is their relation to each other ? What terms are used to indicate such a re- lation of stamens to each other ? The pistil. — How many carpels in the pistil ? Is it simple or compound ? Sketch a young pistil, naming the parts. MYRTIFLORjE. 271 The fruit. — What parts of the flower are united in the fruit ? Describe the fruit. What is such a fruit called ? How are the seeds freed ? What is the difference between a fruit and a seed in the pea plant ? The clover (irifolium, . — If it is desired to study a clover, study one in a similar way. Nitrogen gatherers. — The pea, clovers, etc. , are often called nitrogen gatherers (see Chapter XV). During an excursion let the pupils dig up dif- ferent leguminous plants, like the pea, clover, lupine, etc. , and search for the "tubercles" on their roots, compar- ing the form of the tubercles on the different kinds of plants. Pollination. — If the flowers of cy- tisus from a conservatory are at hand attempt to press the point of a pencil in between the parts of the keel in the case of flowers where these parts are still closed ; describe the action of the stamens in throwing the pollen. How could cross-pollination be brought about in such a flower by the visits of insects ? Study the common lupine (Lupinus perennis) in the same way. Study the pea flower with the same ■ object in view ; has the pea flower become adapted to self-pollination ? Material. — Sprays of leaves and flowers ; fruit. Material can usually be obtained fresh early in the spring ,,, ... . , Mw Flg - 2 » and for some time later. Ugf Section of flower f (Knothera. Topic VII: Dicotyledons with distinct petals and epigynous flowers. Order Myrtiflor^e. (The study of the evening primrose may be omitted.) 434. Lesson XV. The evening-primrose family (onograceae). — In the evening-primrose (Oenothera) the flowers are arranged 272 PLANT FAMILIES: DICOTYLEDONS. Fig. 234. Evening primrose (CEnothera biennis) showing flower buds, flowers, and seed pods, (From Kerner and Oliver,) onogracejE. 273 in a loose spike along the end of the stem, each one situated in the axil of a leaf-like bract. The flowers of the family are very characteristic, as shown here. They are sessile in the axil of the bract, and the calyx forms a long tube by the union of the sepals, only the end of the tube being divided into the indi- vidual parts, showing four lobes. On the edge of the open end of the calyx tube are seated the four, somewhat heart-shaped, yellowish petals, and here are also seated the eight stamens. The four carpels are united into a single pistil within the base of the calyx tube and united with it, so that the calyx tube seems to be on the end of the pistil. The flowers soon fade and fall away from the pistil, and this grows into an elongated four-angled, pod. Since the lower flowers on the stem are the older, we find nearly mature fruit and fresh flowers, with all intermediate grades, on the same plant. The plants grow by roadsides and in old fields. They are from 10cm to a meter or more high (one to five feet). The leaves are lanceolate or oblong, toothed and repand on the margin. In many of the species of the family the parts of the flower are in fours as in the evening primrose, but in others the number is variable. CHAPTER XLV. DICOTYLEDONS (Continued). SympetaLjE. 435. In the remaining families the corolla is gamopetalous, that is, the petals are coherent into a more or less well-formed tube, though they may be free at the end. For this reason they are known as the sympetalce. Topic VIII: Dicotyledons with united petals, flower parts in five whorls. Order Bicornes. 436. Lesson XVI. The whortleberry family (vacciniacese). — (This study may be omitted. ) — The common whortleberry, or huckleberry (Gaylussacia resinosa), flowers in May and June. The shrubs are from 7,ocm to i meter (1-3 feet) high, and are much branched. The leaves are ovate, and when young • are more or less clammy from numerous resinous dots, from which the plant gets its specific name (resinosa). The flowers are borne on separate shoots from the leaves of the same season, and hang in one-sided short racemes as shown in fig. 235. The calyx is short, five-lobed, and adheres to the ovary. The corolla is tubular, at length cylindrical with five short lobes, and is whitish in color. The stamens are ten in number, and the compound ovary has a single style. The fruit is a rounded black, edible berry or drupe, with ten seeds. 274 LABI ATM. 275 Topic IX: Dicotyledons with united petals, flower parts in four whorls. Order Tubiflorje. 437. Lesson XVII. The mint family (labiatae).— The mint family contains a large number of genera and takes its common name from the mints, of which there are several species belong- ing to the genus mentha. In the figure of the ' ' dead-nettle ' ' Fig. 235. Whortleberry (Gaylussacia re- si no s a). Fig. 836. Spray of dead-nettle (Laminum am- plexicaule), leaves and flowers. (Lamium amplexicaule), which is also one of the members of this family, we see that the lobes of the irregular corolla are arranged in such a manner as to suggest two lips, an upper and a lower one. From this character of the corolla, which obtains in nearly all the members, the family receives its name of Labiatce. The calyx is five-lobed. The stamens, four in number, arise from the tube of the corolla, and converge in 276 PLANT FAMILIES: DICOTYLEDONS. pairs. The ovary is divided- into four lobes, and at the maturity of the seed these form four nutlets. The leaves are rounded, crenate on the margins, the lower ones petioled and heart-shaped, and the upper ones sessile and clasping around the stem beneath the flower clusters. From the clasp- ing character of the upper leaves the plant derives its specific name of amplexicaule. The Fig. 237- plant occurs in waste places and is rather Diagram of lamium r flower, common. Of the two exercises given below one may be omitted. Exercise 79. 438. The catnip (Nepeta cataria). — While the "dead nettle" is used here to illustrate the mint family other species may be studied instead. The exercise is written for the catnip (Nepeta cataria), * very common weed occurring from July to September. If fresh material is not at hand when the study is made, dried entire plants, and the flowers in formalin may be used, unless it is preferred to use fresh material of some other available species. In that case the dead nettle here illustrated, and the exercise, will serve as a guide for the study. The entire plant. — Note the habit, the character of the branching, the shape of the stem, the character of the surface. Note the form and arrange- of the leaves. Is the plant annual, biennial, or perennial ? The inflorescence. — What is the inflorescence ? The flower ; the parts present, the calyx, form and relation of parts ; the corolla ; form, relation of parts ; into what two parts is the corolla divided ? the name of the two parts ? the number of petals in each part ? Note the stamens, number, size, position in the flower. The pistil ; sketch a pistil showing the nutlets, the long style. To study the stamens remove a corolla, split it open down one side and spread it out on a glass slip and mount in water ; or pin it to a cork. Ex- amine with a good hand lens, or with the lower power of the microscope. Construct the floral diagram. Cross-pollination by insects. — Study the adaptations of the flower for this purpose. The lower lip is the landing place, and the upper lip is the "ban- ner. ' ' If there are color markings on any portion of the flower which serve to guide the insect in entering the flower, describe them and note the location. With a needle imitate the entrance of an insect into the flower and determine the way in which cross-pollination takes place. SCROPHULARIACEM. 277 Compare if possible other members of the mint family in the study of cross- pollination. Material. — Entire plant with flowers and ripe fruit. If fresh plants are not at hand, those that have been pressed and dried may be used for the study of the entire plant and of the leaves. The flowers may be preserved in formalin. Order Personatve. Exercise 80. 439. The figwort family (scrophulariaceae). — Toad flax (Linaria vul- garis). — The toad flax is widely distributed, growing in waste places as a weed from June to October. The entire plant. — Note the short, pale green perennial root stock ; the longer erect annual stem ; is it simple or branched ? Leaves, form and ar- rangement. The inflorescence. — The kind of inflorescence. The flower. — What parts of the flower are present ? Describe the different parts. The calyx. — How many sepals indicated ? what is the form of the calyx ? The corolla. — Form. How many petals indicated ? Describe the form of the corolla and its parts. The stamens. — How many, their position, size? What is the significance of the difference in the size of the stamens? The pistil. — Form, parts ; form of the ovary ; how many carpels present in the pistil ? Study the adaptation of the flower for cross-pollination by the aid of insects ; the lower lip of the corolla as a landing place ; since insects are supposed to be attracted by bright colors, what portion of the flower serves thus to direct the insect ? Note the spur on the corolla, and the nectar inside ; what kinds of insects visit this flower ? Imitate with the end of a pencil the entrance of an insect in a flower and endeavor to make out how cross-pollination takes place. Seed distribution. — Examine ripe seed pods, dry some of them, and then take some of the dry ones and place in water. Describe the action of the pod in scattering the seeds, and the causes. Other members of the family are interesting to compare with the toad flax, as the beard tongue (Penstemon pubescens), turtle head (Chelone glabra), monkey flower (Mimulus ringens), etc. Material Entire plants with the underground stems. Flowers and fruit. If fresh material cannot be had at the time of the study, dried plants (pressed) will answer for the study of the entire plant. Flowers may be pre- served in formalin ; fruits dry. CHAPTER XLVI. DICOTYLEDONS (Concluded). Order Aggregate. 440. Lesson XX. The composite family (compositae). — In all the composites, the flowers are grouped (aggregated) into ' ' heads, "as in the sunflower, where each head is made up of a great many flowers crowded closely together on a widened receptacle. The family is a large one, and is divided into several sections according to the kinds of flowers and the differ- ent ways in which they are combined in the head. In the asters there is one common type illustrated in fig. 238 by the Aster novce-anglicB. In the aster, as is well shown in the figures, the head is composed of two kinds of flowers, the tubular flowers and the ray flowers. In the tubular flowers the corolla is united to form a slender tube, which is five-notched at the end, representing the five petals. In the ray flowers the corolla is extended on one side into a strap-shaped expansion. Together these strap-shaped corollas form the "rays" of the head. The corolla is split down on one side, which permits the end then to expand and form the ' ' strap. ' ' This is a ligula, or more correctly speaking a false ligula. In fact the ray flower is bilabiate. By counting the " teeth " of the false ligula there are found only three, which indicates that the strap here is made up of only three parts of the 5-merous corolla. The two other limbs of the corolla are rudimentary, or sup- pressed, on the opposite side of the tube. True ligulate flowers are found in the chicory, dandelion, or in the hieracium, where the five points are present on the end of the ligula. 278 COMPOSITE. 279 441. The pappus and syngenecious stamens.— The calyx tube in the aster, as in all of the composites, is united with the ovary, while the limb is free. In the aster, as in many others, the limb is divided into slender bristles, the pap- pus. (In some of the com- posites the pappus is in the form of scales. ) The stamens are united by their anthers into a tube (syngenecious) which closely surrounds the style. (In ambrosia the an- thers are sometimes distinct.) The style in pushing through brushes out some of the pollen from the anthers and bears it aloft as in the bell- flower, but the stigmatic sur- face is not yet mature and Aster novze-angliae. Fig. 239. Head of flowers of Aster novse-anglia expanded, so that close pollination cannot take place. There are usually no stamens in the ray-flowers. The ovary is com- posed of two carpels, as i.s shown by the two styles, but there is only one locule, containing an erect, anatropous, ovule. 28o PLANT FAMILIES: DICOTYLEDONS. The floral formula for the composite family then is as follows : Cas, C05, A5, G2. Fig. 240. Fig. 241. Ray flower of Aster Tubular flower novae-angliie. of aster. Fig. 242. Tubular flower opened to show syn- genecious stamens. Fig. 243. Sy ngenec ious stamens opened to show style and two stigmas. 442. Other composites. — The rattlesnake-weed (Hieracium venosum) is an example of another type, with only one kind of flower in the head, the true ligulate flower. The hawk- weed, or devil's paint-brush (H. aurantia- cum) is a related species, which is a troublesome weed. The dandelion and prickly lettuce are also members of the ligulate-flowered composites. A number of the composites have only tubular flowers, as in the thoroughwort (eupatorium) and ever- lasting (antennaria). 443. The composites are the most highly developed plants. — The extent to which the union of the parts of the flower has been carried in the composites, and the close aggregation of the flowers in a head, represent the highest stage of evolution reached by the flowers of the angiosperms. Fig. 244. Diagram of composite flower. (Vines.) COMPOSITE. 28l Exercise 8 1 . 444. The aster (Aster novae-angliae). — (Some other species may be selected if it is more convenient. ) See Exercise 82. The entire plant. — Describe the entire plant; the character of the stem; the position of the leaves ; their form on different portions of the stem ; their attachment to the stem. Compare the ' ' radicle ' ' leaves with the stem leaves. The inflorescence. — Describe the inflorescence, and the position of the flower heads. A single head of flowers.— Describe the involucre. What different kinds of flowers are present ? What is the position of each kind on the head ? De- termine the approximate number of each kind of flowers in a head. The ligulate flowers. — Remove one from the head and sketch it, showing the different parts. How many petals are indicated in the strap ? How many petals are in the tubular portion of the ligulate flower? Is this a true ligula ? Why ? Is the calyx present, and what represents it ? Split open the corolla tube, and determine whether or not the stamens are present. Is the pistil present in the ligulate flower ? The tabular flowers — Describe the corolla. How many petals are indi- cated in the corolla tube ? What is such a corolla called ? The stamens. — Split open the corolla tube down one side, and sketch to show the position of the stamens, and their relation to each other. Split open the anther column, spread it out, and sketch to show the relation of the stamens to each other, and the pistil within. Material. — Entire plants in flower ; also some of the mature fruit heads. Exercise 82. 445. The goldenrod (solidago). — (As an alternate if desired, for Exer- cise 81.) If it is desired to study the goldenrod instead of the aster, it will be well to make a comparison with the aster, and the account of the aster here given will serve as a guide for the study of the goldenrod. The daisy is also a good one to compare with the aster, and the outline for the study of the aster here given will answer for the basis of such a study. Exercise 83. 446. The dandelion (Taraxacum dens leonis). The entire plant — Note the very short stem (the plant is sometimes said to be acaulescent, but it has a short stem). Note the thick root ; the position of the leaves (often called radicle leaves because of their position on the short stem so near the roots) . Sketch a leaf to show its form, 282 PLANT FAMILIES: DICOTYLEDONS. The inflorescence. — What is the kind of inflorescence? Note the leafless stem (flowering scape) which bears the head of flowers. Cut across the stem and split it, and then describe its character. The involucre. — How many whorls of bracts are there in the involucre ? Comparing plants in flower and at different stages of maturity, describe the different positions of the involucre. The flowers. — Are all the flowers strap-shaped ? Note the ligula. Why is it a true ligula ? Describe and sketch a single flower. The calyx. — What represents the calyx ? Describe the free portion, or limb. Wnat is the insertion of the calyx ? The corolla. — What represents the corolla, and how many petals are in- dicated ? The stamens. — What is the relation of the stamens to each other ? What is the name applied to such stamens ? Sketch a few of the stamens to show their relation to each other. The pistil. — How many carpels are represented in the pistil? What is the indication of this ? What is the relation of the different sets of the flower to each other, and what is their insertion ? Give the names applied to these different relations. The fruit. — Comparing the different stages of the ripening seed, describe the changes which take place in the different parts of the flower and head. What parts of the flower are united in the fruit ? What is such a fruit called ? How many seeds in the fruit ? Seed distribution. — How are seeds of the dandelion adapted for seed dis- tribution ? Take a head of ripe seeds, and blow upon it. Note how the seeds float; observe which end falls first upon the ground (see chapter on seed distribution in Ecology). CroBS-pollination. — In some of the composites, as in the daisy, or in the sunflower, determine what provision is present for cross-pollination. Do all the flowers "blossom" at the same time in a single head? Which ones blossom first ? Do the stamens ripen and emerge from the throat of the corolla at the same time as the stigma in the same flower ? Why ? Com- pare the dandelion in these respects. Material. — Entire plants, with flowers (they can be obtained all through the spring) ; heads of fruit in different stages of maturity. ECOLOGY. INTRODUCTION. 447. Life processes in the individual plant. — In studying the phenomena of plant life which relate to the methods of absorption and transportation of food to different parts of the plant, and the internal processes of metabolism concerned in the building up of new plant material, and the formation of waste, as well as certain of the growth phenomena and irritable properties, we have been dealing largely with the individual plant. A study of these life processes we term physiology. They relate to the immediate conditions of existence and well being of the plant. 448. Form in members of the plant body. — Beyond the very simple plants of the lower groups, and a few reduced forms among the higher plants, the plant body becomes more or less bulky or enlarged, and each cell is so situated that it is unable to participate equally in a number, or all, of the life processes. The plant body therefore becomes more or less differentiated into parts, which from the standpoint of physiology are organs for the performance of distinct functions. This leads us in the complex plant body to recognize form as an important cor- relative of function in many cases. The immense variation which has, through time, taken place in the development of plants has resulted in a great diversity of form even in the same members %f the plant body. Within certain limits, how- ever, the form of the plant parts among the individuals of a species is the same, and they are inherited by, or handed down to, the offspring. 283 284 ECOLOGY. 449. Form as indicating relationship. — Where the form of a member is a constant peculiarity of the plants of one kind, differences in form among other plants indicate that there are other kinds, or species, of plants. So that aside from the rela- tion which the members of the plant, as organs, bear to the immediate life functions, the form of the members becomes the measure of the value of relationships among kinds. The study of form in this connection we term morphology. 450. Relation of physiology and morphology. — While physi- ology and morphology are regarded as distinct subjects, still we see how they are interrelated when we consider the details of one or the other subject. It is in the broader concept that the two subjects are fundamentally different. 451. Form and function in a broader sense than the indi- vidual. — Just as the individual life processes relate chiefly to the immediate conditions of existence of the plant, and as the individualized form of the members relates to the immediate conditions of relationship; so the life processes in general, on a grand scale or as affected by seasons, or mutual relations, as well as form on a grand scale, relate to more extended condi- tions of existence, and to relationships, the measure of which is not the form of the plant itself, but the form of the plant community, showing a relationship of different kinds under like conditions of existence. In this sense we are concerned with those processes and forms which are influenced by, or lay hold on, environment. By the environment is meant all the sur- rounding objects, conditions, and forces operating in nature, either temporary, seasonal, or permanent. 452. Mutual and environmental relationships. — While we are engaged with the study of the life processes concerned in nutrition and growth of plants, with the details of form, struc- ture, and systematic relationship, we should not overlook the mutual relationships which exist among plants in their natural habitat, and the phenomena of growth recurring with the seasons, and influenced by environment, or due to inherent INTRODUCTION. 285 qualities. By a study of the life histories of plants, their habits and behavior under different conditions of environment, we shall broaden our concept of nature and cultivate our aesthetic, observational, and reasoning faculties. The subject is too large for full treatment within the limits of a part of an elemen- tary book. The way here can only be pointed out, and the few examples and illustrations, it is hoped, will serve to open the book of nature to the young student, and lead him to study some of the problems which are presented by every region. This study of plants, in their mutual and environmental rela- tionships, is ecology. 453. Some of the factors of environment. — In carrying on studies of this kind one should bear in mind the factors which influence plants in these relationships, that is, what are called the ecologic factors ; in other words, those agencies which make up the environmental conditions of plants, all of which play a greater or lesser role in the habit or status of the plant con- cerned, and which, acting on all plants concerned, give the peculiar color or physiognomy to the plants of a region or of a more restricted community. Such factors are climate, with its modifying meteorological conditions; texture, chemistry, moisture content, covering, topography, exposure, etc., of the soil; influence of light and heat; of animals, of plants themselves, and so on. 454. Suggestions for outdoor studies. — For beginning classes, where only a small part of the time is available, excur- sions can be made from time to time during the year for this purpose, taking certain subjects for each excursion. For example, in the autumn one may study means for the dissemi- nation of seeds, protection of seeds, plant formations, zonal distribution of plants, formation of early spring flowers, etc. ; in the winter, twigs and buds, protection of plants against the cold; and in the spring, opening of the buds and flowers, pollination, etc., and further studies on plant societies, relation of plants to soil, topography, etc. 286 ECOLOG Y. 455. Topics for ecological study. — Some of the topics for ecological study and observation which can be taken up by beginning classes are suggested here. The order in which they may be taken up for study may be dependent to a large extent on the time of the year at which the study is made, and also upon the nearness of the school to the supply of material. But in any place, even in large cities, there are abundant supplies of material for several topics, and by foresight preparation can be made in advance for others. Studies in Perennial Shoots, the annual growth as determined by the ring scars, or position of branches. Trees. Trees with the main shoot continued through as a central trunk, as in the pines, spruces, larches, etc. Trees with a deliquescent trunk, where the main shoot is lost by continual branching, as in the elm, etc. External character of the bark of different trees, and the variation in character of the bark of certain species at different ages. Branching of shoots, different types of, in trees, shrubs. Underground shoots, as in certain ferns like the brake, sensi- tive fern, where long horizontal shoots are formed, or in the mandrake, the toothwort, etc. Creeping shoots or runners, or trailing shoots as in the poly- pody, the strawberry plant, the clematis, grape vine, club mosses, and others. Perennial underground shoots which bear aerial annual shoots, as in trillium, the mandrake, jack-in-the-pulpit, blood-root, etc. Many of these shoots also contain stored nutriment for the growth of the annual shoot. Studies of Leaf Arrangement can be made from the bare shoots by observing the positions of the leaf scars. Studies of Buds and Bud Formation, protection of buds dur- ing the winter, opening of the buds. 1NTR0D UCTJON. 287 Studies in the Relation of Plants to Light. Direction of shoots with reference to the source of light; compare shoots which have illumination equally on all sides with those which are lighted on one side only. Direction of branches with reference to the source of light ; compare the branching of a tree which has grown in an open field with one of the same species which has grown in. the forest (in the forest the lower limbs die away when they are quite small because the overgrowth of foliage at the top of the trees shuts out the light) ; compare also the branching of trees at the edge of a forest, or at the edge of a clump of trees where one side is strongly lighted and the other side is shaded by the adjacent trees. Leaf position with reference to access of light can be studied during the season when the shoots are clothed with foliage. Compare positions of leaves on trees when the foliage is dense; the leaves are nearly on the periphery of the tree, or at the ends of the branches. Sometimes even in the same species, when the foliage is thin at the ends of the branches, a great development of leaves and young shoots through the centre of the tree takes place. Compare position of leaves with reference to position of sun at different times of day. On some species the leaves are strongly turned, to face the sun, while on others the upper leaf surface faces the field of diffused light. Compare the compass plant (Lactuca scariola). Compare positions of leaves on prostrate stems, and on the upright branches of the same. Compare the lengths of petioles when leaves are clustered at the base of the shoot, or on a short shoot. Compare the positions of the flowers on trees and other plants with varying density of foliage. Studies in the Relation of Plants to Water. (Water is one of the most important factors in influencing plant life. ) During the growing season observe the effect on different 288 ECOLOG Y. plants in the variation of water-supply; for example in dry periods when the soil becomes dry, observe how much more quickly some plants wilt than others on bright days. Observe the difference in the character of the leaves of these different plants, and determine what peculiarity of the leaf in the one case favors the loss of water, while in the other case water is conserved, or the leaf does not lose water readily. With reference to the adaptations of plants to the giving off of water, or of conserving water, Shimper divides them into three classes : i. The Xerophytes; plants which love dry places, or usually grow in dry places. They possess means for conserving water, or for checking rapid trans- piration. The plants are either perennial or annual, and the leaves are not easily wilted. In some of the plants the leaves are absent, or rudi- mentary or reduced to spines, as in the cacti. The larger number of the xerophytes occur in dry regions. Xerophytic structures. Some of the xerophytic structures are thick and succulent stems, or leaves; leaves with a thick cuticle, with a thick- ened epidermis ; covering for the leaf, or stem, in the form of hairs or scales; narrow thick leaves; inrolled edges of leaves; the stomates are often protected by being sunk in deep cavities. 2. The Hygrophytes; plants which love damp situations, or grow in damp or wet situations. They possess means for giving off water, or for ready transpira- tion; there is a large water content usually in the tissues. Hygrophytes are perennial or annual. The leaves are easily wilted. 3. The Tropophytes; the plants usually grow in tem- perate regions. They possess means for conserv- INTROD UCTTON. 289 ing water at some seasons and for losing water at others. The plants are all perennial. The peren- nial parts are xeropBytic, while the annual parts are hygrophytic. Examples: trees and shrubs which possess foliage leaves in summer and in the winter the shoots are devoid of leaves. The plants are thus enabled to turn from one condition to another. (The first part of the word tropophyte means to turn, while the latter part means plant.') Compare such plants astrillium, jack-in-the-pulpit, etc. , with underground perennial shoots, and aerial annual shoots. The pines, spruces, etc., are protected from rapid transpiration during the winter by having narrow and thick leaves, and also by some in- ternal changes in the leaf as winter comes on. This division of plant forms into classes as xerophytes, hygro- phytes, and tropophytes is often very marked in wide regions. The coastal plains and the mountain regions of the tropics are characterized by hygrophytes; the steppes, deserts, polar regions, and alpine regions of the temperate zones by xero- phytes; while the greater part of the North Temperate zone is characterized by tropophytes. Between these classes there are intermediate forms which break down any attempt to draw a hard and fast line between them; yet such a classification, even if it is arbitrary, is con- venient. Also the plants of one class may occur in regions where another class is dominant. For example, the touch-me- not (impatiens) is a hygrophyte, and it occurs in the region dominated by the tropophytes. The parsley (portulaca), the mullein (verbascum) are xerophytes, and they also occur in the same legion; while the heaths, the labrador tea, etc., which occur in sphagnum moors are also xerophytes, and yet occur in the region dominated by the tropophytes. (See Chapter LII.) 29O ECOLOGY. Studies in the Relation of Plants to Soil. Observations can be made on the plants occurring on differ- ent kinds of soil, as sandy, clay, loam, rocky soil, poor or rich soil, in waste places, uncared parts of fields or gardens, etc. One very important condition of the soil is its varying physical condition of texture, and the presence of various chemical substances, which influence greatly the character of the vegetation; but this subject could not well form one for study by young students, since a knowledge of the constituents of the soil would be necessary. Warming divides plants into four classes: 1. Mesophytes, those plants which occupy a middle posi- tion with reference to the water-supply. 2. Hydrophytes, those plants which grow in damp or wet situations. 3. Xerophytes, those plants which grow in dry situa- tions. 4. Halophytes, those plants which grow in soil or water which contains an excess of certain salts. Some soils contain such an abundance of certain salts that only certain plants grow there. These plants are known as halo- phytes (salt loving). The salt lands in the great Salt Lake basin, the alkaline lands of California, Nebraska, and Dakota may be cited as examples. Certain families of plants, like the goose-foots, are peculiarly adapted to growing in such soil, though there are plants from a number of families which are found in such situations. The great amount of salt in the soil renders the absorption of water difficult by the plant, so these plants are provided with means for checking transpiration, or they would wilt. In this respect the halophytes resemble the xerophytes, and the structures for checking rapid transpiration are similar. The plants growing in the salt water are also halophytes, and those which have parts that are constantly out INTRODUCTION. 2CjI of the water, also possess xerophytic structures for the purpose of checking transpiration. Studies of Plants in their Relation to Animals. Studies in cross-pollination by the aid of insects would come under this head. Studies in Pollination brought about in other ways. Studies of Nutrition as shown in parasitic plants, in sym- biosis, etc. (See Chapter XV. ) Studies in the Relation of Life Histories of plants to sea- sonal changes as suggested in Chapter XXXVIII. Com- pare in this respect plants which flower at different seasons of the year. Studies in the Struggle between Plants for the occupation of the land. (See Chapter XLVIII. ) Studies in Soil Formation by plants. (See Chapter L.) Studies in Zonal Distribution of plants and in plant com- munities. (See Chapter XLIX. ) Studies in the Relation of Plants to Climate. (See Chapter LII. ) 456. Suggestions. — Brief discussions of a few of these topics are given here to suggest how such studies may be carried on- with young pupils. For a fuller discussion of the topics enumerated above, the student is referred to the author's larger ' ' Elementary Botany ' ' and to the works dealing more largely with the subject of ecology cited in the Appendix. But it should be borne in mind that the beginning student cannot in a few excursions make any systematic ecological study, since some special knowledge of botany would be necessary as a foundation. Some of the general truths, however, can be observed. CHAPTER XLVII. SEED DISTRIBUTION. 457. Means for dissemination of seeds. — During late summer or autumn a walk in the woods or a field often convinces us of the perfection and variety of means with which plants are pro- vided for the dissemination of their seeds, especially when we discover that several hundred seeds or fruits of different plants Fig. 245. Bur of bidens or bur-marigold, show- ing barbed seeds. Fig. 246. Seed pod of tick-treefoil (desmodium); at the right some of the hooks greatly magnified. are stealing a ride at our expense and annoyance. The hooks and barbs on various seed-pods catch into the hairs of passing animals and the seeds may thus be transported considerable distances. Among the plants familiar to us, which have such contrivances for unlawfully gaining transportation, are the 292 SEED DISTRIBUTION. 293 ibeggar-ticks or stick-tights, or sometimes called bur-marigold ((bidens), the tick-treefoil (desmodium), or cockle-bur (xan- thium), and burdock (arctium). 458. Dissemination by water. — Other plants like some of the sedges, etc., living on the margins of streams and of lakes, have seeds which are provided with floats. The wind or the flowing of the water transports them often to distant points. 459. Dissemination by animals. — Many plants possess at- tractive devices, and offer a substantial reward, as a price for Fig. 247. Seeds of geum showing the hooklets where the end of the style is kneed. the distribution of their seeds. Fruits and berries are devoured by birds and other animals; the seeds within, often passing unharmed, maybe carried long distances. Starchy and albumi- nous seeds and grains are also devoured, and while many such seeds are destroyed, others are not injured, and finally are lodged in suitable places for growth, often remote from the original locality. Thus animals willingly or unwillingly become agents in the dissemination of plants over the earth. Man in 294 ECOLOG V. the development of commerce is often responsible for the wide distribution of harmful as well as beneficial species. 460. Mechanisms for ejecting seeds? — Other plants are more independent, and mechanisms are employed for violently eject- ing seeds from the pod or fruit. The unequal tension of the pods of the common vetch (Vicia sativa) when drying causes, the valves to contract unequally, and on a dry summer day the valves twist and pull in opposite directions until they suddenly Fig. 248. Touch-me-not (Impatiens fulva) ; side and front view of flower below ; above unopened pod, and opening to scatter the seed. snap apart, and the seeds are thrown forcibly for some distance. In the impatiens, or touch-me-not, as it is better known, when the pods are ripe, often the least touch, or a pinch, or jar, sets the five valves free, they coil up suddenly, and the small seeds are whisked for several yards in all directions. During autumn, on dry days, the pods of the witch hazel contract unequally, and the valves are suddenly spread apart, when the seeds, as from a catapult, are hurled away. Other plants have learned how useful the ' ' wind ' ' may be if SEED DISTRIBUTION. 295 the seeds are provided with ' ' floats, " " parachutes, ' ' or winged devices which buoy them up as they are whirled along, often , . miles away. In Hjl/Ly ' late spring or early summer the pods of the willow burst open, exposing the seeds, each with a tuft of white hairs making a mass of soft down. As the delicate hairs dry, they straighten out in a loose spread- ing tuft, which frees the individual seeds from the compact mass. Here they are caught by cur- rents of air and float off singly or in small clouds. 461. Theprickly lettuce. — In late summer or early autumn the seeds of the prickly let- tuce (Lactuca sca- riola) are caught up from the road- sides by the winds, and carried to ¥ f Fig - 249 -. . fields where they Lactuca scanola. J are unbidden as well as unwelcome guests. This plant is shown in fig. 249. 296 ECOLOG Y. 462. The wild lettuce. — A related species, the wild lettuce (Lactuca canadensis) occurs on roadsides and in the borders of fields, and is about one meter in height. The heads of small yellow or purple flowers are arranged in a loose or branching panicle. The flowers are rather inconspicuous, the rays pro- jecting but little above the apex of the enveloping involucral bracts, which closely press together, forming a flower-head more or less flask -shaped. At the time of flowering the involucral bracts spread some- what at the apex, and the tips of the flowers are a little more prominent. As the flowers then wither, the bracts press closely together again and the head is closed. As the seeds ripen the bracts die, and in drying bend outward and downward, hugging the flower stem below, or they fall away. The seeds are thus exposed. The dark brown achenes stand over the surface of the receptacle, each one tipped with the long slender beak of the ovary. The " pappus," which is so abundant in many of the plants belonging to the composite family, forms here a pencil-like tuft at the tip of this long beak. As the involucral bracts dry and curve downward, the pappus also dries, and in doing so bends downward and stands outward, bristling like the spokes of a fairy wheel. It is an interesting coincidence that this takes place simultaneously with the pappus of all the seeds of a head, so that the ends of the pappus bristles of adjoining seeds meet, forming a many-sided dome of a delicate and beautiful texture. This causes the beaks of the achenes to be crowded apart, and with the leverage thus brought to bear upon the achenes they are pried off the receptacle. They are thus in a position to be wafted away by the gentlest zephyr, and they go sailing away on the wind like a miniature parachute. As they come slowly to the ground the seed is thus carefully lowered first, so that it touches the ground in a position for the end which contains the root of the embryo to come in con- tact with the soil. 463. The milkweed, or silkweed. — The common milkweed, SEED DISTRIBUTION. 207 or silkweed (Asclepias cornuti), so abundant in rich grounds, is attractive not only because of the peculiar pendent flower Fig. 250. Milkweed (Asclepias cornuti) ; dissemination of seed. clusters, but also for the beautiful floats with which it sends its seeds skyward, during a puff of wind, to finally lodge on the earth. 464. Means for floating the seeds. — The large boat-shaped, tapering pods, in late autumn, are packed with oval, flat- tened, brownish seeds, which overlap each other in rows like shingles on a roof. These make a pretty picture as the pod in drying splits along the suture on the convex side, and exposes them to view. The silky tufts of numerous long, delicate white hairs on the inner end of each seed, in 298 ECO LOG V. drying, bristle out, and thus lift the seeds out of their en- closure, when they are borne, buoyant as vapor, bearing the embryo plant, which is to take its place as a contestant in the battle for existence. Fig. 251. Seed distribution of virgin's bower (clematis). 465. The virgin's bower. — The virgin's bower (Clematis virginiana), too, clambering over fence and shrub, makes a SEED DISTRIBUTION. 299 show of having transformed its exquisite white flower clusters into grayish-white puffs, which scatter in the autumn gusts into hundreds of arrow-headed, spiral plumes. The achenes have plumose styles, and the spiral form of the plume gives a' curious twist to the falling seed (fig. 251). CHAPTER XLVIII. STRUGGLE FOR OCCUPATION OF LAND. 466. Retention of made soil. — In the struggle of plants for existence, there are a number of species which stand ready to rush in where new opportunities present themselves by changed conditions, or by newly made soil. The permanent drainage of ponds or marshes brings changed conditions, and the flora there undergoes remarkable transformations. The deposits of the washings of streams in protected places along the shores, or at their mouths, where deltas or lateral plateaus are made by the accumulations of soil scoured off the banks of the stream, or washed off the fields during rains, make new ground. With such banks of newly made_ ground are deposited seeds carried along with the soil, or dropped there by the wind, by birds, or other agencies of seed distribution. 467. Vegetation of sand dunes. — Along the sandy beaches of lakes, or of the ocean, drift piles of the fine sand are formed, which often are moved onward by the wind. The surface par- ticles are moved onward to the leeward of the drift, and so on. The form and location of the sand dune gradually changes. Such drifts sometimes slowly but surely march along over soil where a rich vegetation grows, and over valuable land. Even on these sand dunes there are certain plants which can gain a foothold and grow. When a sufficient number obtain a foot- hold in such places they retain the sand and prevent the move- ment of the dune. 468. Reforestation of lands. — When by the action of fire or wind, or through the agency of man, portions of forests are 300 OCCUPATION OF LAND. 301 302 EC0L0G Y. partially or completely destroyed, a new set of conditions is presented over these areas. One of the most important is that light is admitted where before towering trees permitted but a limited and characteristic undergrowth to remain. Hundreds of forms, which for years have been dormant, are now awakened from their long sleep, and new and recent importations of seeds, wnich are constantly rushing in, spring into existence to fill the gap, multiply their numbers, and make more sure the perpetua- tion of their kind. 469. The weaker ones are overcome. — The earliest to appear are not always the ones to endure the longest, and a battle Fig. 253. Abandoned field in Alabama, growing up to broom-sedge and trees. (Photograph by Prof. P. H. Mell.) royal takes place during years for supremacy. The weaker ones are gradually overcome by the more vigorous, and a new crop of trees, which often springs up in such places, finally usurps again the domain, in the name of the same or of a different species. 470. Feral plants in neglected fields. — Domestic plants pro- OCCUPA TION OF LAND. 303 ected by man occupy cultivated fields. When cultivation eases, or the crop is removed, or the fields are neglected, mndreds of species of feral plants, which are constantly spring- ig up, now flourish, bear seed, and take more or less complete Fig. 254. abandoned field, Alabama, self reforested by pines. (Photograph by Prof. P. H. Mell.) ossession of the soil. Impoverished land, abandoned by man, ecomes nurtured by nature. Weeds, grass, flowers spring up 1 great variety often. Some can thrive but little better than le abandoned crops, while others, peculiarly fitted because of ne or another adapted structure or habit, flourish. Crab-grass 304 ECOLOG Y. and other low-growing plants often cover and protect the soil from the direct rays of the sun, and thus conserve moisture. Fig. 255. Self-sown white pine in abandoned orchard ; trees 9-20 years old;- Near'Ithaca. (Photo- graph by the author.) *' ' The clovers which spring up here and there, by the aid of the minute organisms in their roots, gather nitrogen. The meli- lotus,' the passion flower, and other deep-rooted plants reach down- to Virgin soil and lift up plant food. Each year plant OCCUPA TION OF LAND. 305 remains are added to, and enrich, the soil. In some places grasses, like the broom-sedge (andropogon), succeed the weeds, and a turf is formed. 471. Trees follow weeds and grasses. — Seeds of trees in the mean time find lodgment. During the first few years of their growth they are protected by the herbaceous annuals or peren- nials. In time they rise above these. Each year adds to their height and spread of limb, until eventually forest again stands where it was removed years before. In the Piedmont section of the Southern States such a view as is presented in fig. 253 represents how abandoned fields are taken by the broom-sedge, to be followed later by pines, and later by a forest as shown in fig- 254. 472. Self-sown white pines. — In New York State many abandoned hillsides are being reforested slowly by nature with the white pine. Fig. 255 represents a group of self-sown pines ranging from three to six meters high (10-20 feet), growing up in an abandoned orchard near Ithaca. In this reforestation of impoverished lands, man can give great assistance by timely and proper planting. CHAPTER XLIX. ZONAL DISTRIBUTION OF PLANTS. 473. On the margins of lakes or ponds, where the slope is gradual from the land into the water, one often has an oppor- tunity to study the relation of various plants to different conditions of soil and water. In rowing near the south shore of Lake Cayuga, I have often been impressed with the definite areas occupied by certain plants. Figure 257 is from a photograph, taken from the boat, of the shore distribution of these plants. The most striking feature here is the grouping of certain kinds of plants in definite lines or zones. Here the limitations of the zones are quite distinct, so that the transition from one zone to another is quite abrupt, though there is some mixture of the kinds at the zone of transition, or tension line. 474. Zonal arrangement. — This arrangement of plants under such environmental influences is termed ' ' zonal distribution of plants. ' ' The slope where this photograph was taken is so 306 Fig. 256. Sagittaria variabilis. ZONAL DISTRIBUl^ION OF PLANTS. 307 3o8 ECOLOG Y. symmetrical that plants suited by their long habit of growing at certain depths of water, or in soil of a certain moisture content, are readily drawn into zones parallel with the shore line. Fig. 258. Sagittaria variabilis. Several zones can be readily made out in this region; two of them at least do not show in the picture since they are sub- merged. 475. Submerged zones in the foreground. — If we treat of the ZONAL DISTRIBUTION OF PLANTS. 309 two submerged zones, the first one is in the rear of the point from where the photograph was taken, and consists of extensive areas of chara in four to five meters of water. The second zone Fig. 259. Sagittaria heterophylla. Often forms a zone just outside of the Sagittaria variabilis. then is in the water shown in the foreground of the picture. The plants here are also submerged, or only a small portion reaches the surface of the water, and so the zone does not 3'° ECOLOGY. show. In this zone occurs the curious Vallesneria spiralis, with its corkscrew flower stem, and various potamogetons. 476. The visible zones. — In the third zone, or the first one which shows in the picture, are great masses of the arrow-leaf (sagittaria) so variable in the form of its leaves. Next is the fourth zone, made up here chiefly of bullrushes (scirpus), and occasionally are clumps of the cattail flag (typha). Behind this is the fifth zone, only to be distinguished at this distance by the bright flower heads of the boneset (Eupatorium perfolia- tum) and joepye-weed (Eupatorium purpureum), and the blue vervain (Verbena hastata), which occurs on the land. Willows make a compact and distinct sixth zone, while at the right, the oaks on the hillside beyond form a seventh zone, and still farther back is a zone of white pines, making the eighth. CHAPTER L. SOIL FORMATION IN ROCKY REGIONS AND IN MOORS. Lichens. 477. The lichen, parmelia. — Many of the lichens are small and inconspicuous. They often appear only as bits of color on tree trunk or rock. One of the conspicuous ones on stones lying on the ground is the grayish-green thallus of Parmelia contigua (fig. 260). Its pretty, flattened, forking lobes ra- diate in all directions, advancing at the margin, and covering year by year more and more of the stone surface. Numerous cup-shaped fruit bodies (apothecia) are scattered over the central area. The thallus clings closely to the rock surface by numerous holdfasts from the under side, which penetrate minute crevices of the rock. The lichen derives its food from the air and water. By its closely fitting habit it retains in contact with the rock certain acids formed by the plant in growth, or in the decay of the older parts, which slowly disintegrate the surface of the rock. These disintegrated particles of the rock, mingled with the lichen debris, add to the soil in those localities. 478. Lichens are among the pioneers in soil making. — The habit which many lichens have of flourishing on the bare rocks fits them to be among the pioneers in the formation of soil in rocky regions which have recently become bared of ice or snow. The retreat of glaciers from peaks long scoured by ice, or the unloading of broken rocks along its melting edge, exposes the rocks to the weathering action of the different elements. Now 3" 312 ECOLOGY. the lichens lay hold on them and invest them with fantastic figures of varied color. Disintegrating rock, debris of plants and animals, join to form the virgin soil. Certain of the blue- green algse, as well as some of the mosses, are able to gain a foothold on rocks and assist in this process of soil formation. Fig. 260. Rock lichen (Parmelia contigua). A view of rocks thrown down by the melting and retreating edge of a glacier in Greenland is shown in fig. 261. These rocks at the time the photograph was taken had no plant life on them. At other places in the vicinity of this glacier, rocks SOIL FORMATION : ROCK DISINTEGRATION. 3 I 3 longer uncovered by ice were being covered by plant life. One of the Greenland rock lichens is shown in fig. 262. 479. Other plants of rocky regions. — Certain of the higher plants also find means of attachment to the bare rocks of the Fig. 261. Edge of glacier in Greenland, showing freshly deposited rocks. (From Prof. R. S. Tarr.) arctic and mountain regions. The roots penetrate into narrow crevices in the rock, and are able to draw on the water which is elevated by capillarity. Such plants, however, which live on bare rocks, whether in the arctic or in mountain regions, have 3H ECOLOG Y. leaves which enable them to endure long periods of drought. These plants have either succulent leaves like certain of the stone-crops (sedum), or small thick leaves which are closely overlapped as in the Saxifraga oppositifolia. Few of us, unfortunately, can make the trip to the arctic regions to study these interesting plants which play such an V' • • B « J> y iPll 1 {a H r "iff j w- ■■■trw-® ^J ^4P vara ,; ^-^' t t m^^^S 9 Jig? MP V 1* < l In rii. ■■ - ~ | Rep B^T^y ■ ~ Fig. 262. Rock lichen (umbilicaria) from Greenland. important role in the economy of nature. Rocky places, how- ever, or loose stones are common nearer home. Observation of their flora, and the means by which such plants derive nutri- ment, store moisture, or protect themselves from drought, will well repay outdoor excursions. SOIL FORMATION: ROCK DISINTEGRATION. 315 ■ •n 3l6 ECOLOGY. 480. Filling of ponds by plants. — Not only are plants im- portant agencies in the formation of soil in rocky regions, they are slowly but surely playing a part in the changes of soil and in the topography of certain regions. This is very well marked in the region of small ponds, where the bottom slopes gradually out to the deeper water in the centre. Striking examples are sometimes found where the surface of the country is very broken or hilly with shallow basins intervening. In what are termed morainic regions, the scene of the activity of ancient glaciers, or in the mountainous districts, we have opportunities for studying plant formations, which slowly, to be sure, but nevertheless certainly, fill in partly or completely these basins, so that '.the water is confined to narrow limits, or is entirely replaced by plant remains in various stages of disintegration, upon which a characteristic flora appears. 481. A plant atoll. — In the morainic regions of central New York there are some interesting and striking examples of the effects of plants on the topography of small and shallow basins. These formations sometimes take the shape of " atolls," though plants, and not corals, are the chief agencies in their gradual evolution. Fig. 263 is from a photograph of one of these plant atolls about 15 miles from Ithaca, N. Y. , along the line of the E. C. & N. R. R. near a former flag station known as Chicago. The basin here shown is surrounded by three hills, and is formed by the union of their bases, thus forming a pond with no outlet. 482. Topography of the atoll moor. — The entire basin was once a large pond, which has become nearly filled by the growth of a vegetation characteristic of such regions. Now only a small, nearly circular, central pond remains, while entirely around the edge of the earlier basin is a ditch, in many places with from $o-6ocm. of water. There is a broad zone of land then lying between the central pond and the marginal ditch. Just inside of the ring formed by the ditch is an elevated ring extending all around, which is higher than any other part SOIL FORMATION: ROCK DISINTEGRATION. 317 of the atoll. On a portion of this ring grow certain grasses and carices. The soil for some depth shows a wet peat made up of decaying grasses, carices, and much peat moss (sphagnum). In some places one element seems to predominate, and in other cases another element. On some portions of the outer ring are shrubs one to three meters in height, and occasionally small trees have gained a foothold. Next inside of this belt is a broad, level zone, with Carex filiformis, other carices, grasses, with a few dicotyledons. Intermingled are various mosses and much sphagnum. The soil formation underneath contains remains of carices, grasses, and sphagnum. This intermediate zone is not a homogeneous one. At certain places are extensive areas in which Carex filiformis predominates, while in another place another carex, or grasses predominate. 483. A floating inner zone. — But the innermost zone, that which borders on the water, is in a large measure made up of the leather-leaf shrub, cassandra, and is quite homogeneous. The dense zone of this shrub gives the elevated appearance to the atoll immediately around the central pond, and the cassandra is nearly one meter in height, the "ground" being but little above the level of the water. As one approaches this zone, the ground yields, and by swinging up and down, waves pass over a considerable area. From this we know that underneath the mat of living and recent vegetation there is water, or very thin mud, so that a portion of this zone is "floating." The inner, or cassandra, zone is more unstable, that is, it is all " afloat," though firmly anchored to the intermediate zone. The roots of the shrubs interlace throughout the zone, firmly anchoring all parts together, so that the wind cannot break it up. Between the tufts of the cassandra are often numerous open places, so that the water or thin mud on which the zone floats reaches the surface, and one must exercise care in walk- ing to prevent a disagreeable plunge. No resistance is offered 3i« ECOLOGY. e 4 a to-a SOIL FORMATION: ROCK DISINTEGRATION. 3I9 to a pole two or three meters long in thrusting it down these holes. Grasses, carices, mosses, sphagnum, and occasionally moor-loving dicotyledons occur, anchored for the most part about the roots of the Cassandra. Standing at the inner margin of the cassandra zone, one can see the mud, resembling a black ooze, formed of the titrated plant remains, which have floated out from the bottom of the older formations. In some places this lies very near the surface, and then certain aquatic plants like bidens, and others, find a footing. Upon this black ooze the formation can continue to encroach upon the central pond. Agitated by the wind, more and more of the ooze passes out- ward, so that in time there is a likelihood that the pond will cease to exist, yielding, as it has in other places, the right of possession to the contentious vegetation. 484. How was the atoll formed? — In the early formation of the atoll, it is possible that certain of the water-loving carices and grasses began to grow some distance (three to four meters) from the shore, where the water was of a depth suited to their habit. The stools of these plants gradually came nearer the surface of the water. As they approach the surface, other plants, not so strong-rooted, like mosses, sphagnum, etc., find anchorage, and are also protected to some extent from the direct rays of sunlight. Partial disintegration of the dead plant parts and mingling with the soil gradually fill on the inside of the zone, so that the depth of the water there becomes less. Now the zone of the carices can be extended inward. The continued growth of the sphagnum and the dying away of the lower part of the plant add to the bulk of the plant remains in the zone, and finally quite a firm ground is formed, shutting off the shallow water near the shore from the deeper water of the pond. As time goes on other plants enter and complicate the formation, and even make new ones, as when the cassandra takes possession. The original pond here was rather oblong, and one end possi- bly much shallower than the other, so that it filled in much 320 ECOLOGY. more rapidly, leaving the central pond at the east end. Over a portion of the west end there is an extensive cassandra forma- tion, with some ledum (Iabrador tea), but separated from the circular cassandra zone by an intermediate zone. In this end- cassandra formation other shrubs, and white pines five to fifteen years old, are gaining a foothold, and in a quarter of a century or more, if left undisturbed, one may expect considerable changes in the flora of this atoll. It is possible that a rise of the water for a number of years when the earlier zones were floating accounts for the circular elevation and atoll forma- tion, or that the dense shade from forest trees years ago may have checked the growth of plants in the margin, thus leaving a marginal depression. 485. A black-spruce moor. — A somewhat similar but more advanced plant formation occurs east of Freeville, N. Y., and about nine miles distant from Ithaca. The centre of the basin, which was perhaps shallower than the former one, has become completely filled, and all of the central formation is more elevated than the margin by the shore of the basin. All around the margin in wet weather the ground is more or less sub- merged, while all the central portion is so elevated that the numerous stools or hummocks of grasses like eriophorum, with its white tufts sparkling in the sunlight like a firmament of stars, shrubs like cassandra, pyrus, nemopanthes, etc., support one in walking above the water which rises in the intervening spaces. Sphagnum, polytrichum, and other mosses grow, especially in the stools of the other plants, where they now are shaded by the larger growth, and in drier seasons catch the water which trickles down during rain. Years ago the forest encroached on this formation, and trees of the hemlock-spruce, black spruce, larch, etc., of consider- able size gained a footing, first along the margin, then along the more elevated zone a short distance within. The black spruce trees spread all over the centre of the formation, attain- ing a height of one to six or eight meters, while the trees of the SOIL FORMATION \- ROCK DISINTEGRATION. %2\ marginal zone where they first entered, and the ground is some- what more eleva- ted, attained a much greater height. 486. Fall of the trees on the marginal zone when the wind break was r e moved. — T hese large trees of the marginal z. o n e , though they were rooted to a great ^| extent in loose S. 5 soil, nevertheless were protected from winds by the forests on the sur- rounding hills. When, however, :hese hills on three sides were cleared 'or cultivation the vind had full weep, and many >f the large trees rere uprooted by he force of the ales. This view i supported by the ict that the west- 322 ECOLOG Y. ern hill is still covered by forest, and large spruce trees of the marginal zone are still standing, though several were up-rooted September, 1896, during a fierce southeastern gale, the wind from this direction having full play upon them. 487. Dying of the spruce of the central area. — This removal of the forests from the surrounding hills very likely had its influence in hastening the melting of the winter snows on the hills, so that excessive quantities of water from this source Fig. 266. Dying black spruce in moor. (Photograph by the author.) rushed quickly down into the swamp, flooding it at certain seasons much higher than the normal high-water mark during former times, when the hills were forest-covered. Also during rains the water would now rush quickly down into the swamp, flooding it at these times. This greater quantity of water has had its effect, probably, in causing many of the young spruces over the centre of the formation to die off. SOIL FORMATION: ROCK DISINTEGRATION. 323 488. Effect of fire. — This may also have been hastened by fires which would now more often sweep over the swamp during dry seasons. In partial evidence of this are many young spruce trees with scars near the ground where the bark has been destroyed. This gives admittance to wood-boring insects which farther aid in the process of weakening and debilitating the trees. The dying off of the lower limbs of these marsh spruces suggests the action of fire, as well as excessive moisture at times. Many of them now present only a small convex top of living branches. It is interesting to observe the gradation in this respect in different trees. 489. Weird aspect of dead spruces. — The weird aspect pre- sented by a clump of these dying young spruce trees is height- ened also by the changes in the form of the branches as they die. The living branches have a graceful sigmoid sweep with their free ends curving upwards as in many conifers. As the branches die, the free ends curve downward more and more, all gradations being presented in a single tree. A group of such dying spruce trees is shown in fig. 266. Some have been long dead; only the knotted, weather-beaten trunks still remain tottering to their final condition. Others with leafless, dried, sprawling branches go swirling with every wind, while a few struggle on in the presence of these untoward conditions. 490. Other morainic moors. — In other basins, where the hills on all sides are still forest-clad, more equable temperature and moisture conditions are conserved. This permits plants to flourish here which in the exposed basins are disappearing from the formations or -only leading a miserable existence. . This is strikingly true of some sphagnum formations. In the atoll formation described tne evidence suggests that sphagnum formerly played a more active part in the evolution of that type of moor than has been the case since the hills were denuded of their trees. So also in the spruce moor, sphagnum probably was at one time a prominent factor in the formation of the early vegetation. But excessive drought during certain seasons, and 324 ECOLOG V. full exposure to the sun and wind, have served to lessen its influence and importance. But where protected from the wind, to a large extent from the heat of the sun, and supplied with a suitable moisture condition, the sphagnum flourishes. It grows either alone in shallow water, en- croaching more and more on the centre of the basin, or follows after and anchors among water-loving grasses and carices. In some cases it may thus largely cover such earlier formations. An examination of the sphagnum plant shows us how well it is adapted to flourish under such con- ditions. The main axis of the plant bears lateral branches nearly at right angles, but with a graceful downward sweep at the extremity. These pri- mary lateral branches bear secondary branches, which arise, usually several, from near the point of attachment to the main axis. They hang down- ward, overlap on those below, and* completely cover the main axis or stem. The leaves of sphagnum are peculiarly adapted for the purpose of taking up quantities of water. Not all the cells of the leaf are green, but alternate rows of cells become broadened, lose their chlorophyll, and their protoplasm collapses on the inner faces of the cell walls in such a way as to form thickened lines, giving a peculiar sculpturing effect to them. Perforations also take place in the walls. These Fig. 267. Two fruiting plants of sphagnum. (From Kerner and Oliver.) ■ SOIL FORMATION: ROCK DISINTEGRATION. 32$ empty cells absorb large quantities of water, and by capillarity it is lifted on from one cell to another. These pendent branches, then, which envelop the sphagnum stem, lift water up from the Where isoetes grows Fig. 268. A small morainic basin near Ithaca. (Photograph by the author.) moist substratum to supply the leaves and growing parts of the plant which are at the upper extremity. 491, Increase each year. — Year by year the extension of the sphagnum increases slowly upward by growth of the ends of the 326 ECOLOG Y. individual plants, while the older portions below die off, partly disintegrate, and pass over into the increasing solidity and bulk of the peat. It thus happens sometimes that the centres of Kig. 269. Cypress knees, Mississippi. (Photograph by H. von Schrenk.) such basins or moors are more elevated than the margins, because here a greater amount of water exists in the depths which is pumped up for use by the plants themselves. Such a formation is sometimes called a " high moor." 492. Change in form. — Because of the peculiar topographic features of these basins, together with the conditions of mois- ture, etc., changes in their form are quite readily observed. SOIL FORMATION: ROCK DISINTEGRATION . Wj But no less important are the influences of plants on soil con- ditions on the hills, and in more level areas. Old plant parts, and plant remains, by decay add to the bulk, fertility, and changing texture and physical condition of the soil. 493. The bald cypress (Taxodium distichum). — Very char- acteristic are the formations presented by the forests of the bald cypress of the South, which grows in swampy or marshy places. The "knees" on the roots of this cypress make grotesque figures in the cypress forest. These take the form of upright columnar outgrowths, broader at the base or point of attach- ment to the horizontal root, and possess a fancied resemblance to a knee. These knees are said to occur at points on the horizontal root above and opposite the point where a root branch extends downward into the soft marsh soil. They thus give strength to the horizontal root at the point of attachment of the branch which penetrates into the soft soil, and during gales they hold these root branches more rigidly in position than would be the case if the horizontal root could easily bend at this point. The knees thus are supposed by some to strengthen the anchor formed by the root in the loose soil. Their development may be the result of mechanical irritation at these points on the horizontal root, brought about by the strain on the roots from the swaying of the tree. Others regard them as organs for aerating the portions of the root system which are usually submerged in water or wet soil, and in this sense the knees are sometimes termed pneumatophores. The knees catch and hold floating plant remains during floods, and by the decay of this debris the fertility of the soil is increased. CHAPTER LI. PLANT COMMUNITIES: SEASONAL CHANGES. 494. Relations of plants. — One of the interesting subjects for observation in the study of the habits and haunts of plants is the relation of plants to each other in communities. In the topography of the moors, and of the land near and on the margins of bodies of water, we have seen how the adaptation of plants to certain moisture conditions of the soil, and to varying depths of the water, causes those of a like habit in this respect to be arranged in definite zones. Often there is a pre- dominating species in a given zone, while again there may be several occupying the same zone, more or less equally sharing the occupation. Many times one species is the dominant form, while several others exist by sufferance. 495. Plants of widely different groups may exist in the same community. — So it is that plants of widely different rela- tionships have become adapted to grow under almost identical environmental conditions. The reed or grass growing in the water is often accompanied by floating mats of filamentous algae like spirogyra, zygnema; or other species, as cedogonium, coleo- chsete, attach themselves to these higher lords of creation; while desmids find a lodging place on their surface or entangled in the meshes of the other algae. Chara also is often an accom- paniment in such plant communities, and water-loving mosses, liverworts, and fern-like plants as marsilia. Thus the widest range of plant life, from the simple diatom or monad to the complex flowering plant, may, by normal habit or adapted form, live side by side, each able to hold its place in the com- munity. 328 PLANT COMMUNITIES: SEASONAL CHANGES. 329 In field or forest, along glade or glen, on mountain slope or in desert regions, similar relationships of plants in communities are manifest. The seasons, too, seem to vegetate, blossom, and fruit, for in the same locality there is a succession of differ- ent forms, the later ones coming on as the earlier ones dis- appear. 496. Seasonal succession in plant communities. — The wooded slopes in springtime teem with trillium, dentaria, Fig. 270. Azalea (Rhododendron nudicaulis). podophyllum, and other vernal blossoms, while on the steeper hillsides the early saxifrage is to be found. In the rocky por- tions of the glen, which is aiso a favorite lodgment for this prettv, white saxifrage, the wild columbine loves to linger and Jangle its spurred flowers. The lichen-colored ledge is wreathed 330 ECOLOGY. Fig. 271. Walking fern, climbing down a hillside. PLANT COMMUNITIES : SEASONAL CHANGES. 33 l with moss and fern. On the partly sunlit slopes the clusters of azalea are radiant with blossoms, while here and there the shad- bush, or service-berry (amelanchier), with its mass of white flower-sprays, overhangs some cliff, and the cockspur thorn (Crataegus) vies with it in the profusion of floral display. Near by sheets of water pour themselves unceasingly on the rocks below, scattering spray on the thirsty marchantia. Out from the steep slopes above rise the graceful sprays of the yew (taxus), i 1 -^M^ ttf» %M^fl htii ,Mki| WW : , »*. A £- w ^ r^*t tm -^'/J^^ *w¥- ^tw^^M- ii^ .* ■f w w w "*2 F,«f ^y # J B M W ""*-»•** "M I^Jp! : #S 7i if 1 ''1 '■ J^ * . jytt ; i H*i #1 fr. ■" *t *fp ] i *n m0 ^^^^^ H / ^^^= Fig. 272. Spray of kalmia flowers. shaded by the towering hemlock spruces. The ' ' walking-fern here, holding fast above, climbs downward by long graceful strides. 497. Change in color with the season. — But the scene shifts, and while these flowers . cast their beauty for the season, others put on their glory. The flowering dogwood spreads its decep- 33 2 ECOLOG Y. tive bracts as a halo around the clusters of insignificant flowers. The laurel (kalmia) with its clusters of fluted pinkish blossoms is a joy only too brief. Smaller and less pretentious ones abound, like the whortleberries, amphicarpaea, bush-clover (lespedeza), sarsaparilla, and so on. 498. Autumn plants. — In the autumn the glen is clothed with another robe of beauty. With the fall of the " sere and i yellow leaf," golden-rod and aster still linger long in beauty Fig. 273. Spray of witch-hazel (hamamelis) with flowers ; section of flower below. and profusion. When the leaves have fallen the witch-hazel (hamamelis) begins to flower, and the snows begin to come before it has finished spreading its curled yellow petals. 499. The landscape a changing panorama. — In our tem- perate regions the landscape is a changing panorama; forest and field, clothed with a changing verdure, don and doff their foliage with a precision that suggests a self-regulating mechan- ism. In the glad new spring the mild warmth of the sun stirs the dormant life to renewed activity. With the warming up of the soil, root absorption again begins, and myriads of tiny root hairs pump up watery solutions of nutriment and various salts. PLANT COMMUNITIES: SEASONAL CHANGES. 333 These are carried to the now swelling buds where formative processes and growth elongate the shoot and expand the leaf. Buds long wrapped in winter sleep toss back the protecting scales. In a multitude of ways the different shrubs and trees Fig. 274. Opening buds of hickory. now discard the winter armature which has served so good a purpose, and tiny bud leaves show a multitude of variations from simple bud scale to perfect leaf, a remarkable diversifica- tion in which the plant from lateral members of the stem forms 334 ECOLOG y. organs to serve such a variety of purpose under such diametri- cally opposed environmental conditions. 500. Refoliation of bare forests in spring. — There is a Fig. 275. Austrian pine, showing young growth of branches in early spring. certain charm watching the refoliation of the bare forests, when the cool gray and brown tints are slowly succeeded by the light PLANT COMMUNITIES: SEASONAL CHANGES. 335 yellow-green of the young leaves, which presents to us a warm- ing glow of color. Then the snow-clad fields change to gray, and soon are enveloped in a living sea of color. The quiet hum of myriads of opening buds and flowers in harmony with the general awakening of nature, and the trickling streamlets which unite into the gurgling brooks, makes sweet music to our attentive minds. 501. Contrast of color in evergreens. — The evergreens dis- play a striking contrast of color. The leafy, fan-shaped branches of the hemlock-spruce (tsuga) are fringed with the light green of the new growth. The pines lift up numbers of cylindrical shoots, with the leaf fascicles for a time sheathed in the whitened scales, while the shoots are tipped with the brown or flame-colored female flowers, reminding one of a Christmas tree lighted with numerous candles. The numerous clusters of staminate flowers suggest the bundles of toys and gifts, and one inquires if this beautiful aspect of some pines when putting on their new growth did not suggest the idea of the Christmas tree at yule time. 502. The summer tints are more subdued. — As summer time draws on the new needles of the pine are unsheathed, the light green tints of the forest are succeeded by darker and subdued colors, which better protect the living substance from the intense light and heat of midsummer. The physiological processes for which the leaf is fitted go on, and formative materials are evolved in the countless chlorophyll bodies and transported to growing regions, or stored for future use. In transpiration the leaf is the terminus of the great water current started by the roots. Here the nutrient materials, for which the water serves as a vehicle, are held back, while the surplus water evaporates into the air in volumes which surprise us when we know that it is unseen. 503. Autumn colors. — As summer is succeeded by autumn, a series of automatic processes goes on in the plant which fits it for its long winter rest again. Long before the frosts appear, 33 6 ECOLOGY. here and there the older leaves of certain shrubs lose more or less of the green color and take on livelier tints. With the disintegration of the chlorophyll bodies, other colors, which in some cases were masked by the green, are uncovered. In other cases decomposition products result in the formation of new colors. These coloring substances to some extent absorb the sun's rays, so that much of the nitrogenous substances in the leaf may not be destroyed, but may pass slowly back into the stem and be stored for future use. 504. Fall of the leaf. — The gorgeous display of color, then, which the leaves of many trees and shrubs put on is one of the many useful adaptations of plants. While this is going on in deciduous trees, the petiole of the leaf near its point of attach- ment to the stem is preparing to cut loose from the latter by forming what is called a separative layer of tissue. At this point the cells in a ring around the central vascular bundle grow rapidly so as to unduly strain the central tissue and epidermis, making it brittle. In this condition a light puff of wind whirls them away in eddies to the ground. The frosts of autumn assist in the separation of the leaf from the stem, but play no part in the coloration of the leaf. As the cold weather of autumn and winter draws slowly on, these trees and shrubs cast off their leaves, and thus get rid of the extensive transpiration surface, or in some cases the dead leaves may cling for quite a long period to the trees. However, in the death and fall of the leaves of these deciduous trees and shrubs, or the dying back of the aerial shoots of perennial herbaceous plants, there is a most useful adaptation of the plant to lay aside, for the cold period, its extensive transpira- tion surface. For while the soil is too cool for root absorption, should transpiration go on rapidly, as would happen if the leaf surface remained in a condition for evaporation, the plants would lose all their water and dry up. CHAPTER LII. ADAPTATION OF PLANTS TO CLIMATE. 505. Some characteristics of desert vegetation. — One of the important factors in plant form and distribution is that of clmate, which is modified by varying conditions, as tempera- ture, humidity of the air, dryness, etc. In desert regions where the air and soil are very dry, and plants are subject to long periods of drought, there is a very characteristic vegetation, and a variety of forms have become adapted to resist the drying action of the climate. Some of the plants, especially the larger ones, have very suc- culent stems or trunks, or they are more or less expanded but thickened, while the leaves are reduced to mere spines or hairs, as in the cacti. If plants in desert regions had thin and broadly expanded leaves, transpiration would be so rapid, and so great, as to kill them. In these succulent stems there is a propor- tionately small surface area exposed, so that transpiration is reduced. The chlorophyll resides here in the stems, and they function as foliage leaves in many other plants do. Other plants of the desert, which do not have succulent stems, are provided with closely appressed and small, thick, scale-like leaves. The leaves in many of these plants have an epidermis of several layers of cells, so that transpiration does not take place so rapidly. In addition to this the stomata are sunk in pits, or cavities, so that the guard cells are not so exposed to the drying action of currents of air at the surface. In still other cases the leaves and stems are covered with a dense felt of hairs which serves as a cushion to protect them 337 338 ECOLOGY. from the direct rays of the sun, and also from the fierce blastb of dry air which frequently sweep over these regions. The hairs are so close, and so interwoven, that the air caught in the interstices is not easily displaced, and the leaves are not then subject to the drying effects of the passing winds. 506. Some plants of temperate regions possess characters of desert vegetation. — Even in temperate regions in localities where the climate is more equable, certain plants, strangely, are similarly modified, or provided with protecting armor. The common purslane (portulaca) is an example of a succulent plant, and we know how well it is able to resist periods of drought, even when cut free from the soil. With the oncoming of rains it revives, and starts new growth, while in wet weather cutting it free from its roots scarcely interferes with its growth. Similarly the common mullein (Verbascum thapsus), the leaves and stems of which, are so densely covered with stellate hairs, is able to resist dry periods. One can see how efficient this panoply of trichomes is by immersing the leaves in water. It is very difficult to remove the air from the interstices of the interwoven trichomes so as to wet the epidermis. 507. Alpine plants with desert characteristics.- — Alpine plants (those on high mountains), as well as arctic plants, are similarly modified, having usually either succulent stems and leaves, or small, thick and appressed leaves, or leaves covered with numerous hairs. Cassiope, occurring on mountain sum- mits of the northeastern United States, and far northward, has numerous needle-shaped, closely imbricated leaves. The plants need the protection afforded them by these peculiarities in these alpine and arctic regions because of the dry air and winds, as well as because of the bright sunlight in these regions. Because of the bright sunlight in alpine and arctic regions many of the plants are noted for the brilliant colors of the flowers. 508. Low statnre of alpine plants a protection against wind and cold. — Another protection to plants from winds and ADAPTATION TO CLIMATE. 3J^ Fig. 276. Birch trees from Greenland, one third natural size. 34Q ECOLOG V. ' Fig. 277. Willows from Greenland, one third natural size. ADAPTATION TO CLIMATE. 341 from the cold in such regions is their low stature. Many of the herbaceous plants have very short stems, and the leaves lie close to the soil, the plants and flowers sometimes half covered with the snow. The heat absorbed by the soil is thus imparted to the plant. Trees in such regions (if the elevation or latitude is not beyond the tree line) have very short and crooked stems, and sometimes are of great age when only a foot or more high, and the trunk is quite small. In figure 276 are shown some birch trees from Greenland, one third natural size, the entire tree being here shown. Similarly figure 277 represents some of the arctic willows, one third natural size. 509. Some plants of swamps and moors present characters of arctic or desert vegetation. — Many of the plants of our swamps and moors have the characters of arctic or of desert vegetation, i.e., small, thick leaves, or leaves with a stout epidermis. The labrador tea (Ledum latifolium), an inhabitant of cold moors or mountain woods, has thick, stout leaves with a hard epidermis on the upper side, and the lower side of the leaves is densely covered with brown, woolly hairs. Transpira- tion is thus lessened. This is necessitated because of the cold soil and water of the moor surrounding the roots, which under these conditions absorb water slowly. Were the leaves broad with a thin and unprotected epidermis, transpiration would be in excess of absorption, and the leaves would wither. Cassan- dra, or leather-leaf, and chiogenes, or creeping snowberry, are other examples of these shrubs growing in cold moors. 510. Hairs on young leaves protect against cold and wet. —Hairs on young leaves in winter buds afford protection from cold and from the wet. The young leaves of the winter buds of many of our ferns are covered with a dense felt of woolly hairs. In species of osmunda this is very striking. The leaves ire quite well formed, though small, during the autumn, and the sporangia are nearly mature. The hairs are so numerous, and so closely matted together, that they can be torn off in the form of a thick woolly cap. APPENDIX. COLLECTION AND PRESERVATION OF MATERIAL. Spirogyra may be collected in pools where the water is present for a large part of the year, or on the margins of large bodies of water. To keep fresh, a small quantity should be placed in a large open vessel with water in a cool place fairly well lighted. In such places it may be kept several months in good condition. Some species of vaucheria occur in places frequented by oedogonium or spirogyra, while others occur in running water, or still others on damp ground. Frequently fine specimens of vaucheria in fruit may be found during the winter growing on the soil of pots in greenhouses. The jack-in-the-pulpit, also known as Indian turnip, growing in damp ground I have found when potted and grown in the conservatory yields an abundance of the vaucheria, probably the spores of the alga having been transferred with the soil on the plants. When material cannot be obtained fresh for study, it may be preserved in advance in formalin or alcohol. Wheat rust. — The cluster-cup stage may be collected in May or June on the leaves of the barberry. Some of the affected leaves may be dried between drying-papers. Other specimens should be preserved in 2% formalin or in 70$ alcohol. If the cluster cup cannot be found on the barberry, other species may be preserved for study. The uredospore and teleutospore stages can usually be found abundantly on wheat and oats, especially on late-sown oats 343 344 APPENDIX. minute black specks on the surface of the leaf. The leaves should be preserved dry after drying under pressure. Liverworts. Marchantia. — The green thallus (gametophyte) of marchan- tia may be found at almost any season of the year along shady banks washed by streams, or on the wet low shaded soil. Plants with the cups of gemmae are found throughout a large part of the year. They are sometimes found in greenhouses, especially where peat soil from marshy places is used in potting. In May and June male and female plants bear the gametophores and sexual organs. These can be preserved in 2%% formalin or in 70$ alcohol. If one wishes to preserve the material chiefly for the antheridia and archegonia a small part of the thallus may be preserved with the gametophores, or the gametophores alone. In July the sporogonia mature. When these have pushed out between the curtains underneath the ribs of the gametophore, they can be preserved for future study by placing a portion of the thallus bearing the gametophore in a tall vial with 2% for- malin. Plants with the sporogonia mature, but not yet pushed from between the curtains on the under side, can be collected in a tin box which contains damp paper to keep the plants moist. Here the sporogonia will emerge, and by examining them day by day, when some of the sporogonia have emerged, these plants can be quickly transferred to the vials of formalin before the spo- rogonia have opened and lost their spores. In this condition the plant can be preserved for several years for study of the gross character of the sporogonia and the attachment to the gameto- phyte. From some of the other plants permanent mounts in glycerine jelly may be made of the spores and elaters. Eiccia. — Riccia occurs on muddy, usually shaded ground. Some species float on the surface of the water. It may be pre- served in 2$ formalin or 70$ alcohol. Cephalozia, ptilidium, bazzania, jungermannia, frullania, and other foliose liverworts may be found on decaying logs, on the COLLECTION AND PRESERVATION OF MATERIAL. 345 trunks of trees, in damp situations. They may be preserved in formalin or alcohol. Some of the material may also be dried under pressure. Mosses are easily found and preserved. Male and female plants for the study of the sexual organs should be preserved in formalin or alcohol. In all these studies whenever possible living material freshly collected should be used. Ferns. For the study of the general aspect of the fern plant, polypo- dium, aspidium, onoclea, or other ferns may be preserved dry after pressure in drying sheets. A portion of the stem with the leaves attached should be collected. These may be mounted on stiff cardboard for use. The sporangia and spores can also be studied from dried material, but for this purpose the ferns should be collected before the spores have been scattered, but soon after the sporangia are mature. But when greenhouses are near it is usually easy to obtain a few leaves of some fern when the sporangia are just mature but not yet open. To prevent them from opening and scattering the spores in the room before the class is ready to use them, immerse the leaves in water until ready to make the mounts ; or preserve them in a damp chamber where the air is saturated with moisture. For study of the prothallia of ferns, spores should be caught in paper bags by placing therein portions of leaves bearing ma- ture sporangia which have not yet opened. They should be kept in a rather dry but cool place for one or two months. Then the spores may be sown on well-drained peat soil in pots, and on bits of crockery strewn over the surface. Keep the pots in a glass-covered case ^here the air is moist and the light is not strong. If possible a gardener in a conservatory should be consulted, and usually they are very obliging in giving sugges- tions or even aid in growing the prothallia. Lycopodium, equisetum, selaginella, isoetes, and other pteri- dophytes desired may be preserved dry and in 70$ alcohol. Pines, — The ripe cones should be collected before the seeds 34^ APPENDIX. scatter, and be preserved dry. Other stages of the development of the female cones should be preserved either in 70$ alcohol or in 2\ I5 2 Sporophyll, equisetum, 176 ; pine, 188; trillium, 197 Spring beauty, 226 Spruce moor, 320-324 Stamens, 201, 203, 206 Starch, 70-80 Stem, 219 Stomates, 58, 59 Strawberry, 265, 268 Sundew, 90, 91 Sweet flag, 243 Sympetalse (sym-pet'a-lse), 274 Syncarpous (syn-car'pous), 229, 230 Taraxacum (tar-ax' a-cum), 281 Taxodium (tax-o'di-um), 327 Taxonomy (tax on'o-my), 231-235 Taxus, 209 Tendrils, 219 Testa, 208, 210 Thallophytes, 217 Thallus, 217 Thorns, 219 Tissues (syopsis of), 68 Tissue tension, 46-48 Toad flax, 277 Touch-me-not, 294 Transpiration, 5 T -54> 5^-59 Trillium, 194 Trillium erectum, 231, 232 Tropophytes (trop'o-phytes), 288, 289 Tubers, 219 Tubiflorae (tu-bi-flo'rse), 275 Turgescence, 28-30, 45-49 Turgidity, 45-49 Turgor, 28-30, 45-49 Ulmacea? (ul-ma'ce-se), 255 Ulmus, 255 Ulva, 217 Umbel, 227 Uncinula (un-cin'u-la), 134-138 Unifolium (u-ni-fo'Ii-um),- 237 Uromyces (u-ro-my'ces), 87, 88 Urticiflors (ur-ti-ci-flo'rse), 255 Vacciniacese (vac-cin-i-a'ce-se), 274 Vaucheria (vau cher'i-a), 120-124 Venus fly-trap, 89, 91 Viola, 260 Violacese (vi-o-la'ce-se), 260 Violet family, 260 Virgin's bower, 298 Wake robin, 232 Walking fern, 331 Wheat rust, 129-133 White pine, 184-193 Whortleberry, 274 Wild lettuce, 296 Willow family, 250 Witch hazel, 332 Xerophytes (xer'o-phytes), 288, 289 Yew, 209 Zonal distribution, 306 Zygospore, zygote, 117, 118 AMERICAN NATURE SERIES In the hope of doing something toward furnishing a series where the seeker will surely find a readable book of high authority, the publishers of the American Science Series have begun the publi- cation of the American Nature Series. It is the intention that in its own way, the new series shall stand on a par with its famous prede- cessor. 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