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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #62998 (https://www.gutenberg.org/ebooks/62998)
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-Project Gutenberg's USDA Bulletin No. 844, by H. S. Coe and J. N. Martin
-
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world at no cost and with almost no restrictions
-whatsoever. You may copy it, give it away or re-use it under the terms
-of the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org. If you are not located in the United States, you'll
-have to check the laws of the country where you are located before using
-this ebook.
-
-
-
-Title: USDA Bulletin No. 844
- Sweet-Clover Seed
-
-Author: H. S. Coe
- J. N. Martin
-
-Release Date: August 21, 2020 [EBook #62998]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK USDA BULLETIN NO. 844 ***
-
-
-
-
-Produced by Tom Cosmas from files generously provided by
-the USDA through The Internet Archive and placed in the
-Public Domain.
-
-
-
-
-
-
-
-
-
-
-Transcriber Note
-
-Text emphasis is denoted as _Italics_.
-
-
-
-
- UNITED STATES DEPARTMENT OF AGRICULTURE
-
- BULLETIN No. 844
-
- Contribution from the Bureau of Plant Industry
-
- WM. A. TAYLOR, Chief
-
-
- Washington, D. C. PROFESSIONAL PAPER August 11, 1920
-
-
- SWEET-CLOVER SEED
-
-Part I.--Pollination Studies of Seed Production
-
-Part II.--Structure and Chemical Nature of the Seed Coat and its
-Relation to Impermeable Seeds of Sweet Clover
-
-By
-
-H. S. COE, formerly Assistant Agronomist, Office of Forage-Crop
-Investigations, and J. N. MARTIN, Professor of Morphology and Cytology,
-Iowa State College
-
-CONTENTS
-
- Page
- Part I.--Pollination Studies of Seed Production.
- Unsatisfactory yields of sweet-clover seed 1
- Previous investigations of the pollination of sweet clover 2
- Outline of pollinating experiments 3
- Structure of the flowers of Melilotus alba 4
- Development of the floral organs of sweet clover 5
- Fertilization in Melilotus alba 8
- Development of the seed 8
- Mature pollen of sweet clover 9
- Germination of the pollen 9
- Cross-pollination and self-pollination of sweet clover 10
- Artificial manipulation of sweet-clover flowers 10
- Seed production of Melilotus alba under ordinary field
- conditions 13
- Efficiency of certain kinds of insects as pollinators of
- sweet clover 14
- Relation of the position of the flowers on Melilotus alba
- plants to seed production 19
- Influence of the weather at blossoming time upon seed
- production 20
- Insect pollinators of sweet clover 21
- Effect of moisture upon the production of Melilotus alba seed 22
-
- Part II.--Structure and Chemical Nature of the Seed Coat
- and its Relation to Impermeable Seeds of Sweet Clover.
- Historical summary 26
- Material and methods 30
- Structure of the seed coat 31
- Microchemistry of the seed coat 33
- The seed coat in relation to the absorption of water 34
- A comparison of permeable and impermeable seed coats 34
- The action of sulphuric acid on the coats of impermeable seeds 35
-
- Literature Cited 36
-
-[Illustration]
-
-
-WASHINGTON GOVERNMENT PRINTING OFFICE
-
-1920
-
- UNITED STATES DEPARTMENT OF AGRICULTURE
-
- BULLETIN No. 844
-
- Contribution from the Bureau of Plant Industry
-
- WM. A. TAYLOR, Chief
-
-
- Washington, D. C. PROFESSIONAL PAPER August 11, 1920
-
-
-
-
- SWEET-CLOVER SEED
-
-Part I.--Pollination Studies of Seed Production
-
-Part II.--Structure and Chemical Nature of the Seed Coat and its
-Relation to Impermeable Seeds of Sweet Clover
-
-
-By H. S. Coe, _formerly Assistant Agronomist, Office of
-Forage-Crop Investigations_, and J. N. Martin, _Professor of
-Morphology and Cytology, Iowa State College_.
-
-
-
-
-CONTENTS
-
-
- Page
- Part I.--Pollination Studies of Seed Production.
- Unsatisfactory yields of sweet-clover seed 1
- Previous investigations of the pollination of sweet clover 2
- Outline of pollinating experiments 3
- Structure of the flowers of Melilotus alba 4
- Development of the floral organs of sweet clover 5
- Fertilization in Melilotus alba 8
- Development of the seed 8
- Mature pollen of sweet clover 9
- Germination of the pollen 9
- Cross-pollination and self-pollination of sweet clover 10
- Artificial manipulation of sweet-clover flowers 10
- Seed production of Melilotus alba under ordinary field
- conditions 13
- Efficiency of certain kinds of insects as pollinators of
- sweet clover 14
- Relation of the position of the flowers on Melilotus alba
- plants to seed production 19
- Influence of the weather at blossoming time upon seed
- production 20
- Insect pollinators of sweet clover 21
- Effect of moisture upon the production of Melilotus alba seed 22
-
- Part II.--Structure and Chemical Nature of the Seed Coat
- and its Relation to Impermeable Seeds of Sweet Clover.
- Historical summary 26
- Material and methods 30
- Structure of the seed coat 31
- Microchemistry of the seed coat 33
- The seed coat in relation to the absorption of water 34
- A comparison of permeable and impermeable seed coats 34
- The action of sulphuric acid on the coats of impermeable seeds 35
-
- Literature Cited 36
-
-
-
-
-Part I.--POLLINATION STUDIES OF SEED PRODUCTION.
-
-
-UNSATISFACTORY YIELDS OF SWEET-CLOVER SEED.
-
-In some sections of the country much trouble has been experienced for
-a few years past in obtaining satisfactory yields of sweet-clover
-seed. This difficulty has been due for the most part to the following
-causes: (1) To cutting the plants at an improper stage of development,
-(2) to the use of machinery not adapted to the handling of the crop,
-(3) to the shedding of immature pods, and (4) possibly to the lack of
-pollination. As the first two have been overcome, mainly because of a
-better understanding of the requirements for handling this crop, the
-subject matter of this bulletin is concerned primarily with the factors
-which produce the third and fourth causes.
-
-Where the production of seed was disappointing although the plants
-produced an abundance of flowers, it has been observed that many
-apparently were not fertilized, or if fertilized the pods aborted. In
-order to obtain data in regard to the causes of the failure of sweet
-clover to produce a normal seed yield, a study was made of the insects
-which were most active in pollinating the flowers, the source of the
-pollen necessary to effect fertilization, and the conditions under
-which the flowers must be pollinated in order to become fertilized.
-The relation of environmental conditions to the shedding of immature
-pods was also investigated. In order to overcome local environmental
-factors as much as possible, the experiments were conducted on the
-Government Experiment Farm at Arlington, Va., and in cooperation with
-the botanical department of the Iowa State College at Ames, Iowa.
-
-
-PREVIOUS INVESTIGATIONS OF THE POLLINATION OF SWEET CLOVER.
-
-Since Darwin (4, p. 360)[1] published the statement that a plant of
-_Melilotus officinalis_ protected from insect visitation produced but
-a very few seeds, while an unprotected plant produced many, other
-scientists have investigated this subject. Knuth (19, v. 1, p. 37),
-in giving a list of the best known cases of self-sterility in plants,
-mentions _Melilotus officinalis_. The same author (19, v. 2, p. 282)
-states that since the stigma projects beyond the anthers, automatic
-self-pollination is difficult, and for the same reasons Müller (29, p.
-180) believes that self-fertilization is not apt to occur.
-
-[1] The serial numbers in parentheses refer to "Literature cited,"
-pages 36-38.
-
-In 1901 Kirchner (18, p. 7) covered a number of _Melilotus alba_
-racemes with nets. On one of the plants 12 protected racemes produced
-187 seeds and on another plant only one seed was obtained from
-10 covered racemes. This experiment was duplicated in 1904, with
-the result that 40 netted racemes produced an average of 38 seeds
-each. Kirchner concluded from this experiment that spontaneous
-self-pollination occurs regularly even though the stigma projects above
-the anthers. He (18, p. 8) also performed an experiment with _Melilotus
-officinalis_ in 1901. At this time 16 isolated racemes produced a total
-of 11 seeds. This experiment was repeated in 1904, with the result
-that 16 protected racemes produced an average of 14 seeds each. As
-the racemes on one of the plants that was protected in 1904 died,
-Kirchner concluded that the flowers of _M. officinalis_ were especially
-sensitive to inclosure in nets and that the failures to obtain more
-than a very few seeds on protected racemes in Darwin's experiment and
-in his first experiment were due to this cause.
-
-According to Kerner (17, v. 2, p. 399) the peas and lentils (Pisum and
-Ervum) and the different species of horned clover and stone clover
-(Lotus and Melilotus) as well as the numerous species of the genus
-Trifolium and also many others produce seeds when insects are excluded
-from the plants, and only isolated species of these genera gave poor
-yields without insect visitation.
-
-
-OUTLINE OF POLLINATING EXPERIMENTS.
-
-The yield of sweet-clover seed varies greatly from year to year in many
-parts of the United States. It has been assumed that this variation
-was due to climatic conditions, as excellent seed crops were seldom
-harvested in seasons of excessive rainfall or of prolonged drought just
-preceding or during the flowering period. The lack of a sufficient
-number of suitable pollinating insects also was thought to be an
-important factor in reducing seed production. This was especially true
-where the acreage of sweet clover was large and where few, if any,
-honeybees were kept.
-
-In order to obtain data upon the factors influencing the yield of
-seed, a series of experiments was outlined to determine (1) whether
-the flowers are able to set seed without the assistance of outside
-agencies, (2) whether cross-pollination is necessary, (3) the different
-kinds of insects which are active agents in pollinating sweet clover,
-and (4) whether a relation exists between the quantity of moisture in
-the soil and the production of seed.
-
-The racemes containing the flowers which were to be pollinated by hand
-were covered with tarlatan before any of the flowers opened and were
-kept covered except while being pollinated until the seeds were nearly
-mature. This cloth has about twice as many meshes to the linear inch as
-ordinary mosquito netting and served to exclude all insects that are
-able to pollinate the flowers. When entire plants were to be protected
-from all outside agencies, cages covered with cheesecloth, glass
-frames, or wire netting were used.
-
-A preliminary study of the pollination of _Melilotus alba_ and _M.
-officinalis_ showed that both were visited by the same kinds of insects
-and that both required the same methods of pollination in order to set
-seed. On this account _M. alba_ was used in most of the experiments
-reported in this bulletin. Where _M. officinalis_ was employed it is so
-stated.
-
-
-STRUCTURE OF THE FLOWERS OF MELILOTUS ALBA.
-
-[Illustration: Fig. 1.--Different parts of the flower of
-_Melilotus alba_: 1, Side view of the flower; 2, side view of the
-flower with the carina and alæ slightly depressed; 3, side view of the
-flower, showing the carina and alæ depressed sufficiently to expose
-the staminal tube and the tenth free stamen; 4, ala; 5, ate and carina
-spread apart to show their relative position and shape; 6, flower after
-the petals have been removed, showing in detail the calyx and staminal
-tube; 7, the staminal tube split open to show the relative size and
-position of the pistil, _a_, Alæ; _b_, vexillum; _c_, carina; _d_,
-calyx; _c_, stigma; _b_, anthers: _g_, tenth free stamen; _h_, digitate
-process of the superior basal angle of an ala; _i_, depressions in the
-ala; _j_, staminal tube; _k_, pistil.]
-
-The racemes of _Melilotus alba_ contain from 10 to 120 flowers with
-an average of approximately 50 per raceme for all of the racemes of a
-plant growing under cultivation in a field containing a good stand.
-
-The flower consists of a green, smooth, or slightly pubescent calyx
-with 5-pointed lobes and with an irregular white corolla of five
-petals. (Fig. 1.) The claws of the petals are not united nor are they
-attached to the staminal tube which is formed by the union of the
-filaments of the nine inferior stamens. As the claws of the alæ and
-carina are not attacked to the staminal tube; the petals may be bent
-downward sufficiently far so that many different kinds of insects may
-secure without difficulty the nectar secreted around the base of the
-ovary.
-
-The fingerlike processes of the alæ are appressed closely to the
-carina, therefore the alæ are bent downward with the carina by insects.
-These processes grasp the staminal tube superiorly and tightly when
-the carina and alæ are in their natural positions, but when the carina
-is pressed downward by insects the fingerlike processes open slightly
-but not so far that they do not spring back to their original position
-when the pressure is removed. The staminal tube splits superiorly to
-admit the tenth free stamen. The filament of this superior stamen lies
-along the side of this staminal tube. The filaments of the nine stamens
-which compose the staminal tube separate in the hollow of the carina.
-All stamens bear fertile anthers. The pistil is in the staminal tube,
-the upper part of the style and stigma of which is inclosed with the
-anthers in the carina. The stigma is slightly above the stamens.
-
-An insect inserts its head into a sweet-clover flower between the
-vexillum and carina, the stigma, therefore, comes into direct contact
-with the head of the insect and cross-pollination is effected. At the
-same time the anthers brush against the insect, so that its head is
-dusted with pollen, to be carried to other flowers.
-
-
-DEVELOPMENT OF THE FLORAL ORGANS OF SWEET CLOVER.
-
-[Illustration: Fig. 2.--Lengthwise sectional view of a very
-young flower of _Melilotus alba_, showing the relative development of
-the stamens and pistil. In the upper set of stamens the divisions of
-the mother cells are completed, while division is just beginning in
-the lower set of stamens. In the ovules the outer integuments are well
-started on their development, _a_, Anther; _o_, ovule; _p_, pistil. ×
-38.]
-
-The stamens of _Melilotus alba_ and _M. officinalis_ may be divided
-into two sets, according to their length and time of development.
-(Fig. 2.) The longer set extends about the length of the anthers
-above the shorter set, and the pollen mother cells in the longer set
-divide to form pollen grains at least two days earlier than those
-in the shorter set. At the time the pollen mother cells divide, the
-longer set of stamens is approximately three-eighths of a millimeter
-in length and the pistil about half a millimeter long. The stigma and
-a portion of the style project beyond the stamens, and this relative
-position is maintained to maturity. The pollen mother cells undergo the
-reduction division while the megaspore mother cells are just being
-differentiated and while the outer integuments are barely prominent at
-the base of the nucellus. The pollen grains are formed while the embryo
-sac is beginning to develop. The division of the megaspore mother cell
-does not occur until a number of days later, and the embryo sac is
-not mature until the flower is nearly ready to open. Thus, the pollen
-grains are formed a week to 10 days before the embryo sac is ready for
-fertilization. The pollen grains increase in size and undergo internal
-changes after their formation. These changes, which are not completed
-until the flower is one-half or more of its mature length, may be
-regarded as the ripening processes, and they are undoubtedly necessary
-before the pollen is capable of functioning. For this reason it is
-probable that the pollen grains are not able to function much before
-the embryo sac is mature.
-
-[Illustration: Fig. 3.--Stigma at the time of pollination,
-showing its papillate character and the position of the pollen in
-reference to the papillæ in pollination. × 175.]
-
-The pistils of _Melilotus alba_ and _M. officinalis_ are straight for
-the greater part of their length, but curve rather abruptly toward
-the keel just below the capitate stigma. The surface of the stigma is
-papillate. (Fig. 3.) In their reaction with Sudan III, alkanin, and
-safranin the Walls of the papillæ of the stigma show that some fatlike
-substances are present. Aside from water, the contents of the papillæ
-consist chiefly of a fine emulsion of oil.
-
-
-DEVELOPMENT OF THE OVULES.
-
-The number of ovules in the ovary of _Melilotus alba_ varies from
-two to five; however, most commonly, three or four ovules occur. In
-_Melilotus officinalis_ the number in each ovary ranges from three to
-six. In both species the ovules are campylotropous at maturity with the
-micropylar end turned toward the base of the ovary.
-
-Mature ovules contain two integuments, but the inner one does not close
-entirely around the end of the nucellus. The outer integument develops
-considerably ahead of the inner one. The outer integument is much
-thickened at the micropylar end, the seed coat is formed from it, and
-the inner integument is used as nourishment by the endosperm and embryo.
-
-The number of megaspore mother cells in an ovule varies from one to
-many. Two or more embryo sacs often start to develop in the same ovule,
-but seldom more than one matures. (Pl. I, figs. 1, 2, and 3.) In
-general, the development of the embryo sac proceeds in the ordinary
-way, as described by Young (44, p. 133), with the inner megaspore
-functioning. (Text fig. 4 and Pl. II, fig. 1.) In its development
-the nucellus is destroyed rapidly, the destruction being most rapid
-first at the micropylar end proceeding backward. The nucellus is
-completely destroyed at the micropylar end by the time the embryo sac
-is mature, and consequently the embryo sac comes in contact with the
-outer integument in this region. (Pl. II, fig. 1.) As the destruction
-of the nucellus extends toward the chalazal end the embryo sac becomes
-much elongated and tubelike. The antipodals disappear early, so that
-a mature embryo sac consists of the egg, the synergids, and the two
-polars. The two polars lie in contact in the micropylar end of the sac
-near the egg until fertilization.
-
-
-STERILITY OF THE OVULES.
-
-In _Melilotus alba_ and _M. officinalis_ there is very little tendency
-toward sterility of ovules. In an extended study of ovules developing
-under normal and under excessive moisture conditions only an occasional
-one was found in which no reproductive cells were differentiated, and
-no ovaries were found in which all of the ovules were sterile.
-
-[Illustration: Fig. 4.--Median section through an ovule,
-showing the embryo sac with four nuclei and the position of the
-integuments. × 150.]
-
-
-DEVELOPMENT OF THE POLLEN.
-
-The pollen mother cells do not separate, but previous to the reduction
-division the protoplasm shrinks from the walls, thus forming a dense
-globular mass which often occupies less than half the lumen of the
-mother cell. (Pl. I, fig. 4.) Nuclear division occurs while they are
-in this contracted condition, and four nuclei are formed from two
-successive divisions. The cytoplasm is equally distributed around each
-nucleus. The four masses of protoplasm separate, and as they enlarge
-a number of times and develop into mature pollen grains they become
-binucleate, and a wall is gradually formed around each. (Pl. I, figs. 5
-and 6.) At first the cytoplasm is quite dense and contains some starch
-but no fatty oils. However, the cytoplasm of mature pollen grains is
-vacuolate, and it contains a fatty oil in the form of an emulsion.
-Soon after the pollen grains are formed, the walls of the mother cells
-disappear, thus permitting the pollen grains to lie loose in the anther.
-
-
-FERTILIZATION IN MELILOTUS ALBA.
-
-The time intervening between pollination and fertilization was
-investigated with both self-pollinated and cross-pollinated flowers.
-In cross-pollination the parents were separate plants. This point was
-investigated with plants out of doors during the summer of 1916 and
-with plants in the greenhouse during the following winter. The time
-elapsing between pollination and fertilization ranged from 50 to 55
-hours and was not longer in the case of self-pollinated than with
-cross-pollinated flowers. Furthermore, the rate of the development of
-the embryo in each kind of pollination was studied and was found to
-be as rapid in self-pollination as in cross-pollination. Therefore,
-self-pollination is apparently as effective as cross-pollination in
-_Melilotus alba_ so far as the vigor of pollen tubes and the rate at
-which embryos develop are concerned. _Melilotus officinalis_ was not
-studied in reference to this point.
-
-Considerable difference often exists in the size of the young embryos
-in the ovules of the same pod. This is due in part to a difference in
-the time of fertilization, although some of it is due to a difference
-in nourishment. It was observed that the ovule first fertilized might
-be an upper one, lower one, or any one between these. Occasionally one
-or more ovules are not fertilized.
-
-
-DEVELOPMENT OF THE SEED.
-
-A proembryo with a rather long suspensor is developed from the
-fertilized egg. (Pl. II, fig. 2). The endosperm, which quite early
-forms a peripheral layer around the entire embryo sac, develops most
-rapidly about the embryo, which soon becomes thoroughly embedded in it.
-(Pl. III, figs. 1 and 2.) After the embryo has used up the endosperm in
-the micropylar end and has enlarged so much as to occupy nearly all of
-the space in this region, the development of the endosperm becomes more
-active in the chalazal end, and when the embryo is mature there is very
-little endosperm left.
-
-The seed coat begins to form about the time of fertilization,
-although it apparently does not depend upon it, for in ovules where
-fertilization is prevented the outer integument undergoes the early
-modifications in the development of the seed coat before the ovule
-breaks down. The development of the seed coat is apparent first at
-the micropylar and chalazal ends, where the outer cells of the outer
-integument become much elongated and their outer walls thicken very
-soon after fertilization. The modifications in the development of
-the seed coat extend around the ovule from these points, involving
-at first only the outer or epidermal layer of cells which form the
-malpighian layer. Later, the cells just beneath the malpighian layer
-form the osteosclerid layer. Accompanying or closely following the
-formation of the osteosclerid cells, the remaining cell layers of the
-outer integument become modified into the nutritive and aleurone layer,
-and the seed coat is fully formed. Meantime the inner integument is
-practically all used as food.
-
-Plate I.
-
-[Illustration]
-
-Development of the Ovules and Pollen in Sweet Clover.
-
-Fig. 1.--Section through the nucellus of an ovule of
-_Melilotus alba_, showing two megaspore mother cells. × 360. Fig.
-2.--Median section through an ovule of _Melilotus alba_, showing the
-two cells resulting from the first division of the megaspore mother
-cell, and the relative development of the different parts of the ovule.
-× 300. Fig. 3.--Section through the nucellus of an ovule of _Melilotus
-alba_, showing two embryo sacs, one being more advanced than the other.
-× 360. Fig. 4.--Protoplasm of the pollen mother cell of _Melilotus
-alba_ contracted and ready to undergo division. × 560. Fig. 5.--Pollen
-grains of _Melilotus alba_ just formed, showing their dense cytoplasm
-and the presence of the mother-cell wall. × 560. Fig. 6.--_a_, Mature
-pollen grain of _Melilotus alba_, showing the binucleate condition at
-the time of shedding; _b_, surface view. × 560.
-
-
-Plate II.
-
-[Illustration]
-
-Fig. 1.--Median Section through an Ovule of Melilotus alba.
-
-The embryo sac is shown ready for fertilization. The egg and synergids
-are in contact with the outer integument at the micropylar end. The
-remains of the antipodals may be seen at the chalazal end. × 180.
-
-[Illustration]
-
-Fig. 2.--Section through an Ovule of Melilotus alba, about Three
-Days After Fertilization.
-
-The proembryo, the endosperm, and modifications of the integuments are
-shown. At this stage the suspensor prominent part of the proembryo, and
-the endosperm is most abundant around the embryo. The inner integument
-is being rapidly destroyed, and the outer integument is beginning to
-form the seed coat, as is indicated by the modifications in the outer
-layer of its cells, which are elongating and thickening their outer
-walls. × 33.
-
-
-Plate III.
-
-[Illustration]
-
-Fig. 1.--Section of an Ovule of Melilotus alba after
-Fertilization.
-
-The stage of development is a little later than that shown in Plate II,
-figure 2. The embryo is embedded deeply in endosperm tissue. × 45.
-
-[Illustration]
-
-Fig. 2.--Section through an Ovule of Melilotus alba after the
-Embryo is Nearly Half Mature.
-
-But little endosperm remains except in the chalazal end, and very
-little remains of either the nucellus or inner integument. The
-modifications which transform the outer integument into a seed coat are
-well under way. Not only the outer layer of cells which becomes the
-Malpighian layer is quite well modified, but also the layer beneath is
-being transformed into the osteosclerid layer. × 30.
-
-
-Plate IV.
-
-[Illustration]
-
-Stubble of Melilotus alba.
-
-These plants, which were cut 12 inches above the ground during rainy
-weather, had made a 40 to 42 inch growth. The stubble became infected
-at the top and the light-colored portions of them were killed by
-disease, thus checking the water supply to the growing branches above
-the infection.
-
-
-MATURE POLLEN OF SWEET CLOVER.
-
-The pollen grains of _Melilotus alba_ and of _M. officinalis_ are quite
-similar. Each grain contains three germ pores, and when viewed so
-that the pores are visible they present a slightly angled appearance.
-The average dimensions of the pollen of _Melilotus alba_ and of _M.
-officinalis_ are 26 by 32 microns and 24 by 30 microns, respectively,
-when measured in the positions shown in _b_ in Plate I, figure 6.
-
-The walls of the pollen grains have cutin deposited in them, as shown
-by their reactions with Sudan III, alkanin, safranin, and chloriodid of
-zinc. The contents of the pollen grains give a distinct reaction when
-tested for fat, and Millon's reagent shows that also some protein is
-present. Tests for sugars and starch showed that these substances are
-not present in perceptible quantities in mature pollen grains, although
-some starch is present in immature pollen.
-
-
-GERMINATION OF THE POLLEN.
-
-The germination of the pollen of _Melilotus alba_ permits considerable
-variation in moisture, as is illustrated in Table I.
-
-Table I.--_Germination of the pollen of Melilotus alba in water and in
-solutions of cane sugar of different strengths._
-
- ---------------+--------+---------------------------------------
- | | Cane sugar in solution (per cent).
- | Pure +----+----+----+----+----+----+----+----
- Melilotus alba.| water. | 8 | 12 | 18 | 24 | 30 | 35 | 45 | 55
- ---------------+--------+----+----+----+----+----+----+----+----
- Germination | | | | | | | | |
- of pollen | 33 | 23 | 64 | 46 | 60 | 46 | 31 | 22 | 0
- per cent | | | | | | | | |
- ---------------+--------+----+----+----+----+----+----+----+----
-
-The results given in Table I represent the average of 12 tests. Some
-of the pollen grains burst in pure water and in the weak cane sugar
-solutions, the percentage of bursting being greatest in pure water and
-decreasing as the percentage of sugar in the solution was increased.
-There was considerable variation in the percentages of germination in
-both water and in the solutions of different strengths, and at times
-there was very little bursting which was not accompanied by a high
-percentage of germination. The pollen tubes grew as rapidly in water as
-in any of the sugar solutions, some reaching a length of 100 microns
-in six hours. As the pollen tubes made no more growth in the solutions
-of sugar than in water, it is evident that the sugar is not used as
-food, but helps in germination by reducing the rate at which water is
-absorbed.
-
-To judge from Table I, the pollen of sweet clover can be effective not
-only under ordinary conditions but also when the flowers are wet with
-rain or dew or when the stigma is so dry that in order to obtain water
-from the papillæ the pollen must overcome a high resistance offered by
-the sap of the papillæ, a resistance that may be equal to the osmotic
-pressure of a 45 per cent solution of cane sugar. This is in accord
-with results obtained under field conditions; as flowers that were
-pollinated while rain was falling set seed satisfactorily, indicating
-that a high percentage of humidity in the atmosphere does not check the
-germination of the pollen sufficiently to interfere with fertilization.
-Neither was the setting of seed affected when the soil about the roots
-of plants was kept saturated with water, showing that the excessive
-quantity of water in the stigmas resulting from an abundance of water
-in the soil did not interfere with the fertilization of the flowers.
-
-No definite counts were made of the germination of the pollen of
-_Melilotus officinalis_ in the solutions of cane sugar of different
-strengths, but observations show that the moisture requirement of the
-pollen of this species is approximately the same as that of _Melilotus
-alba_.
-
-
-CROSS-POLLINATION AND SELF-POLLINATION OF SWEET CLOVER.
-
-Results published by previous investigators on the cross-pollination
-and self-pollination of sweet clover do not agree. The experiments of
-Darwin (4) show that the flowers are self-pollinated to only a small
-extent. On the other hand, Kirchner (18) and Kerner (17) find that
-self-pollination occurs generally and that cross-pollination is not
-necessary for the production of seed. However, all investigators agree
-that many different kinds of insects are able to pollinate sweet clover.
-
-Because of the diverse opinions as to the pollination of sweet clover,
-a number of experiments were conducted to determine (1) whether insect
-visitation was necessary to pollinate the flowers, (2) if necessary,
-whether the flowers must be cross-pollinated, and (3) what insects are
-active agents as pollinators of sweet clover.
-
-ARTIFICIAL MANIPULATION OF SWEET-CLOVER FLOWERS.[2]
-
-[2] The writers wish to acknowledge their indebtedness to Mr. Carl
-Kurtzweil for assistance in conducting part of the field experiments at
-Ames.
-
-Experiments were conducted to determine, if possible, the effect of
-various types of artificial manipulation of sweet-clover flowers when
-in full bloom on the production of seed. Only healthy, vigorous plants
-growing on well-drained soil were selected for these experiments.
-Before any of the flowers were open, the individual racemes were
-covered with tarlatan and labeled. (Fig. 5.) As soon as part of the
-flowers opened, the racemes were uncovered and after removing all
-flowers that were not open the open flowers were pollinated and the
-racemes re-covered. If the flowers of sweet clover are not fertilized
-they will remain open for two to three days, then wither, and in a
-short time drop. But after being fertilized the ovules enlarge very
-rapidly, and the corollas usually drop in about seven or eight days.
-Therefore, all fertilized flowers can be distinguished a few days after
-fertilization has taken place. Counts were made of the number of pods
-which formed in 10 to 12 days after pollination. An outline of the
-experiments is given in Table II.
-
-[Illustration: Fig. 5.--Individual racemes of white sweet
-clover covered with cheesecloth to protect them from insect visitation.]
-
-Table II.--_Treatment of sweet-clover flowers in the
-artificial-manipulation experiments._
-
- ------------+---------------------------------------------------------
- Experiment. | Method of pollinating the flowers.
- ------------+---------------------------------------------------------
- A | Check--covered.
- |
- B | Check--open to insect visitation at all times.
- |
- C | A separate toothpick was used to spring the keel of each
- | flower on the raceme.
- |
- D | One toothpick was used to spring the keels of all the
- | flowers on a raceme.
- |
- E | Cross-pollinated.
- |
- F | Raceme rolled several times between thumb and finger.
- ------------+---------------------------------------------------------
-
-As insects, and especially honeybees, usually visit all recently
-opened flowers on a raceme, experiments C and D were conducted to
-determine whether more seed would be produced when pollen from other
-flowers on the same raceme was placed on the stigmas of the flowers
-than when only the pollen produced by each flower was placed on its
-own stigma. The effect of pollination when only the pollen produced by
-an individual flower was placed on its own stigmas was also obtained
-in experiment F, as by this method of pollination no pollen was
-transferred from one flower to another. It can not be stated definitely
-that the seed produced by the cross-pollinated flowers was the result
-of fertilization with foreign pollen, as the anthers were not removed
-from the flowers pollinated because it would be necessary to remove
-the anthers when the flowers were not more than two-thirds mature, and
-in doing this the flowers would be so mutilated that only occasionally
-would pollination at this time or at a later date be effective. The
-flowers listed in experiment E were pollinated a short time before they
-opened, and in each case pollen taken from flowers of other plants
-was placed on the stigmas. The petals of the cross-pollinated flowers
-were not mutilated, and in each case they returned to their original
-positions soon after pollination. The results obtained in experiment B,
-where the racemes were simply labeled and left open to the action of
-insects at all times, serve for comparison with other experiments where
-the flowers were protected from insect visitation and were artificially
-manipulated.
-
-Martin (25) found the setting of alfalfa seed and Westgate (40)
-found the setting of red-clover seed to be affected by an excessive
-quantity of moisture in the soil or atmosphere. In order to overcome
-the possible effect of this or of other detrimental factors, in each
-experiment only the flowers on a certain number of racemes were
-pollinated at one time. All of the experiments were repeated a number
-of times during the months of July and August, 1916, and the results
-given in Table III show the total number of flowers pollinated and the
-number of pods that formed during the two months.
-
-The results presented in Table III show that flowers fertilized with
-pollen transferred from another plant produced a higher percentage
-of pods than any of the other treatments. The results obtained in
-experiment D, where the same toothpick was used to spring the keels
-of all the flowers on a raceme, show that this method of pollination
-produced an average of 7.24 pods per raceme more than the racemes in
-experiment C. where a separate toothpick was used for each flower.
-These results indicate that pollen transferred from one flower to
-another on the same raceme is more effective than when the pollen
-produced by an individual flower is used to fertilize its own stigma.
-However, the results of experiment C prove that self-pollination
-is effective in _Melilotus alba_. In experiment B. which was the
-open check, 4.3 per cent more flowers set seed than on the racemes
-where the same toothpick was used to spring all the keels, but 11.57
-per cent more seed was obtained than in experiment C. Spontaneous
-self-pollination occurs to only a very small extent, as will be seen
-from the results of experiment A, in which an average of only 2.9 per
-cent of the flowers set seed.
-
-Table III.--_Effect of different types of artificial
-manipulation on the seed production of sweet clover at Arlington, Va.,
-and at Ames, Iowa, in 1916._
-
- ----------+--------+---------------------------+-------------------
- | | Total number of-- | Flowers that set
- | | | seed (per cent).
- | Experi-+--------+--------+---------+---------+---------
- Location. | ment. |Racemes.|Flowers.|Pods set.| At each |
- | | | | | station.| Average.
- ----------+--------+--------+--------+---------+---------+---------
- | | | | | |
- Arlington | A | 49 | 3,510 | 144 | 4.1 |} 2.9
- Ames | A | 84 | 4,536 | 92 | 2.0 |}
- | | | | | |
- Arlington | B | 100 | 5,599 | 3,973 | 70.95 |} 66.51
- Ames | B | 196 | 1,276 | 600 | 47.02 |}
- | | | | | |
- Arlington | C | 50 | 1,229 | 701 | 57.03 |} 54.94
- Ames | C | 75 | 289 | 133 | 46.02 |}
- | | | | | |
- Arlington | D | 50 | 1,480 | 936 | 63.24 |} 62.18
- Ames | D | 88 | 575 | 342 | 59.47 |}
- | | | | | |
- Arlington | E | 31 | 377 | 307 | 81.43 |} 70.10
- Ames | E | 48 | 175 | 80 | 45.71 |}
- | | | | | |
- Arlington | F | 30 | 933 | 524 | 56.16 |.........
- ----------+--------+--------+--------+---------+---------+---------
-
-
-SEED PRODUCTION OF MELILOTUS ALBA UNDER ORDINARY FIELD CONDITIONS.
-
-The production of seed of _Melilotus alba_ under ordinary field
-conditions varies considerably, not only in different parts of the
-country but also on different fields in the same region. A number
-of factors contribute to this variation, one of the most important
-of which appears to be the inability of the plant to supply all the
-developing seed with sufficient moisture, causing some of them to
-abort. As pointed out on page 22 this condition was very marked in
-certain parts of the country in 1916. However, poor seed production
-is not always correlated with lack of moisture, for the seed crop
-was a failure in 1915, where cloudy and rainy weather prevailed much
-of the time the plants were in bloom. It is believed that the lack
-of pollination by insects was the principal cause for the failure of
-seed to set, as very few insects visit sweet-clover flowers when such
-conditions prevail. As sweet-clover pollen will germinate in pure
-water and as plants which have their roots submerged in water set seed
-abundantly when pollinated, the failure of the seed crop in 1915 was
-not due to excessive moisture.
-
-As a rule, thin stands of sweet clover produce more seed to the acre
-than thick stands and isolated plants more seed than those growing
-in either a thick or thin stand. The correlation of seed production
-with the thickness of stand is probably due to the shading and partial
-prevention of insect visitation to part of the racemes on the lower
-branches. Most of the flowers upon the lower branches of isolated
-plants are directly exposed to sunlight and to insect visits: therefore
-the racemes on these branches produce as large a percentage of seed as
-the racemes on the upper branches. In a thick stand, little seed is
-produced by racemes on the lower branches.
-
-A plant approximately 3 feet high growing close to the center of
-a field at Arlington. Va., in which was an average stand of four
-sweet-clover plants to the square foot was selected in order to
-determine the number of racemes produced and the average number of
-seeds to the raceme. This plant produced 196 racemes, which contained
-an average of 20.4 pods each. The racemes varied from 2 to 10 cm. in
-length, and the number of pods to the raceme ranged from to 75. The
-racemes on the upper and most exposed portions of the plants were
-larger and the flowers produced a much higher percentage of pods than
-the racemes close to the bases of the larger branches. Many of the
-small racemes on the lower branches produced less than five pods each.
-
-The data obtained from the two plants at Arlington that were protected
-from night-flying insects may also be cited here, as the results of
-that experiment show that night-flying insects are not an important
-factor in the production of sweet-clover seed, and, further. because
-they were growing under the same conditions, in the same plat, and were
-approximately of the same size. These two plants produced a total of
-544 racemes, with an average of 20.9 pods each. The number of pods to
-the raceme varied from to 86.
-
-
-EFFICIENCY OF CERTAIN KINDS OF INSECTS AS POLLINATORS OF SWEET CLOVER.
-
-In order further to test the self-sterility of sweet clover and to
-determine the relative efficiency of night-flying and of different
-kinds of day-flying insects as pollinators of the flowers, a number
-of cages covered with cheesecloth, glass, or wire screen having 14
-meshes to the linear inch were placed over plants at Arlington. Va.,
-and at Ames. Iowa, in July and August. 1916. The bases of the cages
-were buried several inches in the ground, so that insects could not
-pass under them. Cheesecloth was used to cover most of the cages and
-was made into sacks of such a size that they could be put on or removed
-from the frames of the cages without difficulty. It was stretched
-tightly over the frames and fastened to their bases with laths.
-
-A cage having two sides and the top of glass but with ends covered with
-cheesecloth to permit ventilation was used at Ames to protect a number
-of plants from insect visitation at all times. The purpose of this
-cage was to determine whether the partial shading of the plants in the
-cages covered with cheesecloth would have any effect upon the setting
-of seed.
-
-The cage covered with wire netting having 14 meshes to the linear inch
-was used to determine the efficiency as pollinators of sweet clover of
-insects so small that they could pass through openings of this size.
-
-The plants used in the experiments at Arlington were growing close to
-the center of a field of sweet clover. Volunteer plants in a field
-that contained only a scattering stand were used at Ames. The cages
-were placed over the plants in all of these experiments before any of
-the flowers opened, and the work was continued until they were through
-blooming.
-
-PLANTS SUBJECT TO INSECT VISITATION AT ALL TIMES.
-
-A plant subject to insect visits at all times and growing in the same
-plat as those inclosed in the cages at Arlington was selected as a
-check to those inclosed in the cages during their entire flowering
-period or for only a portion of it. This plant, which was in bloom at
-the same time as those inclosed in the cages, produced 196 racemes with
-an average of 20.4 pods each. As all of the racemes were collected and
-as those on the lower portions of the plant were smaller than those
-on the upper branches, the average number of seeds per raceme is much
-lower than it would have been if only the larger racemes had been
-collected.
-
-An isolated plant that was subject to insect visits at all times was
-selected for a check to the cage work conducted at Ames. This was
-necessary in order to get results that would be comparable with those
-obtained from the plants inclosed in the cages, as the cage experiments
-at Ames were conducted with isolated plants. The plant produced 239
-racemes, with an average of 41.6 pods.
-
-PLANTS PROTECTED FROM INSECT VISITATION DURING THEIR ENTIRE FLOWERING
-PERIOD.
-
-On July 3, 1916, a cage 3 feet square and 3½ feet high, covered with
-cheesecloth, was placed over three sweet-clover plants at Arlington.
-(Fig. 6.) This cage was not opened until August 3, when practically
-all of the racemes had passed the flowering stage and the few seeds
-that formed on some of them were practically mature. The three plants
-inclosed in the cage produced 904 racemes, with an average of 0.63 pod
-each. No pods were produced on 594 racemes, while 150 produced but one
-each. None of the racemes produced more than five pods.
-
-This experiment was duplicated at Ames in August, 1916, with the result
-that the three protected plants produced a total of 776 racemes, with
-an average of 0.19 pod each.
-
-[Illustration: Fig. 6.--Cage covered with cheesecloth to
-protect plants from insect visitation.]
-
-The plants inclosed at Arlington produced 0.44 pod to the raceme more
-than the plants inclosed at Ames, and the average for the six plants
-at Arlington and at Ames is only 0.42 pod to the raceme. Results given
-below for nine plants inclosed in the glass-covered cage show that the
-pods produced per raceme by different plants varied from 0.1 to 0.45,
-which is slightly less than the variation in the two cages covered with
-cheese-cloth.
-
-In order to determine whether the shading of the plants in the
-cheesecloth-covered cages had caused the production of seed to be
-reduced, a cage 4 feet wide, 4 feet high, and 10 feet long, having
-glass sides and top, but with ends covered with cheesecloth to permit
-ventilation, was placed over nine plants at Ames in August, 1916. The
-results obtained in this experiment are presented in Table IV.
-
-Table IV.--_Production of sweet-clover seed by plants
-protected from insect visitation during their entire flowering period
-at Ames, Iowa, in 1916._
-
-
-
- | Racemes | Pods produced | Average number of
- Plant. | per plant.| by all racemes. | pods to the raceme.
- ----------+-----------+-----------------+-------------------
- | | |
- No. 1 | 84 | 17 | 0.20
- No. 2 | 130 | 58 | .44
- No. 3 | 166 | 30 | .18
- No. 4 | 199 | 88 | .44
- No. 5 | 243 | 35 | .27
- No. 6 | 131 | 36 | .27
- No. 7 | 119 | 13 | .10
- No. 8 | 182 | 83 | .45
- No. 9 | 340 | 142 | .41
- +-----------+-----------------+-------------------
- Total | 1,594 | 592 | .......
- Average | | | .31
- ----------+-----------+-----------------+-------------------
-
-
-The results given in Table IV show that an average of 0.31 of a pod
-to the raceme was obtained from 1,594 racemes and that the variation
-in seed production of the different plants was from 0.1 to 0.45 to
-the raceme. The average seed production for the nine plants is 0.11
-seed to the raceme less than the average results obtained from the six
-plants that were covered with cheesecloth. As this difference is well
-within the limit of variation for individual plants, it may be stated
-that the shading of the plants in the cheesecloth-covered cages did not
-reduce the production of seed. The results of this experiment show that
-spontaneous self-pollination does not occur regularly, as stated by
-Kirchner.
-
-FLOWERS POLLINATED ONLY BY NIGHT-FLYING INSECTS.
-
-In order to determine the importance of night-flying insects as
-pollinators, two cheesecloth-covered cages 3 feet square and 3½
-feet high were placed over sweet-clover plants at Arlington on July
-10, 1916. The covers of the cages were removed each evening at 7:30
-and replaced each morning at 4:30 o'clock. Practically all the flowers
-on these plants had bloomed by August 2, and the seed produced was
-nearly mature. The few racemes that contained opened flowers or buds
-were discarded. The three plants in one cage produced 723 racemes,
-with an average of 3.76 pods each, while the one plant in the other
-cage produced 227 racemes, with an average of 3.58 pods to the raceme.
-The four plants, therefore, produced a total of 950 racemes, with an
-average of 3.71 pods each. The only night-flying insect found working
-on sweet clover while these plants were in bloom was _Diacrisia
-virginica_ Fabr.
-
-This experiment was duplicated at Ames in August, 1916, with the result
-that one plant subject to visitation only by night-flying insects
-produced 486 racemes, with an average of 16.5 pods each.
-
-The results obtained in these experiments show that night-flying
-insects were much more active in pollinating sweet clover at Ames than
-at Arlington. However, as the results obtained from the plants subject
-to visitation by day-flying insects only were practically the same as
-those obtained from plants which were subject to insect visitation at
-all times, it is concluded that night-flying insects were not a factor
-in the pollination of sweet clover at Arlington or at Ames in 1916.
-
-FLOWERS POLLINATED ONLY BY DAY-FLYING INSECTS.
-
-A cheesecloth-covered cage, 3 feet square and 3½ feet high, was
-placed on July 7, 1916, over two sweet-clover plants at Arlington,
-before any of the flowers opened. As the cover of this cage was
-removed at 7.30 a. m. and replaced at 4.30 p. m. each day during the
-experiment, the plants were subject to visitation by day-flying insects
-only. As soon as all of the flowers on most of the racemes had bloomed,
-and before any mature pods shattered, the racemes were removed from the
-plants and the pods produced by each raceme counted. The two plants
-produced a total of 544 racemes, with an average of 20.9 pods each.
-
-This experiment was also conducted at Ames. One plant was protected
-from insect visitation at night in August, 1916, with the result that
-it produced 418 racemes, with an average of 41.11 pods each.
-
-PLANTS PROTECTED FROM ALL INSECTS THAT COULD NOT PASS THROUGH A WIRE
-SCREEN HAVING 14 MESHES TO THE LINEAR INCH.
-
-It is well known that many small insects, and especially those
-belonging to the family Syrphidæ and to the genus Halictus, frequent
-sweet-clover flowers, but no records have been noted that show how
-important these insects are as pollinators of this plant. In order to
-obtain data on this subject a cage 12 feet square and 6½ feet high,
-made of wire screen having 14 meshes to the linear inch, was placed
-over a few plants at Ames, in July, 1916, before they began to bloom.
-The base of the cage was buried several inches in the soil, so that
-no insects could get into it. As these plants were growing in a field
-where there was a sufficient supply of moisture at all times, they
-made a growth of 5 to 6 feet. For this reason all the racemes were
-collected from only a portion of one of the plants instead of from
-the entire plant, as was done with the smaller ones inclosed in the
-cheesecloth-covered cages. The branches selected contained 224 racemes,
-with an average of 24.53 pods each. Many insects that were able to pass
-through the wire netting were observed working on the flowers of the
-inclosed plants.
-
-A check plant, subject to visitation by all insects and growing within
-a few yards of the cage, contained 264 racemes, with an average of
-28.23 pods each.
-
-This experiment shows that small insects are efficient pollinators
-of sweet clover and that the plant to which all insects had access
-produced an average of only 3.7 pods to the raceme more than the
-one inclosed in the cage. As these plants were growing close to a
-strip of timber and some distance from a field of sweet clover, it
-is probable that more small insects worked on the flowers than would
-have been the case if the cage had been located in the center of a
-field of sweet clover. Though these results show that small insects
-are able to pollinate sweet-clover flowers freely, it is very doubtful
-whether insects of this kind would be numerous enough to pollinate
-sufficient flowers in a large field of sweet clover for profitable
-seed production. The honeybee is the most efficient pollinator of this
-plant, and it is believed that in many sections it is responsible for
-the pollination of more than half of the flowers.
-
-SUMMARY OF INSECT-POLLINATION STUDIES.
-
-The data secured in the different experiments where sweet-clover
-flowers were subject to insect visitation at one time or another are
-presented in detail in Table V.
-
-Table V.--_Summary of the insect pollination studies conducted
-at Arlington, Va., and Ames, Iowa, in 1916._
-
- ----------+-------+-------------------------+----------------------------
- | | | Number of--
- |Number | +--------+---------+---------
- Location. | of | Method of treatment. |Racemes.| Pods |Pods per
- |plants.| | |produced.| raceme,
- | | | | | average.
- ----------+-------+-------------------------+--------+---------+---------
- Arlington.| 1 |Check--subject to insect | 196 | 4,013 | 20.47
- | | visitation at all times.| | |
- Ames. | 1 | do. | 239 | 9,943 | 41.60
- Arlington.| 3 |Protected from all | 904 | 577 | .63
- | | insects. | | |
- Ames. | 12 | do. | 2,370 | 653 | .27
- Arlington.| 3 |Visited by night-flying | 723 | 2,720 | 3.76
- | | insects only (cage 1). | | |
- Do. | 1 |Visited by night-flying | 227 | 152 | .67
- | | insects only (cage 2). | | |
- Ames. | 1 |Visited by night-flying | 486 | 8,024 | 16.51
- | | insects only. | | |
- Arlington.| 2 |Visited by day-flying | 544 | 11,397 | 20.95
- | | insects only. | | |
- Ames. | 1 | do. | 418 | 17,186 | 41.11
- Do. | 9 |Protected from all | 1,594 | 502 | .31
- | | insects. | | |
- ----------+-------+-------------------------+--------+---------+---------
-
-The results in Table V show that an average of 0.37 pod to the raceme
-was obtained from the plants protected from visitation by all insects
-during the flowering period. As the racemes of _Melilotus alba_ will
-average approximately 50 flowers each, less than 1 per cent of them
-set seed without being pollinated by insects. The results obtained in
-the cages in which only night-flying insects had access to the flowers
-show that these insects pollinate sweet clover to a slight extent,
-but that the number of pods produced by them is so few that it may be
-assumed that these flowers would have been pollinated by day-flying
-insects. This assumption is borne out by the results obtained in the
-cages where only day-flying insects had access to the flowers, as the
-results obtained in these cages at Arlington and Ames, respectively,
-are approximately the same as those obtained on the plants subject
-to insect visitation at all times. It will be noted that the yield
-of seed on the plants visited by insects at Ames is much higher than
-that of the plants subjected to insect visits during the same period
-at Arlington. This difference in seed yield may be attributed to the
-fact that isolated plants were used in the experiments at Ames, and
-at Arlington the experiments were conducted with plants growing under
-field conditions.
-
-
-RELATION OF THE POSITION OF THE FLOWERS ON MELILOTUS ALBA PLANTS TO
-SEED PRODUCTION.
-
-Observations of sweet-clover plants grown under cultivation, and
-especially when the stands were thick, showed that the flowers of the
-racemes on the upper and exposed branches produced a larger percentage
-of seed than those on the lower branches which were less exposed. It is
-thought by some that the failure of the flowers on the lower racemes
-to be fertilized is due to shading; but the results obtained in the
-cheesecloth and glass covered cages do not warrant this belief, as it
-is doubtful whether the shading of the flowers on the lower racemes is
-more than that caused by the cheesecloth. It is probably the lack of
-pollination that causes this decrease in seed production on the lower
-branches of plants growing close together, as a vast number of flowers
-open each day on portions of the plants which are exposed directly to
-visitation by insects and are therefore more accessible to them.
-
-In order to obtain information upon the number of flowers that produce
-seed on the upper and lower portions, respectively, of sweet-clover
-plants when grown under field conditions and where the stand contained
-four to five plants to the square foot, a number of racemes were
-labeled on different portions of the plants at Ames in 1915 and 1916.
-When the pods were partly mature, records were made of the number of
-flowers that produced pods. The results obtained are given in Table VI.
-
-Table VI.--_Relation of the position of sweet-clover flowers
-on the plants to seed production, at Ames, Iowa, in 1915 and 1916._
-
- -----+------------------------+---------+------------------------------
- | | | Pods formed.
- | |Number of+--------+------------+--------
- Year.|Position of the flowers.| flowers.| Number.| Percentage.| Average.
- -----+------------------------+---------+--------+------------+--------
- | | | | |
- 1915 | Upper half of plants | 812 | 357 | 43.9 } |
- 1916 | do | 261 | 101 | 38.7 } | 42.6
- | | | | |
- 1915 | Lower half of plants | 344 | 44 | 12.7 } |
- 1916 | do | 216 | 59 | 27.3 } | 18.3
- -----+------------------------+---------+--------+------------+--------
-
-The flowers on the upper racemes of the plants produced 31.2 per cent
-more pods than those on the lower racemes in 1915. and 11.4 per cent
-more in 1916. These results prove that insects more frequently visit
-the flowers that are directly exposed and are therefore more accessible.
-
-INFLUENCE OF THE WEATHER AT BLOSSOMING TIME UPON SEED PRODUCTION.
-
-The seed production of sweet clover is seldom satisfactory when rainy
-or muggy weather prevails during the flowering period. In order to
-obtain data as to the relation existing between the visits of insects
-and the prevailing weather conditions, a record of insect visits and
-of the number of flowers that opened each day was kept for a period of
-nine days at Ames in August, 1915.
-
-In this experiment the racemes were marked early each morning just
-above the last flowers which had opened the previous day, and early
-the following morning the number of flowers which had opened the
-previous day was noted. The number of flowers that were pollinated was
-determined by the number of pods that formed. Table VII gives in detail
-the results obtained.
-
-Table VII.--_Influence of the weather at blossoming time upon
-the yield of sweet -clover seed, at Ames. Iowa, in 1915._
-
- -------+-------------------------+---------+-------+-------+-----------
- | | |Number | |
- | | | of | | Percentage
- Date, | Weather conditions. | Insect |flowers| Pods | of flowers
- 1915. | |visitors.| that |formed.| that
- | | |opened.| | matured.
- -------+-------------------------+---------+-------+-------+-----------
- Aug. 16|Cloudy and showery | Very few| 102 | 18 | 17.6
- Aug. 17|Rain all day | None | 69 | 4 | 5.7
- Aug. 18|Cloudy most of the day | Very few| 60 | 20 | 33.3
- Aug. 19|Clear and cool | Numerous| 94 | 53 | 56.3
- Aug. 20|Mostly clear and warm | do | 61 | 38 | 62.2
- Aug. 21|Clear and warm | do | 81 | 44 | 54.3
- Aug. 22|Partly cloudy and warm |} | | |
- Aug. 23| do |} do | 181 | 100 | 55.2
- Aug. 24|Cloudy till mid-afternoon| Few | 37 | 12 | 32.4
- -------+-------------------------+---------+-------+-------+-----------
-
-The data given in Table VII show that the percentage of effective
-pollination is much higher in clear weather, when insects are active,
-than in cloudy or rainy weather, when but few insects visit the flowers.
-
-
-INSECT POLLINATORS OF SWEET CLOVER.
-
-On account of the ease with which the heavy flow of nectar of
-sweet-clover flowers may be obtained many insects visit the flowers,
-thereby pollinating them. While the useful insect visitors of flowers
-of red clover are limited to a few species of Hymenoptera, those
-pollinating sweet-clover blossoms are many and belong to such orders as
-Coleoptera, Lepidoptera, and Diptera, as well as to the Hymenoptera.
-However, in the United States the honeybee is the most important
-pollinator of sweet clover. In many parts of the country the different
-species of Halictus, commonly known as sweat bees, rank next in
-importance. The margined soldier beetles (_Chauliognathus marginatus_
-Fabr.) were very active pollinators at Arlington, Va., in the latter
-part of June and first part of July, 1916, but the woolly bear
-(_Diacrisia virginica_ Fabr.) was the only night-flying insect found
-working on sweet clover at Arlington.
-
-Insects belonging to the genera Halictus, Syritta, and Paragus were
-very active pollinators at Ames, Iowa, in 1916, and ranked next in
-importance to the honeybee. In fact, the results obtained in the
-cage where the plants were protected from visitation by insects that
-could not pass through a screen having 14 meshes to the linear inch
-showed that these small insects were able under the conditions of that
-experiment to pollinate practically as many flowers as larger insects.
-
-The insects listed below were collected while visiting _Melilotus alba_
-and _M. officinalis_ flowers in 1916.
-
-
-AT ARLINGTON, VA.
-
- _Neuroptera._--_Perithemis domitia_ Dru., _Enallagma_ sp.
-
- _Hemiptera._--_Adelphocoris rapidus_ Say, _Lygus pratensis_ Linn,
- (tarnished plant bug).
-
- _Coleoptera._--_Chauliognathus marginatus_ Fabr. (margined soldier
- beetle), _Diabrotica 12-punctata_ Oliv. (southern corn rootworm).
-
- _Lepidoptera._--_Pieris protodice_ Bd. (imported cabbage butterfly),
- _Heodes hypophleas_ Bd., _Lycaena comyntas_ Gdt., _Hylephila
- campestris_ Bd., _Scepsis fulvicollis_ Hubn., _Ancyloxypha numitor_
- Fabr., _Pholisora catullus_ Fabr., _Pyraustid_ sp., _Loxostege
- similalis_ Gn. (garden webworm), _Thecla melinus_ Hubn., _Colias
- philodice_ Gdt. (the common sulphur butterfly), _Tarachidia
- caudefactor_ Hubn., _Pyrameis atalanta_ Linn., Drasteria (2 species),
- _Diacrisia virginica_ Fabr. (the woolly bear).
-
- _Hymenoptera._--_Halictus lerouxi_ Lep., _H. provancheri_ (sweat
- bee), _H. pectoralis_ Sm. (sweat bee), Halictus (3 unidentified
- species), _H. legatus_ Say, _Bombus affinis_ Cr., _B. impatiens_
- Harris (bumblebee), _Melissodes bimaculata_ Lep., _Polistes pallipes_
- Lep. (paper wasp), _Megachile_ sp. (leaf-cutter bee), _Coelioxys
- octodentata_ Say, _Xylocopa virginica_ Drury (common carpenter bee),
- _Pompiloides_ sp., _Apis mellifica_ Linn, (honeybee), _Philanthus
- punctatus_ Say, _Sphex nigricans_ Dahlb. (caterpillar hawk), _S.
- pictipennis_ Walsh (caterpillar hawk).
-
- _Diptera._--_Archytas analis_ Fabr., _Chrysomyia macellaria_ Fabr.
- (screw-worm fly),. _Pollenia rudis_ Fabr. (cluster fly), _Ocyptera
- carolinae_ Desv., _Trichophora ruficauda_ V. D. W., _Eristalis
- arbustorum_ Linn., _Physocephala tibialis_ Say.
-
-
-AT AMES, IOWA.
-
- _Hemiptera._--_Lygus pratensis_ Linn., _Adelphocoris rapidus_ Say,
-
- _Coleoptera._--_Coccinella transversoguttata_ Fabr.
-
- _Lepidoptera._--_Eurymus eurytheme_ Bdv., _Chrysophanus_ sp., Lycaena
- (2 species),. _Libythea bachmani_ Kirtland, _Pieris rapae_ Linn.
-
- _Hymenoptera._--_Angochlora_ sp., _Apis mellifica_ Linn., _Colletes_
- sp., _Halictus lerouxi_ Lep., _H. provancheri_ D. J., _Halictus_ sp.,
- _Elis_ sp., _Calliopsis andreniformis_ Smith, _Polistes_ sp., _Sphex_
- sp., _Eumenes fraterna_ Say, _Sceliphron_ sp., _Isodontia harrisi_,
- Fern., _Cerceris_ sp., _Oxybelus_ sp.
-
- _Diptera._--_Syritta_ sp., _Paragus_ sp., _Chrysomyia macellaria_
- Desv., Syrphidæ (2 unidentified specimens).
-
-
-EFFECT OF MOISTURE UPON THE PRODUCTION OF MELILOTUS ALBA SEED.
-
-Careful inspection of a number of sweet-clover fields in Iowa and
-Illinois in the autumn of 1916 indicated that many plants were unable
-to obtain sufficient moisture for the proper development of their
-flowers. Examination of flowers that aborted shortly after reaching
-their mature size showed that the anther sacs had not burst, even
-though the pollen grains were mature. Apparently for the same reason
-many immature pods aborted. The precipitation for July, 1916, in
-Livingston County, Ill., where the sweet-clover seed crop suffered
-materially for lack of moisture, was 3.2 inches less than normal, while
-the temperature was 4.5° F. above normal. In August the precipitation
-was 0.96 of an inch below normal and the temperature 4.2° F. above
-normal. At Ames, Iowa, the precipitation was 3.54 inches below
-normal and the temperature 5.4° F. above normal in July. Both the
-precipitation and temperature were about normal at Ames in August, but
-most of the precipitation fell before the experiments were commenced.
-
-In north-central Illinois the seed production of sweet clover was
-very irregular. Some fields produced an abundance of seed, while a
-large percentage of the pods on the plants in other fields near by,
-where the thickness of the stand, size of the plants, and conditions
-in general were approximately the same, aborted. It was evident that
-all stands producing a good seed crop were growing on well-drained
-soil and that those which were not yielding satisfactorily were on
-poorly drained land. It is well known that sweet clover will produce
-deep taproots only when the plants are growing in well-drained soil
-and that a much-branched surface root system will be formed on poorly
-drained land, and especially when there is an excess of moisture or a
-high water table during the first season's growth. During this droughty
-period in 1916 the upper layer of soil became so depleted of moisture
-that the plants with surface root systems were unable to obtain
-sufficient water to mature their seed. On the other hand, the lack of
-precipitation and the high temperatures did not affect the moisture
-content of the subsoil sufficiently to interfere with the normal seed
-production of deep-rooted plants. According to Lutts (22, p. 47) this
-same condition was found to be true in Ohio in 1916.
-
-As a rule, under droughty conditions the second crop of sweet clover
-will produce a higher yield of seed than the first crop, as the second
-growth of the plants is seldom more than half as much as the first,
-thereby requiring less moisture. However, if showery hot weather
-prevails when the first crop is cut, the end of each stub is very apt
-to become infected, usually with a species of Fusarium, which kills all
-the cortex as far back as the upper bud or young shoot and that part
-of it on the opposite side of this bud to the bud below. If the second
-bud from the top of a stub is not directly opposite the upper one the
-decay may extend nearly to the ground. (Pl. IV.) The destruction of
-half to two-thirds of the cortex from 2 to 4 inches below the upper bud
-materially reduces the quantity of water that can be conveyed to the
-branch above the base of the dead area. Plants thus infected obtain
-sufficient moisture for seed production only under the most favorable
-conditions. When the first crop is cut during warm dry weather, and
-especially when the first crop has not been permitted to make more than
-a 30 to 32 inch growth, the stubble seldom decays, and in no instance
-have the plants been observed to decay as far back as the upper buds.
-
-An experiment was conducted at Ames in the latter part of August and
-first part of September, 1916, to determine the effect of watering
-plants that were aborting a large percentage of their flowers and
-immature pods. For this purpose several volunteer plants growing in
-a meadow were selected. A hole 12 inches square and 14 inches deep
-was dug 8 inches from the crown of one plant, and each evening during
-the experiment 2 gallons of water were poured into the hole. The top
-of the hole was kept covered, so as to check evaporation from it as
-much as possible. Another plant of the same size and growing about 15
-yards from the watered plant served as a check. On both plants many
-of the flowers and immature buds were aborting at the beginning of
-the experiment. The soil in this field was so depleted of moisture
-that the leaves of the plants wilted during the hottest part of the
-days preceding the experiment. The foliage on the check plant wilted
-each day for the first five days of the experiment. On the sixth day
-0.96 of an inch of rain fell and four days later 0.23 of an inch
-more. The dropping of the flowers was temporarily checked by these
-precipitations, but owing to the dry, compact condition of the soil
-the rain was not sufficient to check entirely the fall of flowers and
-immature pods. At the beginning of the experiment the racemes on both
-plants were divided into three classes, according to the development of
-the flowers, and labeled. They were collected and the seeds counted as
-soon as the pods at the bases of the racemes commenced to turn brown.
-Table VIII presents the results obtained.
-
-Table VIII.--_Effect of water upon the seed production of
-sweet clover when growing under droughty conditions at Ames, Iowa, in
-1916._
-
- ------------------------+-------------------------------------+---------
- |Plant not watered.| Plant watered. |
- +--------+---------+--------+---------+
- | | Average | | Average |
- Stage of development | Number |number of| Number |number of|Increase
- when labeled. | of |pods per | of |pods per | from
- |racemes | raceme |racemes | raceme |watering.
- |labeled.| that |labeled.| that |
- | | matured.| | matured.|
- ------------------------+--------+---------+--------+---------+---------
- Flowers at the base of | | | | |
- the racemes just ready| 49 | 27.39 | 110 | 55.63 | 28.24
- to open. | | | | |
- | | | | |
- Pods 3 to 6 days old | 30 | 21.13 | 112 | 39.81 | 18.68
- | | | | |
- Pods 9 to 12 days old | 35 | 15.23 | 50 | 29.86 | 14.63
- | | | | |
- ------------------------+--------+---------+--------+---------+---------
-
-
-The effect of the water was noticeable soon after the first
-application, as the leaves and flowers on this plant became turgid and
-the anther sacs burst at the proper stage of their development. Very
-few flowers fell after the second day. The water decidedly checked
-the aborting of immature pods, as is shown by the results obtained on
-the racemes which were labeled after the pods had formed. The racemes
-which contained pods 3 to 6 days old when labeled matured 9.95 pods to
-the raceme more than those which contained older pods at the beginning
-of the experiment, but this was expected, as most of the aborting
-which caused this difference had taken place before the racemes were
-labeled. As very few pods aborted before they were 3 to 6 days old, the
-difference of 9.95 pods to the raceme in favor of the ones labeled
-when the flowers at their bases were just ready to open was largely
-due to the dropping of the flowers on the older racemes before the
-experiment was begun.
-
-It will be seen that the production of mature pods on the plant not
-watered was much greater on the racemes that were labeled before
-the flowers opened than on the older racemes. This difference is
-undoubtedly due to the precipitation which fell on the sixth and tenth
-days of the experiment. It is believed that the yield of 15.23 pods
-to the raceme on the ones labeled when the pods were 9 to 12 days old
-is representative of the production of pods per raceme previous to
-the precipitation and that the other racemes on this plant would have
-yielded proportionately if conditions had remained the same.
-
-In the early spring of 1916, _Melilotus alba_ was planted in several
-large pots in the greenhouse of the Department of Agriculture at
-Washington, D. C. These pots were placed outside the greenhouse in
-the late spring, where they remained until the following January,
-when they were taken into the greenhouse. The plants grew rapidly and
-began to flower during the latter part of April, 1917. At this time
-two pots were placed in a large cage made of screen having 20 meshes
-to the linear inch. One pot was submerged in a tub of water, so that
-the soil was saturated at all times, while the plant in the other pot
-was given only sufficient water to keep it from wilting. The pods on a
-few racemes were self-pollinated and the results obtained are given in
-Table IX.
-
-Table IX.--_Effect of moisture on the seed production of
-Melilotus alba at Washington, D. C, in 1917._
-
- -------------------------+------------------+---------+--------+--------
- |Total number of-- | Flowers that matured
- | | (per cent).
- +--------+---------+---------+--------+--------
- Soil treatment. | | | Pods | |
- |Racemes.| Flowers.| formed. | Total. |Increase.
- -------------------------+--------+---------+---------+--------+--------
- | | | | |
- Soil given only a limited| 12 | 227 | 65 | 28.63 | ......
- quantity of water. | | | | |
- Soil saturated. | 17 | 425 | 235 | 55.03 | 26.22
- -------------------------+--------+---------+---------+--------+--------
-
-The results of this experiment compare favorably with those obtained
-under field conditions at Ames in 1916.
-
-
-
-
-Part II.--STRUCTURE AND CHEMICAL NATURE OF THE SEED COAT AND ITS
-RELATION TO IMPERMEABLE SEEDS OF SWEET CLOVER.[3]
-
-[3] The writers wish to acknowledge the service rendered by Mr. H.
-S. Doty, Instructor in Botany, Iowa State College, Ames, Iowa, in
-assisting in the preparation of this article.
-
-
-HISTORICAL SUMMARY.
-
-When agriculturists first began to cultivate wild legumes they observed
-that many seeds would not germinate within a comparatively short time
-after planting. Thus the problem of impermeable seeds began to demand
-attention many years ago. However, impermeable seeds are not confined
-to the Leguminosæ, as they occur also in the Malvaceæ, Chenopodiaceæ,
-Convolvulaceæ, Cannaceæ, and other families.
-
-Since the first account of the structure of legume seed coats by
-Malpighi (23 v. 1) in 1687, many investigators have contributed to our
-knowledge of the structure of the coats of seeds belonging to this
-family.
-
-Pammel (31) made an extensive study of legume seeds, including all the
-genera in the sixth edition of Gray's Manual, as well as genera not
-included in that publication. He found that the seed coat uniformly
-consisted of three layers, namely, the outer layer of Malpighian cells,
-the osteosclerid layer, and the inner layer of nutrient cells. Pammel's
-work included a study of the seed coats of _Melilotus alba_ and _M.
-officinalis_, and the descriptions and illustrations in his publication
-agree for the most part with the results obtained in the investigations
-reported in this article. However, more variation was noticed in the
-different layers of the seed coat than he describes.
-
-The cause of impermeability in seeds has been investigated by many.
-It has been found to be due to the embryos in some seeds, such as the
-hawthorns, but in most cases to the structure of the seed coat, and
-especially so in the Leguminosæ. Crocker (3) states that, exactly
-opposite to the common view, the cause of delayed germination generally
-lies in the seed coats rather than in the embryos. Nobbe (29) thought
-that the hardness of leguminous seeds was due to the Malpighian layer,
-and in a later publication Nobbe and Haenlein (30, p. 81) state that
-the absorbent power of many seeds is inhibited or entirely arrested
-by the cones of the Malpighian cells and the shields built up between
-them, which consist principally of cutin. Huss (15) agrees with Nobbe
-and Haenlein. Verschaffelt (39) found that the impermeability of the
-seeds of Cæsalpiniaceæ and Mimosaceæ investigated was due to, the
-inability of water to pass through the canals of the seed coat. By
-soaking the seeds in alcohol or other substances which change the
-capillarity of the pores, the seed coats were made readily permeable
-to water. Gola (6) states that the cause of the impermeability of seeds
-is the peculiar character of the Malpighian cells, which prevents their
-infiltration and consequent increase in volume, while Bergtheil and Day
-(2) found that the hardness of the seeds of _Indigofera arrecta_ was
-due to their possession of a very thin outer covering of a substance
-resistant to water. Ewart (5, p. 185) believes that in most impermeable
-seeds the cuticle prohibits the absorption of water, but gives as an
-exception _Adansonia digitata_, in which the whole integument seems to
-be permeable to water with difficulty. The following is quoted from
-White (42, p. 205):
-
- As a general rule in small and medium-sized seeds the cuticle is well
- developed and represents the impermeable part of the seed coat, while
- in the cases of large seeds, such as those of _Adansonia gregorii_,
- _Mucuna gigantea_, _Wistaria maideniana_, and _Guilandina bonducella_,
- the cuticle is relatively unimportant and inconspicuous. In these
- seeds the extreme resistance which they exhibit appears to be located
- in the palisade cells.
-
-In discussing the seed coat of _Melilotus alba_, Rees (33, p. 404)
-states that the outer layer consists of palisade cells covered,
-externally by a structureless membrane, which, however, did not
-appear to be cuticle but hemicellulose, as it stained magenta with
-chloriodid of zinc. The greater part of the walls of the palisade
-cells also appears to be composed of hemicellulose and the outer ends
-only were cuticularized. In order to find whether the outer membrane
-was in itself impermeable to water, this author treated seeds for
-short intervals in sulphuric acid to dissolve the outside covering
-without directly affecting the palisade cells. Seeds treated in this
-manner swelled in water and microscopic examination showed that the
-ends of the palisade cells were quite intact, but had separated from
-each other. From this it was concluded that the outer membrane is
-instrumental in conferring impermeability on the seed, although not
-directly responsible for it, as is the case with a true cuticle. It
-is further believed that it probably served as a cement substance
-by means of which the cuticularized ends of the cells were held
-together closely, thus forming a barrier through which water could not
-penetrate, but that as soon as this barrier was removed the ends of the
-palisade cells separated and water passed in between them.
-
-More than 20 years ago machines were devised by Kuntze, Michalowski
-(27, p. 86), Huss (15), and later by Hughes (14), to scarify
-impermeable seeds. Other methods have been recommended and employed to
-some extent for hastening the germination of seeds. Hiltner (13, p.
-44) treated seeds of red clover, white clover, and alfalfa 10, 30, and
-60 minutes with concentrated sulphuric acid and found that the best
-germination resulted from the 60-minute treatment. Love and Leighty
-(21) also treated the seeds of various legumes with concentrated
-sulphuric acid and obtained a better germination in all cases. In
-their investigations with _Melilotus alba_ it was found that a 2-hour
-treatment resulted in some injury to the seed, but that a treatment
-varying from 25 minutes to 1 hour gave good results. In most cases in
-our investigations the seed coats of sweet clover became permeable
-to water after a treatment of 15 minutes in concentrated sulphuric
-acid, and within 5 minutes all of the Malpighian cells were destroyed
-down to the light line. Harrington (10) found that the soil, season,
-climate, color, or size of red-clover seeds had no influence upon
-the percentage of impermeable seeds and that the good germination
-ordinarily obtained with red clover was due to the scarifying of the
-seed coats by the rasps of hulling machines. Harrington (11) also
-studied the agricultural value of impermeable seeds and found that
-alternations of temperature cause the softening and germinating of
-many impermeable clover seeds when a temperature of 10° C. or cooler
-is used in alternation with a temperature of 20° C. or warmer and that
-the effect of such an alternation of temperature is greatly increased
-by previously exposing the seeds to germinating conditions at a
-temperature of 10° C. or cooler and is decreased by previously exposing
-the seeds to germinating conditions at a temperature of 30° C. It is a
-well-known fact that impermeable seeds which remain in the field over
-winter germinate readily the following spring.
-
-The light line is the most important and interesting feature of
-the Malpighian cell, at least so far as _Melilotus alba_ and _M.
-officinalis_ are concerned. But one light line occurs in the
-Malpighian cells in most Leguminosæ, although Pammel (32) reports two
-well-developed light lines in _Gymnocladus canadensis_, Junowicz (16)
-found three in _Lupinus varius_, and Sempolowski (36) two in _Lupinus
-angustifolius_.
-
-Many investigators have studied the light line, and different theories
-have been advanced as to its function, physical properties, and
-chemical nature. Schleiden and Vogel (35, p. 26) in describing the
-mature testa of _Schizolobium excelsum_ in 1838 undoubtedly referred to
-the light line when they stated that the walls of the Malpighian cells
-were not equally thickened. Mettenius (26), in 1846, was probably the
-first definitely to describe the light line. This author believed it
-was composed of pore canals, all appearing at the same height in the
-cells, but he was unable to prove this by cross sections. Lohde (20)
-studied the light line in seeds of _Hibiscus trionum_ and found it
-cutinized. Hanstein (8) states that the Malpighian cells are composed
-of two cell layers and the light line is produced by the adjoining
-walls of the ends of the cells. Later, this same author (9), according
-to Harz (12), refers to the light line as a perforated disk composed of
-tissue of strong refracting power.
-
-Russow (34) concludes that the light line is produced by neither
-chemical nor mechanical changes but is caused by a modified molecular
-structure containing less water than the remainder of the cell wall.
-Hiltner (13) agrees with Russow's explanation. Harz (12, p. 561) also
-agrees with Russow and adds that he has observed that the light line
-disappeared in a number of cases after applications of nitric acid.
-Wigand and Dennert (43) suggested that the light line is due to a
-series of erect fissures, while Tietz (37, p. 32) believes it is due
-to a chemical modification and that the phenomenon results from the
-exceptionally extreme density of parts of the cellulose membrane.
-Junowicz (16) found evidence of cellulose material. The cell wall
-at this point was strongly refractive and had a different molecular
-structure. After studying _Phaseolus vulgaris_, Haberlandt (7, p.
-38) agrees with the Russow explanation. In the seed of this plant
-the light line colored blue after being treated with chloriodid of
-zinc. Sempolowski (36), who investigated the light line in _Lupinus
-angustifolius_, states that there is not only a difference in the
-molecular structure but also a chemical modification of the cell wall
-at this point, since with iodin and sulphuric acid the cell wall
-colored blue, whereas the light line colored yellow. Wettstein (41),
-who studied seeds of Nelumbo, agrees with Russow (34) and Sempolowski
-(36) that chemical and physical modifications occur. He found that
-iodin and sulphuric acid colored the Malpighian cells intensely blue,
-the light line at first yellowish, and then later it gradually became
-blue. This reaction may be accelerated by heat. Iodin produced the same
-effect, and the light line colored blue more rapidly. When treated with
-a water-withdrawing medium the light line was not altered for some
-time, but finally disappeared with continued application. Cooking for a
-long time in caustic potash or standing in cold caustic potash caused
-the cells to swell, while the light line remained uninjured at first
-but finally disappeared. He also believed that the absence of pore
-canals in the region of the light line caused it to be more dense.
-
-Nobbe and Haenlein (30) treated sections of seed coats of _Trifolium
-pratense_ with iodin and sulphuric acid and found that the light line
-colored blue as readily as the thickened ridges that radiate inward
-from it, but that the outer processes of the palisade cells projecting
-from the light line toward the cuticle stained dark brown. They also
-state that various causes work to produce such unusual lusters in
-the light line, the principle one of which is the thickened ridges
-which radiate inward, reach their greatest development at this point,
-and coalesce in the lumen of the cell. The result is that the light
-line falls upon a continuously homogeneous medium, while in the inner
-portions of the ridges the light passes through media of varying
-opacity, such as cellulose, water, and protoplasm, whereby it is
-progressively subdued in varying degrees by partial reflection. Pammel
-(31, p. 147) studied the light line in _Melilotus alba_ and found that
-it consisted of a narrow but distinct refractive zone below the conical
-layer. The refractive zone colored blue with chloriodid of zinc. The
-whole upper part was, however, more or less refractive, while the
-remainder of the cell wall contained pigment and colored blue with
-chloriodid of zinc. Small canals project into the walls, in some cases
-extending beyond the light line.
-
-Beck (1) found that the light-refracting power of the light line was
-much greater than that of the undifferentiated membrane and stated that
-there may be in addition to this a chemical difference which can not be
-detected with the present microchemical methods. He does not believe
-that it is cuticularized or that it contains less water than the rest
-of the cell.
-
-Marlière (24, p. 11) gives a physical explanation and states that
-the true cause of the light line lies in the peculiar structure
-of the secondary membrane of the Malpighian cell. Tunmann (38, p.
-559) observed that it did not hydrolize in weak acids and therefore
-decided that it was not hemicellulose. He found that it dissolved in
-concentrated sulphuric acid more readily than the regions surrounding
-it and that it was composed of pectin or callose. In our investigations
-the main portion of the light line of _Melilotus alba_ and _M.
-officinalis_ was very resistant to concentrated sulphuric acid, only
-the narrow outer portion being attacked. It showed evidence of callose.
-
-
-MATERIAL AND METHODS.
-
-Permeable and impermeable seeds[4] of _Melilotus alba_ and _M.
-officinalis_ were obtained from commercial samples and also from
-samples collected in the field. Those selected for sectioning were
-allowed to dry after being removed from the germinator and then
-embedded on the ends of pine blocks in glycerin gum, which was made by
-dissolving 10 grams of powdered gum arabic in 10 c. c. of water and
-adding 40 drops of glycerin. After the glycerin gum had dried for 24
-hours, the seeds were easily sectioned. This method of embedding causes
-no change in the seed coat. It is more satisfactory than the paraffin
-method for holding the seeds firmly. The glycerin gum dissolved readily
-when the sections were mounted in water.
-
-[4] The term "permeable" is used in this paper to designate seeds whose
-coats are permeable to water in two weeks or less at temperatures
-favorable for germination, while the term "impermeable" is used to
-designate seeds whose seed coats are impermeable to water for this
-length of time when temperatures are favorable for germination.
-Impermeable seeds are commonly referred to as "hard seeds," and they
-may become permeable in time.
-
-In the microchemical studies Sudan III, alcanin, chlorophyll solution,
-and phosphoric acid iodin were used to test for cutin or suberin;
-sulphuric acid and iodin, chloriodid of zinc, and chloriodid of
-calcium for cellulose; phloroglucin and hydrochloric acid for lignin;
-ruthenium red for pectic substances; and sulphuric acid, Congo red, and
-aniline blue for callose.
-
-Where very thin sections were necessary for detailed study of the
-structure of the seed coat, pods in various stages of development were
-collected, and after the usual preliminary treatment they were embedded
-in paraffin and sectioned with the microtome. Microchemical tests were
-made with these sections by using various specific stains. Safranin was
-used to test for cutin, suberin, and lignin; haematoxylin and methyl
-blue for cellulose ; methylene blue, methyl violet B, mauvein, and
-ruthenium red for pectic substances; and aniline blue and Congo red for
-callose. In studying some points with reference to the pore system of
-the seed coat, it was necessary to use free-hand sections of fresh pods.
-
-In studying the seed coat in relation to the absorption of water,
-both permeable and impermeable seeds were soaked in water solutions
-of safranin, gentian violet, eosin, and haematoxylin, then dried and
-embedded in glycerin gum for sectioning. Seeds were soaked in stains
-dissolved in 95 per cent alcohol to test the penetration of alcohol. It
-was evident that the seed coats did not act as a filter, as the stains
-passed through them with the water or alcohol.
-
-
-STRUCTURE OF THE SEED COAT.
-
-There is very little endosperm present in mature seeds of _Melilotus
-alba_ or _M. officinalis_. That which is present is quite permeable to
-water and therefore bears no relation to the impermeable seeds of these
-plants.
-
-The outer layer of the seed coat, which is the modified epidermal layer
-of the ovule, is known as the Malpighian layer. (Pl. V, figs. 1 and
-2.) The cells constituting this layer, commonly called palisade cells,
-are the most highly modified cells of the seed coat. They are very
-much elongated, their length varying in the different regions of the
-coat, and their outer tangential walls and the outer portions of their
-radial walls are so much thickened that their lumina are confined to
-the inner portion of the cells, sometimes occupying less than half the
-length of the cells. The inner tangential walls and inner portions of
-the radial walls are thickened just previous to the death of the cells,
-the thickening sometimes being only slight and sometimes so much as to
-leave only very narrow lumina.
-
-There is a very thin layer on the outer surface of the Malpighian
-cells which has been called cuticle by previous investigators, but
-the chemical composition of this layer and its perviousness to water
-indicate that there is very little cutin present. This layer is
-probably the primary epidermal cell wall rather than a deposit on the
-outer surface of the wall. To determine this a study of the development
-of the Malpighian cells is necessary.
-
-Beneath the so-called cuticle there is the much thickened outer portion
-of the Malpighian cells in which there are two rather distinct regions,
-one constituting the conelike structures and the other forming a
-continuous layer over the conelike structures, separating them from
-the cuticle and filling in between them. These two regions separate
-easily, and in cutting sections the outer region, called by some the
-cuticularized portion, often breaks away, leaving the entire surface of
-the cones exposed.
-
-The term "cuticularized layer" will be used to designate all of the
-thickening covering the cones, including that around the cones as well
-as the portion between the cones and the cuticle. This term is not
-entirely appropriate, for the region is practically free from cutin,
-but for the want of a better term it will be used. There are canals
-in the cuticularized layer and cones, which are easily seen when the
-sections are treated with chloriodid of zinc or sulphuric acid. A
-surface view of a section showing the cones and cuticularized layer
-when mounted in glycerin shows the canals as dark lines due to the
-air inclosed. The canals are most abundant along the lines where the
-lateral walls of the cells join, but many are within the cones and in
-the cuticularized substance between the cones. (Pl. V, fig. 5.)
-
-The well-developed light line in _Melilotus alba_ and _M. officinalis_
-is found just below the bases of the cones. In some seed coats only
-a few and in others none of the canals which are common in the cones
-and cuticularized region cross the light line. A very distinct line of
-small canals filled with air and thus forming a dark band is present
-just above the fight line, thus making the light line more conspicuous.
-(Pl. V, fig. 3.) When the lumina of the cells extend across the light
-line, they are exceedingly small. The light line is the most compact
-region of the Malpighian layer and is conspicuous because it refracts
-the light much more than the regions above and below it.
-
-Just below the Malpighian is a layer of cells variously modified and
-known as the osteosclerid. The cells of this layer are often referred
-to as the hourglass cells on account of their shape. In some regions
-of the seed coat they are expanded at both ends and their walls are
-much thickened, the thickenings forming ridges on the radial walls,
-while in other regions only the upper tangential wall and a portion of
-the radial walls are thickened and the cells are expanded only at the
-inner end, thus having the shape of the frustum of a cone. Beneath the
-osteosclerid layer is the nutrient layer.
-
-The nutrient layer contains chloroplasts. It varies not only in the
-number of layers of cells composing it, but also in the modifications
-of these cells. This layer ranges from four to seven cells in thickness
-in the different parts of the seed coat.
-
-
-PLATE V.
-
-[Illustration]
-
-Structure of the Seed Coat of Sweet Clover.
-
-Fig. 1.--Section of the seed coat of _Melilotus officinalis_. × 450.
-Fig. 2.--Another section of the seed coat of _Melilotus officinalis_,
-showing the variation in size and modifications that occur in the
-three layers. × 450. Fig. 3.--Section of the Malpighian layer of a
-_Melilotus alba_ seed, showing a line of canals just above the light
-zone. × 450. Fig. 4.--Section of the Malpighian layer of a permeable
-_Melilotus alba_ seed. × 450. Fig. 5.--Tangential section of the
-Malpighian cells cut between the cuticle and tops of the cones, showing
-pores. × 530. Fig. 6.--Section through the Malpighian layer of an
-impermeable _Melilotus alba_ seed. × 450. Fig. 7.--Section through
-the Malpighian layer of an impermeable _Melilotus alba_ seed, showing
-the region through which water and stains readily passed. × 450. Fig.
-8.--Cross section of a Malpighian cell of a permeable _Melilotus alba_
-seed through the region of the light zone, showing the lumen not
-entirely closed. × 530. Fig. 9.--Section through the Malpighian layer
-of a _Melilotus alba_ seed shaded to show the portions which react to
-the cellulose and pectose tests. × 450. Fig. 10.--Section through the
-Malpighian layer of a _Melilotus alba_ seed which shows the condition
-of the seed coat after 60 minutes' treatment of concentrated sulphuric
-acid. That portion above the light zone was destroyed, and the lumina
-as small pores through which much of the stain now passed were seen
-extending across the light line. The lines between the cells were much
-more distinct, appearing as small intercellular spaces through which
-some stain passed. × 450. _a_, Cuticle; _b_, cuticularized layer; _c_,
-conelike portion of the thickening of the Malpighian cells; _d_, light
-line; _e_, region of a hard seed coat through which water and stains
-readily passed; _l_, lumen; _M_, Malpighian cells; _N_, nutrient cells;
-_O_, osteosclerid cells; _p_, canals just above light zone.
-
-
-MICROCHEMISTRY OF THE SEED COAT.
-
-Tests for cutin showed that there was very little present in the seed
-coat. Slight reactions for cutin were observed in the cuticle, in the
-outer margin of the cuticularized layer, and in the basal portion of
-the cones. These reactions were so slight as to be almost negligible.
-It is evident that the cuticle and cuticularized layer are not well
-named in _Melilotus alba_ and _M. officinalis_. Tests for cellulose
-showed that it was present in the cuticle, cuticularized layer, cones,
-the walls of the Malpighian cells below the light line, and the walls
-of the cells of the osteosclerid and nutrient layers. (Pl. V, fig. 9.)
-The reaction for cellulose in the Malpighian cells was quite distinct
-in the walls below the light line, less distinct in the cones and
-cuticle, and least distinct in the cuticularized layer.
-
-Tests for lignin occasionally showed slight traces in the Malpighian
-cells below the light line. When treated with reagents for pectic
-substances, the cuticle, cuticularized layer, cones, and all cell walls
-below the light line gave a definite reaction. The reaction of the
-cones and cuticle was more pronounced than the cuticularized layer.
-Tests for callose gave no reaction except in the upper part of the
-light line. This part of the light line stained slightly blue with
-aniline blue and was easily dissolved with sulphuric acid. In cutting
-free-hand sections of fresh material the Malpighian layer sometimes
-broke along this line. The greater part of the light line reacted to
-none of the tests, and its chemical nature was not determined.
-
-When microtome sections of seeds in different stages of development
-were treated with various stains, the results were in accord with those
-obtained with free-hand sections. Thus with safranin the periphery and
-cones of the Malpighian cells were slightly stained, while haematoxylin
-and methyl blue stained all the seed coat except the light line. The
-cones and cuticle stained more readily than the cuticularized layer,
-but neither stained as deeply as the cell walls below the light line.
-Methylene blue, methyl violet B, and mauvein stained all above the
-light line, indicating the presence of pectic substances; however, the
-staining was more prominent in the cones and cuticle.
-
-The difference in reaction of the cones and cuticularized layer to
-the cellulose and pectose tests probably indicates a difference in
-density rather than a difference in chemical composition. Since the
-cuticularized layer separates readily from the cones, there may be a
-difference in physical properties.
-
-With Congo red the upper part of the light line was only very slightly
-stained, but aniline blue had a more pronounced effect.
-
-The microchemical tests applied to the seed coat show that in the
-region above the light line there is only a slight trace of cutin
-or suberin, but a considerable amount of cellulose and pectose. All
-cell walls below the light line are mainly cellulose but contain some
-pectose. The upper portion of the light line contains callose, but the
-remainder of the light line appears to be chemically different from all
-other parts of the seed coat or else so dense as to resist the attack
-of the reagents.
-
-
-THE SEED COAT IN RELATION TO THE ABSORPTION OF WATER.
-
-A study of permeable seeds soaked in water containing stains showed
-that there were no local regions through which the water passed.
-The stains passed through all regions of the seed coat. Coating the
-micropylar region with vaseline retarded germination, but had no
-effect upon the percentage of germination at the end of three days. In
-seed coats through which the stain had passed, the light line was not
-stained. Some stain was found in the canals which crossed the light
-line, and much more in the cell cavities. There was no evidence that
-the stain had permeated the substance of the light line. It was able to
-cross the light line only when pores were present.
-
-In impermeable seeds the stains passed readily to the light line.
-(Pl. V, fig. 7.) It was evident that the absorption of water was
-not prevented by either the cuticularized layer or the cone-shaped
-structures of the Malpighian layer, but by the light line. The region
-outside of the light line became stained in a few hours, but there
-was no trace of the stain within the light line after the seeds had
-remained a week in the stains. Alcohol did not penetrate the seed coat
-more readily than water.
-
-
-A COMPARISON OF PERMEABLE AND IMPERMEABLE SEED COATS.
-
-No difference in chemical structure was found between the coats of
-permeable and impermeable seeds. The principal differences were in the
-character and amount of thickening of the cell walls.
-
-In many of the permeable seeds some of the canals were found to extend
-across the light line, but this was not true for all permeable seeds.
-(Pl. V, fig. 8.) Oblique sections of permeable seed coats showed that
-the cell cavities, although reduced to mere pores by the thickening of
-their radial walls, extended across the light line into the base of the
-cones, thus forming a passageway through which the stains passed to the
-larger portions of the cell cavities below the light line. (Pl. V, fig.
-4.)
-
-In the coats of the impermeable seeds the light line was usually
-broader, the Malpighian cells thickened more below the light line,
-and the main cavities of the Malpighian cells were more reduced and
-farther below the light line than in the coats of permeable seeds. (Pl.
-V, fig. 6.) No canals except occasionally a few very small ones were
-seen crossing the light line in impermeable seeds. Cross and oblique
-sections showed that the lumina of the Malpighian cells were closed
-in the region of the light line. Thus it was found that permeable and
-impermeable seeds differ mainly in the amount of thickening which
-occurs in the walls of the Malpighian cells. In the impermeable seeds
-the thickening which begins at the outer tangential wall of the
-Malpighian cell extends farther toward the inner tangential wall,
-leaving the cell lumina smaller and farther below the light line than
-in permeable seeds. The thickening is also more complete in impermeable
-seeds, leaving fewer and smaller canals across the light line as well
-as closing the cell lumina in the region of the light line.
-
-
-THE ACTION OF SULPHURIC ACID ON THE COATS OF IMPERMEABLE SEEDS.
-
-Impermeable seeds were soaked in concentrated sulphuric acid (sp. gr.
-1.84) for 15, 30, and 60 minutes; then washed and put in the staining
-solutions. After they had swollen, they were removed from the staining
-solutions, dried, and embedded in glycerin gum. A study of these seeds
-showed that the acid had eaten away all of the material outside of the
-light line and that the stain had passed through all regions of the
-seed coat. (Pl. V, fig. 10.) When observed under the microscope, it was
-seen that the action of the acid was rapid, destroying the cuticle,
-cuticularized layer, and cones in about 5 minutes. After 15 minutes
-treatment with acid the light line, aside from the presence of canals
-and pores not previously visible, seemed to be very little affected.
-The division lines along which the lateral walls of the Malpighian
-cells were joined now became much more distinct across the light line,
-thus indicating that there was some swelling in this region. When a
-close examination of the path of the stain was made the cell lumina,
-and occasionally very small pores, were found to extend across the
-light line. The presence of the stain in the pores indicated that
-they were paths of the stain across the light line. Some of the stain
-passed along the lines between cells and through the occasional canals
-crossing the light line, but judging from the intensity of the stain in
-the lumina the canals appeared to be the principal passageways.
-
-The action of the acid in opening the cell cavities across the light
-line was not determined. It may be due to the swelling of the light
-line or to the removal of substances closing the pores.
-
-No seeds were exposed to the acid for longer than an hour, but at the
-end of this period the light line was still intact. As compared with
-other portions of the Malpighian layer, it is extremely resistant to
-concentrated sulphuric acid. Since all cell walls below the light line
-are mainly cellulose, the resistance of the light line prevents the
-acid from destroying the entire seed coat and reaching the embryo.
-
-
-
-
-LITERATURE CITED.
-
-
-(1) Beck, Gunther.
-
-
- 1878. Vergleichende Anatomie der Samen von Vicia und Ervum. _In_
- Sitzber. K. Akad. Wiss. [Vienna], Math. Naturw. Kl., Bd. 77,
- Abt. 1, p. 545-579, 2 pl.
-
-(2) Bergtheil, C, and Day, D. L.
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- 1907. On the cause of "hardness" in the seeds of Indigofera
- arrecta. _In_ Ann. Bot., v. 21, no. 81, p. 57-60, pl. 7.
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-(3) Crocker, William.
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- 1906. Role of seed coats in delayed germination. _In_ Bot. Gaz., v.
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-(4) Darwin, Charles.
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- 1885. The effects of cross and self fertilisation in the vegetable
- kingdom. 482 p. New York.
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-(5) Ewart, Alfred J.
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- 1908. On the longevity of seeds. _In_ Proc. Roy. Soc. Victoria, v.
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-(6) Gola, Guiseppe.
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- 1905. Ricerche sulla biologia e sulla fisiologia dei semi a
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-(7) Haberlandt, G.
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- 1877. Ueber die Entwickelungsgeschichte und den Bau der Samenschale
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-(8) 1863. Erläuterung des Nardoo genannten Nahrungsmittels der
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-(9) 1866. Pilulariae globuliferae generatio cum Marsilia comparata.
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- Harrington, George T.
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-(10) 1915. Hard clover seed and its treatment in hulling. U. S.
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-(11) 1916. Agricultural value of impermeable seeds. _In_ Jour. Agr.
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-(12) Harz, C. D.
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- 1885. Landwirtschaftliche Samenkunde. 1362 p., 201 fig. Berlin.
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-(13) Hiltner, L.
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- 1902. Die Keimungsverhältnisse der Leguminosensamen und
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-(14) Hughes, H. D.
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-(15) Huss, Mathias.
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-(16) Junowicz, R.
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- 1878. Die Lichtlinie in den Prismenzellen der Samenschalen. _In_
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-(17) Kerner von Marilaun, Anton.
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- 1891. Pflanzenleben. 2 Bd. Leipzig.
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-(18) Kirchner, O.
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- 1905. Über die Wirkung der Selbstbestäubung bei den Papilionaceen.
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-(19) Knuth, Paul.
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- 1906-8. Handbook of flower pollination, based on Hermann Müller's
- work upon "The fertilisation of flowers by insects," transl. by
- J. R. Ainsworth Davis. 3 v., illus. Oxford. Bibliography, v. 1,
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-(20) Lohde, Georg.
-
- 1874. Ueber die Entwicklungsgeschichte und den Bau einiger
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-(21) Love, Harry H., and Leighty, Clyde E.
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- 1912. Germination of seed as affected by sulphuric acid treatment.
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-(22) Lutts, F. M.
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-(23) Malpighi, Marcello.
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-(24) Marlière, H.
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- 1897. Sur la graine et spécialement sur l'endosperme du Ceratonia
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-(25) Martin, J. N.
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- 1915. Relation of moisture to seed production in alfalfa. Iowa Agr.
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-(26) Mettenius, Georg.
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- 1846. Beitraege zur Kenntniss der Rhizocarpeen. 65 p., 3 pl.
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-(27) Die Hohenheimer Samenritzmachine.
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- 1894. _In_ Braunschweig. Landw. Ztg., Jahrg. 62, Nr. 19, p. 86.
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-(28) Müller, Hermann.
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-
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-<pre>
-
-Project Gutenberg's USDA Bulletin No. 844, by H. S. Coe and J. N. Martin
-
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world at no cost and with almost no restrictions
-whatsoever. You may copy it, give it away or re-use it under the terms
-of the Project Gutenberg License included with this eBook or online at
-www.gutenberg.org. If you are not located in the United States, you'll
-have to check the laws of the country where you are located before using
-this ebook.
-
-
-
-Title: USDA Bulletin No. 844
- Sweet-Clover Seed
-
-Author: H. S. Coe
- J. N. Martin
-
-Release Date: August 21, 2020 [EBook #62998]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK USDA BULLETIN NO. 844 ***
-
-
-
-
-Produced by Tom Cosmas from files generously provided by
-the USDA through The Internet Archive and placed in the
-Public Domain.
-
-
-
-
-
-
-</pre>
-
-
-
-<div class="figcenter illowp46" id="cover" style="max-width: 17.3125em;">
- <img class="w100" src="images/cover.png" alt="" />
-</div>
-
-
-<div class="bboxb">
-<div class="bbox">
-
-<div class="chapter">
-<p class="caption4 nobreak">UNITED STATES DEPARTMENT OF AGRICULTURE</p>
-
-<p class="caption2">BULLETIN No. 844</p>
-
-<p class="tdc">Contribution from the Bureau of Plant Industry</p>
-
-<p class="tdc">WM. A. TAYLOR, Chief</p>
-</div>
-
-<hr class="full" />
-
-<p class="tdc">
-Washington, D. C.&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;PROFESSIONAL PAPER&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;August 11, 1920<br />
-</p>
-
-<hr class="full" />
-
-<h1>SWEET-CLOVER SEED</h1>
-
-<h2>Part I.&mdash;Pollination Studies of Seed Production</h2>
-
-<h2>Part II.&mdash;Structure and Chemical Nature of the Seed Coat and
-its Relation to Impermeable Seeds of Sweet Clover</h2>
-
-<p class="tdc">By</p>
-
-<p class="caption3">H. S. COE, formerly Assistant Agronomist, Office of Forage-Crop
-Investigations, and J. N. MARTIN, Professor of Morphology
-and Cytology, Iowa State College</p>
-
-<hr class="full" />
-
-<h2>CONTENTS</h2>
-
-
-<table class="tblcont" style="padding:12px;" summary="TOC">
-<tr>
- <td></td>
- <td class="tdr smaller">Page</td>
-</tr>
-<tr>
- <td><div class="tdl hanging"><a href="#Part_I_POLLINATION_STUDIES_OF_SEED_PRODUCTION">Part I.</a>&mdash;Pollination Studies of Seed Production.</div></td>
- <td></td>
-</tr>
-<tr>
- <td class="tdl2">Unsatisfactory yields of sweet-clover seed</td>
- <td class="tdr"><a href="#UNSATISFACTORY_YIELDS">1</a></td>
-</tr>
-<tr>
- <td class="tdl2">Previous investigations of the pollination of sweet clover</td>
- <td class="tdr"><a href="#PREVIOUS_INVESTIGATIONS">2</a></td>
-</tr>
-<tr>
- <td class="tdl2">Outline of pollinating experiments</td>
- <td class="tdr"><a href="#OUTLINE_OF_POLLINATING">3</a></td>
-</tr>
-<tr>
- <td class="tdl2">Structure of the flowers of Melilotus alba</td>
- <td class="tdr"><a href="#STRUCTURE">4</a></td>
-</tr>
-<tr>
- <td class="tdl2">Development of the floral organs of sweet clover</td>
- <td class="tdr"><a href="#DEVELOPMENT_ORGANS">5</a></td>
-</tr>
-<tr>
- <td class="tdl2">Fertilization in Melilotus alba</td>
- <td class="tdr"><a href="#FERTILIZATION">8</a></td>
-</tr>
-<tr>
- <td class="tdl2">Development of the seed</td>
- <td class="tdr"><a href="#DEVELOPMENT_SEED">8</a></td>
-</tr>
-<tr>
- <td class="tdl2">Mature pollen of sweet clover</td>
- <td class="tdr"><a href="#MATURE_POLLEN">9</a></td>
-</tr>
-<tr>
- <td class="tdl2">Germination of the pollen</td>
- <td class="tdr"><a href="#GERMINATION">9</a></td>
-</tr>
-<tr>
- <td class="tdl2">Cross-pollination and self-pollination of sweet clover</td>
- <td class="tdr"><a href="#CROSS-POLLINATION">10</a></td>
-</tr>
-<tr>
- <td class="tdl2">Artificial manipulation of sweet-clover flowers</td>
- <td class="tdr"><a href="#ARTIFICIAL_MANIPULATION">10</a></td>
-</tr>
-<tr>
- <td class="tdl2">Seed production of Melilotus alba under&nbsp; ordinary field conditions</td>
- <td class="tdr"><a href="#SEED_PRODUCTION">13</a></td>
-</tr>
-<tr>
- <td class="tdl2">Efficiency of certain kinds of insects as pollinators of sweet clover</td>
- <td class="tdr"><a href="#EFFICIENCY_POLLINATORS">14</a></td>
-</tr>
-<tr>
- <td><div class="tdl2 hanging">Relation of the position of the flowers on Melilotus alba plants to seed production</div></td>
- <td class="tdr"><a href="#RELATION_OF_THE_POSITION">19</a></td>
-</tr>
-<tr>
- <td class="tdl2">Influence of the weather at blossoming time upon seed production</td>
- <td class="tdr"><a href="#INFLUENCE_WEATHER">20</a></td>
-</tr>
-<tr>
- <td class="tdl2">Insect pollinators of sweet clover</td>
- <td class="tdr"><a href="#INSECT_POLLINATORS">21</a></td>
-</tr>
-<tr>
- <td class="tdl2">Effect of moisture upon the production of Melilotus alba seed&nbsp;</td>
- <td class="tdr"><a href="#EFFECT_OF_MOISTURE">22</a></td>
-</tr>
-
-<tr>
- <td><div class="tdl hanging"><a href="#Part_II_STRUCTURE_AND_CHEMICAL_NATURE_OF_THE_SEED">Part II.</a>&mdash;Structure and Chemical
- Nature of the Seed Coat and its Relation to Impermeable Seeds of Sweet Clover.</div></td>
- <td></td>
-</tr>
-<tr>
- <td class="tdl2">Historical summary</td>
- <td class="tdr"><a href="#HISTORICAL_SUMMARY">26</a></td>
-</tr>
-<tr>
- <td class="tdl2">Material and methods</td>
- <td class="tdr"><a href="#MATERIAL_AND_METHODS">30</a></td>
-</tr>
-<tr>
- <td class="tdl2">Structure of the seed coat</td>
- <td class="tdr"><a href="#STRUCTURE_SEED_COAT">31</a></td>
-</tr>
-<tr>
- <td class="tdl2">Microchemistry of the seed coat</td>
- <td class="tdr"><a href="#MICROCHEMISTRY">33</a></td>
-</tr>
-<tr>
- <td class="tdl2">The seed coat in relation to the absorption of water</td>
- <td class="tdr"><a href="#ABSORPTION_OF_WATER">34</a></td>
-</tr>
-<tr>
- <td class="tdl2">A comparison of permeable and impermeable seed coats</td>
- <td class="tdr"><a href="#PERMEABLE_AND_IMPERMEABLE">34</a></td>
-</tr>
-<tr>
- <td class="tdl2">The action of sulphuric acid on the coats of impermeable seeds&nbsp;</td>
- <td class="tdr"><a href="#SULPHURIC_ACID">35</a></td>
-</tr>
-<tr>
- <td class="tdl">Literature Cited</td>
- <td class="tdr"><a href="#LITERATURE_CITED">36</a></td>
-</tr>
-</table>
-
-<div class="figcenter illowp86" id="logo1" style="max-width: 4.875em;">
- <img class="w100" src="images/logo1.png" alt="" />
-</div>
-
-
-<p class="tdc">WASHINGTON<br />
-GOVERNMENT PRINTING OFFICE<br />
-1920</p>
-
-</div>
-</div>
-
-
-
-<p><span class="pagenum"><a id="Page_1"></a>[Pg 1]</span></p>
-
-
-<div class="chapter">
-<table style="width:100%;" summary="header">
-<tr>
- <td class="bdl bdt bdr tdc" colspan="3">UNITED STATES DEPARTMENT OF AGRICULTURE</td>
-</tr>
-<tr>
- <td class="bdl">
- <div class="figcenter illowp88" id="logo2" style="max-width: 4.9375em;">
- <img class="w100" src="images/logo2.png" alt="" />
- </div>
- </td>
- <td><p class="caption1">BULLETIN No. 844</p>
- <p class="tdc">Contribution from the Bureau of Plant Industry<br />
- WM. A. TAYLOR, Chief</p></td>
- <td class="bdr">
- <div class="figcenter illowp86" id="logo3" style="max-width: 4.75em;">
- <img class="w100" src="images/logo3.png" alt="" />
- </div>
- </td>
-</tr>
-<tr>
- <td class="tdl bdt">Washington, D. C.</td>
- <td class="bdt">PROFESSIONAL PAPER</td>
- <td class="tdr bdt">August 11, 1920</td>
-</tr>
-</table>
-
-<h2 class="nobreak" id="SWEET-CLOVER_SEED">SWEET-CLOVER SEED</h2>
-</div>
-
-<h3>Part I.&mdash;Pollination Studies of Seed Production</h3>
-
-<h3>Part II.&mdash;Structure and Chemical Nature of the Seed Coat and
-its Relation to Impermeable Seeds of Sweet Clover</h3>
-
-
-<p class="ind2em">By <span class="smcap">H. S. Coe</span>, <i>formerly Assistant Agronomist, Office of Forage-Crop
-Investigations</i>, and <span class="smcap">J. N. Martin</span>, <i>Professor of Morphology
-and Cytology, Iowa State College</i>.</p>
-
-
-<hr class="r20" />
-
-<h2>CONTENTS</h2>
-
-<div style=" width: 600px; margin: 0 auto;">
-<table class="tblcont" summary="TOC">
-<tr>
- <td></td>
- <td class="tdr smaller">Page</td>
-</tr>
-<tr>
- <td><div class="tdl hanging"><a href="#Part_I_POLLINATION_STUDIES_OF_SEED_PRODUCTION">Part I.</a>&mdash;Pollination Studies of Seed Production.</div></td>
- <td></td>
-</tr>
-<tr>
- <td class="tdl2">Unsatisfactory yields of sweet-clover seed</td>
- <td class="tdr"><a href="#UNSATISFACTORY_YIELDS">1</a></td>
-</tr>
-<tr>
- <td class="tdl2">Previous investigations of the pollination of sweet clover</td>
- <td class="tdr"><a href="#PREVIOUS_INVESTIGATIONS">2</a></td>
-</tr>
-<tr>
- <td class="tdl2">Outline of pollinating experiments</td>
- <td class="tdr"><a href="#OUTLINE_OF_POLLINATING">3</a></td>
-</tr>
-<tr>
- <td class="tdl2">Structure of the flowers of Melilotus alba</td>
- <td class="tdr"><a href="#STRUCTURE">4</a></td>
-</tr>
-<tr>
- <td class="tdl2">Development of the floral organs of sweet clover</td>
- <td class="tdr"><a href="#DEVELOPMENT_ORGANS">5</a></td>
-</tr>
-<tr>
- <td class="tdl2">Fertilization in Melilotus alba</td>
- <td class="tdr"><a href="#FERTILIZATION">8</a></td>
-</tr>
-<tr>
- <td class="tdl2">Development of the seed</td>
- <td class="tdr"><a href="#DEVELOPMENT_SEED">8</a></td>
-</tr>
-<tr>
- <td class="tdl2">Mature pollen of sweet clover</td>
- <td class="tdr"><a href="#MATURE_POLLEN">9</a></td>
-</tr>
-<tr>
- <td class="tdl2">Germination of the pollen</td>
- <td class="tdr"><a href="#GERMINATION">9</a></td>
-</tr>
-<tr>
- <td class="tdl2">Cross-pollination and self-pollination of sweet clover</td>
- <td class="tdr"><a href="#CROSS-POLLINATION">10</a></td>
-</tr>
-<tr>
- <td class="tdl2">Artificial manipulation of sweet-clover flowers</td>
- <td class="tdr"><a href="#ARTIFICIAL_MANIPULATION">10</a></td>
-</tr>
-<tr>
- <td class="tdl2">Seed production of Melilotus alba under&nbsp; ordinary field conditions</td>
- <td class="tdr"><a href="#SEED_PRODUCTION">13</a></td>
-</tr>
-<tr>
- <td class="tdl2">Efficiency of certain kinds of insects as pollinators of sweet clover</td>
- <td class="tdr"><a href="#EFFICIENCY_POLLINATORS">14</a></td>
-</tr>
-<tr>
- <td><div class="tdl2 hanging">Relation of the position of the flowers on Melilotus alba plants to seed production</div></td>
- <td class="tdr"><a href="#RELATION_OF_THE_POSITION">19</a></td>
-</tr>
-<tr>
- <td class="tdl2">Influence of the weather at blossoming time upon seed production</td>
- <td class="tdr"><a href="#INFLUENCE_WEATHER">20</a></td>
-</tr>
-<tr>
- <td class="tdl2">Insect pollinators of sweet clover</td>
- <td class="tdr"><a href="#INSECT_POLLINATORS">21</a></td>
-</tr>
-<tr>
- <td class="tdl2">Effect of moisture upon the production of Melilotus alba seed&nbsp;</td>
- <td class="tdr"><a href="#EFFECT_OF_MOISTURE">22</a></td>
-</tr>
-
-<tr>
- <td><div class="tdl hanging"><a href="#Part_II_STRUCTURE_AND_CHEMICAL_NATURE_OF_THE_SEED">Part II.</a>&mdash;Structure and Chemical
- Nature of the Seed Coat and its Relation to Impermeable Seeds of Sweet Clover.</div></td>
- <td></td>
-</tr>
-<tr>
- <td class="tdl2">Historical summary</td>
- <td class="tdr"><a href="#HISTORICAL_SUMMARY">26</a></td>
-</tr>
-<tr>
- <td class="tdl2">Material and methods</td>
- <td class="tdr"><a href="#MATERIAL_AND_METHODS">30</a></td>
-</tr>
-<tr>
- <td class="tdl2">Structure of the seed coat</td>
- <td class="tdr"><a href="#STRUCTURE_SEED_COAT">31</a></td>
-</tr>
-<tr>
- <td class="tdl2">Microchemistry of the seed coat</td>
- <td class="tdr"><a href="#MICROCHEMISTRY">33</a></td>
-</tr>
-<tr>
- <td class="tdl2">The seed coat in relation to the absorption of water</td>
- <td class="tdr"><a href="#ABSORPTION_OF_WATER">34</a></td>
-</tr>
-<tr>
- <td class="tdl2">A comparison of permeable and impermeable seed coats</td>
- <td class="tdr"><a href="#PERMEABLE_AND_IMPERMEABLE">34</a></td>
-</tr>
-<tr>
- <td class="tdl2">The action of sulphuric acid on the coats of impermeable seeds&nbsp;</td>
- <td class="tdr"><a href="#SULPHURIC_ACID">35</a></td>
-</tr>
-<tr>
- <td class="tdl">Literature Cited</td>
- <td class="tdr"><a href="#LITERATURE_CITED">36</a></td>
-</tr>
-</table>
-</div>
-
-<hr class="r20" />
-
-<div class="chapter">
-<h2 class="nobreak" id="Part_I_POLLINATION_STUDIES_OF_SEED_PRODUCTION">Part I.&mdash;POLLINATION STUDIES OF SEED PRODUCTION.</h2>
-</div>
-
-
-<h3><a id="UNSATISFACTORY_YIELDS"></a>UNSATISFACTORY YIELDS OF SWEET-CLOVER SEED.</h3>
-
-<p>In some sections of the country much trouble has been experienced
-for a few years past in obtaining satisfactory yields of sweet-clover
-seed. This difficulty has been due for the most part to the following
-causes: (1) To cutting the plants at an improper stage of development,
-<span class="pagenum"><a id="Page_2"></a>[Pg 2]</span>
-(2) to the use of machinery not adapted to the handling of the
-crop, (3) to the shedding of immature pods, and (4) possibly to the
-lack of pollination. As the first two have been overcome, mainly
-because of a better understanding of the requirements for handling
-this crop, the subject matter of this bulletin is concerned primarily
-with the factors which produce the third and fourth causes.</p>
-
-<p>Where the production of seed was disappointing although the
-plants produced an abundance of flowers, it has been observed
-that many apparently were not fertilized, or if fertilized the pods
-aborted. In order to obtain data in regard to the causes of the
-failure of sweet clover to produce a normal seed yield, a study was
-made of the insects which were most active in pollinating the flowers,
-the source of the pollen necessary to effect fertilization, and the
-conditions under which the flowers must be pollinated in order to
-become fertilized. The relation of environmental conditions to the
-shedding of immature pods was also investigated. In order to
-overcome local environmental factors as much as possible, the
-experiments were conducted on the Government Experiment Farm
-at Arlington, Va., and in cooperation with the botanical department
-of the Iowa State College at Ames, Iowa.</p>
-
-
-<h3><a id="PREVIOUS_INVESTIGATIONS"></a>PREVIOUS INVESTIGATIONS OF THE POLLINATION OF SWEET CLOVER.</h3>
-
-<p>Since Darwin (<a href="#lit_4">4</a>, p. 360)<a id="FNanchor_1" href="#Footnote_1" class="fnanchor">[1]</a> published the statement that a plant of
-<i>Melilotus officinalis</i> protected from insect visitation produced but a
-very few seeds, while an unprotected plant produced many, other
-scientists have investigated this subject. Knuth (<a href="#lit_19">19</a>, v. 1, p. 37), in
-giving a list of the best known cases of self-sterility in plants, mentions
-<i>Melilotus officinalis</i>. The same author (<a href="#lit_19">19</a>, v. 2, p. 282) states
-that since the stigma projects beyond the anthers, automatic self-pollination
-is difficult, and for the same reasons Müller (<a href="#lit_29">29</a>, p. 180)
-believes that self-fertilization is not apt to occur.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_1" href="#FNanchor_1" class="label">[1]</a> The serial numbers in parentheses refer to "Literature cited," pages 36-38.</p></div>
-
-<p>In 1901 Kirchner (<a href="#lit_18">18</a>, p. 7) covered a number of <i>Melilotus alba</i>
-racemes with nets. On one of the plants 12 protected racemes
-produced 187 seeds and on another plant only one seed was obtained
-from 10 covered racemes. This experiment was duplicated in 1904,
-with the result that 40 netted racemes produced an average of 38 seeds
-each. Kirchner concluded from this experiment that spontaneous
-self-pollination occurs regularly even though the stigma projects
-above the anthers. He (<a href="#lit_18">18</a>, p. 8) also performed an experiment with
-<i>Melilotus officinalis</i> in 1901. At this time 16 isolated racemes produced
-a total of 11 seeds. This experiment was repeated in 1904,
-with the result that 16 protected racemes produced an average of 14
-seeds each. As the racemes on one of the plants that was protected
-<span class="pagenum"><a id="Page_3"></a>[Pg 3]</span>
-in 1904 died, Kirchner concluded that the flowers of <i>M. officinalis</i>
-were especially sensitive to inclosure in nets and that the failures to
-obtain more than a very few seeds on protected racemes in Darwin's
-experiment and in his first experiment were due to this cause.</p>
-
-<p>According to Kerner (<a href="#lit_17">17</a>, v. 2, p. 399) the peas and lentils (Pisum
-and Ervum) and the different species of horned clover and stone
-clover (Lotus and Melilotus) as well as the numerous species of the
-genus Trifolium and also many others produce seeds when insects
-are excluded from the plants, and only isolated species of these
-genera gave poor yields without insect visitation.</p>
-
-
-<h3><a id="OUTLINE_OF_POLLINATING"></a>OUTLINE OF POLLINATING EXPERIMENTS.</h3>
-
-<p>The yield of sweet-clover seed varies greatly from year to year in
-many parts of the United States. It has been assumed that this
-variation was due to climatic conditions, as excellent seed crops were
-seldom harvested in seasons of excessive rainfall or of prolonged
-drought just preceding or during the flowering period. The lack of
-a sufficient number of suitable pollinating insects also was thought
-to be an important factor in reducing seed production. This was
-especially true where the acreage of sweet clover was large and where
-few, if any, honeybees were kept.</p>
-
-<p>In order to obtain data upon the factors influencing the yield of
-seed, a series of experiments was outlined to determine (1) whether
-the flowers are able to set seed without the assistance of outside agencies,
-(2) whether cross-pollination is necessary, (3) the different kinds
-of insects which are active agents in pollinating sweet clover, and (4)
-whether a relation exists between the quantity of moisture in the soil
-and the production of seed.</p>
-
-<p>The racemes containing the flowers which were to be pollinated by
-hand were covered with tarlatan before any of the flowers opened and
-were kept covered except while being pollinated until the seeds were
-nearly mature. This cloth has about twice as many meshes to the
-linear inch as ordinary mosquito netting and served to exclude all
-insects that are able to pollinate the flowers. When entire plants
-were to be protected from all outside agencies, cages covered with
-cheesecloth, glass frames, or wire netting were used.</p>
-
-<p>A preliminary study of the pollination of <i>Melilotus alba</i> and <i>M. officinalis</i>
-showed that both were visited by the same kinds of insects
-and that both required the same methods of pollination in order to
-set seed. On this account <i>M. alba</i> was used in most of the experiments
-reported in this bulletin. Where <i>M. officinalis</i> was employed
-it is so stated.</p>
-
-<p><span class="pagenum"><a id="Page_4"></a>[Pg 4]</span></p>
-
-
-<h3><a id="STRUCTURE"></a>STRUCTURE OF THE FLOWERS OF MELILOTUS ALBA.</h3>
-
-<div class="figcenter illowp69" id="fig1" style="max-width: 26.9375em;">
- <img class="w100" src="images/fig1.png" alt="" />
- <div class="fig_caption2"><p><span class="smcap">Fig. 1.</span>&mdash;Different parts of the flower of <i>Melilotus alba</i>: 1, Side view of the flower; 2, side view of the flower
- with the carina and alæ slightly depressed; 3, side view of the flower, showing the carina and alæ depressed
- sufficiently to expose the staminal tube and the tenth free stamen; 4, ala; 5, ate and carina
- spread apart to show their relative position and shape; 6, flower after the petals have been removed,
- showing in detail the calyx and staminal tube; 7, the staminal tube split open to show the relative size
- and position of the pistil, <i>a</i>, Alæ; <i>b</i>, vexillum; <i>c</i>, carina; <i>d</i>, calyx; <i>c</i>, stigma; <i>b</i>, anthers: <i>g</i>, tenth free
- stamen; <i>h</i>, digitate process of the superior basal angle of an ala; <i>i</i>, depressions in the ala; <i>j</i>, staminal
- tube; <i>k</i>, pistil.</p></div>
-</div>
-
-<p>The racemes of <i>Melilotus alba</i> contain from 10 to 120 flowers with
-an average of approximately 50 per raceme for all of the racemes of
-a plant growing under cultivation in a field containing a good stand.</p>
-
-<p>The flower consists of a green, smooth, or slightly pubescent calyx
-with 5-pointed lobes and with an irregular white corolla of five petals.
-(<a href="#fig1">Fig. 1.</a>) The claws of the petals are not united nor are they attached
-to the staminal tube which is formed by the union of the filaments of
-the nine inferior stamens. As the claws of the alæ and carina are not
-<span class="pagenum"><a id="Page_5"></a>[Pg 5]</span>
-attacked to the staminal tube; the petals may be bent downward
-sufficiently far so that many different kinds of insects may secure
-without difficulty the nectar secreted around the base of the ovary.</p>
-
-<p>The fingerlike processes of the alæ are appressed closely to the
-carina, therefore the alæ are bent downward with the carina by
-insects. These processes grasp the staminal tube superiorly and
-tightly when the carina and alæ are in their natural positions, but
-when the carina is pressed downward by insects the fingerlike processes
-open slightly but not so far that they do not spring back to their
-original position when the pressure is
-removed. The staminal tube splits
-superiorly to admit the tenth free
-stamen. The filament of this superior
-stamen lies along the side of this
-staminal tube. The filaments of the
-nine stamens which compose the staminal tube separate in the hollow of the
-carina. All stamens bear fertile anthers. The pistil is in the staminal
-tube, the upper part of the style and
-stigma of which is inclosed with the
-anthers in the carina. The stigma
-is slightly above the stamens.</p>
-
-<p>An insect inserts its head into a
-sweet-clover flower between the vexillum and carina, the stigma, therefore,
-comes into direct contact with the
-head of the insect and cross-pollination
-is effected. At the same time the anthers brush against the insect, so that
-its head is dusted with pollen, to be
-carried to other flowers.</p>
-
-
-<h3><a id="DEVELOPMENT_ORGANS"></a>DEVELOPMENT OF THE FLORAL ORGANS OF SWEET CLOVER.</h3>
-
-<div class="figright illowp53" id="fig2" style="max-width: 10.8125em;">
- <img class="w100" src="images/fig2.png" alt="" />
- <div class="fig_caption2"><p><span class="smcap">Fig. 2.</span>&mdash;Lengthwise sectional view of a very
- young flower of <i>Melilotus alba</i>, showing the
- relative development of the stamens and
- pistil. In the upper set of stamens the divisions
- of the mother cells are completed,
- while division is just beginning in the
- lower set of stamens. In the ovules the
- outer integuments are well started on their
- development, <i>a</i>, Anther; <i>o</i>, ovule; <i>p</i>,
- pistil. × 38.</p></div>
-</div>
-
-<p>The stamens of <i>Melilotus alba</i> and <i>M. officinalis</i> may be divided
-into two sets, according to their length and time of development.
-(<a href="#fig2">Fig. 2.</a>) The longer set extends about the length of the anthers
-above the shorter set, and the pollen mother cells in the longer set
-divide to form pollen grains at least two days earlier than those in
-the shorter set. At the time the pollen mother cells divide, the
-longer set of stamens is approximately three-eighths of a millimeter
-in length and the pistil about half a millimeter long. The stigma
-and a portion of the style project beyond the stamens, and this relative
-position is maintained to maturity. The pollen mother cells
-undergo the reduction division while the megaspore mother cells are
-<span class="pagenum"><a id="Page_6"></a>[Pg 6]</span>
-just being differentiated and while the outer integuments are barely
-prominent at the base of the nucellus. The pollen grains are formed
-while the embryo sac is beginning to develop. The division of the
-megaspore mother cell does not occur until a number of days later,
-and the embryo sac is not mature until the flower is nearly ready to
-open. Thus, the pollen grains are formed a week to 10 days before
-the embryo sac is ready for fertilization. The pollen grains increase
-in size and undergo internal changes after their formation. These
-changes, which are not completed until the flower is one-half or more
-of its mature length, may be regarded as the ripening processes, and
-they are undoubtedly necessary before the pollen is capable of functioning.
-For this reason it is probable that the pollen grains are not
-able to function much before the embryo sac is mature.</p>
-
-<div class="figleft illowp100" id="fig3" style="max-width: 17.4375em;">
- <img class="w100" src="images/fig3.png" alt="" />
- <div class="fig_caption2"><p><span class="smcap">Fig. 3.</span>&mdash;Stigma at the time of pollination, showing its papillate
- character and the position of the pollen in reference to the papillæ
- in pollination. × 175.</p></div>
-</div>
-
-<p>The pistils of <i>Melilotus alba</i> and <i>M. officinalis</i> are straight for
-the greater part of
-their length, but curve
-rather abruptly toward
-the keel just below the
-capitate stigma. The
-surface of the stigma
-is papillate. (<a href="#fig3">Fig. 3.</a>)
-In their reaction with
-Sudan III, alkanin, and
-safranin the Walls of
-the papillæ of the stigma
-show that some fatlike substances are present. Aside from water,
-the contents of the papillæ consist chiefly of a fine emulsion of oil.</p>
-
-
-<h4>DEVELOPMENT OF THE OVULES.</h4>
-
-<p>The number of ovules in the ovary of <i>Melilotus alba</i> varies from
-two to five; however, most commonly, three or four ovules occur.
-In <i>Melilotus officinalis</i> the number in each ovary ranges from three
-to six. In both species the ovules are campylotropous at maturity
-with the micropylar end turned toward the base of the ovary.</p>
-
-<p>Mature ovules contain two integuments, but the inner one does
-not close entirely around the end of the nucellus. The outer integument
-develops considerably ahead of the inner one. The outer
-integument is much thickened at the micropylar end, the seed coat
-is formed from it, and the inner integument is used as nourishment
-by the endosperm and embryo.</p>
-
-<p>The number of megaspore mother cells in an ovule varies from
-one to many. Two or more embryo sacs often start to develop in
-the same ovule, but seldom more than one matures. (<a href="#plate1">Pl. I, figs. 1, 2, and 3.</a>)
-<span class="pagenum"><a id="Page_7"></a>[Pg 7]</span>
-In general, the development of the embryo sac proceeds
-in the ordinary way, as described by Young (<a href="#lit_44">44</a>, p. 133), with the
-inner megaspore functioning. (Text <a href="#fig4">fig. 4</a> and <a href="#plate2f1">Pl. II, fig. 1</a>.) In its
-development the nucellus is destroyed rapidly, the destruction being
-most rapid first at the micropylar end proceeding backward. The
-nucellus is completely destroyed at the micropylar end by the time
-the embryo sac is mature, and consequently the embryo sac comes in
-contact with the outer integument in this region. (<a href="#plate2f1">Pl. II, fig. 1.</a>)
-As the destruction of the nucellus extends toward the chalazal end
-the embryo sac becomes much elongated and tubelike. The antipodals
-disappear early, so that a mature embryo sac consists of the
-egg, the synergids, and the two polars. The two polars lie in contact
-in the micropylar end of
-the sac near the egg until
-fertilization.</p>
-
-<h4>STERILITY OF THE OVULES.</h4>
-
-<div class="figright illowp77" id="fig4" style="max-width: 16.75em;">
- <img class="w100" src="images/fig4.png" alt="" />
- <div class="fig_caption2"><p><span class="smcap">Fig. 4.</span>&mdash;Median section through an ovule, showing the embryo
- sac with four nuclei and the position of the integuments.
- × 150.</p></div>
-</div>
-
-<p>In <i>Melilotus alba</i> and <i>M. officinalis</i> there is very
-little tendency toward
-sterility of ovules. In an
-extended study of ovules
-developing under normal
-and under excessive moisture conditions only an
-occasional one was found
-in which no reproductive
-cells were differentiated,
-and no ovaries were found
-in which all of the ovules
-were sterile.</p>
-
-
-<h4>DEVELOPMENT OF THE POLLEN.</h4>
-
-<p>The pollen mother cells do not separate, but previous to the reduction
-division the protoplasm shrinks from the walls, thus forming a
-dense globular mass which often occupies less than half the lumen of
-the mother cell. (<a href="#plate1">Pl. I, fig. 4.</a>) Nuclear division occurs while they
-are in this contracted condition, and four nuclei are formed from two
-successive divisions. The cytoplasm is equally distributed around
-each nucleus. The four masses of protoplasm separate, and as they
-enlarge a number of times and develop into mature pollen grains they
-become binucleate, and a wall is gradually formed around each.
-(<a href="#plate1">Pl. I, figs. 5 and 6.</a>) At first the cytoplasm is quite dense and contains
-some starch but no fatty oils. However, the cytoplasm of
-<span class="pagenum"><a id="Page_8"></a>[Pg 8]</span>
-mature pollen grains is vacuolate, and it contains a fatty oil in the
-form of an emulsion. Soon after the pollen grains are formed, the
-walls of the mother cells disappear, thus permitting the pollen grains
-to lie loose in the anther.</p>
-
-
-<h3><a id="FERTILIZATION"></a>FERTILIZATION IN MELILOTUS ALBA.</h3>
-
-<p>The time intervening between pollination and fertilization was
-investigated with both self-pollinated and cross-pollinated flowers.
-In cross-pollination the parents were separate plants. This point
-was investigated with plants out of doors during the summer of 1916
-and with plants in the greenhouse during the following winter. The
-time elapsing between pollination and fertilization ranged from 50 to
-55 hours and was not longer in the case of self-pollinated than with
-cross-pollinated flowers. Furthermore, the rate of the development
-of the embryo in each kind of pollination was studied and was found
-to be as rapid in self-pollination as in cross-pollination. Therefore,
-self-pollination is apparently as effective as cross-pollination in
-<i>Melilotus alba</i> so far as the vigor of pollen tubes and the rate at which
-embryos develop are concerned. <i>Melilotus officinalis</i> was not studied
-in reference to this point.</p>
-
-<p>Considerable difference often exists in the size of the young embryos
-in the ovules of the same pod. This is due in part to a difference
-in the time of fertilization, although some of it is due to a difference
-in nourishment. It was observed that the ovule first fertilized
-might be an upper one, lower one, or any one between these. Occasionally
-one or more ovules are not fertilized.</p>
-
-
-<h3><a id="DEVELOPMENT_SEED"></a>DEVELOPMENT OF THE SEED.</h3>
-
-<p>A proembryo with a rather long suspensor is developed from the
-fertilized egg. (<a href="#plate2f2">Pl. II, fig. 2</a>). The endosperm, which quite early
-forms a peripheral layer around the entire embryo sac, develops most
-rapidly about the embryo, which soon becomes thoroughly embedded
-in it. (<a href="#plate3">Pl. III, figs. 1 and 2.</a>) After the embryo has used up the
-endosperm in the micropylar end and has enlarged so much as to
-occupy nearly all of the space in this region, the development of the
-endosperm becomes more active in the chalazal end, and when the
-embryo is mature there is very little endosperm left.</p>
-
-<p>The seed coat begins to form about the time of fertilization,
-although it apparently does not depend upon it, for in ovules where
-fertilization is prevented the outer integument undergoes the early
-modifications in the development of the seed coat before the ovule
-breaks down. The development of the seed coat is apparent first at
-the micropylar and chalazal ends, where the outer cells of the outer
-integument become much elongated and their outer walls thicken
-very soon after fertilization. The modifications in the development
-of the seed coat extend around the ovule from these points, involving
-at first only the outer or epidermal layer of cells which form the
-malpighian layer. Later, the cells just beneath the malpighian layer
-form the osteosclerid layer. Accompanying or closely following the
-formation of the osteosclerid cells, the remaining cell layers of the
-outer integument become modified into the nutritive and aleurone
-layer, and the seed coat is fully formed. Meantime the inner integument
-is practically all used as food.</p>
-
-
-<div class="bboxpl">
-<div class="tdr2"><a id="plate1"></a><span class="smcap">Plate I.</span></div>
-
-<div class="figcenter illowp64" style="max-width: 27.625em;">
- <img class="w100" src="images/plate1.png" alt="" />
-</div>
-
-<div class="fig_caption"><span class="smcap">Development of the Ovules and Pollen in Sweet Clover.</span></div>
-
-<div class="hanging2"><span class="smcap">Fig. 1.</span>&mdash;Section through the nucellus of an ovule of <i>Melilotus alba</i>, showing two megaspore mother cells.
-× 360. Fig. 2.&mdash;Median section through an ovule of <i>Melilotus alba</i>, showing the two cells resulting
-from the first division of the megaspore mother cell, and the relative development of the different
-parts of the ovule. × 300. Fig. 3.&mdash;Section through the nucellus of an ovule of <i>Melilotus alba</i>,
-showing two embryo sacs, one being more advanced than the other. × 360. Fig. 4.&mdash;Protoplasm of the
-pollen mother cell of <i>Melilotus alba</i> contracted and ready to undergo division. × 560. Fig. 5.&mdash;Pollen
-grains of <i>Melilotus alba</i> just formed, showing their dense cytoplasm and the presence of the mother-cell
-wall. × 560. Fig. 6.&mdash;<i>a</i>, Mature pollen grain of <i>Melilotus alba</i>, showing the binucleate condition
-at the time of shedding; <i>b</i>, surface view. × 560.</div>
-</div>
-
-
-<div class="bboxpl">
-<div class="tdr2"><a id="plate2"></a><span class="smcap">Plate II.</span></div>
-
-<div class="figcenter illowp98" id="plate2f1" style="max-width: 25.75em;">
- <img class="w100" src="images/plate2f1.png" alt="" />
-</div>
-
-<div class="fig_caption"><span class="smcap">Fig. 1.&mdash;Median Section through an Ovule of Melilotus alba.</span></div>
-
-<div class="hanging2">The embryo sac is shown ready for fertilization. The egg and synergids are in contact with the
-outer integument at the micropylar end. The remains of the antipodals may be seen at the
-chalazal end. × 180.</div>
-
-<div class="figcenter illowp100" id="plate2f2" style="max-width: 25.8125em;">
- <img class="w100" src="images/plate2f2.png" alt="" />
-</div>
-
-<div class="fig_caption"><span class="smcap">Fig. 2.&mdash;Section through an Ovule of Melilotus alba, about Three
-Days After Fertilization.</span></div>
-
-<div class="hanging2">The proembryo, the endosperm, and modifications of the integuments are shown. At this stage
-the suspensor prominent part of the proembryo, and the endosperm is most abundant around
-the embryo. The inner integument is being rapidly destroyed, and the outer integument is
-beginning to form the seed coat, as is indicated by the modifications in the outer layer of its cells,
-which are elongating and thickening their outer walls. × 33.</div>
-</div>
-
-
-<div class="bboxpl">
-<div class="tdr2"><a id="plate3"></a><span class="smcap">Plate III.</span></div>
-
-<div class="figcenter illowp100" id="plate3f1" style="max-width: 25.5em;">
- <img class="w100" src="images/plate3f1.png" alt="" />
-</div>
-
-<div class="fig_caption"><p><span class="smcap">Fig. 1.&mdash;Section of an Ovule of Melilotus alba after Fertilization.</span></p></div>
-
-<div class="hanging2">The stage of development is a little later than that shown in Plate II, figure 2. The embryo is
-embedded deeply in endosperm tissue. × 45.</div>
-
-<div class="figcenter illowp86" id="plate3f2" style="max-width: 24.4375em;">
- <img class="w100" src="images/plate3f2.png" alt="" />
-</div>
-
-<div class="fig_caption"><span class="smcap">Fig. 2.&mdash;Section through an Ovule of Melilotus alba after the Embryo
-is Nearly Half Mature.</span></div>
-
-<div class="hanging2">But little endosperm remains except in the chalazal end, and very little remains of either the
-nucellus or inner integument. The modifications which transform the outer integument into a
-seed coat are well under way. Not only the outer layer of cells which becomes the Malpighian
-layer is quite well modified, but also the layer beneath is being transformed into the osteosclerid
-layer. × 30.</div>
-</div>
-
-
-
-<div class="bboxpl">
-<div class="tdr2"><a id="plate4"></a><span class="smcap">Plate IV.</span></div>
-
-<div class="figcenter illowp45" style="max-width: 26.3125em;">
- <img class="w100" src="images/plate4.png" alt="" />
-</div>
-
-<div class="fig_caption"><span class="smcap">Stubble of Melilotus alba.</span></div>
-
-<div class="hanging2">These plants, which were cut 12 inches above the ground during rainy weather, had made a 40 to 42 inch
-growth. The stubble became infected at the top and the light-colored portions of them were killed by
-disease, thus checking the water supply to the growing branches above the infection.</div>
-</div>
-
-
-<p><span class="pagenum"><a id="Page_9"></a>[Pg 9]</span></p>
-
-
-<h3><a id="MATURE_POLLEN"></a>MATURE POLLEN OF SWEET CLOVER.</h3>
-
-<p>The pollen grains of <i>Melilotus alba</i> and of <i>M. officinalis</i> are quite
-similar. Each grain contains three germ pores, and when viewed
-so that the pores are visible they present a slightly angled appearance.
-The average dimensions of the pollen of <i>Melilotus alba</i> and of <i>M. officinalis</i>
-are 26 by 32 microns and 24 by 30 microns, respectively, when
-measured in the positions shown in <i>b</i> in <a href="#plate1">Plate I, figure 6</a>.</p>
-
-<p>The walls of the pollen grains have cutin deposited in them, as
-shown by their reactions with Sudan III, alkanin, safranin, and
-chloriodid of zinc. The contents of the pollen grains give a distinct
-reaction when tested for fat, and Millon's reagent shows that also
-some protein is present. Tests for sugars and starch showed that
-these substances are not present in perceptible quantities in mature
-pollen grains, although some starch is present in immature pollen.</p>
-
-
-<h3><a id="GERMINATION"></a>GERMINATION OF THE POLLEN.</h3>
-
-<p>The germination of the pollen of <i>Melilotus alba</i> permits considerable
-variation in moisture, as is illustrated in <a href="#Table_I">Table I</a>.</p>
-
-<p><a id="Table_I"></a><span class="smcap">Table I.</span>&mdash;<i>Germination of the pollen of Melilotus alba in water and in solutions of
-cane sugar of different strengths.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb" rowspan="2">Melilotus alba.</td>
- <td class="bdt bdb bdl" rowspan="2">Pure water.</td>
- <td class="bdt bdb bdl" colspan="8">Cane sugar in solution (per cent).</td>
-</tr>
-<tr>
- <td class="bdb bdl">8</td>
- <td class="bdb bdl">12</td>
- <td class="bdb bdl">18</td>
- <td class="bdb bdl">24</td>
- <td class="bdb bdl">30</td>
- <td class="bdb bdl">35</td>
- <td class="bdb bdl">45</td>
- <td class="bdb bdl">55</td>
-</tr>
-<tr>
- <td class="bdb">Germination of pollen per cent</td>
- <td class="bdb bdl">33</td>
- <td class="bdb bdl">23</td>
- <td class="bdb bdl">64</td>
- <td class="bdb bdl">46</td>
- <td class="bdb bdl">60</td>
- <td class="bdb bdl">46</td>
- <td class="bdb bdl">31</td>
- <td class="bdb bdl">22</td>
- <td class="bdb bdl">0</td>
-</tr>
-</table>
-
-<p>The results given in <a href="#Table_I">Table I</a> represent the average of 12 tests.
-Some of the pollen grains burst in pure water and in the weak cane
-sugar solutions, the percentage of bursting being greatest in pure
-water and decreasing as the percentage of sugar in the solution was
-increased. There was considerable variation in the percentages of
-germination in both water and in the solutions of different strengths,
-and at times there was very little bursting which was not accompanied
-by a high percentage of germination. The pollen tubes grew as
-rapidly in water as in any of the sugar solutions, some reaching a
-<span class="pagenum"><a id="Page_10"></a>[Pg 10]</span>
-length of 100 microns in six hours. As the pollen tubes made no
-more growth in the solutions of sugar than in water, it is evident
-that the sugar is not used as food, but helps in germination by reducing
-the rate at which water is absorbed.</p>
-
-<p>To judge from <a href="#Table_I">Table I</a>, the pollen of sweet clover can be effective
-not only under ordinary conditions but also when the flowers are
-wet with rain or dew or when the stigma is so dry that in order to
-obtain water from the papillæ the pollen must overcome a high resistance
-offered by the sap of the papillæ, a resistance that may be
-equal to the osmotic pressure of a 45 per cent solution of cane sugar.
-This is in accord with results obtained under field conditions; as
-flowers that were pollinated while rain was falling set seed satisfactorily,
-indicating that a high percentage of humidity in the atmosphere
-does not check the germination of the pollen sufficiently to interfere
-with fertilization. Neither was the setting of seed affected when the
-soil about the roots of plants was kept saturated with water, showing
-that the excessive quantity of water in the stigmas resulting from an
-abundance of water in the soil did not interfere with the fertilization
-of the flowers.</p>
-
-<p>No definite counts were made of the germination of the pollen of
-<i>Melilotus officinalis</i> in the solutions of cane sugar of different strengths,
-but observations show that the moisture requirement of the pollen
-of this species is approximately the same as that of <i>Melilotus alba</i>.</p>
-
-
-<h3><a id="CROSS-POLLINATION"></a>CROSS-POLLINATION AND SELF-POLLINATION OF SWEET CLOVER.</h3>
-
-<p>Results published by previous investigators on the cross-pollination
-and self-pollination of sweet clover do not agree. The experiments
-of Darwin (<a href="#lit_4">4</a>) show that the flowers are self-pollinated to
-only a small extent. On the other hand, Kirchner (<a href="#lit_18">18</a>) and Kerner
-(<a href="#lit_17">17</a>) find that self-pollination occurs generally and that cross-pollination
-is not necessary for the production of seed. However, all
-investigators agree that many different kinds of insects are able to
-pollinate sweet clover.</p>
-
-<p>Because of the diverse opinions as to the pollination of sweet clover,
-a number of experiments were conducted to determine (1) whether
-insect visitation was necessary to pollinate the flowers, (2) if necessary,
-whether the flowers must be cross-pollinated, and (3) what
-insects are active agents as pollinators of sweet clover.</p>
-
-<h3><a id="ARTIFICIAL_MANIPULATION"></a>ARTIFICIAL MANIPULATION OF SWEET-CLOVER FLOWERS.<a id="FNanchor_2" href="#Footnote_2" class="fnanchor">[2]</a></h3>
-
-<div class="footnote">
-
-<p><a id="Footnote_2" href="#FNanchor_2" class="label">[2]</a> The writers wish to acknowledge their indebtedness to Mr. Carl Kurtzweil for assistance in conducting
-part of the field experiments at Ames.</p></div>
-
-<p>Experiments were conducted to determine, if possible, the effect
-of various types of artificial manipulation of sweet-clover flowers
-when in full bloom on the production of seed. Only healthy, vigorous
-<span class="pagenum"><a id="Page_11"></a>[Pg 11]</span>
-plants growing on well-drained soil were selected for these experiments.
-Before any of the flowers were open, the individual
-racemes were covered with tarlatan and labeled. (<a href="#fig5">Fig. 5.</a>) As soon
-as part of the flowers opened, the racemes were uncovered and after
-removing all flowers that were not open the open flowers were pollinated
-and the racemes re-covered. If the flowers of sweet clover
-are not fertilized they will remain open for two to three days, then
-wither, and in a short time drop. But after being fertilized the ovules
-enlarge very rapidly, and the corollas usually drop in about seven
-or eight days. Therefore, all fertilized flowers can be distinguished
-a few days after fertilization has taken place. Counts were made of
-the number of pods which formed in 10 to 12 days after pollination.
-An outline of the experiments is given in Table II.</p>
-
-<div class="figcenter illowp90" id="fig5" style="max-width: 25.875em;">
- <img class="w100" src="images/fig5.png" alt="" />
- <div class="fig_caption2"><p><span class="smcap">Fig. 5.</span>&mdash;Individual racemes of white sweet clover covered with cheesecloth to protect them from insect
-visitation.</p></div>
-</div>
-
-<p><a id="Table_II"></a><span class="smcap">Table II.</span>&mdash;<i>Treatment of sweet-clover flowers in the artificial-manipulation experiments.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb">Experiment.</td>
- <td class="bdt bdb bdl">Method of pollinating the flowers.</td>
-</tr>
-<tr>
- <td>A</td>
- <td class="bdl">Check&mdash;covered.</td>
-</tr>
-<tr>
- <td>B</td>
- <td class="bdl">Check&mdash;open to insect visitation at all times.</td>
-</tr>
-<tr>
- <td class="vtop">C</td>
- <td class="bdl">A separate toothpick was used to spring the keel of each flower on the raceme.</td>
-</tr>
-<tr>
- <td>D</td>
- <td class="bdl">One toothpick was used to spring the keels of all the flowers on a raceme.</td>
-</tr>
-<tr>
- <td>E</td>
- <td class="bdl">Cross-pollinated.</td>
-</tr>
-<tr>
- <td class="bdb">F</td>
- <td class="bdb bdl">Raceme rolled several times between thumb and finger.</td>
-</tr>
-</table>
-
-
-<p><span class="pagenum"><a id="Page_12"></a>[Pg 12]</span></p>
-
-<p>As insects, and especially honeybees, usually visit all recently
-opened flowers on a raceme, experiments C and D were conducted to
-determine whether more seed would be produced when pollen from
-other flowers on the same raceme was placed on the stigmas of the
-flowers than when only the pollen produced by each flower was placed
-on its own stigma. The effect of pollination when only the pollen
-produced by an individual flower was placed on its own stigmas was
-also obtained in experiment F, as by this method of pollination no
-pollen was transferred from one flower to another. It can not be
-stated definitely that the seed produced by the cross-pollinated
-flowers was the result of fertilization with foreign pollen, as the
-anthers were not removed from the flowers pollinated because it
-would be necessary to remove the anthers when the flowers were not
-more than two-thirds mature, and in doing this the flowers would be
-so mutilated that only occasionally would pollination at this time
-or at a later date be effective. The flowers listed in experiment E
-were pollinated a short time before they opened, and in each case
-pollen taken from flowers of other plants was placed on the stigmas.
-The petals of the cross-pollinated flowers were not mutilated, and
-in each case they returned to their original positions soon after pollination.
-The results obtained in experiment B, where the racemes
-were simply labeled and left open to the action of insects at all times,
-serve for comparison with other experiments where the flowers were
-protected from insect visitation and were artificially manipulated.</p>
-
-<p>Martin (<a href="#lit_25">25</a>) found the setting of alfalfa seed and Westgate (<a href="#lit_40">40</a>)
-found the setting of red-clover seed to be affected by an excessive
-quantity of moisture in the soil or atmosphere. In order to overcome
-the possible effect of this or of other detrimental factors, in
-each experiment only the flowers on a certain number of racemes
-were pollinated at one time. All of the experiments were repeated a
-number of times during the months of July and August, 1916, and
-the results given in <a href="#Table_III">Table III</a> show the total number of flowers pollinated
-and the number of pods that formed during the two months.</p>
-
-<p>The results presented in <a href="#Table_III">Table III</a> show that flowers fertilized
-with pollen transferred from another plant produced a higher percentage
-of pods than any of the other treatments. The results obtained
-in experiment D, where the same toothpick was used to
-spring the keels of all the flowers on a raceme, show that this method
-of pollination produced an average of 7.24 pods per raceme more than
-the racemes in experiment C. where a separate toothpick was used
-for each flower. These results indicate that pollen transferred from
-one flower to another on the same raceme is more effective than when
-the pollen produced by an individual flower is used to fertilize its
-own stigma. However, the results of experiment C prove that self-pollination
-is effective in <i>Melilotus alba</i>. In experiment B. which
-<span class="pagenum"><a id="Page_13"></a>[Pg 13]</span>
-was the open check, 4.3 per cent more flowers set seed than on the
-racemes where the same toothpick was used to spring all the keels,
-but 11.57 per cent more seed was obtained than in experiment C.
-Spontaneous self-pollination occurs to only a very small extent, as
-will be seen from the results of experiment A, in which an average of
-only 2.9 per cent of the flowers set seed.</p>
-
-<p><a id="Table_III"></a><span class="smcap">Table III.</span>&mdash;<i>Effect of different types of artificial manipulation on the
-seed production of sweet clover at Arlington, Va., and at Ames, Iowa, in
-1916.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb" rowspan="2">Location.</td>
- <td class="bdt bdb bdl" rowspan="2">Experiment.</td>
- <td class="bdt bdb bdl" colspan="3">Total number of&mdash;</td>
- <td class="bdt bdb bdl" colspan="3">Flowers that set seed (per cent).</td>
-</tr>
-<tr>
- <td class="bdl bdb">Racemes.</td>
- <td class="bdl bdb">Flowers.</td>
- <td class="bdl bdb">Pods set.</td>
- <td class="bdl bdb">At each station.</td>
- <td class="bdl bdb" colspan="2">Average.</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Arlington</td>
- <td class="bdl">A</td>
- <td class="bdl">49</td>
- <td class="bdl">3,510</td>
- <td class="bdl">144</td>
- <td class="bdl">4.1</td>
- <td class="bdl" rowspan="2">}</td>
- <td rowspan="2">2.9</td>
-</tr>
-<tr>
- <td>Ames</td>
- <td class="bdl">A</td>
- <td class="bdl">84</td>
- <td class="bdl">4,536</td>
- <td class="bdl">92</td>
- <td class="bdl">2.0</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Arlington</td>
- <td class="bdl">B</td>
- <td class="bdl">100</td>
- <td class="bdl">5,599</td>
- <td class="bdl">3,973</td>
- <td class="bdl">70.95</td>
- <td class="bdl" rowspan="2">}</td>
- <td rowspan="2">66.51</td>
-</tr>
-<tr>
- <td>Ames</td>
- <td class="bdl">B</td>
- <td class="bdl">196</td>
- <td class="bdl">1,276</td>
- <td class="bdl">600</td>
- <td class="bdl">47.02</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Arlington</td>
- <td class="bdl">C</td>
- <td class="bdl">50</td>
- <td class="bdl">1,229</td>
- <td class="bdl">701</td>
- <td class="bdl">57.03</td>
- <td class="bdl" rowspan="2">}</td>
- <td rowspan="2">54.94</td>
-</tr>
-<tr>
- <td>Ames</td>
- <td class="bdl">C</td>
- <td class="bdl">75</td>
- <td class="bdl">289</td>
- <td class="bdl">133</td>
- <td class="bdl">46.02</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Arlington</td>
- <td class="bdl">D</td>
- <td class="bdl">50</td>
- <td class="bdl">1,480</td>
- <td class="bdl">936</td>
- <td class="bdl">63.24</td>
- <td class="bdl" rowspan="2">}</td>
- <td rowspan="2">62.18</td>
-</tr>
-<tr>
- <td>Ames</td>
- <td class="bdl">D</td>
- <td class="bdl">88</td>
- <td class="bdl">575</td>
- <td class="bdl">342</td>
- <td class="bdl">59.47</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Arlington</td>
- <td class="bdl">E</td>
- <td class="bdl">31</td>
- <td class="bdl">377</td>
- <td class="bdl">307</td>
- <td class="bdl">81.43</td>
- <td class="bdl" rowspan="2">}</td>
- <td rowspan="2">70.10</td>
-</tr>
-<tr>
- <td>Ames</td>
- <td class="bdl">E</td>
- <td class="bdl">48</td>
- <td class="bdl">175</td>
- <td class="bdl">80</td>
- <td class="bdl">45.71</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td class="bdb">Arlington</td>
- <td class="bdb bdl">F</td>
- <td class="bdb bdl">30</td>
- <td class="bdb bdl">933</td>
- <td class="bdb bdl">524</td>
- <td class="bdb bdl">56.16</td>
- <td class="bdb bdl" colspan="2">.........</td>
-</tr>
-</table>
-
-
-<h3><a id="SEED_PRODUCTION"></a>SEED PRODUCTION OF MELILOTUS ALBA UNDER ORDINARY FIELD CONDITIONS.</h3>
-
-<p>The production of seed of <i>Melilotus alba</i> under ordinary field conditions
-varies considerably, not only in different parts of the country
-but also on different fields in the same region. A number of factors
-contribute to this variation, one of the most important of which
-appears to be the inability of the plant to supply all the developing
-seed with sufficient moisture, causing some of them to abort. As
-pointed out on page 22 this condition was very marked in certain
-parts of the country in 1916. However, poor seed production is
-not always correlated with lack of moisture, for the seed crop was a
-failure in 1915, where cloudy and rainy weather prevailed much of
-the time the plants were in bloom. It is believed that the lack of
-pollination by insects was the principal cause for the failure of seed to
-set, as very few insects visit sweet-clover flowers when such conditions
-prevail. As sweet-clover pollen will germinate in pure water
-and as plants which have their roots submerged in water set seed
-abundantly when pollinated, the failure of the seed crop in 1915 was
-not due to excessive moisture.</p>
-
-<p>As a rule, thin stands of sweet clover produce more seed to the
-acre than thick stands and isolated plants more seed than those
-growing in either a thick or thin stand. The correlation of seed
-<span class="pagenum"><a id="Page_14"></a>[Pg 14]</span>
-production with the thickness of stand is probably due to the shading
-and partial prevention of insect visitation to part of the racemes on
-the lower branches. Most of the flowers upon the lower branches
-of isolated plants are directly exposed to sunlight and to insect visits:
-therefore the racemes on these branches produce as large a percentage
-of seed as the racemes on the upper branches. In a thick
-stand, little seed is produced by racemes on the lower branches.</p>
-
-<p>A plant approximately 3 feet high growing close to the center of a
-field at Arlington. Va., in which was an average stand of four sweet-clover
-plants to the square foot was selected in order to determine
-the number of racemes produced and the average number of seeds
-to the raceme. This plant produced 196 racemes, which contained
-an average of 20.4 pods each. The racemes varied from 2 to 10 cm.
-in length, and the number of pods to the raceme ranged from to 75.
-The racemes on the upper and most exposed portions of the plants
-were larger and the flowers produced a much higher percentage of
-pods than the racemes close to the bases of the larger branches.
-Many of the small racemes on the lower branches produced less than
-five pods each.</p>
-
-<p>The data obtained from the two plants at Arlington that were
-protected from night-flying insects may also be cited here, as the
-results of that experiment show that night-flying insects are not an
-important factor in the production of sweet-clover seed, and, further.
-because they were growing under the same conditions, in the same
-plat, and were approximately of the same size. These two plants
-produced a total of 544 racemes, with an average of 20.9 pods each.
-The number of pods to the raceme varied from to 86.</p>
-
-
-<h3><a id="EFFICIENCY_POLLINATORS"></a>EFFICIENCY OF CERTAIN KINDS OF INSECTS AS POLLINATORS OF SWEET CLOVER.</h3>
-
-<p>In order further to test the self-sterility of sweet clover and to determine
-the relative efficiency of night-flying and of different
-kinds of day-flying insects as pollinators of the flowers, a number of
-cages covered with cheesecloth, glass, or wire screen having 14
-meshes to the linear inch were placed over plants at Arlington. Va.,
-and at Ames. Iowa, in July and August. 1916. The bases of the
-cages were buried several inches in the ground, so that insects could
-not pass under them. Cheesecloth was used to cover most of the
-cages and was made into sacks of such a size that they could be put
-on or removed from the frames of the cages without difficulty. It
-was stretched tightly over the frames and fastened to their bases
-with laths.</p>
-
-<p>A cage having two sides and the top of glass but with ends covered
-with cheesecloth to permit ventilation was used at Ames to protect
-a number of plants from insect visitation at all times. The purpose
-<span class="pagenum"><a id="Page_15"></a>[Pg 15]</span>
-of this cage was to determine whether the partial shading of the
-plants in the cages covered with cheesecloth would have any effect
-upon the setting of seed.</p>
-
-<p>The cage covered with wire netting having 14 meshes to the linear
-inch was used to determine the efficiency as pollinators of sweet
-clover of insects so small that they could pass through openings of
-this size.</p>
-
-<p>The plants used in the experiments at Arlington were growing
-close to the center of a field of sweet clover. Volunteer plants in a
-field that contained only a scattering stand were used at Ames. The
-cages were placed over the plants in all of these experiments before
-any of the flowers opened, and the work was continued until they
-were through blooming.</p>
-
-<h4>PLANTS SUBJECT TO INSECT VISITATION AT ALL TIMES.</h4>
-
-<p>A plant subject to insect visits at all times and growing in the same
-plat as those inclosed in the cages at Arlington was selected as a
-check to those inclosed in the cages during their entire flowering
-period or for only a portion of it. This plant, which was in bloom at
-the same time as those inclosed in the cages, produced 196 racemes
-with an average of 20.4 pods each. As all of the racemes were collected
-and as those on the lower portions of the plant were smaller
-than those on the upper branches, the average number of seeds per
-raceme is much lower than it would have been if only the larger
-racemes had been collected.</p>
-
-<p>An isolated plant that was subject to insect visits at all times was
-selected for a check to the cage work conducted at Ames. This was
-necessary in order to get results that would be comparable with those
-obtained from the plants inclosed in the cages, as the cage experiments
-at Ames were conducted with isolated plants. The plant produced
-239 racemes, with an average of 41.6 pods.</p>
-
-<h4>PLANTS PROTECTED FROM INSECT VISITATION DURING THEIR ENTIRE FLOWERING
-PERIOD.</h4>
-
-<p>On July 3, 1916, a cage 3 feet square and 3&frac12; feet high, covered with
-cheesecloth, was placed over three sweet-clover plants at Arlington.
-(<a href="#fig6">Fig. 6.</a>) This cage was not opened until August 3, when practically
-all of the racemes had passed the flowering stage and the few seeds
-that formed on some of them were practically mature. The three
-plants inclosed in the cage produced 904 racemes, with an average
-of 0.63 pod each. No pods were produced on 594 racemes, while 150
-produced but one each. None of the racemes produced more than
-five pods.</p>
-
-<p><span class="pagenum"><a id="Page_16"></a>[Pg 16]</span></p>
-
-<p>This experiment was duplicated at Ames in August, 1916, with the
-result that the three protected plants produced a total of 776 racemes,
-with an average of 0.19 pod each.</p>
-
-<div class="figcenter illowp77" id="fig6" style="max-width: 18.4375em;">
- <img class="w100" src="images/fig6.png" alt="" />
- <div class="fig_caption2"><p><span class="smcap">Fig. 6.</span>&mdash;Cage covered with cheesecloth to protect
-plants from insect visitation.</p></div>
-</div>
-
-<p>The plants inclosed at Arlington produced 0.44 pod to the raceme
-more than the plants inclosed at Ames, and the average for the six
-plants at Arlington and at Ames is only 0.42 pod to the raceme.
-Results given below for nine plants inclosed in the glass-covered cage
-show that the pods
-produced per raceme
-by different plants
-varied from 0.1 to
-0.45, which is slightly
-less than the variation
-in the two cages
-covered with cheese-cloth.</p>
-
-<p>In order to determine
-whether the
-shading of the plants
-in the cheesecloth-covered
-cages had
-caused the production
-of seed to be reduced,
-a cage 4 feet
-wide, 4 feet high, and
-10 feet long, having
-glass sides and top,
-but with ends covered with cheesecloth to permit ventilation, was
-placed over nine plants at Ames in August, 1916. The results
-obtained in this experiment are presented in <a href="#Table_IV">Table IV</a>.</p>
-
-<p><a id="Table_IV"></a><span class="smcap">Table IV.</span>&mdash;<i>Production of sweet-clover seed by plants protected from
-insect visitation during their entire flowering period at Ames, Iowa,
-in 1916.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb">Plant.</td>
- <td class="bdt bdb bdl">Racemes per plant.</td>
- <td class="bdt bdb bdt bdl">Pods produced by all racemes.</td>
- <td class="bdt bdb bdl">Average number of pods to the raceme.</td>
-</tr>
-<tr>
- <td>No. 1</td>
- <td class="bdl">84</td>
- <td class="bdl">17</td>
- <td class="bdl">0.20</td>
-</tr>
-<tr>
- <td>No. 2</td>
- <td class="bdl">130</td>
- <td class="bdl">58</td>
- <td class="bdl">.44</td>
-</tr>
-<tr>
- <td>No. 3</td>
- <td class="bdl">166</td>
- <td class="bdl">30</td>
- <td class="bdl">.18</td>
-</tr>
-<tr>
- <td>No. 4</td>
- <td class="bdl">199</td>
- <td class="bdl">88</td>
- <td class="bdl">.44</td>
-</tr>
-<tr>
- <td>No. 5</td>
- <td class="bdl">243</td>
- <td class="bdl">35</td>
- <td class="bdl">.27</td>
-</tr>
-<tr>
- <td>No. 6</td>
- <td class="bdl">131</td>
- <td class="bdl">36</td>
- <td class="bdl">.27</td>
-</tr>
-<tr>
- <td>No. 7</td>
- <td class="bdl">119</td>
- <td class="bdl">13</td>
- <td class="bdl">.10</td>
-</tr>
-<tr>
- <td>No. 8</td>
- <td class="bdl">182</td>
- <td class="bdl">83</td>
- <td class="bdl">.45</td>
-</tr>
-<tr>
- <td>No. 9</td>
- <td class="bdl">340</td>
- <td class="bdl">142</td>
- <td class="bdl">.41</td>
-</tr>
-<tr>
- <td class="bdt">Total</td>
- <td class="bdt bdl">1,594</td>
- <td class="bdt bdl">592</td>
- <td class="bdt bdl">.......</td>
-</tr>
-<tr>
- <td class="bdb">Average</td>
- <td class="bdb bdl">.......</td>
- <td class="bdb bdl">.......</td>
- <td class="bdb bdl">.31</td>
-</tr>
-</table>
-
-
-<p>The results given in <a href="#Table_IV">Table IV</a> show that an average of 0.31 of a
-pod to the raceme was obtained from 1,594 racemes and that the
-variation in seed production of the different plants was from 0.1 to
-0.45 to the raceme. The average seed production for the nine plants
-<span class="pagenum"><a id="Page_17"></a>[Pg 17]</span>
-is 0.11 seed to the raceme less than the average results obtained from
-the six plants that were covered with cheesecloth. As this difference
-is well within the limit of variation for individual plants, it may be
-stated that the shading of the plants in the cheesecloth-covered cages
-did not reduce the production of seed. The results of this experiment
-show that spontaneous self-pollination does not occur regularly, as
-stated by Kirchner.</p>
-
-<h4>FLOWERS POLLINATED ONLY BY NIGHT-FLYING INSECTS.</h4>
-
-<p>In order to determine the importance of night-flying insects as
-pollinators, two cheesecloth-covered cages 3 feet square and 3&frac12; feet
-high were placed over sweet-clover plants at Arlington on July 10,
-1916. The covers of the cages were removed each evening at 7:30
-and replaced each morning at 4:30 o'clock. Practically all the
-flowers on these plants had bloomed by August 2, and the seed produced
-was nearly mature. The few racemes that contained opened
-flowers or buds were discarded. The three plants in one cage produced
-723 racemes, with an average of 3.76 pods each, while the one
-plant in the other cage produced 227 racemes, with an average of
-3.58 pods to the raceme. The four plants, therefore, produced a
-total of 950 racemes, with an average of 3.71 pods each. The only
-night-flying insect found working on sweet clover while these plants
-were in bloom was <i>Diacrisia virginica</i> Fabr.</p>
-
-<p>This experiment was duplicated at Ames in August, 1916, with the
-result that one plant subject to visitation only by night-flying insects
-produced 486 racemes, with an average of 16.5 pods each.</p>
-
-<p>The results obtained in these experiments show that night-flying
-insects were much more active in pollinating sweet clover at Ames
-than at Arlington. However, as the results obtained from the plants
-subject to visitation by day-flying insects only were practically the
-same as those obtained from plants which were subject to insect
-visitation at all times, it is concluded that night-flying insects were
-not a factor in the pollination of sweet clover at Arlington or at Ames
-in 1916.</p>
-
-<h4>FLOWERS POLLINATED ONLY BY DAY-FLYING INSECTS.</h4>
-
-<p>A cheesecloth-covered cage, 3 feet square and 3&frac12; feet high, was
-placed on July 7, 1916, over two sweet-clover plants at Arlington,
-before any of the flowers opened. As the cover of this cage was
-removed at 7.30 a. m. and replaced at 4.30 p. m. each day during the
-experiment, the plants were subject to visitation by day-flying
-insects only. As soon as all of the flowers on most of the racemes had
-bloomed, and before any mature pods shattered, the racemes were
-removed from the plants and the pods produced by each raceme
-counted. The two plants produced a total of 544 racemes, with an
-average of 20.9 pods each.</p>
-
-<p><span class="pagenum"><a id="Page_18"></a>[Pg 18]</span></p>
-
-<p>This experiment was also conducted at Ames. One plant was
-protected from insect visitation at night in August, 1916, with the
-result that it produced 418 racemes, with an average of 41.11 pods
-each.</p>
-
-<h4>PLANTS PROTECTED FROM ALL INSECTS THAT COULD NOT PASS THROUGH A WIRE
-SCREEN HAVING 14 MESHES TO THE LINEAR INCH.</h4>
-
-<p>It is well known that many small insects, and especially those
-belonging to the family Syrphidæ and to the genus Halictus, frequent
-sweet-clover flowers, but no records have been noted that show how
-important these insects are as pollinators of this plant. In order to
-obtain data on this subject a cage 12 feet square and 6&frac12; feet high,
-made of wire screen having 14 meshes to the linear inch, was placed
-over a few plants at Ames, in July, 1916, before they began to bloom.
-The base of the cage was buried several inches in the soil, so that no
-insects could get into it. As these plants were growing in a field
-where there was a sufficient supply of moisture at all times, they made
-a growth of 5 to 6 feet. For this reason all the racemes were collected
-from only a portion of one of the plants instead of from the entire
-plant, as was done with the smaller ones inclosed in the cheesecloth-covered
-cages. The branches selected contained 224 racemes, with
-an average of 24.53 pods each. Many insects that were able to pass
-through the wire netting were observed working on the flowers of the
-inclosed plants.</p>
-
-<p>A check plant, subject to visitation by all insects and growing
-within a few yards of the cage, contained 264 racemes, with an average
-of 28.23 pods each.</p>
-
-<p>This experiment shows that small insects are efficient pollinators
-of sweet clover and that the plant to which all insects had access
-produced an average of only 3.7 pods to the raceme more than the
-one inclosed in the cage. As these plants were growing close to a
-strip of timber and some distance from a field of sweet clover, it is
-probable that more small insects worked on the flowers than would
-have been the case if the cage had been located in the center of a
-field of sweet clover. Though these results show that small insects
-are able to pollinate sweet-clover flowers freely, it is very doubtful
-whether insects of this kind would be numerous enough to pollinate
-sufficient flowers in a large field of sweet clover for profitable seed
-production. The honeybee is the most efficient pollinator of this
-plant, and it is believed that in many sections it is responsible for the
-pollination of more than half of the flowers.</p>
-
-<h4>SUMMARY OF INSECT-POLLINATION STUDIES.</h4>
-
-<p>The data secured in the different experiments where sweet-clover
-flowers were subject to insect visitation at one time or another are
-presented in detail in <a href="#Table_V">Table V</a>.</p>
-
-<p><span class="pagenum"><a id="Page_19"></a>[Pg 19]</span></p>
-
-<p><a id="Table_V"></a><span class="smcap">Table V.</span>&mdash;<i>Summary of the insect pollination studies conducted
-at Arlington, Va., and Ames, Iowa, in 1916.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb" rowspan="2">Location.</td>
- <td class="bdt bdb bdl" rowspan="2">Number of plants.</td>
- <td class="bdt bdb bdl" rowspan="2">Method of treatment.</td>
- <td class="bdt bdb bdl" colspan="3">Number of&mdash;</td>
-</tr>
-<tr>
- <td class="bdb bdl">Racemes.</td>
- <td class="bdb bdl">Pods produced.</td>
- <td class="bdb bdl">Pods per raceme, average.</td>
-</tr>
-<tr>
- <td>Arlington.</td>
- <td class="bdl">1</td>
- <td class="bdl">Check&mdash;subject to insect visitation at all times.</td>
- <td class="bdl">196</td>
- <td class="bdl">4,013</td>
- <td class="bdl">20.47</td>
-</tr>
-<tr>
- <td>Ames.</td>
- <td class="bdl">1</td>
- <td class="bdl">do.</td>
- <td class="bdl">239</td>
- <td class="bdl">9,943</td>
- <td class="bdl">41.60</td>
-</tr>
-<tr>
- <td>Arlington.</td>
- <td class="bdl">3</td>
- <td class="bdl">Protected from all insects.</td>
- <td class="bdl">904</td>
- <td class="bdl">577</td>
- <td class="bdl">.63</td>
-</tr>
-<tr>
- <td>Ames.</td>
- <td class="bdl">12</td>
- <td class="bdl">do.</td>
- <td class="bdl">2,370</td>
- <td class="bdl">653</td>
- <td class="bdl">.27</td>
-</tr>
-<tr>
- <td>Arlington.</td>
- <td class="bdl">3</td>
- <td class="bdl">Visited by night-flying insects only (cage 1).</td>
- <td class="bdl">723</td>
- <td class="bdl">2,720</td>
- <td class="bdl">3.76</td>
-</tr>
-<tr>
- <td>Do.</td>
- <td class="bdl">1</td>
- <td class="bdl">Visited by night-flying insects only (cage 2).</td>
- <td class="bdl">227</td>
- <td class="bdl">152</td>
- <td class="bdl">.67</td>
-</tr>
-<tr>
- <td>Ames.</td>
- <td class="bdl">1</td>
- <td class="bdl">Visited by night-flying insects only.</td>
- <td class="bdl">486</td>
- <td class="bdl">8,024</td>
- <td class="bdl">16.51</td>
-</tr>
-<tr>
- <td>Arlington.</td>
- <td class="bdl">2</td>
- <td class="bdl">Visited by day-flying insects only.</td>
- <td class="bdl">544</td>
- <td class="bdl">11,397</td>
- <td class="bdl">20.95</td>
-</tr>
-<tr>
- <td>Ames.</td>
- <td class="bdl">1</td>
- <td class="bdl">do.</td>
- <td class="bdl">418</td>
- <td class="bdl">17,186</td>
- <td class="bdl">41.11</td>
-</tr>
-<tr>
- <td class="bdb">Do.</td>
- <td class="bdb bdl">9</td>
- <td class="bdb bdl">Protected from all insects.</td>
- <td class="bdb bdl">1,594</td>
- <td class="bdb bdl">502</td>
- <td class="bdb bdl">.31</td>
-</tr>
-</table>
-
-<p>The results in <a href="#Table_V">Table V</a> show that an average of 0.37 pod to the
-raceme was obtained from the plants protected from visitation by all
-insects during the flowering period. As the racemes of <i>Melilotus
-alba</i> will average approximately 50 flowers each, less than 1 per cent
-of them set seed without being pollinated by insects. The results
-obtained in the cages in which only night-flying insects had access to
-the flowers show that these insects pollinate sweet clover to a slight
-extent, but that the number of pods produced by them is so few that
-it may be assumed that these flowers would have been pollinated by
-day-flying insects. This assumption is borne out by the results
-obtained in the cages where only day-flying insects had access to the
-flowers, as the results obtained in these cages at Arlington and Ames,
-respectively, are approximately the same as those obtained on the
-plants subject to insect visitation at all times. It will be noted that
-the yield of seed on the plants visited by insects at Ames is much
-higher than that of the plants subjected to insect visits during the
-same period at Arlington. This difference in seed yield may be
-attributed to the fact that isolated plants were used in the experiments
-at Ames, and at Arlington the experiments were conducted
-with plants growing under field conditions.</p>
-
-
-<h3><a id="RELATION_OF_THE_POSITION"></a>RELATION OF THE POSITION OF THE FLOWERS ON MELILOTUS ALBA
-PLANTS TO SEED PRODUCTION.</h3>
-
-<p>Observations of sweet-clover plants grown under cultivation, and
-especially when the stands were thick, showed that the flowers of the
-racemes on the upper and exposed branches produced a larger percentage
-of seed than those on the lower branches which were less
-exposed. It is thought by some that the failure of the flowers on the
-lower racemes to be fertilized is due to shading; but the results obtained
-in the cheesecloth and glass covered cages do not warrant this
-<span class="pagenum"><a id="Page_20"></a>[Pg 20]</span>
-belief, as it is doubtful whether the shading of the flowers on the
-lower racemes is more than that caused by the cheesecloth. It is
-probably the lack of pollination that causes this decrease in seed production
-on the lower branches of plants growing close together, as a
-vast number of flowers open each day on portions of the plants which
-are exposed directly to visitation by insects and are therefore more
-accessible to them.</p>
-
-<p>In order to obtain information upon the number of flowers that
-produce seed on the upper and lower portions, respectively, of sweet-clover
-plants when grown under field conditions and where the stand
-contained four to five plants to the square foot, a number of racemes
-were labeled on different portions of the plants at Ames in 1915 and
-1916. When the pods were partly mature, records were made of the
-number of flowers that produced pods. The results obtained are
-given in <a href="#Table_VI">Table VI</a>.</p>
-
-<p><a id="Table_VI"></a><span class="smcap">Table VI.</span>&mdash;<i>Relation of the position of sweet-clover flowers on the plants
-to seed production, at Ames, Iowa, in 1915 and 1916.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb" rowspan="2">Year.</td>
- <td class="bdt bdb bdl" rowspan="2">Position of the flowers.</td>
- <td class="bdt bdb bdl" rowspan="2">Number of flowers.</td>
- <td class="bdt bdb bdl" colspan="4">Pods formed.</td>
-</tr>
-<tr>
- <td class="bdb bdl">Number.</td>
- <td class="bdb bdl">Percentage.</td>
- <td class="bdb bdl" colspan="2">Average.</td>
-</tr>
-<tr>
- <td>1915</td>
- <td class="bdl">Upper half of plants</td>
- <td class="bdl">812</td>
- <td class="bdl">357</td>
- <td class="bdl">43.9</td>
- <td class="bdl" rowspan="2"><span class="fnsz2">}</span></td>
- <td rowspan="2">42.6</td>
-</tr>
-<tr>
- <td>1916</td>
- <td class="bdl">do</td>
- <td class="bdl">261</td>
- <td class="bdl">101</td>
- <td class="bdl">38.7</td>
-</tr>
-<tr>
- <td>&nbsp;</td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>1915</td>
- <td class="bdl">Lower half of plants</td>
- <td class="bdl">344</td>
- <td class="bdl">44</td>
- <td class="bdl">12.7</td>
- <td class="bdb bdl" rowspan="2"><span class="fnsz2">}</span></td>
- <td class="bdb" rowspan="2">18.3</td>
-</tr>
-<tr>
- <td class="bdb">1916</td>
- <td class="bdb bdl">do</td>
- <td class="bdb bdl">216</td>
- <td class="bdb bdl">59</td>
- <td class="bdb bdl">27.3</td>
-</tr>
-</table>
-
-<p>The flowers on the upper racemes of the plants produced 31.2 per
-cent more pods than those on the lower racemes in 1915. and 11.4 per
-cent more in 1916. These results prove that insects more frequently
-visit the flowers that are directly exposed and are therefore more
-accessible.</p>
-
-<h3><a id="INFLUENCE_WEATHER"></a>INFLUENCE OF THE WEATHER AT BLOSSOMING TIME UPON SEED PRODUCTION.</h3>
-
-<p>The seed production of sweet clover is seldom satisfactory when
-rainy or muggy weather prevails during the flowering period. In
-order to obtain data as to the relation existing between the visits of
-insects and the prevailing weather conditions, a record of insect visits
-and of the number of flowers that opened each day was kept for a
-period of nine days at Ames in August, 1915.</p>
-
-<p>In this experiment the racemes were marked early each morning
-just above the last flowers which had opened the previous day, and
-early the following morning the number of flowers which had opened
-the previous day was noted. The number of flowers that were pollinated
-was determined by the number of pods that formed. <a href="#Table_VII">Table
-VII</a> gives in detail the results obtained.</p>
-
-<p><span class="pagenum"><a id="Page_21"></a>[Pg 21]</span></p>
-
-<p><a id="Table_VII"></a><span class="smcap">Table VII.</span>&mdash;<i>Influence of the weather at blossoming time upon the yield of sweet -clover
-seed, at Ames. Iowa, in 1915.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb">Date, 1915.</td>
- <td class="bdt bdb bdl">Weather conditions.</td>
- <td class="bdt bdb bdl" colspan="2">Insect visitors.</td>
- <td class="bdt bdb bdl">Number of flowers that opened.</td>
- <td class="bdt bdb bdl">Pods formed.</td>
- <td class="bdt bdb bdl">Percentage of flowers that matured.</td>
-</tr>
-<tr>
- <td>Aug. 16</td>
- <td class="bdl">Cloudy and showery</td>
- <td class="bdl"></td>
- <td>Very few</td>
- <td class="bdl">102</td>
- <td class="bdl">18</td>
- <td class="bdl">17.6</td>
-</tr>
-<tr>
- <td>Aug. 17</td>
- <td class="bdl">Rain all day</td>
- <td class="bdl"></td>
- <td>None</td>
- <td class="bdl">69</td>
- <td class="bdl">4</td>
- <td class="bdl">5.7</td>
-</tr>
-<tr>
- <td>Aug. 18</td>
- <td class="bdl">Cloudy most of the day</td>
- <td class="bdl"></td>
- <td>Very few</td>
- <td class="bdl">60</td>
- <td class="bdl">20</td>
- <td class="bdl">33.3</td>
-</tr>
-<tr>
- <td>Aug. 19</td>
- <td class="bdl">Clear and cool</td>
- <td class="bdl"></td>
- <td>Numerous</td>
- <td class="bdl">94</td>
- <td class="bdl">53</td>
- <td class="bdl">56.3</td>
-</tr>
-<tr>
- <td>Aug. 20</td>
- <td class="bdl">Mostly clear and warm</td>
- <td class="bdl"></td>
- <td>do</td>
- <td class="bdl">61</td>
- <td class="bdl">38</td>
- <td class="bdl">62.2</td>
-</tr>
-<tr>
- <td>Aug. 21</td>
- <td class="bdl">Clear and warm</td>
- <td class="bdl"></td>
- <td>do</td>
- <td class="bdl">81</td>
- <td class="bdl">44</td>
- <td class="bdl">54.3</td>
-</tr>
-<tr>
- <td>Aug. 22</td>
- <td class="bdl">Partly cloudy and warm</td>
- <td class="bdl fnsz2" rowspan="2">}</td>
- <td rowspan="2">do</td>
- <td class="bdl" rowspan="2">181</td>
- <td class="bdl" rowspan="2">100</td>
- <td class="bdl" rowspan="2">55.2</td>
-</tr>
-<tr>
- <td>Aug. 23</td>
- <td class="bdl">do</td>
-</tr>
-<tr>
- <td class="bdb">Aug.&nbsp;24</td>
- <td class="bdb bdl">Cloudy till mid-afternoon</td>
- <td class="bdb bdl"></td>
- <td class="bdb">Few</td>
- <td class="bdb bdl">37</td>
- <td class="bdb bdl">12</td>
- <td class="bdb bdl">32.4</td>
-</tr>
-</table>
-
-<p>The data given in <a href="#Table_VII">Table VII</a> show that the percentage of effective
-pollination is much higher in clear weather, when insects are active,
-than in cloudy or rainy weather, when but few insects visit the
-flowers.</p>
-
-
-<h3><a id="INSECT_POLLINATORS"></a>INSECT POLLINATORS OF SWEET CLOVER.</h3>
-
-<p>On account of the ease with which the heavy flow of nectar of
-sweet-clover flowers may be obtained many insects visit the flowers,
-thereby pollinating them. While the useful insect visitors of flowers
-of red clover are limited to a few species of Hymenoptera, those
-pollinating sweet-clover blossoms are many and belong to such
-orders as Coleoptera, Lepidoptera, and Diptera, as well as to the
-Hymenoptera. However, in the United States the honeybee is the
-most important pollinator of sweet clover. In many parts of the
-country the different species of Halictus, commonly known as sweat
-bees, rank next in importance. The margined soldier beetles
-(<i>Chauliognathus marginatus</i> Fabr.) were very active pollinators at
-Arlington, Va., in the latter part of June and first part of July, 1916,
-but the woolly bear (<i>Diacrisia virginica</i> Fabr.) was the only night-flying
-insect found working on sweet clover at Arlington.</p>
-
-<p>Insects belonging to the genera Halictus, Syritta, and Paragus
-were very active pollinators at Ames, Iowa, in 1916, and ranked
-next in importance to the honeybee. In fact, the results obtained
-in the cage where the plants were protected from visitation by
-insects that could not pass through a screen having 14 meshes to
-the linear inch showed that these small insects were able under
-the conditions of that experiment to pollinate practically as many
-flowers as larger insects.</p>
-
-<p>The insects listed below were collected while visiting <i>Melilotus
-alba</i> and <i>M. officinalis</i> flowers in 1916.</p>
-
-<p><span class="pagenum"><a id="Page_22"></a>[Pg 22]</span></p>
-
-
-<p>AT ARLINGTON, VA.</p>
-
-<div class="blockquot">
-
-<p><i>Neuroptera.</i>&mdash;<i>Perithemis domitia</i> Dru., <i>Enallagma</i> sp.</p>
-
-<p><i>Hemiptera.</i>&mdash;<i>Adelphocoris rapidus</i> Say, <i>Lygus pratensis</i> Linn, (tarnished plant
-bug).</p>
-
-<p><i>Coleoptera.</i>&mdash;<i>Chauliognathus marginatus</i> Fabr. (margined soldier beetle), <i>Diabrotica
-12-punctata</i> Oliv. (southern corn rootworm).</p>
-
-<p><i>Lepidoptera.</i>&mdash;<i>Pieris protodice</i> Bd. (imported cabbage butterfly), <i>Heodes hypophleas</i>
-Bd., <i>Lycaena comyntas</i> Gdt., <i>Hylephila campestris</i> Bd., <i>Scepsis fulvicollis</i> Hubn.,
-<i>Ancyloxypha numitor</i> Fabr., <i>Pholisora catullus</i> Fabr., <i>Pyraustid</i> sp., <i>Loxostege similalis</i>
-Gn. (garden webworm), <i>Thecla melinus</i> Hubn., <i>Colias philodice</i> Gdt. (the common
-sulphur butterfly), <i>Tarachidia caudefactor</i> Hubn., <i>Pyrameis atalanta</i> Linn., Drasteria
-(2 species), <i>Diacrisia virginica</i> Fabr. (the woolly bear).</p>
-
-<p><i>Hymenoptera.</i>&mdash;<i>Halictus lerouxi</i> Lep., <i>H. provancheri</i> (sweat bee), <i>H. pectoralis</i>
-Sm. (sweat bee), Halictus (3 unidentified species), <i>H. legatus</i> Say, <i>Bombus affinis</i>
-Cr., <i>B. impatiens</i> Harris (bumblebee), <i>Melissodes bimaculata</i> Lep., <i>Polistes pallipes</i>
-Lep. (paper wasp), <i>Megachile</i> sp. (leaf-cutter bee), <i>Coelioxys octodentata</i> Say, <i>Xylocopa
-virginica</i> Drury (common carpenter bee), <i>Pompiloides</i> sp., <i>Apis mellifica</i> Linn, (honeybee),
-<i>Philanthus punctatus</i> Say, <i>Sphex nigricans</i> Dahlb. (caterpillar hawk), <i>S. pictipennis</i>
-Walsh (caterpillar hawk).</p>
-
-<p><i>Diptera.</i>&mdash;<i>Archytas analis</i> Fabr., <i>Chrysomyia macellaria</i> Fabr. (screw-worm fly),.
-<i>Pollenia rudis</i> Fabr. (cluster fly), <i>Ocyptera carolinae</i> Desv., <i>Trichophora ruficauda</i>
-V. D. W., <i>Eristalis arbustorum</i> Linn., <i>Physocephala tibialis</i> Say.</p></div>
-
-
-<p>AT AMES, IOWA.</p>
-
-<div class="blockquot">
-
-<p><i>Hemiptera.</i>&mdash;<i>Lygus pratensis</i> Linn., <i>Adelphocoris rapidus</i> Say,</p>
-
-<p><i>Coleoptera.</i>&mdash;<i>Coccinella transversoguttata</i> Fabr.</p>
-
-<p><i>Lepidoptera.</i>&mdash;<i>Eurymus eurytheme</i> Bdv., <i>Chrysophanus</i> sp., Lycaena (2 species),.
-<i>Libythea bachmani</i> Kirtland, <i>Pieris rapae</i> Linn.</p>
-
-<p><i>Hymenoptera.</i>&mdash;<i>Angochlora</i> sp., <i>Apis mellifica</i> Linn., <i>Colletes</i> sp., <i>Halictus lerouxi</i>
-Lep., <i>H. provancheri</i> D. J., <i>Halictus</i> sp., <i>Elis</i> sp., <i>Calliopsis andreniformis</i> Smith, <i>Polistes</i>
-sp., <i>Sphex</i> sp., <i>Eumenes fraterna</i> Say, <i>Sceliphron</i> sp., <i>Isodontia harrisi</i>, Fern., <i>Cerceris</i>
-sp., <i>Oxybelus</i> sp.</p>
-
-<p><i>Diptera.</i>&mdash;<i>Syritta</i> sp., <i>Paragus</i> sp., <i>Chrysomyia macellaria</i> Desv., Syrphidæ (2 unidentified
-specimens).</p></div>
-
-
-<h3><a id="EFFECT_OF_MOISTURE"></a>EFFECT OF MOISTURE UPON THE PRODUCTION OF MELILOTUS ALBA SEED.</h3>
-
-<p>Careful inspection of a number of sweet-clover fields in Iowa and
-Illinois in the autumn of 1916 indicated that many plants were
-unable to obtain sufficient moisture for the proper development of
-their flowers. Examination of flowers that aborted shortly after
-reaching their mature size showed that the anther sacs had not
-burst, even though the pollen grains were mature. Apparently for
-the same reason many immature pods aborted. The precipitation
-for July, 1916, in Livingston County, Ill., where the sweet-clover
-seed crop suffered materially for lack of moisture, was 3.2 inches less
-than normal, while the temperature was 4.5° F. above normal. In
-August the precipitation was 0.96 of an inch below normal and the
-temperature 4.2° F. above normal. At Ames, Iowa, the precipitation
-was 3.54 inches below normal and the temperature 5.4° F. above
-<span class="pagenum"><a id="Page_23"></a>[Pg 23]</span>
-normal in July. Both the precipitation and temperature were about
-normal at Ames in August, but most of the precipitation fell before
-the experiments were commenced.</p>
-
-<p>In north-central Illinois the seed production of sweet clover was
-very irregular. Some fields produced an abundance of seed, while a
-large percentage of the pods on the plants in other fields near by,
-where the thickness of the stand, size of the plants, and conditions
-in general were approximately the same, aborted. It was evident
-that all stands producing a good seed crop were growing on well-drained
-soil and that those which were not yielding satisfactorily
-were on poorly drained land. It is well known that sweet clover
-will produce deep taproots only when the plants are growing in
-well-drained soil and that a much-branched surface root system will
-be formed on poorly drained land, and especially when there is an
-excess of moisture or a high water table during the first season's
-growth. During this droughty period in 1916 the upper layer of soil
-became so depleted of moisture that the plants with surface root
-systems were unable to obtain sufficient water to mature their seed.
-On the other hand, the lack of precipitation and the high temperatures
-did not affect the moisture content of the subsoil sufficiently
-to interfere with the normal seed production of deep-rooted plants.
-According to Lutts (<a href="#lit_22">22</a>, p. 47) this same condition was found to be
-true in Ohio in 1916.</p>
-
-<p>As a rule, under droughty conditions the second crop of sweet
-clover will produce a higher yield of seed than the first crop, as the
-second growth of the plants is seldom more than half as much as the
-first, thereby requiring less moisture. However, if showery hot
-weather prevails when the first crop is cut, the end of each stub is
-very apt to become infected, usually with a species of Fusarium,
-which kills all the cortex as far back as the upper bud or young shoot
-and that part of it on the opposite side of this bud to the bud below.
-If the second bud from the top of a stub is not directly opposite the
-upper one the decay may extend nearly to the ground. (<a href="#plate4">Pl. IV.</a>)
-The destruction of half to two-thirds of the cortex from 2 to 4 inches
-below the upper bud materially reduces the quantity of water that
-can be conveyed to the branch above the base of the dead area.
-Plants thus infected obtain sufficient moisture for seed production
-only under the most favorable conditions. When the first crop is
-cut during warm dry weather, and especially when the first crop has
-not been permitted to make more than a 30 to 32 inch growth, the
-stubble seldom decays, and in no instance have the plants been
-observed to decay as far back as the upper buds.</p>
-
-<p>An experiment was conducted at Ames in the latter part of August
-and first part of September, 1916, to determine the effect of watering
-plants that were aborting a large percentage of their flowers and
-<span class="pagenum"><a id="Page_24"></a>[Pg 24]</span>
-immature pods. For this purpose several volunteer plants growing
-in a meadow were selected. A hole 12 inches square and 14 inches
-deep was dug 8 inches from the crown of one plant, and each evening
-during the experiment 2 gallons of water were poured into the hole.
-The top of the hole was kept covered, so as to check evaporation from
-it as much as possible. Another plant of the same size and growing
-about 15 yards from the watered plant served as a check. On both
-plants many of the flowers and immature buds were aborting at the
-beginning of the experiment. The soil in this field was so depleted
-of moisture that the leaves of the plants wilted during the hottest
-part of the days preceding the experiment. The foliage on the check
-plant wilted each day for the first five days of the experiment. On the
-sixth day 0.96 of an inch of rain fell and four days later 0.23 of an
-inch more. The dropping of the flowers was temporarily checked by
-these precipitations, but owing to the dry, compact condition of the
-soil the rain was not sufficient to check entirely the fall of flowers and
-immature pods. At the beginning of the experiment the racemes on
-both plants were divided into three classes, according to the development
-of the flowers, and labeled. They were collected and the seeds
-counted as soon as the pods at the bases of the racemes commenced
-to turn brown. <a href="#Table_VIII">Table VIII</a> presents the results obtained.</p>
-
-<p><a id="Table_VIII"></a><span class="smcap">Table VIII.</span>&mdash;<i>Effect of water upon the seed production of sweet clover when growing
-under droughty conditions at Ames, Iowa, in 1916.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb" rowspan="2">Stage of development when labeled.</td>
- <td class="bdt bdb bdl" colspan="2">Plant not watered.</td>
- <td class="bdt bdb bdl" colspan="2">Plant watered.</td>
- <td class="bdt bdb bdl" rowspan="2">Increase from watering.</td>
-</tr>
-<tr>
- <td class="bdb bdl">Number of racemes labeled.</td>
- <td class="bdb bdl">Average number of pods per raceme that matured.</td>
- <td class="bdb bdl">Number of racemes labeled.</td>
- <td class="bdb bdl">Average number of pods per raceme that matured.</td>
-</tr>
-<tr>
- <td>Flowers at the base of the racemes just ready to open.</td>
- <td class="bdl">49</td>
- <td class="bdl">27.39</td>
- <td class="bdl">110</td>
- <td class="bdl">55.63</td>
- <td class="bdl">28.24</td>
-</tr>
-<tr>
- <td>&nbsp;</td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Pods 3 to 6 days old</td>
- <td class="bdl">30</td>
- <td class="bdl">21.13</td>
- <td class="bdl">112</td>
- <td class="bdl">39.81</td>
- <td class="bdl">18.68</td>
-</tr>
-<tr>
- <td>&nbsp;</td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Pods 9 to 12 days old</td>
- <td class="bdl">35</td>
- <td class="bdl">15.23</td>
- <td class="bdl">50</td>
- <td class="bdl">29.86</td>
- <td class="bdl">14.63</td>
-</tr>
-<tr>
- <td class="bdb"></td>
- <td class="bdb bdl"></td>
- <td class="bdb bdl"></td>
- <td class="bdb bdl"></td>
- <td class="bdb bdl"></td>
- <td class="bdb bdl"></td>
-</tr>
-</table>
-
-<p>The effect of the water was noticeable soon after the first application,
-as the leaves and flowers on this plant became turgid and the
-anther sacs burst at the proper stage of their development. Very
-few flowers fell after the second day. The water decidedly checked
-the aborting of immature pods, as is shown by the results obtained
-on the racemes which were labeled after the pods had formed. The
-racemes which contained pods 3 to 6 days old when labeled matured
-9.95 pods to the raceme more than those which contained older pods
-at the beginning of the experiment, but this was expected, as most
-of the aborting which caused this difference had taken place before
-the racemes were labeled. As very few pods aborted before they
-were 3 to 6 days old, the difference of 9.95 pods to the raceme in favor
-<span class="pagenum"><a id="Page_25"></a>[Pg 25]</span>
-of the ones labeled when the flowers at their bases were just ready to
-open was largely due to the dropping of the flowers on the older
-racemes before the experiment was begun.</p>
-
-<p>It will be seen that the production of mature pods on the plant
-not watered was much greater on the racemes that were labeled
-before the flowers opened than on the older racemes. This difference
-is undoubtedly due to the precipitation which fell on the sixth and
-tenth days of the experiment. It is believed that the yield of 15.23
-pods to the raceme on the ones labeled when the pods were 9 to 12
-days old is representative of the production of pods per raceme previous
-to the precipitation and that the other racemes on this plant
-would have yielded proportionately if conditions had remained the
-same.</p>
-
-<p>In the early spring of 1916, <i>Melilotus alba</i> was planted in several
-large pots in the greenhouse of the Department of Agriculture at
-Washington, D. C. These pots were placed outside the greenhouse
-in the late spring, where they remained until the following January,
-when they were taken into the greenhouse. The plants grew rapidly
-and began to flower during the latter part of April, 1917. At this
-time two pots were placed in a large cage made of screen having 20
-meshes to the linear inch. One pot was submerged in a tub of water,
-so that the soil was saturated at all times, while the plant in the other
-pot was given only sufficient water to keep it from wilting. The
-pods on a few racemes were self-pollinated and the results obtained
-are given in Table IX.</p>
-
-<p><a id="Table_IX"></a><span class="smcap">Table IX.</span>&mdash;<i>Effect of moisture on the seed production of Melilotus alba at Washington,
-D. C, in 1917.</i></p>
-
-<table summary="data">
-<tr>
- <td class="bdt bdb" rowspan="2">Soil treatment.</td>
- <td class="bdt bdb bdl" colspan="3">Total number of--</td>
- <td class="bdt bdb bdl" colspan="2">Flowers that matured (per cent).</td>
-</tr>
-<tr>
- <td class="bdb bdl">Racemes.</td>
- <td class="bdb bdl">Flowers.</td>
- <td class="bdb bdl">Pods formed.</td>
- <td class="bdb bdl">Total.</td>
- <td class="bdb bdl">Increase.</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Soil given only a limited quantity of water.</td>
- <td class="bdl">12</td>
- <td class="bdl">227</td>
- <td class="bdl">65</td>
- <td class="bdl">28.63</td>
- <td class="bdl">......</td>
-</tr>
-<tr>
- <td></td>
- <td class="bdl">&nbsp;</td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
- <td class="bdl"></td>
-</tr>
-<tr>
- <td>Soil saturated.</td>
- <td class="bdl">17</td>
- <td class="bdl">425</td>
- <td class="bdl">235</td>
- <td class="bdl">55.03</td>
- <td class="bdl">26.22</td>
-</tr>
-<tr>
- <td class="bdb">&nbsp;</td>
- <td class="bdl bdb"></td>
- <td class="bdl bdb"></td>
- <td class="bdl bdb"></td>
- <td class="bdl bdb"></td>
- <td class="bdl bdb"></td>
-</tr>
-</table>
-
-<p>The results of this experiment compare favorably with those obtained
-under field conditions at Ames in 1916.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_26"></a>[Pg 26]</span></p>
-
-<h2 class="nobreak" id="Part_II_STRUCTURE_AND_CHEMICAL_NATURE_OF_THE_SEED">Part II.&mdash;STRUCTURE AND CHEMICAL NATURE OF THE SEED
-COAT AND ITS RELATION TO IMPERMEABLE SEEDS OF
-SWEET CLOVER.<a id="FNanchor_3" href="#Footnote_3" class="fnanchor">[3]</a></h2>
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_3" href="#FNanchor_3" class="label">[3]</a> The writers wish to acknowledge the service rendered by Mr. H. S. Doty, Instructor in Botany, Iowa
-State College, Ames, Iowa, in assisting in the preparation of this article.</p></div>
-
-
-<h3><a id="HISTORICAL_SUMMARY"></a>HISTORICAL SUMMARY.</h3>
-
-<p>When agriculturists first began to cultivate wild legumes they
-observed that many seeds would not germinate within a comparatively
-short time after planting. Thus the problem of impermeable
-seeds began to demand attention many years ago. However, impermeable
-seeds are not confined to the Leguminosæ, as they occur also
-in the Malvaceæ, Chenopodiaceæ, Convolvulaceæ, Cannaceæ, and
-other families.</p>
-
-<p>Since the first account of the structure of legume seed coats by
-Malpighi (<a href="#lit_23">23</a> v. 1) in 1687, many investigators have contributed to
-our knowledge of the structure of the coats of seeds belonging to this
-family.</p>
-
-<p>Pammel (<a href="#lit_31">31</a>) made an extensive study of legume seeds, including
-all the genera in the sixth edition of Gray's Manual, as well as
-genera not included in that publication. He found that the seed coat
-uniformly consisted of three layers, namely, the outer layer of Malpighian
-cells, the osteosclerid layer, and the inner layer of nutrient
-cells. Pammel's work included a study of the seed coats of <i>Melilotus
-alba</i> and <i>M. officinalis</i>, and the descriptions and illustrations in
-his publication agree for the most part with the results obtained in
-the investigations reported in this article. However, more variation
-was noticed in the different layers of the seed coat than he describes.</p>
-
-<p>The cause of impermeability in seeds has been investigated by
-many. It has been found to be due to the embryos in some seeds,
-such as the hawthorns, but in most cases to the structure of the seed
-coat, and especially so in the Leguminosæ. Crocker (<a href="#lit_3">3</a>) states that,
-exactly opposite to the common view, the cause of delayed germination
-generally lies in the seed coats rather than in the embryos.
-Nobbe (<a href="#lit_29">29</a>) thought that the hardness of leguminous seeds was due
-to the Malpighian layer, and in a later publication Nobbe and Haenlein
-(<a href="#lit_30">30</a>, p. 81) state that the absorbent power of many seeds is inhibited
-or entirely arrested by the cones of the Malpighian cells and the
-shields built up between them, which consist principally of cutin.
-Huss (<a href="#lit_15">15</a>) agrees with Nobbe and Haenlein. Verschaffelt (<a href="#lit_39">39</a>)
-found that the impermeability of the seeds of Cæsalpiniaceæ and
-Mimosaceæ investigated was due to, the inability of water to pass
-through the canals of the seed coat. By soaking the seeds in alcohol
-or other substances which change the capillarity of the pores, the seed
-<span class="pagenum"><a id="Page_27"></a>[Pg 27]</span>
-coats were made readily permeable to water. Gola (<a href="#lit_6">6</a>) states that
-the cause of the impermeability of seeds is the peculiar character of
-the Malpighian cells, which prevents their infiltration and consequent
-increase in volume, while Bergtheil and Day (<a href="#lit_2">2</a>) found that the
-hardness of the seeds of <i>Indigofera arrecta</i> was due to their possession
-of a very thin outer covering of a substance resistant to water.
-Ewart (<a href="#lit_5">5</a>, p. 185) believes that in most impermeable seeds the cuticle
-prohibits the absorption of water, but gives as an exception <i>Adansonia
-digitata</i>, in which the whole integument seems to be permeable to
-water with difficulty. The following is quoted from White (<a href="#lit_42">42</a>, p.
-205):</p>
-
-<div class="blockquot">
-
-<p class="smaller">As a general rule in small and medium-sized seeds the cuticle is well developed
-and represents the impermeable part of the seed coat, while in the cases of large seeds,
-such as those of <i>Adansonia gregorii</i>, <i>Mucuna gigantea</i>, <i>Wistaria maideniana</i>, and <i>Guilandina
-bonducella</i>, the cuticle is relatively unimportant and inconspicuous. In these
-seeds the extreme resistance which they exhibit appears to be located in the palisade
-cells.</p></div>
-
-<p>In discussing the seed coat of <i>Melilotus alba</i>, Rees (<a href="#lit_33">33</a>, p. 404)
-states that the outer layer consists of palisade cells covered, externally
-by a structureless membrane, which, however, did not appear
-to be cuticle but hemicellulose, as it stained magenta with chloriodid
-of zinc. The greater part of the walls of the palisade cells also
-appears to be composed of hemicellulose and the outer ends only
-were cuticularized. In order to find whether the outer membrane
-was in itself impermeable to water, this author treated seeds for short
-intervals in sulphuric acid to dissolve the outside covering without
-directly affecting the palisade cells. Seeds treated in this manner
-swelled in water and microscopic examination showed that the ends
-of the palisade cells were quite intact, but had separated from each
-other. From this it was concluded that the outer membrane is
-instrumental in conferring impermeability on the seed, although not
-directly responsible for it, as is the case with a true cuticle. It is
-further believed that it probably served as a cement substance by
-means of which the cuticularized ends of the cells were held together
-closely, thus forming a barrier through which water could not penetrate,
-but that as soon as this barrier was removed the ends of the
-palisade cells separated and water passed in between them.</p>
-
-<p>More than 20 years ago machines were devised by Kuntze, Michalowski
-(<a href="#lit_27">27</a>, p. 86), Huss (<a href="#lit_15">15</a>), and later by Hughes (<a href="#lit_14">14</a>), to scarify
-impermeable seeds. Other methods have been recommended and
-employed to some extent for hastening the germination of seeds.
-Hiltner (<a href="#lit_13">13</a>, p. 44) treated seeds of red clover, white clover, and
-alfalfa 10, 30, and 60 minutes with concentrated sulphuric acid and
-found that the best germination resulted from the 60-minute treatment.
-Love and Leighty (<a href="#lit_21">21</a>) also treated the seeds of various
-<span class="pagenum"><a id="Page_28"></a>[Pg 28]</span>
-legumes with concentrated sulphuric acid and obtained a better
-germination in all cases. In their investigations with <i>Melilotus alba</i>
-it was found that a 2-hour treatment resulted in some injury to the
-seed, but that a treatment varying from 25 minutes to 1 hour gave
-good results. In most cases in our investigations the seed coats
-of sweet clover became permeable to water after a treatment of
-15 minutes in concentrated sulphuric acid, and within 5 minutes all
-of the Malpighian cells were destroyed down to the light line. Harrington
-(<a href="#lit_10">10</a>) found that the soil, season, climate, color, or size of
-red-clover seeds had no influence upon the percentage of impermeable
-seeds and that the good germination ordinarily obtained with red
-clover was due to the scarifying of the seed coats by the rasps of
-hulling machines. Harrington (<a href="#lit_11">11</a>) also studied the agricultural
-value of impermeable seeds and found that alternations of temperature
-cause the softening and germinating of many impermeable
-clover seeds when a temperature of 10° C. or cooler is used in alternation
-with a temperature of 20° C. or warmer and that the effect
-of such an alternation of temperature is greatly increased by previously
-exposing the seeds to germinating conditions at a temperature
-of 10° C. or cooler and is decreased by previously exposing the seeds
-to germinating conditions at a temperature of 30° C. It is a well-known
-fact that impermeable seeds which remain in the field over
-winter germinate readily the following spring.</p>
-
-<p>The light line is the most important and interesting feature of the
-Malpighian cell, at least so far as <i>Melilotus alba</i> and <i>M. officinalis</i> are
-concerned. But one light line occurs in the Malpighian cells in
-most Leguminosæ, although Pammel (<a href="#lit_32">32</a>) reports two well-developed
-light lines in <i>Gymnocladus canadensis</i>, Junowicz (<a href="#lit_16">16</a>) found three in
-<i>Lupinus varius</i>, and Sempolowski (<a href="#lit_36">36</a>) two in <i>Lupinus angustifolius</i>.</p>
-
-<p>Many investigators have studied the light line, and different
-theories have been advanced as to its function, physical properties,
-and chemical nature. Schleiden and Vogel (<a href="#lit_35">35</a>, p. 26) in describing
-the mature testa of <i>Schizolobium excelsum</i> in 1838 undoubtedly referred
-to the light line when they stated that the walls of the Malpighian
-cells were not equally thickened. Mettenius (<a href="#lit_26">26</a>), in 1846, was
-probably the first definitely to describe the light line. This author
-believed it was composed of pore canals, all appearing at the same
-height in the cells, but he was unable to prove this by cross sections.
-Lohde (<a href="#lit_20">20</a>) studied the light line in seeds of <i>Hibiscus trionum</i> and
-found it cutinized. Hanstein (<a href="#lit_8">8</a>) states that the Malpighian cells are
-composed of two cell layers and the light line is produced by the
-adjoining walls of the ends of the cells. Later, this same author (<a href="#lit_9">9</a>),
-according to Harz (<a href="#lit_12">12</a>), refers to the light line as a perforated disk
-composed of tissue of strong refracting power.</p>
-
-<p><span class="pagenum"><a id="Page_29"></a>[Pg 29]</span></p>
-
-<p>Russow (<a href="#lit_34">34</a>) concludes that the light line is produced by neither
-chemical nor mechanical changes but is caused by a modified molecular
-structure containing less water than the remainder of the cell
-wall. Hiltner (<a href="#lit_13">13</a>) agrees with Russow's explanation. Harz (<a href="#lit_12">12</a>,
-p. 561) also agrees with Russow and adds that he has observed that
-the light line disappeared in a number of cases after applications of
-nitric acid. Wigand and Dennert (<a href="#lit_43">43</a>) suggested that the light line
-is due to a series of erect fissures, while Tietz (<a href="#lit_37">37</a>, p. 32) believes it is
-due to a chemical modification and that the phenomenon results
-from the exceptionally extreme density of parts of the cellulose
-membrane. Junowicz (<a href="#lit_16">16</a>) found evidence of cellulose material.
-The cell wall at this point was strongly refractive and had a different
-molecular structure. After studying <i>Phaseolus vulgaris</i>, Haberlandt
-(<a href="#lit_7">7</a>, p. 38) agrees with the Russow explanation. In the seed of this
-plant the light line colored blue after being treated with chloriodid
-of zinc. Sempolowski (<a href="#lit_36">36</a>), who investigated the light line in <i>Lupinus
-angustifolius</i>, states that there is not only a difference in the molecular
-structure but also a chemical modification of the cell wall at this
-point, since with iodin and sulphuric acid the cell wall colored blue,
-whereas the light line colored yellow. Wettstein (<a href="#lit_41">41</a>), who studied
-seeds of Nelumbo, agrees with Russow (<a href="#lit_34">34</a>) and Sempolowski (<a href="#lit_36">36</a>)
-that chemical and physical modifications occur. He found that iodin
-and sulphuric acid colored the Malpighian cells intensely blue, the
-light line at first yellowish, and then later it gradually became blue.
-This reaction may be accelerated by heat. Iodin produced the same
-effect, and the light line colored blue more rapidly. When treated
-with a water-withdrawing medium the light line was not altered for
-some time, but finally disappeared with continued application.
-Cooking for a long time in caustic potash or standing in cold caustic
-potash caused the cells to swell, while the light line remained uninjured
-at first but finally disappeared. He also believed that the
-absence of pore canals in the region of the light line caused it to be
-more dense.</p>
-
-<p>Nobbe and Haenlein (<a href="#lit_30">30</a>) treated sections of seed coats of <i>Trifolium
-pratense</i> with iodin and sulphuric acid and found that the light line
-colored blue as readily as the thickened ridges that radiate inward
-from it, but that the outer processes of the palisade cells projecting
-from the light line toward the cuticle stained dark brown. They also
-state that various causes work to produce such unusual lusters in
-the light line, the principle one of which is the thickened ridges which
-radiate inward, reach their greatest development at this point, and
-coalesce in the lumen of the cell. The result is that the light line
-falls upon a continuously homogeneous medium, while in the inner
-portions of the ridges the light passes through media of varying
-opacity, such as cellulose, water, and protoplasm, whereby it is
-<span class="pagenum"><a id="Page_30"></a>[Pg 30]</span>
-progressively subdued in varying degrees by partial reflection. Pammel
-(<a href="#lit_31">31</a>, p. 147) studied the light line in <i>Melilotus alba</i> and found that it
-consisted of a narrow but distinct refractive zone below the conical
-layer. The refractive zone colored blue with chloriodid of zinc.
-The whole upper part was, however, more or less refractive, while the
-remainder of the cell wall contained pigment and colored blue with
-chloriodid of zinc. Small canals project into the walls, in some
-cases extending beyond the light line.</p>
-
-<p>Beck (<a href="#lit_1">1</a>) found that the light-refracting power of the light line was
-much greater than that of the undifferentiated membrane and stated
-that there may be in addition to this a chemical difference which can
-not be detected with the present microchemical methods. He does
-not believe that it is cuticularized or that it contains less water than
-the rest of the cell.</p>
-
-<p>Marlière (<a href="#lit_24">24</a>, p. 11) gives a physical explanation and states that the
-true cause of the light line lies in the peculiar structure of the secondary
-membrane of the Malpighian cell. Tunmann (<a href="#lit_38">38</a>, p. 559)
-observed that it did not hydrolize in weak acids and therefore decided
-that it was not hemicellulose. He found that it dissolved in concentrated
-sulphuric acid more readily than the regions surrounding it
-and that it was composed of pectin or callose. In our investigations
-the main portion of the light line of <i>Melilotus alba</i> and <i>M. officinalis</i>
-was very resistant to concentrated sulphuric acid, only the narrow
-outer portion being attacked. It showed evidence of callose.</p>
-
-
-<h3><a id="MATERIAL_AND_METHODS"></a>MATERIAL AND METHODS.</h3>
-
-<p>Permeable and impermeable seeds<a id="FNanchor_4" href="#Footnote_4" class="fnanchor">[4]</a> of <i>Melilotus alba</i> and <i>M. officinalis</i>
-were obtained from commercial samples and also from samples
-collected in the field. Those selected for sectioning were allowed
-to dry after being removed from the germinator and then embedded
-on the ends of pine blocks in glycerin gum, which was made by
-dissolving 10 grams of powdered gum arabic in 10 c. c. of water and
-adding 40 drops of glycerin. After the glycerin gum had dried
-for 24 hours, the seeds were easily sectioned. This method of embedding
-causes no change in the seed coat. It is more satisfactory
-than the paraffin method for holding the seeds firmly. The glycerin
-gum dissolved readily when the sections were mounted in water.</p>
-
-<div class="footnote">
-
-<p><a id="Footnote_4" href="#FNanchor_4" class="label">[4]</a> The term "permeable" is used in this paper to designate seeds whose coats are permeable to water in
-two weeks or less at temperatures favorable for germination, while the term "impermeable" is used to
-designate seeds whose seed coats are impermeable to water for this length of time when temperatures are
-favorable for germination. Impermeable seeds are commonly referred to as "hard seeds," and they may
-become permeable in time.</p></div>
-
-<p>In the microchemical studies Sudan III, alcanin, chlorophyll solution,
-and phosphoric acid iodin were used to test for cutin or suberin;
-sulphuric acid and iodin, chloriodid of zinc, and chloriodid of
-calcium for cellulose; phloroglucin and hydrochloric acid for lignin;
-<span class="pagenum"><a id="Page_31"></a>[Pg 31]</span>
-ruthenium red for pectic substances; and sulphuric acid, Congo red,
-and aniline blue for callose.</p>
-
-<p>Where very thin sections were necessary for detailed study of the
-structure of the seed coat, pods in various stages of development
-were collected, and after the usual preliminary treatment they were
-embedded in paraffin and sectioned with the microtome. Microchemical
-tests were made with these sections by using various specific
-stains. Safranin was used to test for cutin, suberin, and lignin;
-haematoxylin and methyl blue for cellulose ; methylene blue, methyl
-violet B, mauvein, and ruthenium red for pectic substances; and
-aniline blue and Congo red for callose. In studying some points
-with reference to the pore system of the seed coat, it was necessary
-to use free-hand sections of fresh pods.</p>
-
-<p>In studying the seed coat in relation to the absorption of water,
-both permeable and impermeable seeds were soaked in water solutions
-of safranin, gentian violet, eosin, and haematoxylin, then dried
-and embedded in glycerin gum for sectioning. Seeds were soaked
-in stains dissolved in 95 per cent alcohol to test the penetration of
-alcohol. It was evident that the seed coats did not act as a filter,
-as the stains passed through them with the water or alcohol.</p>
-
-
-<h3><a id="STRUCTURE_SEED_COAT"></a>STRUCTURE OF THE SEED COAT.</h3>
-
-<p>There is very little endosperm present in mature seeds of <i>Melilotus
-alba</i> or <i>M. officinalis</i>. That which is present is quite permeable to
-water and therefore bears no relation to the impermeable seeds of
-these plants.</p>
-
-<p>The outer layer of the seed coat, which is the modified epidermal
-layer of the ovule, is known as the Malpighian layer. (<a href="#plate5">Pl. V, figs. 1
-and 2.</a>) The cells constituting this layer, commonly called palisade
-cells, are the most highly modified cells of the seed coat. They are
-very much elongated, their length varying in the different regions of
-the coat, and their outer tangential walls and the outer portions of
-their radial walls are so much thickened that their lumina are confined
-to the inner portion of the cells, sometimes occupying less than
-half the length of the cells. The inner tangential walls and inner
-portions of the radial walls are thickened just previous to the death
-of the cells, the thickening sometimes being only slight and sometimes
-so much as to leave only very narrow lumina.</p>
-
-<p>There is a very thin layer on the outer surface of the Malpighian
-cells which has been called cuticle by previous investigators, but the
-chemical composition of this layer and its perviousness to water
-indicate that there is very little cutin present. This layer is probably
-the primary epidermal cell wall rather than a deposit on the outer
-surface of the wall. To determine this a study of the development
-of the Malpighian cells is necessary.</p>
-
-<p><span class="pagenum"><a id="Page_32"></a>[Pg 32]</span></p>
-
-<p>Beneath the so-called cuticle there is the much thickened outer
-portion of the Malpighian cells in which there are two rather distinct
-regions, one constituting the conelike structures and the other forming
-a continuous layer over the conelike structures, separating them
-from the cuticle and filling in between them. These two regions
-separate easily, and in cutting sections the outer region, called by
-some the cuticularized portion, often breaks away, leaving the entire
-surface of the cones exposed.</p>
-
-<p>The term "cuticularized layer" will be used to designate all of the
-thickening covering the cones, including that around the cones as
-well as the portion between the cones and the cuticle. This term is
-not entirely appropriate, for the region is practically free from cutin,
-but for the want of a better term it will be used. There are canals in
-the cuticularized layer and cones, which are easily seen when the
-sections are treated with chloriodid of zinc or sulphuric acid. A
-surface view of a section showing the cones and cuticularized layer
-when mounted in glycerin shows the canals as dark lines due to the
-air inclosed. The canals are most abundant along the lines where
-the lateral walls of the cells join, but many are within the cones and
-in the cuticularized substance between the cones. (<a href="#plate5">Pl. V, fig. 5.</a>)</p>
-
-<p>The well-developed light line in <i>Melilotus alba</i> and <i>M. officinalis</i> is
-found just below the bases of the cones. In some seed coats only a
-few and in others none of the canals which are common in the cones
-and cuticularized region cross the light line. A very distinct line of
-small canals filled with air and thus forming a dark band is present
-just above the fight line, thus making the light line more conspicuous.
-(<a href="#plate5">Pl. V, fig. 3.</a>) When the lumina of the cells extend across the light
-line, they are exceedingly small. The light line is the most compact
-region of the Malpighian layer and is conspicuous because it refracts
-the light much more than the regions above and below it.</p>
-
-<p>Just below the Malpighian is a layer of cells variously modified
-and known as the osteosclerid. The cells of this layer are often
-referred to as the hourglass cells on account of their shape. In some
-regions of the seed coat they are expanded at both ends and their
-walls are much thickened, the thickenings forming ridges on the
-radial walls, while in other regions only the upper tangential wall and
-a portion of the radial walls are thickened and the cells are expanded
-only at the inner end, thus having the shape of the frustum of a cone.
-Beneath the osteosclerid layer is the nutrient layer.</p>
-
-<p>The nutrient layer contains chloroplasts. It varies not only in
-the number of layers of cells composing it, but also in the modifications
-of these cells. This layer ranges from four to seven cells in
-thickness in the different parts of the seed coat.</p>
-
-
-<div class="bboxpl">
-<div class="tdr2"><a id="plate5"></a><span class="smcap">Plate V.</span></div>
-
-<div class="figcenter illowp53" style="max-width: 26.5625em;">
- <img class="w100" src="images/plate5.png" alt="" />
-</div>
-
-<div class="fig_caption">Structure of the Seed Coat of Sweet Clover.</div>
-
-<div class="hanging2">Fig. 1.&mdash;Section of the seed coat of <i>Melilotus officinalis</i>. × 450. Fig. 2.&mdash;Another section of the seed
-coat of <i>Melilotus officinalis</i>, showing the variation in size and modifications that occur in the three
-layers. × 450. Fig. 3.&mdash;Section of the Malpighian layer of a <i>Melilotus alba</i> seed, showing a line of
-canals just above the light zone. × 450. Fig. 4.&mdash;Section of the Malpighian layer of a permeable
-<i>Melilotus alba</i> seed. × 450. Fig. 5.&mdash;Tangential section of the Malpighian cells cut between the
-cuticle and tops of the cones, showing pores. × 530. Fig. 6.&mdash;Section through the Malpighian layer
-of an impermeable <i>Melilotus alba</i> seed. × 450. Fig. 7.&mdash;Section through the Malpighian layer of an
-impermeable <i>Melilotus alba</i> seed, showing the region through which water and stains readily passed.
-× 450. Fig. 8.&mdash;Cross section of a Malpighian cell of a permeable <i>Melilotus alba</i> seed through the
-region of the light zone, showing the lumen not entirely closed. × 530. Fig. 9.&mdash;Section through the
-Malpighian layer of a <i>Melilotus alba</i> seed shaded to show the portions which react to the cellulose and
-pectose tests. × 450. Fig. 10.&mdash;Section through the Malpighian layer of a <i>Melilotus alba</i> seed which
-shows the condition of the seed coat after 60 minutes' treatment of concentrated sulphuric acid. That
-portion above the light zone was destroyed, and the lumina as small pores through which much of
-the stain now passed were seen extending across the light line. The lines between the cells were
-much more distinct, appearing as small intercellular spaces through which some stain passed. × 450.
-<i>a</i>, Cuticle; <i>b</i>, cuticularized layer; <i>c</i>, conelike portion of the thickening of the Malpighian cells; <i>d</i>,
-light line; <i>e</i>, region of a hard seed coat through which water and stains readily passed; <i>l</i>, lumen; <i>M</i>,
-Malpighian cells; <i>N</i>, nutrient cells; <i>O</i>, osteosclerid cells; <i>p</i>, canals just above light zone.</div>
-</div>
-
-
-<p><span class="pagenum"><a id="Page_33"></a>[Pg 33]</span></p>
-
-
-<h3><a id="MICROCHEMISTRY"></a>MICROCHEMISTRY OF THE SEED COAT.</h3>
-
-<p>Tests for cutin showed that there was very little present in the
-seed coat. Slight reactions for cutin were observed in the cuticle, in
-the outer margin of the cuticularized layer, and in the basal portion
-of the cones. These reactions were so slight as to be almost negligible.
-It is evident that the cuticle and cuticularized layer are not
-well named in <i>Melilotus alba</i> and <i>M. officinalis</i>. Tests for cellulose
-showed that it was present in the cuticle, cuticularized layer, cones,
-the walls of the Malpighian cells below the light line, and the walls of
-the cells of the osteosclerid and nutrient layers. (<a href="#plate5">Pl. V, fig. 9.</a>)
-The reaction for cellulose in the Malpighian cells was quite distinct in
-the walls below the light line, less distinct in the cones and cuticle,
-and least distinct in the cuticularized layer.</p>
-
-<p>Tests for lignin occasionally showed slight traces in the Malpighian
-cells below the light line. When treated with reagents for pectic substances,
-the cuticle, cuticularized layer, cones, and all cell walls
-below the light line gave a definite reaction. The reaction of the
-cones and cuticle was more pronounced than the cuticularized layer.
-Tests for callose gave no reaction except in the upper part of the
-light line. This part of the light line stained slightly blue with
-aniline blue and was easily dissolved with sulphuric acid. In cutting
-free-hand sections of fresh material the Malpighian layer sometimes
-broke along this line. The greater part of the light line reacted to
-none of the tests, and its chemical nature was not determined.</p>
-
-<p>When microtome sections of seeds in different stages of development
-were treated with various stains, the results were in accord
-with those obtained with free-hand sections. Thus with safranin
-the periphery and cones of the Malpighian cells were slightly stained,
-while haematoxylin and methyl blue stained all the seed coat except
-the light line. The cones and cuticle stained more readily than the
-cuticularized layer, but neither stained as deeply as the cell walls
-below the light line. Methylene blue, methyl violet B, and mauvein
-stained all above the light line, indicating the presence of pectic substances;
-however, the staining was more prominent in the cones and
-cuticle.</p>
-
-<p>The difference in reaction of the cones and cuticularized layer to
-the cellulose and pectose tests probably indicates a difference in
-density rather than a difference in chemical composition. Since the
-cuticularized layer separates readily from the cones, there may be a
-difference in physical properties.</p>
-
-<p>With Congo red the upper part of the light line was only very
-slightly stained, but aniline blue had a more pronounced effect.</p>
-
-<p>The microchemical tests applied to the seed coat show that in the
-region above the light line there is only a slight trace of cutin or
-<span class="pagenum"><a id="Page_34"></a>[Pg 34]</span>
-suberin, but a considerable amount of cellulose and pectose. All
-cell walls below the light line are mainly cellulose but contain some
-pectose. The upper portion of the light line contains callose, but
-the remainder of the light line appears to be chemically different
-from all other parts of the seed coat or else so dense as to resist the
-attack of the reagents.</p>
-
-
-<h3><a id="ABSORPTION_OF_WATER"></a>THE SEED COAT IN RELATION TO THE ABSORPTION OF WATER.</h3>
-
-<p>A study of permeable seeds soaked in water containing stains
-showed that there were no local regions through which the water
-passed. The stains passed through all regions of the seed coat.
-Coating the micropylar region with vaseline retarded germination,
-but had no effect upon the percentage of germination at the end of
-three days. In seed coats through which the stain had passed, the
-light line was not stained. Some stain was found in the canals which
-crossed the light line, and much more in the cell cavities. There was
-no evidence that the stain had permeated the substance of the light
-line. It was able to cross the light line only when pores were present.</p>
-
-<p>In impermeable seeds the stains passed readily to the light line.
-(<a href="#plate5">Pl. V, fig. 7.</a>) It was evident that the absorption of water was not
-prevented by either the cuticularized layer or the cone-shaped structures
-of the Malpighian layer, but by the light line. The region outside
-of the light line became stained in a few hours, but there was no
-trace of the stain within the light line after the seeds had remained
-a week in the stains. Alcohol did not penetrate the seed coat more
-readily than water.</p>
-
-
-<h3><a id="PERMEABLE_AND_IMPERMEABLE"></a>A COMPARISON OF PERMEABLE AND IMPERMEABLE SEED COATS.</h3>
-
-<p>No difference in chemical structure was found between the coats of
-permeable and impermeable seeds. The principal differences were
-in the character and amount of thickening of the cell walls.</p>
-
-<p>In many of the permeable seeds some of the canals were found to
-extend across the light line, but this was not true for all permeable
-seeds. (<a href="#plate5">Pl. V, fig. 8.</a>) Oblique sections of permeable seed coats
-showed that the cell cavities, although reduced to mere pores by the
-thickening of their radial walls, extended across the light line into
-the base of the cones, thus forming a passageway through which the
-stains passed to the larger portions of the cell cavities below the light
-line. (<a href="#plate5">Pl. V, fig. 4.</a>)</p>
-
-<p>In the coats of the impermeable seeds the light line was usually
-broader, the Malpighian cells thickened more below the light line,
-and the main cavities of the Malpighian cells were more reduced and
-farther below the light line than in the coats of permeable seeds.
-(<a href="#plate5">Pl. V, fig. 6.</a>) No canals except occasionally a few very small ones
-were seen crossing the light line in impermeable seeds. Cross and
-<span class="pagenum"><a id="Page_35"></a>[Pg 35]</span>
-oblique sections showed that the lumina of the Malpighian cells were
-closed in the region of the light line. Thus it was found that permeable
-and impermeable seeds differ mainly in the amount of thickening
-which occurs in the walls of the Malpighian cells. In the impermeable
-seeds the thickening which begins at the outer tangential wall
-of the Malpighian cell extends farther toward the inner tangential
-wall, leaving the cell lumina smaller and farther below the light line than
-in permeable seeds. The thickening is also more complete in impermeable
-seeds, leaving fewer and smaller canals across the light line
-as well as closing the cell lumina in the region of the light line.</p>
-
-
-<h3><a id="SULPHURIC_ACID"></a>THE ACTION OF SULPHURIC ACID ON THE COATS OF IMPERMEABLE SEEDS.</h3>
-
-<p>Impermeable seeds were soaked in concentrated sulphuric acid
-(sp. gr. 1.84) for 15, 30, and 60 minutes; then washed and put in the
-staining solutions. After they had swollen, they were removed from
-the staining solutions, dried, and embedded in glycerin gum. A
-study of these seeds showed that the acid had eaten away all of the
-material outside of the light line and that the stain had passed
-through all regions of the seed coat. (<a href="#plate5">Pl. V, fig. 10.</a>) When observed
-under the microscope, it was seen that the action of the acid was
-rapid, destroying the cuticle, cuticularized layer, and cones in about
-5 minutes. After 15 minutes treatment with acid the light line,
-aside from the presence of canals and pores not previously visible,
-seemed to be very little affected. The division lines along which the
-lateral walls of the Malpighian cells were joined now became much
-more distinct across the light line, thus indicating that there was
-some swelling in this region. When a close examination of the path
-of the stain was made the cell lumina, and occasionally very small
-pores, were found to extend across the light line. The presence of
-the stain in the pores indicated that they were paths of the stain
-across the light line. Some of the stain passed along the lines between
-cells and through the occasional canals crossing the light line,
-but judging from the intensity of the stain in the lumina the canals
-appeared to be the principal passageways.</p>
-
-<p>The action of the acid in opening the cell cavities across the light
-line was not determined. It may be due to the swelling of the light
-line or to the removal of substances closing the pores.</p>
-
-<p>No seeds were exposed to the acid for longer than an hour, but at the
-end of this period the light line was still intact. As compared with
-other portions of the Malpighian layer, it is extremely resistant to
-concentrated sulphuric acid. Since all cell walls below the light line
-are mainly cellulose, the resistance of the light line prevents the acid
-from destroying the entire seed coat and reaching the embryo.</p>
-
-
-<hr class="chap" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_36"></a>[Pg 36]<br /><a id="Page_37"></a>[Pg 37]</span></p>
-
-<h2 class="nobreak" id="LITERATURE_CITED">LITERATURE CITED.</h2>
-</div>
-
-
-
-<p>(<a id="lit_1">1</a>) <span class="smcap">Beck, Gunther.</span></p>
-
-<div class="blockquot">
-
-<p>1878. Vergleichende Anatomie der Samen von Vicia und Ervum. <i>In</i>
-Sitzber. K. Akad. Wiss. [Vienna], Math. Naturw. Kl., Bd. 77,
-Abt. 1, p. 545-579, 2 pl.</p></div>
-
-<p>(<a id="lit_2">2</a>) <span class="smcap">Bergtheil, C,</span> and <span class="smcap">Day, D. L.</span></p>
-
-<div class="blockquot">
-
-<p>1907. On the cause of "hardness" in the seeds of Indigofera arrecta. <i>In</i>
-Ann. Bot., v. 21, no. 81, p. 57-60, pl. 7.</p></div>
-
-<p>(<a id="lit_3">3</a>) <span class="smcap">Crocker, William.</span></p>
-
-<div class="blockquot">
-
-<p>1906. Role of seed coats in delayed germination. <i>In</i> Bot. Gaz., v. 42, no. 4,
-p. 265-291, 4 fig. Literature cited, p. 290-291.</p></div>
-
-<p>(<a id="lit_4">4</a>) <span class="smcap">Darwin, Charles.</span></p>
-
-<div class="blockquot">
-
-<p>1885. The effects of cross and self fertilisation in the vegetable kingdom.
-482 p. New York.</p></div>
-
-<p>(<a id="lit_5">5</a>) <span class="smcap">Ewart, Alfred J.</span></p>
-
-<div class="blockquot">
-
-<p>1908. On the longevity of seeds. <i>In</i> Proc. Roy. Soc. Victoria, v. 21, pt. 1,
-p. 1-203. Literature, p. 3-4.</p></div>
-
-<p>(<a id="lit_6">6</a>) <span class="smcap">Gola, Guiseppe.</span></p>
-
-<div class="blockquot">
-
-<p>1905. Ricerche sulla biologia e sulla fisiologia dei semi a tegumento impermeabile.
-<i>In</i> Mem. R. Accad. Sci. Torino, s. 2, t. 55, p. 237-270, 1 pl.</p></div>
-
-<p>(<a id="lit_7">7</a>) <span class="smcap">Haberlandt, G.</span></p>
-
-<div class="blockquot">
-
-<p>1877. Ueber die Entwickelungsgeschichte und den Bau der Samenschale bei
-der Gattung Phaseolus. <i>In</i> Sitzber. K. Akad. Wiss. [Vienna],
-Math. Naturw. Kl., Bd. 75, Abt. 1, p. 33-47, 2 pl.</p></div>
-
-<div class="blockquot">
-
-<p><span class="smcap">Hanstein, [Johannes].</span></p></div>
-
-<div class="blockquot">
-
-<p>(<a id="lit_8">8</a>) 1863. Erläuterung des Nardoo genannten Nahrungsmittels der Urbewohner
-Australiens, einer Marsilea-Frucht, nebst Bemerkungen zur Entwicklung
-dieser Gattung. <i>In</i> Monatsber. K. Preuss. Akad. Wiss.
-Berlin, 1862, p. 103-119, 1 pl.</p>
-
-<p>(<a id="lit_9">9</a>) 1866. Pilulariae globuliferae generatio cum Marsilia comparata. 16 p.
-Bonnae. Dissertation.</p></div>
-
-<div class="blockquot">
-
-<p><span class="smcap">Harrington, George T.</span></p></div>
-
-<div class="blockquot">
-
-<p>(<a id="lit_10">10</a>) 1915. Hard clover seed and its treatment in hulling. U. S. Dept. Agr.,
-Farmers' Bul. 676, 8 p.</p>
-
-<p>(<a id="lit_11">11</a>) 1916. Agricultural value of impermeable seeds. <i>In</i> Jour. Agr. Research, v.
-6, no. 20, p. 761-796, 6 fig., pl. 106. Literature cited, p. 796.</p></div>
-
-<p>(<a id="lit_12">12</a>) <span class="smcap">Harz, C. D.</span></p>
-
-<div class="blockquot">
-
-<p>1885. Landwirtschaftliche Samenkunde. 1362 p., 201 fig. Berlin.</p></div>
-
-<p>(<a id="lit_13">13</a>) <span class="smcap">Hiltner, L.</span></p>
-
-<div class="blockquot">
-
-<p>1902. Die Keimungsverhältnisse der Leguminosensamen und ihre Beeinflussung
-durch Organismenwirkung. <i>In</i> Arb. K. Gesundheitsamte,
-Biol. Abt., Bd. 3, Heft 1, p. 1-102, 4 fig.</p></div>
-
-<p>(<a id="lit_14">14</a>) <span class="smcap">Hughes, H. D.</span></p>
-
-<div class="blockquot">
-
-<p>1915. Making legumes grow. <i>In</i> Farm and Fireside, v. 38, no. 19, p. 7, illus.</p></div>
-
-<p>(<a id="lit_15">15</a>) <span class="smcap">Huss, Mathias.</span></p>
-
-<div class="blockquot">
-
-<p>1890. Über Quellungsunfähigkeit von Leguminosensamen und Mittel zu
-deren Abhilfe. 73 p. Halle. Dissertation.</p></div>
-
-<p><span class="pagenum"><a id="Page_38"></a>[Pg 38]</span></p>
-
-<p>(<a id="lit_16">16</a>) <span class="smcap">Junowicz, R.</span></p>
-
-<div class="blockquot">
-
-<p>1878. Die Lichtlinie in den Prismenzellen der Samenschalen. <i>In</i> Sitzber.
-K. Akad. Wiss. [Vienna], Math. Naturw. Kl., Bd. 76, Abt. 1, p.
-335-352, 2 pl.</p></div>
-
-<p>(<a id="lit_17">17</a>) <span class="smcap">Kerner von Marilaun, Anton.</span></p>
-
-<div class="blockquot">
-
-<p>1891. Pflanzenleben. 2 Bd. Leipzig.</p></div>
-
-<p>(<a id="lit_18">18</a>) <span class="smcap">Kirchner, O.</span></p>
-
-<div class="blockquot">
-
-<p>1905. Über die Wirkung der Selbstbestäubung bei den Papilionaceen. <i>In</i>
-Naturw. Ztschr. Land-u. Forstw., Jahrg. 3, Heft 1, p. 1-16; Heft 2,
-p. 49-64; Heft 3, p. 97-111. Literatur-verzeichnis, p. 110-111.</p></div>
-
-<p>(<a id="lit_19">19</a>) <span class="smcap">Knuth, Paul.</span></p>
-
-<div class="blockquot">
-
-<p>1906-8. Handbook of flower pollination, based on Hermann Müller's work
-upon "The fertilisation of flowers by insects," transl. by J. R.
-Ainsworth Davis. 3 v., illus. Oxford. Bibliography, v. 1, p.
-212-380.</p></div>
-
-<p>(<a id="lit_20">20</a>) <span class="smcap">Lohde, Georg.</span></p>
-
-<div class="blockquot">
-
-<p>1874. Ueber die Entwicklungsgeschichte und den Bau einiger Samenschalen.
-42 p., 1 pl. Naumburg. Dissertation.</p></div>
-
-<p>(<a id="lit_21">21</a>) <span class="smcap">Love, Harry H.</span>, and <span class="smcap">Leighty, Clyde E.</span></p>
-
-<div class="blockquot">
-
-<p>1912. Germination of seed as affected by sulphuric acid treatment. N. Y.
-Cornell Agr. Exp. Sta. Bul. 312, p. 293-336, fig. 78-85.</p></div>
-
-<p>(<a id="lit_22">22</a>) <span class="smcap">Lutts, F. M.</span></p>
-
-<div class="blockquot">
-
-<p>1917. Sweet clover, advantages of the crop for soil improvement. <i>In</i> Ohio
-Agr. Exp. Sta. Mo. Bul., v. 2, no. 2, p. 45-47, illus.</p></div>
-
-<p>(<a id="lit_23">23</a>) <span class="smcap">Malpighi, Marcello.</span></p>
-
-<div class="blockquot">
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-
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