MORPHOLOGY,VASCULAR ANATOMY AND EMBRYOLOGY OF PISTILLATE AND STAMINATE FLOWERS OF ASPARAGUS OFFICINALIS

Flowers of three pistillate (female), two heterogametic staminate (male) and two homogametic male genotypes of Asparagus officinalis L. were compared for morphology and vascular anatomy of the flower and for embryological development to the stage of mature ovules and pollen. Flowers are liliaceous, the staminate with rudimentary pistils and the pistillate with collapsed anthers. The uncomplicated vascular pattern differs between staminate and pistillate flowers only in the size and degree of maturation of bundles to stamens and carpels. Longer styles appear to be correlated with a greater extent of ovule development in ovaries of staminate flowers. Microsporogenesis in males is normal with wall development corresponding to the Monocotyledonous type. The tapetum is glandular and binucleate, cytokinesis successive, the tetrads isobilateral or occasionally decussate, and the mature pollen grain two-celled. A pair of heteromorphic, possibly sex, chromosomes was observed in heterogametic male plants. Anther development is initially the same in pistillate flowers, but the tapetum degenerates precociously followed by collapse of microspore mother cells. In pistillate flowers the ovules are hemitropous, bitegmic, and slightly crassinucellate. Megasporogenesis-megagametogenesis conforms to the Polygonum type. In staminate flowers ovule development is like that in pistillate flowers until degeneration starts in nucellar and integumentary cells at the chalazal end. Ovules in both homogametic male genotypes rarely complete meiosis, while in the heterogametic males it is normally completed with about one ovule in 20 flowers forming a mature megagametophyte. Since manipulation of sex expression in Asparagus could be important in developing inbred male and female lines for breeding purposes, those aspects of the morphological and embryological observations presented which might be useful in planning experiments to induce sex changes are discussed briefly.     

Homeotic, Meristic and Cytological Floral Mutants of Thryptomene calycina (family Myrtaceae)

Twenty plants with various phenotypic abnormalities to the flowerswere selected from very large populations of Thryptomene calycinain the Grampian and Black Ranges. Most of these had impairedreproductive function. Normal flowers were epigynous with fivesepals, five petals, five anthers, a single style and two anatropousovules. The mutants were two partially male sterile, tetraploidplants with large flowers, one of which occasionally producedadditional flowers from the leaf axils with peduncles as wellas pedicels; one plant which produced a proportion of hexapetaloidflowers with six stamens; three gross mutants with fleshy, bracteoidpointed petals and sepals, no stamens, vestigial styles andstigmas, exposed ovules and no inferior ovary; one plant withfleshly, bracteoid pointed sepals, vestigial style and stigmabut with exposed ovular structures replaced by four to fivesterile ovules generally inside an abnormal ovary; two plantswith reduced ovary diameter and sterile ovules, shortened style,five reduced sepals and petals and five to eight anthers; threeanthocyanin-free plants; three plants with pink sepals; twoplants with half-sized flowers which produced a proportion offasciated stems; one plant which occasionally produced flowerswithout pedicels which virtually resulted in organs which wereleaf-flower composites; two plants which produced sepals andpetals which contained chlorophyll and prematurely senesced,and had partial substitution of petals by anthers.Copyright1993, 1999 Academic Press Thryptomene calycina, Myrtaceae, Victorian lace flower, floral mutations, mutants, homeotic, meristic, tetraploid, fasciation, male sterility, cut flowers     

Morfologia fiorale embriologia ed embriog in Leontopodium alpinum Cass. var. α typicum fiori e Paoletti

Abstract

FLOWER MORPHOLOGY, EMBRYOLOGY AND EMBRYOGENESIS OF LEONTOPODIUM ALPINUM CASS. VAR. α TYPICUM FIORI E PAOLETTI. — The present work has been carried on with capitules of L. alpinum var. α typicum, included and dissected, differing thus from the previous research which is also summarised (BEAUVERD 1909 a e b, 1910, 1012, 1913 a e b, 1914).

The results are the following: all capitules of the same corymb of this species have the same structure, differing eventually in details. Generally they show outwards a few female flowers, inwards a relevant number of pseudohermaphrodite flowers (the sterile hermaphrodite of BEAUVERD). They are therefore subdioecious capitules with tendency to reduce the already scarce number of female flowers. Both female and pseudohermaphrodite flowers have been extensively described. Some rare hermaphrodite flowers with ovules and anthers, and very rare subhermaphrodite without ovules and empty or almost empty anthers have been also observed.

On the same material, embryological and embryogenetical research has been carried out: from it results that the microsporogenesis proceeds normally, without degeneration. The megasporogenesis and the development of the female gametophyte and the formation of an 8-nucleate have been observed and also several cases of poliantiopody. Many gamethophytes at this stage degenerate; the others develop particularly transversally; the antipodes completely degenerate and the secondary nucleus and the egg cell reach remarkable size. Synergids at this stage appear more or less completely fessurate, in their micropilar part.

Fertilisation occurs through porogamy, the zygote producing a bicellular proembryo which goes on dividing while the nucleus of the endosperm forms a cellular albumen.

The embryological and embryogenetical observations do not completely agree with those made by SOKOLOWSKA-KULCZYCKA (1959) on specimens of L. alpinum collected on the Tatra mountains (Carpathian Mts.), where the tetrad often degenerates and only exceptionally brings to the constitution of an aphid gamethophyte. More frequently apomixis has been observed, which implies a parthenogenetical development of the egg cell.     

The Effects of Inflorescence Size and Flower Position on Biomass and Temporal Sex Allocation in <Emphasis Type="Italic">Lobelia sessiliflora</Emphasis>

To test the prediction of sex allocation theory that plants or flowers high in resource status emphasize the female function, we explored the variation in both biomass (the number of pollen grains and ovules) and temporal (male and female durations) sex allocation among and within plants of protandrous Lobelia sessilifolia in relation to plant size and flower position within plants. Among plants, the mean number of pollen grains and ovules per flower of a plant increased with plant size, whereas the mean P/O ratio (number of pollen grains/number of ovules ratio) decreased with plant size. The mean male duration, the mean female duration, and the mean ratio of male duration/flower longevity per flower of a plant were not correlated with plant size. Thus, large plants emphasized female function in terms of biomass sex allocation, which is consistent with the prediction of size-dependent sex allocation theory. The results for temporal sex allocation, however were inconsistent with the theory. Within plants, the mean number of pollen grains and ovules per flower at each position decreased from lower to upper flowers (early to late blooming flowers) and that of the P/O ratio increased from lower to upper flowers. The mean male duration and the mean female duration per flower decreased from lower to upper flowers, whereas the mean ratio of male duration/flower longevity increased from lower to upper flowers. The population sex ratio changed from male-biased to female-biased. Thus, later blooming flowers emphasized the male function in terms of both biomass and temporal sex allocation, consistent with the sex allocation theory, regarding the change in the population sex ratio.     

Some Effects of Light Intensity, Daylength and Temperature on Flowering and Pollen Tube Growth in the Watermelon (Citrullus lanatus)

The effects of light and temperature on flowering and pollentube growth were studied in watermelon [Citrullus lanatus(Thunb.)Matsum. and Nakai, cv. Early Yates] plants grown in controlledenvironment cabinets. All female flowers were pollinated inone group of plants; none was pollinated in the other group. Temperature increase from 25 ^°C to 35 ^°C with daylengthof 14 h and light intensity of 32 klx caused increase in flowernumber per plant, proportion of male flowers, ovary length anddiameter, ovule number per ovary, rate of pollen tube growthand percentage of penetrated ovules at 24 hand 48 h after pollination.Very few flowers were produced at 40 ^°C, but there was ahigh proportion of male flowers. Increase in daylength from14 h to 24 h at 25 ^°C with light intensity of 32 klx alsoincreased number of flowers per plant, ovary length and diameterand number of ovules per ovary but sex expression and rate ofpollen tube growth were unaffected. Reduction in daylength from14 h to 8 hat 25 °C and light intensity of 32 klx and reductionin light intensity from 32 klx to 8 klx at 25 ^°C and 14h daylength both produced an increase in the percentage of immatureovules. The presence of fruit on the vine resulted in fewerflowers per plant and in reduced ovary legnth and diameter underall conditions tested. The results are discussed in relation to the fruiting responseof the plant.     

Megasporogenesis,Microsporogenesis and Development of Gametophytes in Eleutherococcus senticosus (Araliaceae)

This paper describes megasporogenesis, microsporogenesis, and development of female and male gametophytes in Eleutherococcus senticosus. The main results are as follows: Flowers of E. senticosus are epigynous, pentamerous. Anthers are 4 -microsporangiate. An ovary has 5 loculi. Each ovary loculus has 2 ovules: the upper ovule and the lower ovule. The upper one is orthotropous and degenerates after the formation of archesporial cell, while the lower one is anatropous, unitegmic and crassinucellar, and able to continue developing. In male plants, microsporogenesis and development of male gametophytes took place in regular way, but a series of abnormal phenomena were found in megasporogenesis and development of female gametophytes. The microspore mother cells gave rise to tetrahedral tetrads by meiosis. Cytokinesis was of the simultaneous type. The mature pollen was 3-celled and shed singly. The anther wall formation belonged to the dicotyledonous type. At the stage of microspore mother cell, the anther wall consisted of four layers, i.e. epidermis, endothecium, middle layer, and tapetum. The tapetum was of glandular type and its most cells were binucleate. When microspores were at the uninucleate stage, the tapetum began to degenerate in situ. When microspores developed into 3-celled pollen grains, the tapetum had fully degenerates. In the lower ovule of male flower, the megaspore mother cell gave rise to a linear or “T” -shaped tetrad. In some cases, a new archesporial cell over the tetrad or two tetrads parallel or in a series were observed. Furthermore, the position of functional megaspore was variable; any one or two megaspores might be functional, or one megaspore gave rise to a uninucleate embryo sac, but two other megaspores also had a potentiality of developing into the embryo sac. In generally, on the day when flowers opened, female gametophytes contained only 4 cells: a central cell, two irregular synergids and one unusual egg cell. In female plants, microspore mother cells and secondary sporogenous cells were observed. But at the stage of secondary sporogenous cell, the newly differentiated tapetum took the appearance of degeneration. Later, during the whole stage of meiosis, the trace of degenerative tapetum could be seen. At last, the microsporangium degenerated and no tetrad formed. On the blossom day, all anthers shriveled without pollen grains. In female flowers, megasporogenesis and development of female gametophytes were normal: the tetrad of megaspores was linear or “T”-shaped; the chalazal megaspore was usually functional; the development of embryo sac was of the Polygonum type. On the blossom day, most embryo sacs consisted of 7 cells with 8 nuclei or 7 cells with 7 nuclei; but the egg apparatus was not fully developed. In hermaphroditic plants, microsporogenesis was normal but the development of male gametophytes was partially abnormal. When the hermaphroditic flowers blossomed, there were more or less empty pollen grains in the microsporangium and these pollen grains were quite different in size. The development of most gynoecia was normal but numerous abnormal embryo sacs could be seen. On the blossom day, female gametophytes were mainly 7-celled with 8-nuclei or with 7-nuclei or 4-celled with antipodal cells degenerated; the egg apparatus wasnot fully developed either.     

ENERGY DISTRIBUTION IN REPRODUCTIVE STRUCTURES OF AMARYLLIS

Energy content of tissue produced in male and female reproductive structures as well as in associated flower parts of Amaryllis was measured with an oxygen bomb calorimeter. In typical flowers, 6.6% of their total energy (2,880 cal) was in pollen, 4.9% in anther walls, 4.6% in ovules and placentae, and 12.6% in ovary walls and septa. Ovules were estimated to contain only about one-third as much energy as pollen. Mature seeds typically contained about 100 times as much energy as ovules. Total energy in mature seeds per flower was approximately equal to total energy in flower tissues. Proportional allocation of anther energy to pollen increased with anther size. The biological significance of these results is discussed.     

Inbreeding effect on male and female fertility and inheritance of male sterility in Nemophila menziesii (Hydrophyllaceae)

Models of the evolution of gynodioecy assume that inbreeding affects male and female fertility equally and ignore quantitative variation in sex expression. The objectives of this study were to assess inbreeding effects, genetic background, and plant maturity on male and female fertility and the mechanism of male sterility inheritance for Nemophila menziesii (Hydrophyllaceae). Frequency of male-sterile flowers, number of anthers and ovules, and percentage of viable pollen were measured on plants from different pedigrees and five inbreeding levels (F = 0, 0.0625, 0.25, 0.5, and 0.75). Quantitative variation in male sterility was evident. As inbreeding increased, anther and ovule number decreased; the effect on anther number was greater than on ovule number. Pedigrees varied in number of male-sterile flowers and inbreeding effects. Frequency of male-sterile flowers was greatest among first flowers. No trade-off between male and female fertility was detected. A model attributing male sterility to a cytoplasmic locus and restoration to male fertility to a nuclear locus accounted for the distribution of complete sterility and hermaphroditism over the pedigrees. This study suggests that models of the evolution and maintenance of gynodioecy should allow for quantitative variation in male and female fertility components due to inbreeding, pedigree, and plant maturity.     

Size-dependent reproduction in Australian alpine Ranunculus

Abstract The effect of plant size on reproduction in four species of alpine Ranunculus (R. muelleri, R. dissectifolius, R. graniticola and R. niphophilus) was investigated in two sites over two seasons in the field on a total of 190 plants. The effects of plant size (number of leaves) and number of flowers on the number of anthers, ovules and seed per flower and per plant were determined. There was a positive relationship between several measures of reproduction and plant size in all four species, indicating that reproduction is size-dependent. All the results indicate that the main factor controlling the amount of seed produced by alpine Ranunculus is the size of the plant. Specifically, bigger plants produced more seed by producing more flowers, not by producing more ovules per flower, or higher seed set per flower. Correspondingly, bigger plants produced more anthers by producing more flowers, rather than by producing flowers with more anthers. The total number of seeds produced by a plant was directly proportional to plant size in the four species. Therefore, reproductive effort should not vary with plant size in the four species.     

In vitro flowering in cassava (Manihot esculenta Crantz)

Meristem-derived plantlets of cassava (Manihot esculenta Crantz) were induced to flower in vitro. Five genotypes out of 13 consistently responded to our culture conditions giving rise to male or female flowers. Male flowers contained anthers in which meiosis occurred and apparently normal pollen grains were formed.     

Pre-zygotic embryological characters ofPlatycrater arguta, a rare and endangered species endemic to East Asia

Platycrater arguta Sieb. et Zucc. is a rare and endangered species endemic to East Asia. It produces two floral morphs viz. bisexual and male flowers. For bisexual flowers, simultaneous cytokinesis in the microsporocyte meiosis leads to a tetrahedral tetrad. The mature pollen grain is shed at 2-cell stage. The young anther wall is composed of epidermis, endothecium that develops fibrous thickenings at maturity, 1–2 middle layers and tapetum. The tapetum with uninucleate to binucleate cells, disintegrates in situ (glandular tapetum), yet in a small percentage of the anthers (about 37.6%), the tapetum does not disintegrate, causing complete male sterility. The ovules are anatropous, unitegmic, tenuinucellar and the formation of the embryo sac follows the monosporic, Polygonum type. Antipodal cells are lacking in the mature embryo sacs. Before fertilization, two polar nuclei fuse into a secondary nucleus. The formation of microsporangial wall, microsporogenesis and male gametogenesis in male flowers are analogous to those in the bisexual. Prezygotic embryological characters ofP. arguta were reported for the first time, revealing that its endangerment is correlated with the abortion of pollen of a part but not to the female development that is normal.     

Dioecy inHonkenya peploides var.major (Caryophyllaceae)

Sexual difference and pollination system inHonkenya peploides var.major were investigated. The present analyses indicate that sex expression of this plant is functionally dioecious, rather than androdioecious, as described previously. Its flowers are largely pollinated by small bees, hover-flies, flies, and ants. Female flowers were morphologically characterized by conspicuously longer styles and smaller petals, and had no pollen grains, while male flowers had shorter styles, larger petals, and longer filaments, and produced viable pollen grains. Although the male flowers possess many ovules in an ovary, they set fruits at a very low frequency in natural conditions and did not produce fruits by pollination experiments. We suggest that the dioecy of this species has been derived from hermaphrodite through gynodioecy, and not directly from hermaphrodite.     

Gender variation in Actinidia deliciosa,the kiwifruit

Summary Flower and fruit characters were measured in ten female, five male and five fruiting male selections of A. deliciosa var deliciosa (A. Chev) Liang and Ferguson. Flowers from female vines had functional pistils, which contained many ovules. Stamens appeared to be fully developed but produced only empty pollen grains. Flowers from male vines had functional stamens that produced high percentages of pollen grains with stainable cytoplasmic contents. Pistils did not contain ovules and were generally small with vestigial styles. Fruiting male vines had both staminate and bisexual flowers. Staminate flowers were similar to those found on strictly male vines. Bisexual flowers produced ovules and stainable pollen. Pistils were smaller than in pistillate flowers. Although the three flower sexes differed in style length, ovary dimensions and ovules per carpel, staminate and bisexual flowers were similar in number of flowers per inflorescence, stamen filament length, pollen stainability, inflorescence rachis length and carpel number, and differed from pistillate flowers in these characters. The three flower sexes had similar sepal and petal numbers. The fruit of fruiting males were considerably smaller than those of females. Low ovule number appears to be the major factor limiting fruit size in the fruiting males studied. Prospects for developing hermaphroditic kiwifruit cultivars through breeding are discussed.     

Dioecy in the endemic genusDendrocacalia (Compositae) on the Bonin (Ogasawara) Islands

Dendrocacalia crepidifolia Nakai (Compositae, Senecioneae), the only species of this arboreal genus endemic to Haha Island in the Bonin Islands, was found to be dioecious. Male flowers differ from female ones in having a stunted style (style in female exserted from corolla and deeply bifurcating) and anthers filled with fertile pollen (anthers in the female lacking pollen). The size of the corolla and number of florets per head were similar between male and female flowers. The crown area of this arboreal species was also similar in male and female plants. The sex ratio was 0.55 male, not significantly different from 0.5. Both sexes produced nectar of similar sugar concentration (ca. 50%). The flowers are pollinated by feral honeybees (Apis mellifera), but they are thought to have been pollinated by small, lesshairy, endemic solitary bees before honeybees were introduced and subsequently became the dominant bee species on the island. The evolution of dioecy ofDendrocacalia on the island is thought to stem from the deleterious effects of inbreeding that are inherent in plants with geitonogamy. The increased geitonogamy on the island has resulted from increased woodiness (i.e., increased number of flowers per plant) and the original dependence on endemic bee pollinators, which are now endangered.     

短柄五加大,小孢子发生和雌,雄配子体发育的研究

短柄五加花药５枚,每个花药四个花粉囊。小孢子母细胞减数分裂时,胞质分裂为同时型,产生正四面体形的四分体。花药壁由表皮、药室内壁、中层和绒毡层四层细胞组成,其发育类型为双子叶型。腺质绒毡层,其细胞为二核。三细胞型花粉。子房５室,每室两个胚珠,上胚珠败育,下胚珠可育。下胚珠倒生,具单珠被,厚珠心。大孢子母细胞减数分裂形成线性排列的四个大孢子,雌配子体发育属蓼型。开花当天,花粉散开,雌配子体尚未成熟,处     

Differenze Morfologiche ed Anatomiche in Individui Maschili E Femminili di Ginkyo Biloba L.

Abstract

Anatomical and histological differences between ♀ and ♂ plants of GINKYO BILOBA L. — Morphological characters in several ♀ and ♂ specimens of Ginkyo have been checked, with the aim to put in evidence those which are sex-linked. Anatomical data from a previous research have been utilized. (Maugini 1965).

The main results are here summarized.

In the climate of Florence the female plants unfold their buds in the first ten days of April, the male ones in the middle of March, so that the males break their dormancy about one month before the females.

From the buds opening, brachyblasts are formed both in males and females, and catkins and ovules appear. At the beginning of May, the ovules have considerably grown, and catkins are faded. In the meanwhile the leaves have completely grown up in both sexes. Between the end of September and the beginning of October, the seeds become gold-yellow and begin to be shed off. Dissemination may go on for a long while, and still be active when all the leaves are fallen.

Buds are formed during summer, they are very little and sharp in the female, round and bigger in the male.

In both sexes leaves turn yellow and begin to fall between the end of October and the beginning of November. Females are generally considered more precocious than males in shedding leaves, but this behaviour did not result constant in the plants under observations so that the « leaf-fall time » cannot be considered a sex-linked character.

In shoots and stems of males and females, proceeds downwards tracheid deposition and differentiation, the highest activity being in the brachyblasts, where cambium works continuosly, and the lowest in the stem, where late wood formation can be found only in the male plants. Unevenness of cambial activity along the plant axis is particularly evident in the female, where late wood formation in the stem is rare.

The rhythm of cambial activity along shoots and stems of males and females have been compared with that of the buds, with the following results: both in the female and male plants the young leaves start expanding about two months before cambium activity starts in the stem. The male plant is more precocious than the female, probably the slower vegetation rhythm of the female being related to the seed ripening process.     

The phenology of gender in homogamous flowers: temporal change in the residual sex function of flowers of Oil-seed Rape (Brassica napus)

1. We investigated the phenology of the male and female sexual functions in flowers of Oil-seed Rape ( Brassica napus ) that were exposed to pollinators in an experimental garden. The female 'residual sex function' (RSF) of flowers was measured by hand-pollinating with genetically marked pollen in order to determine the proportion of ovules that remained available for fertilization by incoming pollen. Male RSF was measured by estimating the proportion of pollen grains that remained in dehiscing anthers.
2. Following flower opening, an average flower's male and female sexual functions each required for completion c. 13 h of exposure to pollinators. One hour after opening, c. 50% of a flower's ovules were unavailable to incoming pollen whereas only c. 10% of pollen was removed. Therefore, a flower's sexual function was predominantly female for the first hour and predominantly male thereafter.
3. We found a fairly close correspondence between the proportion of the stigma covered with pollen and the depletion of female RSF.
4. On average, floral senescence occurred after c. 14·5 h of exposure to pollinators. Our observations are fairly consistent with a simple, economic model of optimal senescence time because the flowers remained open for approximately the same length of time as was necessary for the completion of their sexual functions.
5. A flower's senescence was hastened when pollen was removed from the anthers, but not when pollen was deposited on the stigma.
6. When flowers were either left undisturbed or hand-pollinated, senescence occurred after c. 24 h. Pollen removal caused senescence after c. 13 h, which also approximated the longevity of flowers in the experimental garden. Apparently, pollen removal governed floral longevity under field conditions.     

RESPONSES OF FLORAL TRAITS TO SELECTION ON PRIMARY SEXUAL INVESTMENT IN SPERGULARIA MARINA: THE BATTLE BETWEEN THE SEXES

Two widespread assumptions underlie theoretical models of the evolution of sex allocation in hermaphroditic species: (1) resource allocations to male and female function are heritable; and (2) there is an intrinsic, genetically based negative correlation between male and female reproductive function. These assumptions have not been adequately tested in wild species, although a few studies have detected either genetic variation in pollen and ovule production per flower or evidence of trade-offs between male and female investment at the whole plant level. It may also be argued, however, that in highly autogamous, perfect-flowered plant taxa that exhibit genetic variation in gamete production, strong stabilizing selection for an efficient pollen:ovule ratio should result in a positive correlation among genotypes with respect to mean ovule and mean pollen production per flower. Here we report the results of a three-generation artificial selection experiment conducted on a greenhouse population of the autogamous annual plant Spergularia marina. Starting with a base population of 1200 individuals, we conducted intense mass selection for two generations, creating four selected lines (high and low ovule production per flower; high and low anther production per flower) and a control line. By examining the direct and correlated responses of several floral traits to selection on gamete production per flower, we evaluated the expectations that primary sexual investment would exhibit heritable variation and that resource-sharing, variation in resource-garnering ability, or developmental constraints mold the genetic correlations expressed among floral organs. The observed direct and correlated responses to selection on male and female gamete production revealed significant heritabilities of both ovule and anther production per flower and a significant negative genetic correlation between them. When plants were selected for increased ovules per flower over two generations, ovule production increased and anther production declined relative to the control line. Among plants selected for decreased anthers per flower, we observed a decline in anther production and an increase in ovule production relative to the control line. In contrast, the lines selected for low ovules per flower and for high anthers per flower exhibited no evidence for significant genetic correlations between male and female primary investment. Correlated responses to selection also indicate a genetically based negative correlation between the production of normal versus developmentally abnormal anthers (staminoid organs); a positive correlation between the production of ovules versus staminoid organs; and a positive correlation between the production of anthers and petals. The negative relationship between male versus female primary investment supports classical sex allocation theory, although the asymmetrical correlated responses to selection indicate that this relationship is not always expressed.     

LABILE SEX EXPRESSION IN ANDROMONOECIOUS SOLANUM HIRTUM: FLORAL DEVELOPMENT AND SEX DETERMINATION

Sex expression (the proportions of hermaphrodite and staminate flowers produced) of the andromonoecious species Solatium hirtum is labile, and this lability of whole plant sex expression is due to labile sex expression of individual floral buds. In this paper I examine the developmental processes that underlie the differences in floral sex expression of hermaphrodite and staminate flowers of Solarium hirtum, focusing particularly on the processes responsible for the observed lability of floral sex expression. Differences in bud growth rate and relative growth of floral organs in these buds are evident at about the time of megasporocyte meiosis (11–12 days before anthesis). However, gynoecial sterility in staminate buds does not occur until just 6–7 days before anthesis. At this time, abnormalities in ovule development occur in staminate buds: the ovules begin to appear necrotic, the integumentary tapetum collapses, and the megagametophytes of many ovules cease normal development. These observations are consistent with the predictions of labile floral development.     

QUANTITATIVE OBSERVATIONS ON THE PATTERN OF SYNERGID DEGENERATION IN BARLEY

Serial sections of 75 ovules taken from two pollinations were examined in order to determine the pattern of early synergid degeneration in Hordeum vulgare (Bonus). It was found that synergid degeneration occurs in various patterns in ovules from successful pollinations: either both synergids degenerate, or only one degenerates; in those ovules where only one synergid degenerates, the degenerate synergid is nearly always located either proximal or distal to the placental attachment of the ovule. The results suggest that 1) synergid degeneration depends upon successful pollination, 2) degeneration of both synergids is equally as likely to occur as degeneration of only one synergid, and 3) in those cases where only one synergid degenerates, there is a greater tendency for the degenerate synergid to be located toward the placenta.