POLLEN TUBE-SYNERGID INTERACTIONS IN PROBOSCIDEA LOUISIANICA (MARTINEACEAE)

The ultrastructure of the synergids of Proboscidea louisianica was investigated from just before fertilization until 48 hr after pollination. It was found that the cytoplasm of one synergid consistently begins to degenerate before arrival of the pollen tube at the embryo sac, and that it is always this synergid which receives the pollen tube tip and its discharge. The other synergid (persistent synergid) remained unchanged throughout the study period. Polysaccharide vesicles of pollen tube origin were observed fusing with the pollen tube wall as well as contributing to cell wall formation of the degenerate synergid. In one ovule (48 hr after pollination) two pollen tubes had entered and grown the length of the micropyle, but only the first tube penetrated the degenerate synergid and discharged normally. The second pollen tube was abutting against the persistent synergid, but had not entered or discharged. In another exceptional case (18 hr after pollination), a pollen tube had grown the length of the micropyle, but did not discharge, or enter either synergid. Both synergids of this ovule were observed to be completely intact. It is concluded that synergid and pollen tube cytoplasmic degeneration is the result of a very specific interaction between these two cells and that this degeneration is probably a prerequisite for normal pollen tube entrance and discharge into the embryo sac, and for male gamete transfer to the egg and central cell.     

FERTILIZATION IN BARLEY

The mature embryo sac of barley consists of an egg, two synergids, a central cell, and up to 100 antipodal cells. At shedding the male gametophyte is 3-celled, consisting of a vegetative cell with a large amount of starch and two sperms having PAS+ boundaries. Before pollination the nucleus and cytoplasm of each synergid appear normal. After pollination the nucleus and cytoplasm of one synergid undergo degeneration. The pollen tube grows along the surface of the integument of the ovule, passes through the micropyle, and enters the degenerate synergid through the filiform apparatus. The pollen tube discharges the vegetative nucleus, two cellular sperms, and a variable amount of starch into the degenerate synergid. Soon after deposition the sperms migrate by an unknown mechanism to the chalazal end of the degenerate synergid. Sperm nuclei then enter the cytoplasm of the egg and central cell, ultimately resulting in the formation of the zygote and primary endosperm nucleus, respectively. Sperm boundaries do not enter egg or central cell, but it was not possible to determine the fate of other sperm components. Degenerate vegetative and synergid nuclei remain in the synergid after fertilization, constituting what are considered to be X-bodies in barley. The second synergid degenerates during early embryogeny.     

Fertilization in Nicotiana tabacum: ultrastructural organization of propane-jet-frozen embryo sacs in vivo

Ovules of Nicotiana tabacum L. were cryofixed with a propane-jet freezer and freeze-substituted in acetone to examine technique-dependent changes in pre- and post-fertilization embryo sacs using rapidly frozen material. Freezing quality was acceptable in 10% of the embryo sacs in the partially dissected ovules, with ice-crystal damage frequently evident in vacuoles and nuclei. One of the two synergids begins to degenerate before pollen-tube arrival in cryofixed material, with breakdown of the plasma membrane and large chalazal vacuole delayed until the penetration of the pollen tube. Early synergid degeneration involved characteristic increases in cytoplasmic electron density and the generation of cytoplasmic bodies to the intercellular space through “pinching-off”. Upon pollen-tube arrival, the male gametes are released through a terminal aperture into the degenerate synergid. Sperm cells undergo morphological alteration before gametic fusion: their mitochondrial electron density increases, the endoplasmic reticulum dilates, cytoplasm becomes finely vacuolated and the surrounding pollen plasma membrane is lost, causing the sperm cells and vegetative nucleus to dissociate. Discharge of the pollen tube results in the formation of numerous enucleated cytoplasmic bodies which are either stripped or shed from sperm cells and pollen-tube cytoplasm. Two so-called X-bodies are found in the degenerate synergid after pollen-tube penetration: the presumed vegetative nucleus occurs at the chalazal end and the presumed synergid nucleus near the micropylar end.     

东北地区野豌豆属VICIAL．物种生物学研究Ⅷ．幼苗形体结构动态和种间界限

在野外居群调查的启示下,本文以组件观点对柳叶野豌豆复合种和歪头菜幼苗亚单位的时序变化与开花关系进行了分析。结果发现在柳叶野豌豆复合种栽培居群中存在打破物种间形体结构特征的个体,即在复叶由一对小叶组成的植株就已开花而进入生殖时期。另外,在歪头菜的野生居群中发现由三或四枚小叶组成复叶的个体,因此,我们推测这种形体结构的变化可能暗示着柳叶野豌豆复合种和歪头菜有着共同的祖先。     

莴苣助细胞发育过程中钙的分布研究

用焦锑酸盐沉淀法对莴苣助细胞中的钙分布进行了观察。结果表明,开花前3天刚形成的助细胞中的钙颗粒很少:开花前2天助细胞壁中的钙颗粒增加;开花前1天助细胞珠孔端细胞壁加厚,其中积累了许多钙颗粒:开花当天助细胞珠孔端的丝状器中聚集了大量的钙颗粒。授粉后1h时两个助细胞的结构和钙分布发生差异,一个呈退化状,其中的钙颗粒明显增多,另一宿存助细胞中的钙分布与授粉前相似。去雄不授粉1天后两个助细胞均保持完好,且两助细胞中的钙分布没有明显差异,表明由花粉管引起一个助细胞中钙含量增加进而导致了助细胞退化。退化助细胞在卵细胞与中央细胞之间形成一薄层。助细胞退化后不同部位的钙颗粒呈现出与受精作用密切有关的变化:授粉后1h时,钙主要聚集在近合点端部位;授粉后2.5h卵细胞即将受精,这时许多细小的钙颗粒主要聚集在卵细胞与中央细胞之间的薄层中;授粉后4h精、卵细胞已融合,这时退化助细胞合点端的钙颗粒明显减少,而在其珠孔端又聚集了较多的钙。上述助细胞中的钙含量变化与吸引花粉管进入胚囊和促使精卵细胞融合密切有关。     

Synergid degeneration in Nicotiana: a quantitative,fluorochromatic and chlorotetracycline study

Summary Synergid degeneration was examined in the isolated embryo sac and egg apparatus of Nicotiana tabacum using quantitative cytology, fluorochromatic reaction (FCR) and chlorotetracycline (CTC). Most synergid degeneration occurs after pollen tubes (PT) arrive in the ovarian chamber between 42 and 48 h after pollination; synergid degeneration was precluded when PT were prevented from entering the ovary by stylar excision indicating that the signal that triggers synergid degeneration travels only relatively short distances in this plant. There was no evidence for any preferentiality between right or left synergids with regard to cell size or degeneration pattern. FCR staining confirms that synergid degeneration involves the loss of membrane integrity and is a reliable indicator of the onset of degeneration. CTC labeling of the degenerated synergid reveals that a concentrated reserve of membrane-bound calcium is present in the receptive synergid, possibly aiding in the attraction, arrest and discharge of the PT, releasing the sperms into the receptive ES.     

FINE STRUCTURE AND COMPOSITION OF THE EGG APPARATUS BEFORE AND AFTER FERTILIZATION IN QUERCUS GAMBELII: THE FUNCTIONAL OVULE

A study of the egg apparatus of Quercus gambelii was made at both the light and the electron microscope levels. This investigation was concerned primarily with the changes that occur in these cells before and after the process of fertilization and what role, if any, is played by the synergids in this phenomenon. The synergids before fertilization are, on the basis of ultrastructure, healthy, intact, functional cells. They have numerous mitochondria, dictyosomes, endoplasmic reticulum, ribosomes, and a typical nucleus. A prominent filiform apparatus is present, but the cell wall only extends a short distance around the micropylar end of the cells. Just before fertilization, one of the synergids degenerates. This is the synergid that receives the pollen tube and its discharge, including both male gametes. Dictyosomes increase in number and activity in the other synergid (persistent synergid) after fertilization. Eventually a complete cell wall forms around both of the synergids. No plasmodesmata are present in these walls. The egg has numerous mitochondria, dictyosomes, endoplasmic reticulum, and ribosomes, both free in the cytoplasm and attached to the endoplasmic reticulum. Lipid bodies are characteristic of this cell. A cell wall is present only around the micropylar end of the egg. After fertilization, little change occurs in the zygote. The number and activity of the dictyosomes increase, apparently in correlation with cell wall formation. The number of lipid bodies increases. The zygote is approximately the same size as the egg. Plastids are scarce, and starch grains are typically absent from all cells of the egg apparatus. It is suggested that the synergids function in the secretion of chemotropic substances that guide the growth of the pollen tube. Comparisons are made between the egg apparatus of Quercus gambelii and that of the other plants studied thus far.     

Studies on nuclear degeneration during programmed cell death of synergid and antipodal cells in<Emphasis Type="Italic"> Triticum aestivum</Emphasis>

Morphological changes in the nuclear degeneration of the synergid (mainly the synergid that receives the pollen tube) and antipodal cells in Triticum aestivum were studied. Although located in the same embryo sac, and derived from the same megaspore, nuclear degeneration of the synergid and antipodal cells differs greatly. Nuclear degeneration in the synergid is characterized by pycnosis, i.e., total chromatin condensation, nuclear deformation and distinct shrinkage in volume, followed by the formation of an irregular and densely stained mass—the degenerated nucleus—while the nucleolus disappears prior to the degradation of chromatin. In contrast, in the nuclear degeneration of antipodal cells, chromatin is only partly condensed and the nuclear volume changes only slightly after the distinct chromatin condensation. Chromatolysis then occurs, i.e., stainable contents disappear while the nuclear envelope is retained. The nucleoli persist after the disappearance of the chromatin. The possible functions of nuclear degeneration of synergid and antipodal cells are discussed, especially with respect to the guidance of pollen tube growth and the proliferation of free-nuclear endosperm. The degeneration of synergids and antipodal cells in T. aestivum are distinct forms of programmed cell death, regarded as cytoplasmic cell death and nuclear degradation in advance of cell death, respectively.     

大葱卵器及受精后助细胞的超微结构

章丘大葱（Ａllium fistulosum L.cv.Zhangqiu)的卵器由１个卵细胞及２个助细胞组成,观察到不少卵器没有卵细胞,只有２个助细胞。卵细胞的核及大部分细胞质位于细胞的合点端,１个大液泡占据了细胞其他部位。卵细胞含有很多的核糖体及多聚核糖体、嵴明显的线粒体、粗面内质网、高尔基体具小泡,卵细胞似是一个活跃的细胞。细胞外被细胞壁,其合点端及侧方与助细胞共同壁不连续,助细胞有一较大的核,位于细胞膨大的部位,众多的小液泡遍布细胞中。核糖体及聚合核糖体、线粒体,粗面内质网及风心圆环状粗面内质丰富,高尔基体及小泡常见,反映了其活跃的代谢作用。助细胞合点端及侧方与卵细胞、中央细胞的共同壁不连续,与卵细胞共同壁含胞间连丝,壁不连续处,有不状多层膜结构伸入卵细胞质,显示助细胞可能对卵细胞提供营养,伟粉后,一个助细胞退化,宿存助细胞至随胚胚期尚存在,它经历了一个缓慢的退化过程,出现质壁分离,细胞质变稀,液泡扩大,细胞器逐渐减少,在椭形胚期,宿存助细胞核内的染色质及核仁消失,有细胞质侵入核内,因宿存助细胞壁变厚,细胞质出现现脂滴,宿存助细胞可能仍有合成功能,宿存助细胞壁出现若干无壁部位,细胞内的营养物质可能通过无壁部位向胚乳转运,供游离核胚乳及胚乳细胞化初期的发育。     

Fertilization inNicotiana tabacum: Cytoskeletal modifications in the embryo sac during synergid degeneration

The cytoskeletal organization of the embryo sac of tobacco (Nicotiana tabacum L.) was examined at maturity and during synergid degeneration, pollen-tube delivery and gamete transfer using rapid-frozen, freeze-substituted and chemically fixed material in combination with immunofluorescence and immunogold electron microscopy. Before fertilization, the synergid is a highly polarized cell with dense longitudinally aligned arrays of microtubules adjacent to the filiform apparatus at the micropylar end of the cell associated with major organelles. The cytoskeleton of the central cell is less polarized, with dense cortical microtubules in the micropylar and chalazal regions and looser, longitudinally oriented cortical microtubules in the lateral region. In the synergid and central cell, F-actin is frequently found at the surface of the organelles and co-localizes with either single microtubules or microtubule bundles. Egg cell microtubules are frequently cortical, randomly oriented and more abundant at the chalazal end of the cell; actin filaments are associated with microtubules and the cortex of the egg cell. At 48 h after pollination and before the pollen tube arrives, the onset of degeneration is evident in one of the two synergids: the electron density of cytoplasmic organelles and the ground cytoplasm increases and the nucleus becomes distorted. Although synergids otherwise remain intact, the vacuole collapses and organelles degenerate rapidly after pollen-tube entry. Abundant electron-dense material extends from the degenerated synergid into intercellular spaces at the chalazal end of the synergid and between the synergids, egg and central cell. Rhodamine-phalloidin and anti-actin immunogold labeling reveal that electron-dense aggregates in this region contain abundant actin forming two distinct bands termed coronas. This actin is part of a mechanism in the egg apparatus which appears to precisely position and facilitate the access of male gametes to the egg and central cell for fusion.Abbreviations ES embryo sac - FA filiform apparatus - Mf microfilament - Mt microtubule - PT pollen tube - RF-FS rapid-freeze freeze-substitution - TEM transmission electron microscopy We thank Gregory W. Strout for technical assistance in the use of the RF-FS technique and Dr. Hongshi Yu for providing Fig. 1. This research was supported by U.S. Department of Agriculture grants 88-37261-3761 and 91-37304-6471. We gratefully acknowledge use of the Samuel Robert Noble Electron Microscopy Laboratory of the University of Oklahoma.     

An ultrastructural study of early endosperm development and synergid changes in unfertilized cotton ovules

Excised, unfertilized cotton (Gossypium hirsutum L.) ovules were cultured for 1–5 days postanthesis and embryo-sac development was studied with the electron microscope. In some ovules the two polar nuclei fuse and the diploid endosperm nucleus goes through a limited number of free nuclear divisions after 2–3 days in culture. Each nucleus has two nucleoli, in contrast to nuclei of fertilized triploid endosperm which have three nucleoli. Precocious cell walls form between the endosperm nuclei on the 3rd day in culture. The morphology of the plastids, mitochondria, rough endoplasmic reticulum (RER), dictyosomes and microbodies, and the amount of starch and lipid in the diploid cellular endosperm are similar to those of the central cell. A few large helical polysomes appear close to plastids and mitochondria. After 2 days in culture, one of the two synergids in the unfertilized cultured ovules shows degenerative changes which in fertilized ovules are associated with the presence of the pollen tube, i.e., increase in electron density, collapse of vacuoles, irregular darkening and thickening of mitochondrial and plastid membranes, disappearance of the plasmalemma and the membranes of the plasmalemma and the membranes of the RER. The second synergid remains unchanged in appearance. The egg cell does not shrink or divide or show structural changes characteristic of the cotton zygote. Embryo-sac development is arrested on the 4th and 5th days in culture. The nucellus continues growth and at 14 days crushes the degenerate embryo sac.     

Actin coronas in normal and indeterminate gametophyte1 embryo sacs of maize

 The actin cytoskeletal organization and nuclear behavior of normal and indeterminate gametophyte1 (ig1) embryo sacs of maize were examined during fertilization. After pollination, during degeneration of one of the synergids and before arrival of the pollen tube, the cytoskeletal elements undergo dramatic changes including formation of the actin coronas at the chalazal end of the degenerating synergid and at the interface between the egg cell and central cell. The actin coronas are present only for a limited period of time and their presence is coordinated with pollen tube arrival and fusion of the gametes; they disappear before the zygote divides. This allows us to estimate the frequency of fertilized ovules along the ear. Up to 88% of the ovules on an ear contain actin coronas in the embryo sacs when observed 16–19 h after pollination, indicating the high frequency of fertilizing kernels along the ear at this stage. In the ig embryo sacs, two or more degenerated synergids containing actin coronas at their chalazal ends receive multiple pollen tubes for gametic fusion and can consequently give rise to twin or polyembryos. These findings with the monocot maize are consistent with previous reports on the dicots Plumbago and Nicotiana, suggesting that the formation of actin coronas in the embryo sac during fertilization is a universal phenomenon in angiosperms and is part of a mechanism of interaction between gametic signaling and actin cytoskeleton behavior which appears to precisely position and facilitate the access of male gametes to the egg cell and central cell for fusion. Received: 15 May 1998 / Revision accepted: 17 August 1998     

Fertilization in maize indeterminate gametophyte1 mutant

Summary. Mature embryo sacs of the maize mutant indeterminate gametophyte1 displayed different cellular patterns compared to those of the wild type. About 40% of the ig1 embryo sacs contained three or more synergids and two or more egg cells at the micropylar end. During fertilization in embryo sacs with two synergids, both of them frequently degenerated and were penetrated by two pollen tubes. 75% of the embryo sacs containing three or more synergid cells were penetrated by two or more pollen tubes, although most of them had only one degenerated synergid. Multiple fusions between the sperm cells and eggs frequently occurred in the same embryo sac, which subsequently generated multiple embryos. There were two or more central cells in about 33% of ig1 embryo sacs. The largest central cell was usually adjacent to the egg apparatus and contained two unfused polar nuclei, while those extra central cells located at the chalazal end usually had a single nucleus. Fertilization occurred only between the male gamete and the largest binucleate central cell. The extra central cells eventually degenerated after fertilization.Present address: GI Basic Research Center, Mayo Clinic, Rochester, Minnesota, U.S.A.Correspondence and reprints: State Key Laboratory of Plant Physiology and Biochemistry, College of Biological Science, China Agricultural University, Beijing 100094, Peoples Republic of China.     

Sul Dioicismo Di Idesia Polycarpa Maxim

Summary

On the dioecism in idesia polycarpa maxim.

Idesia polycarpa Maxim. is a dioecious species, native of Japan and China. Two specimens have been studied for this research, a ♀ and a ♂ one, growing in the Botanical garden of Siena.

The female plant does not present anomalies in the sex behaviour; the male plant, on the contrary, bears occasionaly some flowers with ovaries, which exceptionally develop into fruits.

In the Botanical Garden of Pisa a case of complete sex inversion has been observed (male into female).

In both the ♀ and the ♂ the first development stage is identical and hermaphrodyte. The flower is tendentially proterandrous, unisexuality being attained only successively.

In the male flowers the pystil degenerates while the pollen mother cells undergo meiosis. The ovary ceases developing farther, at the ovule forming stage from the placentae. The only cellular line which degenerates is the epithelium, which lines the ovary inner surface and extends as far the upper surface of the stygma. The microspores tetrads form contemporarily. The tapetum is of the secretory type.

The stamens degenerates in female flowers at the moment corresponding to the passage from the vegetative to the reproductive stage; i. e. the stamens of the female flowers are not capable to carry out the meiosis. The first cellular layer to be reached by a degeneration process is the tapetum; the second is the archesporial tissue. During the degeneration of these two tissues ovules are developing. The female gamethophyte is of the monomegasporial, normal, eightnucleate type. The fruits born by the female plant are roundish, with 8–30 fertile seeds and 50–65 sterile ones. Thè fruits which are exceptionally born by the male plant are bigger, pear-shaped, and countain 20–40 fertile seeds and 65–85 sterile ones.

The epithelium lining the ovaries undergoes total degeneration in normal male flowers; a partial one in the occasional male flowers which have more or less developed pistils. When only the stygma epithelium degenerates, the ovary produces a higher number of ovules even through the whole style region, so that a style does not form and the ovary does not shut, giving a pear-haped fruit.

A higher number of seeds are therefore produced by such an ovary, not only because the placentae go on producing ovules for a longer period, but because also their stylar region is active in this process. It is evident then, that the stigma plays a very important role in the normal closing of the ovary.

In the cases of partial degeneration, ovules remain vital only where the corresponding epithelium is unaltered. This shows that the epithelium has a great importance in the ovule producing phase of the placentae.

Everything seems to point out that the anthers degeneration is autonomous, owing to its own incapacity to undergo meiosis. On the contrary the suppression of the ovary in the male flower is not autonomous and does not occur in a particular moment of the ovary development, but it coincides with microsporogenesis. The suppressor of the ♀ sex therefore acts through the opposite sex. In a male plant where the anthers happen to degenerate, pystils develop in various degree, even completely.

The flowers of the female plant reache the microsporogenesis stadium about 15 days later than those of the male. The author suggests that this delay may be responsible for the realization of the female sex, checking the normal development of the anthers, probably under the influence of environmental factors. On this base he has tried to explain anomalies in male flowers.     

The Arabidopsis mutant feronia disrupts the female gametophytic control of pollen tube reception

Reproduction in angiosperms depends on communication processes of the male gametophyte (pollen) with the female floral organs (pistil, transmitting tissue) and the female gametophyte (embryo sac). Pollen-pistil interactions control pollen hydration, germination and growth through the stylar tissue. The female gametophyte is involved in guiding the growing pollen tube towards the micropyle and embryo sac. One of the two synergids flanking the egg cell starts to degenerate and becomes receptive for pollen tube entry. Pollen tube growth arrests and the tip of the pollen tube ruptures to release the sperm cells. Failures in the mutual interaction between the synergid and the pollen tube necessarily impair fertility. But the control of pollen tube reception is not understood. We isolated a semisterile, female gametophytic mutant from Arabidopsis thaliana, named feronia after the Etruscan goddess of fertility, which impairs this process. In the feronia mutant, embryo sac development and pollen tube guidance were unaffected in all ovules, although one half of the ovules bore mutant female gametophytes. However, when the pollen tube entered the receptive synergid of a feronia mutant female gametophyte, it continued to grow, failed to rupture and release the sperm cells, and invaded the embryo sac. Thus, the feronia mutation disrupts the interaction between the male and female gametophyte required to elicit these processes. Frequently, mutant embryo sacs received supernumerary pollen tubes. We analysed feronia with synergid-specific GUS marker lines, which demonstrated that the specification and differentiation of the synergids was normal. However, GUS expression in mutant gametophytes persisted after pollen tube entry, in contrast to wild-type embryo sacs where it rapidly decreased. Apparently, the failure in pollen tube reception results in the continued expression of synergid-specific genes, probably leading to an extended expression of a potential pollen tube attractant.     

EMBRYO SAC LACKING ANTIPODAL CELLS IN ARABIDOPSIS THALIANA (BRASSICACEAE)

Ultrastructure of the embryo sac lacking antipodals in prefertilization stages in Arabidopsis thaliana has been examined 2 hr before and 5 hr after manual cross pollination. The cytoplasm of both synergids before fertilization is rich in ribosomes, mitochondria, and rough endoplasmic reticulum, and also contains several microbodies and spherosomes. The filiform apparatus includes electron-dense material and a fibrous part. Many cortical microtubules appear in the filiform apparatus area. One of the two synergids degenerates before fertilization. The synergids, the egg cell, and central cell have a rich cytoskeleton of microtubules; only the synergids appear to contain microfilaments. At the chalazal end, the antipodals are initially present but degenerate by the time of pollination in most embryo sacs in the starchless line studied. The embryo sac is completely surrounded by a wall containing an electron-dense layer, separating it from the nucellus, including the chalazal end. When the antipodals have degenerated, the electron-dense layer disappears at the chalazal end only, and the wall between the central cell and the nucellus is homogeneous. Between the central cell and nucellar cells no plasmodesmata are found. The membranes of both antipodal cells at the chalazal end of the embryo sac appear sinuous, like those of transfer cells. The central cell has plastids preferentially distributed around the nucleus, but the other organelles are randomly distributed. The central cell in the embryo sac and the adjacent chalazal nucellar cells show a transfer-cell function in the embryo sac after the antipodals degenerate.     

CAPSELLA EMBRYOGENESIS: THE SYNERGIDS BEFORE AND AFTER FERTILIZATION

The ultrastructure and composition of the synergids of Capsella bursa-pastoris were studied before and after fertilization. The synergids in the mature embryo sac contain numerous plastids, mitochondria, dictyosomes and masses of ER and associated ribosomes. Each synergid contains a large chalazal vacuole, a nucleus with a single nucleolus and is surrounded by a wall. This wall is thickest at the micropyle end of the cell where it proliferates into the filiform apparatus. At the chalazal end of the cell the wall thins and may be absent for small distances. The pollen tube grows into one of the two synergids through the filiform apparatus and extends one-third the length of the cell before it discharges. Following discharge of the pollen tube, mitochondria and plastids of the tube can be identified in the synergid as can hundreds of 0.5 μ polysaccharide spheres liberated by the tube. The method by which the sperm or sperm nuclei enter the egg or central cell is not known although an apparent rupture was found in the wall of the egg near the tip of the pollen tube. The second synergid changes at the time the pollen tube enters the first synergid. These changes result in the disorganization of the nucleus and loss of the chalazal wall and plasma membrane. Eventually this synergid loses its identity as its cytoplasm merges with that of the central cell.     

CHANGES IN MEGAGAMETOPHYTE STRUCTURE IN PAPAVER NUDICAULE L. (PAPAVERACEAE) FOLLOWING IN VITRO PLACENTAL POLLINATION

Papaver nudicaule placentae with attached ovules were dissected out of unpollinated gynoecia 1–3 days after anthesis, dusted with pollen, and cultured on modified Nitsch's growth medium at 23 C. Ovules were removed from expiants at 15, 24, 31, and 48 hr postpollination, fixed in GA-OsO₄, embedded in Spurr's resin and sectioned (1.0 μm) for light microscopy. Placentae, 15 hr after pollination, were fixed and processed for scanning electron microscopy. Pollen germinates within 1 hr. Although most pollen tube growth appears random, there is directional growth toward the micropyle. The crassinucellate ovule contains an embryo sac consisting of three antipodals, two polar nuclei, and an egg apparatus composed of two synergids and a polarized egg having a large chalazal vacuole and micropylar nucleus. Pollen tube access into the megagametophyte is through a degenerate synergid, with fertilization occurring between 24 and 31 hr after pollination. Zygote establishment is accompanied by polarity reversal in which the nucleus assumes the chalazal position subtended by a large micropylar vacuole. Fertilized ovules normally develop into germinable seeds.     

Prepollination degeneration in mature synergids of pearl millet: an examination using antimonate fixation to localize calcium

Summary The pattern of degeneration in mature synergids of pearl millet prior to pollination was examined by transmission electron microscopy after conventional and antimonate fixation to precipitate loosely sequestered calcium (Ca). The extent of degeneration and the distribution of Ca in a synergid varied among samples, and also between some sister synergids. However, there seemed to be no difference between sister synergids in the total amount of precipitates present in each cell. Characteristic signs of degeneration in the antimonatefixed synergids were: a gap above the filiform apparatus with fibrillar material, precipitates, and fusing or disintegrating membranes; increased precipitates in the nucleus, nucleolus, and endoplasmic reticulum; fusion or collapse of a few vacuoles in the chalazal core with precipitates and flocculent material deposited nearby. The numerous mitochondria and proplastids in the micropylar portion of the synergid remained intact and mostly free of precipitates. The shape and content of the chalazal vacuoles appeared to be disparate and dependent on the fixation procedure as well as the extent of degeneration within a synergid. The results suggest that the sister synergids of pearl millet undergo autonomous degeneration apparently in two independent sequences that may be spatially and temporally separated. The vacuoles appear to be dynamic organelles that store Ca in association with some other material. A high concentration of Ca may be localized along or between the common wall of the two filiform apparatuses.On specific Cooperative Agreement 58-6612-8-002 with the Department of Biochemistry, University of Georgia, Athens, GA 30602, USA