玉竹雄配子的发育——着重阐明质体在生殖细胞和营养细胞中的分布和变化

玉竹(Polygonatum simizui Kitag)小孢子在分裂前,质体极性分布导致分裂后形成的生殖细胞不含质体,而营养细胞包含了小孢子中全部的质体。生殖细胞发育至成熟花粉时期,及在花粉管中分裂形成的两个精细胞中始终不含质体。虽然生殖细胞和精细胞中都存在线粒体,但细胞质中无DNA类核。玉竹雄性质体的遗传为单亲母本型。在雄配子体发育过程中,营养细胞中的质体发生明显的变化。在早期的营养细胞质中,造粉质体增殖和活跃地合成淀粉。后期,脂体增加而造粉质体消失。接近成熟时花粉富含油滴。对百合科的不同属植物质体被排除的机理及花粉中贮藏的淀粉与脂体的转变进行了讨论。     

Male gametophyte development inPlumbago zeylanica: cytoplasm localization and cell determination in the early generative cell

Summary The behavior of the generative cell during male gametophyte development inPlumbago zeylanica was examined by epifluorescence microscopy and electron microscopy with organelle nucleoid as a cytoplasm marker. When the thin sections stained with 4,6-diamidino-2-phenylindoIe (DAPI) were observed under an epifluorescence microscope, two types of fluorescence spots were detected in the cytoplasm of the pollen cells before the second mitosis. The spots emitting stronger fluorescence were confirmed as plastid nucleoids and those emitting dimmer fluorescence were mitochondrial nucleoids. Before the first mitosis, both plastid and mitochondrial nucleoids distributed randomly in the cytoplasm of the microspore. A small lenticular generative cell formed with attachment to the interior of the intine after the mitosis. Small vacuoles were found in the lenticular cell. In the cytoplasm of the lenticular cell, both plastid nucleoids and the small vacuoles were distributed randomly at the very beginning but began to migrate in opposite directions immediately. Plastid nucleoids aggregated to the side of the cell that faces the pollen center and the small vacuoles aggregated to the side of the cell that attaches to the inline. As the result, the lenticular generative cell appeared highly polarized in cytoplasm location soon after the first mitosis. In accordance with the definition of the cytoplasm polarization, the primary wall between the generative and the vegetative cells began to flex and the lenticular generative cell started to protrude towards the pollen center. When the generative cell peeled away from the inline, it was spherical in shape with the pole that aggregated plastids towards the vegetative nucleus. But the cell direction appeared to be transformed immediately. The pole that aggregated small vacuoles turned to the position towards the vegetative nucleus and the pole that aggregated plastid nucleoids turned to the position countering to the vegetative nucleus. A cellular protuberance formed at the edge of the pole that aggregated small vacuoles and elongated into a tapered end that got into contact with the vegetative nucleus. The polarization of the cytoplasm kept constant throughout the second mitosis. The small vacuoles that apportioned to the sperm cell which attached the vegetative nucleus (the leading sperm cell) disappeared during sperm cell maturation. Plastid nucleoids were apportioned to the other sperm cell (the trailing sperm cell) completely. Mitochondrial nucleoids became undetectable after the second mitosis.     

Heritable paternal cytoplasmic organelles in alfalfa sperm cells: ultrastructural reconstruction and quantitative cytology.

Sperm cells within pollen grains and pollen tubes of alfalfa (Medicago sativa L.) were observed at the ultrastructural level, and their plastid DNA was detected by DAPI (4,6-diamidino-2-phenylindole) staining. One sperm pair within the pollen grain and three sperm pairs within pollen tubes were reconstructed in three-dimensions from serial ultrathin sections. The two sperm cells are linked by cytoplasmic bridges in both pollen grains and tubes, and the vegetative nucleus is closely associated with the sperm cells within the pollen tube. The number of plastids and plastid nucleoids (DNA aggregates) in the sperm cell pair, collectively, is not significantly different from that in the generative cell; however, over 60% of the sperm cell plastids contain no DNA detectable with DAPI. The mean number of mitochondria in sperm cells is reduced from that in the generative cell (from 54 to 17), which suggests that paternal mitochondrial inheritance probably does not occur in the genotype investigated. Sperm cells of a pair may vary in their shape within the pollen grain and tube, but the number of plastids and mitochondria is not significantly different between the sperm cells. Therefore, heterospermy is not a factor determining cytoplasmic inheritance patterns in this species.     

Brassica napus pollen development during generative cell and sperm cell formation

Summary Brassica napus pollen development during the formation of the generative cell and sperm cells is analysed with light and electron microscopy. The generative cell is formed as a small lenticular cell attached to the intine, as a result of the unequal first mitosis. After detaching itself from the intine, the generative cell becomes spherical, and its wall morphology changes. Simultaneously, the vegetative nucleus enlarges, becomes euchromatic and forms a large nucleolus. In addition, the cytoplasm of the vegetative cell develops a complex ultrastructure that is characterized by an extensive RER organized in stacks, numerous dictyosomes and Golgi vesicles and a large quantity of lipid bodies. Microbodies, which are present at the mature stage, are not yet formed. The generative cell undergoes an equal division which results in two spindle-shaped sperm cells. This cell division occurs through the concerted action of cell constriction and cell plate formation. The two sperm cells remain enveloped within one continuous vegetative plasma membrane. One sperm cell becomes anchored onto the vegetative nucleus by a long extension enclosed within a deep invagination of the vegetative nucleus. Plastid inheritance appears to be strictly maternal since the sperm cells do not contain plastids; plastids are excluded from the generative cell even in the first mitosis.     

Male reproductive cell development in Nicotiana tabacum: male germ unit associations and quantitative cytology during sperm maturation

Generative and sperm cells were examined at four stages of development from generative cell formation to sperm cell maturation using serial transmission electron microscopy. The generative cell and vegetative nucleus are associated in a male germ unit association during pollen maturation and tube elongation, except for generative cell mitosis. At late stages of prophase, this association loosens; the generative cell separates from the vegetative nucleus at metaphase. Slender, unbranched, or occasionally branched projections may be found at one or both ends of the generative cell, or they may be single, blunt, and short. Slender projections are rare during anaphase and telophase. The vegetative nucleus moves back into apposition with one sperm cell at the end of mitosis. During the re-establishment of the association, the vegetative nucleus first touches the end of the leading sperm cell and then moves next to the middle of the sperm nucleus. As the sperm cells enter interphase, a conventional association is re-established between one cell and the vegetative nucleus through one or more long and slender cytoplasmic extensions; these associations are maintained throughout later passage in the pollen tube. During maturation, a significant increase occurs in the surface area of the sperm cells (particularly in the sperm cell in association with the vegetative nucleus), and a lesser increase in nuclear volume and surface area. Other sperm cell parameters, including those of heritable organelles, remain unchanged during sperm cell maturation.     

Generative cell division and sperm cell formation in barley

Summary Shortly before and during division, the generative cell of barley (Hordeum vulgare L.) is located near the vegetative nucleus, in the peripheral layer of the highly vacuolated vegetative cell at the aperture pole. This position is also characteristic of the two resulting sperm cells. Conventional mitosis of the generative cell is followed by cytokinesis through cell plate formation. Just after division, the two sperm cells are enclosed together within a common inner vegetative cell plasma membrane, and they gradually separate from each other only during pollen maturation. The space between the generative or sperm cell plasma membrane and the vegetative cell plasma membrane is very thin and appears to be devoid of a cell wall. Both the generative cell and the young sperm cells contain a normal set of organelles; plastids devoid of starch are only sporadically observed. Our data indicate that in Hordeum vulgare the generative cell divides after migrating inside the pollen grain. This follows the pattern of development well established for several species with tricellular pollen.     

黑麦雄性细胞发育过程中细胞器DNA动态的荧光研究

DAPI(4’,6-diamidino-2-phenylindole)是一种DNA特异结合的荧光染料,可以用于在荧光显微镜下观察和检测各种DNA,尤其是细胞内含量甚微的DNA,包括质体DNA和线粒体DNA,其灵敏性和可靠性是被公认的,并得到了越来越多的Southern杂交实验的证明,而且实验操作简便易行。近几年,DAPI荧光技术已在细胞质遗传的研究领域获得了成功的应用。     

Behavior of organelle nuclei (nucleoids) in generative and vegetative cells during maturation of pollen inLilium longiflorum andPelargonium zonale

Summary The behavior of organelle nuclei during maturation of the male gametes ofLilium longiflorum andPelargonium zonale was examined by fluorescence microscopy after staining with 4,6-diamidino-2-phenylindole (DAPI) and Southern hybridization. The organelle nuclei in both generative and vegetative cells inL. longiflorum were preferentially degraded during the maturation of the male gametes. In the mature pollen grains ofL. longiflorum, there were absolutely no organelle nuclei visible in the cytoplasm of the generative cells. In the vegetative cells, almost all the organelle nuclei were degraded. However, in contrast to the situation in generative cells, the last vestiges of organelle nuclei in vegetative cells did not disappear completely. They remained in evidence in the vegetative cells during germination of the pollen tubes. InP. zonale, however, no evidence of degradation of organelle nuclei was ever observed. As a result, a very large number of organelle nuclei remained in the sperm cells during maturation of the pollen grains. When the total DNA isolated from the pollen or pollen tubes was analyzed by Southern hybridization with a probe that contained therbc L gene, for detection of the plastid DNA and a probe that contained thecox I gene, for detection of the mitochondrial DNA, the same results were obtained. Therefore, the maternal inheritance of the organelle genes inL. longiflorum is caused by the degradation of the organelle DNA in the generative cells while the biparental inheritance of the organelle genes inP. zonale is the result of the preservation of the organelle DNA in the generative and sperm cells. To characterize the degradation of the organelle nuclei, nucleolytic activities in mature pollen were analyzed by an in situ assay on an SDS-DNA-gel after electrophoresis. The results revealed that a 40kDa Ca²⁺-dependent nuclease and a 23 kDa Zn²⁺ -dependent nuclease were present specifically among the pollen proteins ofL. longiflorum. By contrast, no nucleolytic activity was detected in a similar analysis of pollen proteins ofP. zonale.     

Quantitative study of organelle nucleoids during the second pollen grain mitosis inOenothera biennis

Summary The behavior of organelle nucleoids in the generative cell was examined at the second (pollen grain) mitosis by epifluorescence microscopy after staining with 4,6-diamidino-2-phenylindole (DAPI) inOenothera biennis. TheO. biennis generative cell contained a large number of organelle nucleoids distributed randomly in the cytoplasm before mitosis. The epifluorescence images of the nucleoids could be classified distinctly into two groups which corresponded to plastid nucleoids (pt-nucleoids) and mitochondrial nucleoids (mt-nucleoids). Discrimination between pt- and mt-nucleoids was carried out with the aid of DNA immunogold electron microscopy. At metaphase, both pt- and mt-nucleoids migrated to the pole regions of the generative cell. After mitosis, organelle nucleoids in both of the sperm cells scattered in the cytoplasm again. A quantitative examination of pt-nucleoids on 202 pairs of sperm cells showed that the leading sperm cell (Svn) contained 0–39 pt-nucleoids (19.0 ± 7.4) and the trailing sperm cell (Sua) contained 0–40 pt-nucleoids (15.4 ± 6.5). For mt-nucleoids, examination of 28 pairs of sperm cells showed that Svn contained 5–32 mt-nucleoids (14.5 ± 6.8) and Sua contained 6–30 mt-nucleoids (13.4 ±7.5). These results showed that (1) the number of organelle nucleoids per sperm cell varied considerably in the cells studied; (2) quantitative difference in pt- and mt-nucleoids between Svn and Sua could occur in some gametophytes studied; but (3) it was unlikely that there was any pre-differentiational cytoplasm localization and essential sperm heteromorphy with respect to organelle nucleoid content in the gametophyte population.     

Ultrastructural studies on plastids of generative and vegetative cells inLiliaceae 3. Plastid distribution during the pollen development inGasteria verrucosa (Mill.) Duval

Summary This paper describes the development of pollen grains ofGasteria verrucosa from the late microspore to the mature two-cellular pollen grain. Ultrastructural changes and the distribution of plastids as a result of the first pollen mitosis have been investigated using light and electron microscopy. The microspores as well as the generative and the vegetative cell contain mitochondria and other cytoplasmic organelles during all of the observed developmental stages. In contrast, the generative cell and the vegetative cell show a different plastid content. Plastids are randomly distributed within the microspores before pollen mitosis. During the prophase of the first pollen mitosis the plastids become clustered at the proximal pole of the microspore. The dividing nucleus of the microspore is located at the distal pole of the microspore. Therefore, the plastids are not equally distributed into both the generative and the vegetative cell. The possible reasons for the polarization of plastids within the microspore are briefly discussed. The lack of plastids in the generative cell causes a maternal inheritance of plastids inGasteria verrucosa.     

被子植物生殖细胞与精细胞的分离方法

开花植物精细胞的发育经历一个独特的后减数分裂过程,在此过程中每个花粉母细胞减数分裂的产物——小孢子经不对称有丝分裂产生1个大的营养细胞和1个小的生殖细胞,随后生殖细胞经过正常的有丝分裂产生2个精细胞。近几年,随着高通量组学技术的不断完善,利用组学技术比较分析生殖细胞和精细胞的分子特征、揭示决定精细胞命运与功能以及受精识别的重要分子已成为植物生殖生物学备受关注的课题。开展此项研究的关键是建立能获得大量高纯度的生殖细胞与精细胞分离纯化技术。该文综述了被子植物生殖细胞和精细胞分离方法的主要研究进展,分析了关键方法的特点和要点以及不同方法之间的差异和共性,以期为相关领域的研究人员提供借鉴。     

Examination of the cytoplasmic DNA in male reproductive cells to determine the potential for cytoplasmic inheritance in 295 angiosperm species

Mature pollen grains of 295 angiosperm species were screened by epifluorescence microscopy for a marker that denotes the mode of cytoplasmic inheritance. We used the DNA fluorochrome DAPI (4',6-diamidino-2-phenylindole) for pollen cell staining. The presence or absence of fluorescence of cytoplasmic DNA in the generative cell or sperm cells was examined in each species. The species examined represented 254 genera and 98 families, and 40 of these families had not been previously studied in this regard. The cytoplasmic DNA of the generative cell or sperm cells did not fluoresce in 81% of the species examined, from 83% of the genera and 87% of the families examined, indicating the potential for maternal cytoplasmic inheritance in these species. In contrast, the male reproductive cells of 19% of the species, from 17% of the genera and 26% of the families examined, displayed fluorescence of the cytoplasmic DNA, indicating the potential for biparental cytoplasmic inheritance in these species. The results revealed the potential for biparental cytoplasmic inheritance in several species in which the inheritance mode was previously unknown, including plants in the Bignoniaceae, Cornaceae, Cruciferae (Brassicaceae), Cyperaceae, Dipsacaceae, Hydrocharitaceae, Papaveraceae, Portulacaceae, Tiliaceae, Valerianaceae, and Zingiberaceae. Electron microscopy revealed that the sperm cells of Portulaca grandiflora contain both plastid and mitochondrial DNA. However, in the generative cells of Musella lasiocarpa, the mitochondria contain DNA, but the plastids do not. These data provide a foundation for further studies of cytoplasmic inheritance in angiosperms.     

土麦冬离体萌发花粉管中生殖细胞与营养核的动态变化

主要报道了土麦冬人工培养萌发花粉管中生殖细胞与营养核的动态变化。多数花粉管中,生殖细胞与营养核贴合后,开始进行有丝分裂,贴合时,营养核略呈弥散状态。在分裂早中期,生殖细胞与营养核分开,从贴合到分开大约经历３－５ｈ,精子形成后,不与营养核连接。ＤＡＰＩ对生殖细胞的有丝分裂有抑制作用。少数花粉管中,生殖细胞核进行无丝分裂,有缢裂和劈裂两种方式。生殖细胞核发生缢裂的花粉管中,未观察到生殖细胞与营养核的贴     

Ultrastructure of Male Gametophyte in wheat I. The Formation of Generative and Vegetative Cells

The present study of the formation of the generative and vegetative cells in wheat has demonstrated some cytological details at the ultrastructural level. The phragmoplast formed in telophase of the first microsporic mitosis extended centrifugally until it connected with the intine of the pollen grain. A new cell wall was then formed to separate the generative and the vegetative cells. By unequal cytokinesis the former is small and the latter large. In early developmental stage of male gametophyte, the organelles in the cytoplasm of the generaVive cell and the vegetative cells are similar, including mitochondria, dictyosomes, rough endoplasmic retieulum, free and clustered ribosomes and plastids, but microtubules were observed only in the early cytokinesis stage. In the further developmental stage of the male gemetophyte, the generative cell gradually detached from the intine of pollen grain and grew inward to the cytoplasm of the vegetation cell. When the generative cell became round and free in the cytoplasm of the vegetative cell, the wall materials between plasma membranes of the cytoplasm of the generative and the vegetative cells disappeared completely, so that it was a naked cell with a double-layer membrane at this time. The heterogeneity between both cells was then very conspiceous. The organelles in the cytoplasm of the generative cell have hardly any changed besides the degeneration of plastids, but in vegetative cytoplasm the mitochondria and plastids increased dramatically both in number and size. The rapid deposition of starch in the plastids of the cytoplasm of the vegetative cell made the most conspicuous feature of the vegetative cell in mature pollen grain. The significance of the presence of a temporary cell wall in generative cell and heterogeneity between generative and vegetative cells are discussed.     

Cytological Studies of the Cytoplasmic Inheritance in Lilium regale and L. davidii

The distribution and characteristics of plastids and mitochondria in the generative and sperm cells of Lilium regale Wils. and L. davidii Duch. were described. In L. regale there were few plastids and abundant mitochondria in the newly formed generative cell. When the generative cell became free in the vegetative cytoplasm, the plastids degenerated completely within the generative cell. It was further proved by DAPI fluorescent technique that there was no organell DNA in the generative cell within the mature pollen grain or the pollen tube. However, distribution of the plastids was strictly polarizable during the division of the micmspore in L. davidii, resulting the lack of plastids in the newly formed generative cell. Data of RFLP analysis comparable between L. davidii, L. longifiorum and their interspecific hybrid have also proved the plastid inheritance in L. davidii to be of uniparental maternal transmission. Although the mitoehondria were observed both in the generative and sperm cells of L. regale and L. davidii but their DNA was decomposed in the male gametophyte stage. Therefore the mitochondda in the sperm cell could not be transmitted into the offspring. The results provided the detail, cytological evidence that organelles in the microgametophyte are incapable of genetic transmission in the two species of Lilium.     

Arabinogalactan proteins at the cell surface ofBrassica sperm andLilium sperm and generative cells

Antibodies to arabinogalactan proteins were tested for binding to sperm cells ofBrassica campestris and to generative cells and sperm ofLilium longiflorum. Two monoclonal antibodies, JIM8 and JIM13, bound toBrassica sperm in pollen grains and pollen tubes and to isolated sperm. Sperm pairs retained within the vegetative cell inner plasma membrane fluoresced more brightly than single sperm, indicating that the vegetative cell inner plasma membrane that surrounds sperm pairs also contains arabinogalactan proteins. Isolated sperm pairs exhibited a uniform fluorescence while single sperm had patches of fluorescence. InLilium, isolated generative cells and single sperm cells bound antibodies in a patchy pattern. Antibodies to arabinogalactan proteins may be useful in describing the overall shape of sperm cells and for identifying sperm among other cell types.     

The Cytological Mechanism of Biparental Cytoplasmic Inheritance in Pelargonium hortorum -Ultrastructural and DNA Fluorescence Studies of Male and Female

Electron microscopic investigation has demonstrated that plastids and mitochondria are conserved in the generative cell, sperm cells and egg cell of Pelargonium hortorum Bailey. The plastids in the generative cell which contain starch for a short period, gradually changed to proplastids during the maturation of generative cell. The plastids in the sperm cells are large and numerous the characteristics of dense matrix and an abundant endomembrane systems. These plastids always appear ringlike in cross section. In the generative cell and sperms, the spherical or rod-shaped mitochondria are smaller than the.plastids and remain unchanged during the development process from generative cell to sperm cells. DNA filaments are visualized in the transparent central zone of the mitochondria. In the egg cell, plastids are more abundant than mitochondria. The structures of the plastids and mitochondria are obviously different from those in the sperm cell. Most of the plastids are irregularly rod-shaped and contain starch, the mitochondria are about 3 times larger than those in the sperm cells. Most of them are cup-shaped as proved by successive sections. DNA epifluorescence study demonstrated that DNA nucleoids are present in both plastids and mitochondria of the egg, generative cell and sperm cells. In the sperm cells, there is no ringlike DNA nucleoid as is existed in the egg cell. This study has defined the characteristics of the plastids and mitochondria in both male and female gemates of P. hortorurn. The results are essential contributions for further investigation of the biparental organelle transmission in the zygote and proembryo.     

天竺葵质体和线粒体双亲遗传的细胞学机理——雄性和雌性配子超微结构和DNA荧光的研究

天竺葵（Ｐｅｌａｒｇｏｎｉｕｍ ｈｏｒｔｏｒｕｍ Ｂａｉｌｅｙ）生殖细胞和精细胞在发育中始终存在质体和线粒体。在精细胞中,质体的体积大、数量多,具基质浓厚和在切面上多为环状的特点。线粒体在生殖细胞和精细胞中没有差异,体积较质体小得多,球形或杆状,边缘染色较深。在卵细胞中质体的含量比线粒体丰富,这两种细胞器的结构形态与精细胞的有明显的差异。细胞的质体多呈不规则的棒状和含淀粉粒。线粒体比精细胞的大２—３ 倍,许多为环状。ＤＮＡ 荧光的检测证明了在生殖细胞、精细胞和卵细胞中存在质体和线粒体类核。卵中的环状线粒体类核的形态在精细胞中是不存在的。本研究确定了雄性和雌性配子的质体和线粒体在结构形态上各具特点,可作为鉴别它们的标记,从合子中查明雄性质体和线粒体是否传递,以及在胚胎发育的早期雌雄亲本来源的细胞器的动态     

Arabidopsis CDKA;1, a cdc2 homologue, controls proliferation of generative cells in male gametogenesis

The protein kinase cdc2 is conserved throughout eukaryotes and acts as a key regulator of the cell cycle. In plants, A-type cyclin-dependent kinase (CDKA), a homologue of cdc2, has a role throughout the cell cycle. Here we show that a loss-of-function mutation in CDKA;1, encoding the only Arabidopsis CDKA, results in lethality of the male gametophyte. Heterozygous plants produced mature siliques containing about 50% aborted seeds, and segregation distortion was observed in paternal inheritance. Microspores normally undergo an asymmetric cell division, pollen mitosis I (PMI), to produce bicellular pollen grains. The larger vegetative cell does not divide, but the smaller generative cell undergoes mitosis, PMII, to form the two sperm cells, thereby generating tricellular pollen grains. The cdka-1 mutant, however, produces mature bicellular pollen grains, consisting of a single sperm-like cell and a vegetative cell, due to failure of PMII. The mutant sperm-like cell is fertile, and preferentially fuses with the egg cell to initiate embryogenesis. As the central cell nucleus remains unfertilized, however, double fertilization does not occur. In heterozygous plants, the embryo is arrested at the globular stage, most likely because of loss of endosperm development, whereas it is arrested at the one- or two-cell stage in presumptive homozygous plants. Thus, CDKA;1 is essential for cell division of the generative cell in male gametogenesis.     

Ultrastructure of Male Gametophyte in Wheat II. Formation and Development of Sperm Cell

Ultrastructural events in wheat sperm cell development were examined from the division of generative cell stage to the maturation of sperm cell in pollen grains. The results are smnmarized as follows: 1. The generative cell in forming microspore by mitosis goes through a series of changes including tile displacement and transformation. It finally becomes a spindle-shaped cell getting ready for another mitosis. The generative cell at this stage is naked. it is only surrounded by both membranes of its own and vegetative cell Most part of the generative cell is occupied by the conspicuous elliptical nucleus with highly condensed chromatin. With the exception of ribosomes, the organelles in the thin layer of generativc cell cytoplasm are obviously fewer and smaller than those in the vegetative cytoplasm. The mierotubules may also be seen in the cytoplasm of spindle-shaped generative cell parallel to the long axis of the cell. There is no amyloplast in generative cell. 2. When the generative cell has moved to the position close to the vegetative nucleus again, it begins to divide. The formation of sperm cells as the result of mitosis of generative cell, and the development of sperm cell involves the following main changes. The shape of the sperm cell tranforms from spherical to elliptical, finally it forms an elongated cell with a tail-like structure. At the sametime, the distribution of cytoplasm gradually concentrated at one end of the sperm cell to form the cytoplasmic extension, so that the so called "tail" of the sperm cell is formed. There are more organelles, especially the mitochondria, assembling in this part. The sperm cell just formed after mitosis is naked and the enclosed plasma membrane is discontinuous. The sperm cell membrane is enclosed by vegetative cell membrane, and the double membranes may be completed at a later stage. It is considered that the period which follows is very short, the deposition of wall material, the callose, occurs to fill up continuously the space between two membranes, but soon after this period the cell wall becomes discontinuous and the wall material is obviously decreased. The significance of the position of the generative cell before its mitosis and the morphological changes during the development of the sperm cell are discussed in this paper.