黄芪的胚胎学研究Ⅰ、雌雄配子体发育

通过光学显微镜对黄芪雌雄配子体的发育过程进行观察, 同时对花粉发育进行细胞化学实验, 其主要结果如下;1.花粉第一次有丝分裂形成一个较小的半球形生殖细胞和一个较大的营养细胞。2.生殖细胞发育过程中存在暂短的细胞壁, 经PAS反应和苯胺兰荧光显微反应鉴定均为负反应。即:生殖细胞壁并未显示出纤维素或胼胝质性质的壁。3.营养细胞与生殖细胞之间壁的解体及生殖细胞进入营养细胞的过程。4.成熟花粉中的生殖核为孚尔根反应强阳性, 营养核为弱的正反应。5.雌配子体发育起源于珠心组织亚表皮下的孢原细胞其中只有一个孢原直接发育成为蓼型胚囊。 文中对黄芪花蕾外部形态及其内部雌雄配子体的发育作了相关性比较。     

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     

莴苣花粉发育过程中ATP酶的分布

对莴苣花粉发育过程中ATPase的分布特征做了研究。四分体早期的小孢子细胞质中开始出现ATPase反应颗粒。之后,小孢子在发育过程中,花粉内壁聚集大量体积较大的ATPase反应颗粒,并一直保持到花粉即将成熟。在小孢子发育晚期,在花粉萌发孔处和小孢子大液泡中也特异性地聚集了较多ATPase颗粒。二胞花粉刚形成的生殖细胞表面呈现大量的ATPase反应颗粒,当生殖细胞脱离花粉内壁移入营养细胞,ATPase反应颗粒基本消失。生殖细胞分化过程中生殖细胞的ATPase反应颗粒逐渐低于营养细胞中的。在成熟花粉中,精细胞中的ATPase反应颗粒比营养细胞中的少,且主要集中在细胞核中。结果显示花粉发育过程中ATPase的特异分布与花粉发育的一些生物学事件密切相关。     

红松配子体的发育过程

红松是我国主要用材树种,材质优良。我国主要分布在长白山和小兴安岭,随着森林工业的发展,大面积的原始森林迅速减少,人工更新日趋重要。在生产中采用种子育苗,因此对红松种子的发育规律应全面掌握,以便为种子园建立、良种选育采取有效措施提供理论依据。根据国内外有关报导,红松雌雄配子的形成、受精作用已有一定的研究^[14、15],但这些研究只侧重在小孢子母细胞的减数分裂和受精作用。故对雌雄配子体的发育过程仍需深入研究,尤其是授粉后的雄配子体发育和精子进入颈卵器的过程,均未见详细报导。     

The formation of the generative cell in Polystachia pubescens (Orchidaceae)

Summary The formation and nature of the generative cell wall and the detachment mode of the generative cell from the intine in Polystachia pubescens were observed by LM and TEM. Vesicles evenly positioned within the phragmoplast fuse to form a cell plate that divides the microspore into the generative and vegetative cell. This cell plate consists of callose. Before the generative cell leaves the intine, however, the callose is completely resorbed and is not replaced by any other substance. The generative cell becomes detached from the intine by moving towards the centre of the pollen grain. A constriction formed thereby gives the generative cell a bulb-like appearance and leads ultimately to the generative cell being pinched off. Plasma-filled vesicles originating from the generative cell remain between the intine and the plasma membrane of the vegetative cell.     

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.     

Microgametogenesis in Plumbago zeylanica (Plumbaginaceae). 1. Descriptive cytology and three-dimensional organization

The generative cell is initiated as a small, lenticular, unpolarized cell with a cell wall traceable to two origins: the external segment originates as intine, while an inner callose positive cell wall forms de novo. As the lenticular generative cell begins its migration into the pollen cytoplasm, the generative cell becomes polarized both externally and internally, displaying a characteristic shape and patterns of organelle distribution oriented with respect to the vegetative nucleus and independent of pollen aperture location. Separation of the generative cell from the pollen wall begins at the end opposite the vegetative nucleus and results in an elongating protuberance at the opposite end of the generative cell; this becomes associated with a preformed groove located on the surface of the vegetative nucleus. The generative cell subsequently separates from the intine near the vegetative nucleus and moves progressively toward the opposite end of the cell; during this separation, the edge of the wall facing the intine becomes callose-positive and remains so until separating from the intine. The generative cell becomes a free cell within the pollen, which is in physical association with the vegetative nucleus. Generative cell organization and organelle content become increasingly polarized during maturation, with microtubules evident both in the elongating protuberance of the generative cell and in association with organelles. The generative nucleus migrates away from the vegetative nucleus and toward the plastid-rich end of the generative cell, whereas mitochondria are more generally distributed within the cell. Generative cell polarization is made permanent during mitotic division and cytokinesis, i.e., two sperm cells differing in morphology are formed: the larger cell associated with the vegetative nucleus (S_vn) contains a majority of the mitochondria, and the smaller, unassociated sperm cell (S_ua) receives the plastids.     

DEVELOPMENT OF OMNIAPERTURATE POLLEN IN TRILLIUM KAMTSCHATICUM (LILIACEAE)

Ultrastructural changes during omniaperturate pollen development in Trillium kamtschaticum Pall, was examined using transmission electron microscopy. The pollen mother cells are not enveloped within a thick callosic wall. The microspores resulting from successive meiosis are divided by scanty deposition of callosic wall in the tetrad. A primexine/exine template is not recognizable within the tetrad during formation of exinous components. Preexinous globules, originating from vesicles in the callosic wall, accumulate electron-dense materials and develop into exinous globules. The preexinous globules have ca 10 nm wide contacts with tilted and invaginated plasma membrane of the microspore within the callosic wall. After dissolution of the callosic wall, the microspores separate and mitosis subsequently leads to the formation of a generative cell and vegetative cell encased in a loose aggregation of developing exinous globules. When the generative cell is at the pollen grain surface, the channeled zone is initiated at the opposite side of the microspore on the surface of the vegetative cell. Just before pollen maturity, a new layer develops under the channeled zone. Thus, development of the omniaperturate pollen grains of T. kamtschaticum involves some processes that are distinct from those of Canna and Heliconia and some that are similar.     

Determination of a position of a functional pore in the tobacco pollen

Pollen hydration and germination on the "wet" stigma of Nicotiana tabacum L. were studied by SEM and TEM to reveal the role of the stigma in selecting the germinative pore, and in establishing the axis of polarity in the pollen grain. Pollinated stigmas were fixed with glutaraldehyde or osmium tetroxide vapour, or processed with rapid freeze fixation and freeze substitution. Fixation was performed in 5, 15 or 30 min and 3.5 h after pollination. The tube easily emerged from either pore, this process not depending on the pollen grain orientation relative to the stigma. The orientation of pollen tubes remained random till their length becomes longer than the pollen grain diameter. The TEM analysis of ultrastructural changes in poral regions during pollen hydration and germination showed that the germinative pore was positioned just near the generative cell and vegetative nucleus. Within the first 5 min after pollination a new layer of the electron-lucent wall adjacent to the plasma membrane was formed in the region of a future germinative pore. Following 15 min, marked changes were revealed in the cytoplasm region, close to the germinative pore. Minute dictyosome vesicles were accumulated near the plasma membrane. Small mitochondria and short ER cisternae were distal to a zone of secretory vesicles. The data suggest that the axis of polarity in the germinating pollen grain is predetermined by a spatial organization of the vegetative cell.     

ULTRASTRUCTURAL COMPARISION OF POLLEN GRAINS FROM 2n, 3n,AND 4n PLANTS OF EUPHORBIA DULCIS

Pollen development in plants with different ploidy levels of Euphorbia dulcis is similar but some ultrastructural differences do occur. In pollen of diploid plants large aggregations of rough endoplasmic reticulum [RER] are attached to the pollen wall near the young generative cell but such aggregations are not present in other karyotypes. Plastids are detected only in young generative cells of triploid plants. In diploid plants the generative cell becomes spindle-shaped, in triploid and tetraploid plants it remains round during the movement from the pollen wall to the center of the vegetative cell. The intine surrounding the generative cell in 3n plants is thinner than that found in 2n and 4n plants. Pollen grains in tetraploid plants are twice as large as those in diploid plants. Pollen viability is 90% in 2n plants, but only 10% in 4n plants.     

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.     

Pollen morphology and pollen-wall proteins (localization and enzymatic activity) inSesamothamnus lugardii (Pedaliaceae)

The pollen grains ofSesamothamnus lugardii Stapf (Pedaliaceae of subdesert regions of SE tropical Africa) are associated in acalymmate tetrads (cross wall cohesion), with a tectate and perforate exine and 8–12 colpi. The pollen wall consists of an ectexine with a complete, perforate and ample tectum, columellated infratectum and clearly interrupted and fragmented foot layer. The endexine is built of scanty lamellae and granules. The intine is bistratificate, with a homogeneous, fibrillate layer (endintine or intine-2) and a heterogeneous, more lax and channeled layer (exintine or intine-1). Test for glycoprotein is particularly positive in the homogeneous internal intine and channels of external intine. On the other hand acid phosphatase has been localized in the exine and channeled external intine layers. These observations confirm the general interpretation of the distribution of wall compounds.     

Cotton embryogenesis: The pollen cytoplasm

Summary The ultrastructure and composition of cotton (Gossypium hirsutum) pollen, exclusive of the wall, was examined immediately before and after germination. The pollen grain before germination consists of two parts: the outer layer and a central core. The outer layer contains large numbers of mitochondria and dictyosomes as well as endoplasmic reticulum (ER). The core contains units made of spherical pockets of ER which are lined with lipid droplets and filled with small vesicles; the ER is rich in protein and may contain carbohydrate while the vesicles are filled with carbohydrate. Starch-containing plastids are also present in the core as are small vacuoles. The cytoplasm of the pore regions contains many 0.5 spherical bodies containing carbohydrate. After germination the ER pockets open and the lipid droplets and small vesicles mix with the other portions of the cytoplasm. With germination the pore region becomes filled with mitochondria and small vesicles. The vegetative nucleus is large, extremely dense and contains invaginations filled with coils of ER. A greatly reduced nucleolus is present in the generative cell which is surrounded by a carbohydrate wall. The cytoplasm of the generative cell is dense and contains many ribosomes, a few dictyosomes and mitochondria, many vesicles of several sizes, and some ER. No plastids were identified. The generative nucleus is also dense with masses of DNA clumped near the nuclear membrane. An unusual tubular structure of unknown origin or function was observed in the generative cell.     

Pollen ultrastructure in anther cultures of Datura innoxia. III. Incomplete microspore division.

During the microspore division in Datura innoxia, the mitotic spindle is oriented in planes both perpendicular (PE) and oblique (OB) to the spore wall against which the nucleus is situated. However, irrespective of polarity, the usual type of hemispherical wall is laid down at cytokinesis and isolates the generative cell from the rest of the pollen grain (type A). In PE spores the vegetative nucleus initially occupies a central position in the pollen grain, whereas in OB spores the vegetative nucleus lies at the periphery of the grain close to the generative cell. In anther cultures initiated just before the microspore division is due to take place, no marked change can be observed in either orientation or symmetry of the mitotic spindle when the spores divide. In some, however, cytokinesis is disrupted and deposition of the hemispherical wall arrested. In the absence of a complete wall, differentiation of the generative cell cannot take place and binucleate pollen grains are formed having 2 vegetative-type nuclei (type B). The 2 nuclei in the B pollens are always situated against the pollen-grain wall, suggesting that the disruption phenomenon is related to the OB spores. The incomplete wall always makes contact with the intine on the intine-side of the spindle. Wall material may be represented merely as short stubs projecting out from the intine into the cytoplasm, in which event the 2 nuclei lie close to each other and are separated by only a narrow zone of cytoplasm. In other grains the wall is partially developed between the nuclei and terminates at varying distances from the tonoplast; in these, the nuclei are separated by a wider zone of cytoplasm. The significance of these binucleate grains in pollen embryogenesis is discussed.     

洋葱花粉发育过程中ATP酶的分布特征(简报)

在真核细胞中,除了线粒体和叶绿体ATPase的功能是合成ATP外,其余部位ATPase是水解ATP以获取生物能量的代谢酶,在生物体细胞内广泛存在。探索ATPase在细胞中的分布状态是研究细胞生理状态的一种重要手段。ATPase在细胞中的多少可反映出细胞当时的生活状态,这一特征已被初步用于探索小麦和水稻雄性不育的细胞生物学研究中,希望通过比较可育花药和不育花药中ATPase的分布差异寻找雄性不育的机理,发现     

The Development and Structure of the Generative Cell Wall in Polygonatum simizui

The developmental structure and components of the generative cell wall in Polygonatum sirnizui Kitag were studied by means of cytochemical and electron microscope observation. The early generative cell wall separating the generative and vegetative cytoplasm contains callose and cellulose. From the time when the generative cell detaches from the intine untill it is freely suspended in the cytoplasm of the vegetative cell, the wall becomes progressively thinner and does not show the specific fluorescence when stained with aniline blue and cai- cofluor white although it remains PAS positive. At later developmental stage when the generative cell moves into the pollen tube but before its initiation of mitosis, an envelope with weak PAS positive reaction appears on the surface of the cell. Its morphological nature is similar to that of the sperm cell discribed as the "periplasm”. This study proves that a cell wall is present in the generative cell of Polygonatum simizui throughout the developmental process, althrough changes in structure and components of the wall may occur. The properties of the generative cell wall at different stages, its significance in differentiation between generative and vegetative cytoplasm and translocation of nutrient materials, and the possible mechanism of the detachment of the generative cell from the intine are the subjects to discussion.     

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.     

侧柏小孢子的发生和雄配子体的形成

侧柏[Platycladusorientalis（L．）Franco]初生造孢细胞在8月下旬（1992年）形成,11月上旬形成小孢子母细胞,1993年2月中旬形成四分体,2月下旬小孢子从四分体内释放出来,3月中旬形成成熟花粉粒并开始传粉,4月上旬花粉粒在珠心上萌发,5月上旬生殖细胞分裂,6月上旬精原细胞分裂。小孢子母细胞在休眠以前开始减数分裂,解除休眠以后形成成熟的花粒粒。减数分裂从11月上旬开始至次年2月17日结束。小孢子母细胞减数分裂存在扩散双线期。小孢子母细胞以双线期渡过休眠。精原细胞接近颈卵器时开始分裂,形成两个大小相同的精细胞。精细胞独立存在的时间很短。精细胞的细胞质分为三个区域。小孢子母细胞在发育过程中,发现有部分小孢子母细胞退化,在小孢子囊内形成一大的空腔的现象。     

An Ultrastructural Study on Pollen Protoplasts and Pollen Tubes Germinated From Them in Gladiolus gandavensis

Large quantities of protoplasts were isolated enzymatically from the mature pollen grains in Gladiolus gandavensis. Regeneration of cell wall and germination of pollen tubes were performed during culture of purified pollen protoplasts in Ks medium supplemented with 32% sucrose, 0.1 mg/1 2,4-D, 1 mg/1 NAA and 0.2 mg/1 6-BA, with a germination rate up to 47.7%. The materials were fixed gently with gradually increasing concentration of glutaraldehyde, followed by osmium, then preembedded in a thin layer of agar and surveyed under an inverted microscope so as to select desired specimens for subsequent procedure. Small agar blocks containing specimens were dehydrated through ethanal-propylene oxide series, embedded in Araldite and ultratomed. Electron microscopic observations show that the pollen protoplasts are surrounded by a smooth plasma membrane and with ultrastructurally intact cytoplasm, a vegetative nucleus and a generative cell. After 8h of culture, wall regeneration commences resulting in a multilayered, fibrillar wall structure which is different from the intine. No exine is formed. Numerous vesicles participate actively in the wall formation. The wall is uneven in thickness around its periphery; a thickened area somewhat resembling to germ furrow is formed, from which pollen tube emerges. The tubes contain abundant plastids, mitochondria and dictyosomes. Vesicles are released out of the plasma membrane and involved in tube wall formation. After 18h of culture, the vegetative nucleus and generative cell have migrated into the tube. Technical points of preparing pollen protoplast specimens for ultastructural studies and the fearnres of wall regeneration in pollen protoplast culture are discussed.     

DNA Synthesis in Microspores in Anther Culture of Wheat (Triticum aestivum L.)

Anthers with mid-unlnucleate microspores were cultured on W5 medium supplemented with 0.5 mg/l kinetin, 2 mg/l 2,4-D and 9% or 3% sucrose. At a series of interval (0, 1, 1.5, 2, 14 days) after cultured, the anthers were labelled with 3H-thymidine (4 MCi/mi) for 24 h, fixed, and then performed autoradiography according to conventional method. Results show that after cultured for 24 h, 3H-thymidine was incorporated into some late-uninucleate microspores (see Plate I, 3), and after for 2.5 days, vegetative nuclei in pollen grains were la- belled (see Plate I, 4). Usually, vegetative nuclei were labelled frequently and generative ones were labelled rarely. Sometimes generative cell which could synthesis DNA might develop suspensor-like structure individually (see Plate I, 13). During early stage of development of a multicellular pollen grain, the DNA synthesis in the cells were synchronized. With pollen development, the synchronism of DNA synthesis was destroyed. When anthers cultured on medium with 3% sucrose, DNA in microspores could be synthesized normally, and the number of labelled microspores was more than that of anthers cultured on medium with 9% sucrose. However, on medium with 3% sucrose, the nuclei in microspores stopped dividing after one or two divisions and the cell wall of them could not be formed and multicellular pollen was not observed. It seems that the absence of multicellular pollen on medium with 3% sucrose was primarily due to the block of cell division and cell wall formation, not due to the interruption of DNA synthesis.