麦冬花药绒毡层和乌氏体的细微结构

麦冬(Ophiopogon japonicus)的绒毡层发育为分泌型。在小孢子母细胞时期,绒毡层细胞达到了发育的高峰。此时,绒毡层细胞中细胞器非常丰富,具大量线粒体、高尔基体和质体,尤以肉质网含量最多;原乌氏体出现较早,在小孢子母细胞时期绒毡层细胞中就已出现;四分体时期,大量原乌氏体被排入内切向面的质膜和纤维素壁之间;到了小孢子早期,绒毡层细胞失去细胞壁,原乌氏体分布在质膜的凹陷处,孢粉素物质在其上沉积,发育为乌氏体,乌氏体有单个和复合两种类型;当花粉成熟时,绒毡层细胞完全解体。     

ONTOGENETIC DEVELOPMENT OF SPINOUS EXINE IN HIBISCUS SYRIACUS (MALVACEAE)

Pollen development in Hibiscus syriacus L. (Malvaceae) was studied with light (LM), scanning (SEM) and transmission (TEM) electron microscopes, with special attention to the formation of extremely long spines of the pollen grains. At the early tetrad stage, probacules are initiated directly on the plasma membrane and grow in coincidence with the height of primexine matrix within a callosic wall. Subsequently, a pretectum appears at the top of the probacules and then a foot layer is formed by accumulation of white line centered lamellations. Before dissolution of the callosic wall, a reticulate patterned pretectum is established around the microspores. There is not, however, any morphological indication on the initiation of the spines during the tetrad period within a callosic wall. It is after dissolution of the callosic wall that the spines of exine begin to form by the apposition of lamellated sheets. The lamellated sheets show a concentric configuration around the developing supratectal spines. The mature pollen grain is spheroidal, polycolporate, 160–170 μm in diameter, with supratectal spines 20–25 μm long. The supratectal spines of Hibiscus pollen are not homologous with the other exinous protrusions which are determined within the callosic wall during tetrad stage.     

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.     

Fine Structure of Tapetal Cells and Ubisch Bodies in the Anther of Ophiopogon japonicus

The development of the tapetum in Ophiopogon ]aponicus is of secretory type Tapetum develops at their peak during the microspore mother cell stage. There are abundant organelles, consisting of a lot of mitochondria, dictyosomes and plastids, especially endoplasmic reticulum. Pro-Ubisch bodies e. merge as early as at the stage of microspore mother cell. At tetrad stage, a large number of pro-Ubisch bodies accumulate between inner tangential face of the plasmalemma and the cell wall. At the early microspore stage, pro-Ubisch bodies are distributed in the small embayments of the plasmalemma. As the sporopollenin begins to deposit on them, proubisch bodies develop into Ubisch bodies which consist of two types: single and aggregated. Tapetal cells degenerate completely when pollen grains reach maturity.     

地黄绒毡层二型性的超微结构研究

地黄的花药绒毡层具二型性,来源于初生壁细胞的ｐ－绒毡层,细胞较小,为分泌型绒毡层,在小孢子阶段产生乌氏体,于两细胞花粉阶段解体,来源于药隔的ｃ－绒毡层细胞较大,解体的时间早于ｐ－绒毡层,不同药室的ｃ－绒毡层解体的起始时间不一致,可始于小孢母细胞减数分裂,四分体或小孢子阶段,其径向壁面向药室的壁也较早地开始解体,细胞质碎片与细胞器流入药室,分散在小孢子之间,较早解体的ｃ－绒毡层细胞不产生原乌氏体与乌     

Distribution of insoluble polysaccharides, neutral lipids, and proteins in the developing anthers of Campsis radicans (L.) Seem. (Bignoniaceae)

In this study, distribution of polysaccharides, lipids, and proteins in the developing anthers of Campsis radicans (L.) Seem. was examined from sporogenous cell stage to mature pollen, using cytochemical methods. To detect the distribution and dynamic changes of insoluble polysaccharides, lipid bodies, and proteins in the anthers through progressive developmental stages, semi-thin sections of anthers at different developmental stages were stained with periodic-acid-Schiff (PAS) reagent, Sudan black B, and Coomassie brilliant blue, respectively, and examined under light microscope. Ultrastructural observations with TEM were also carried out to determine the storage form of starch in the connective tissue, and storage form of lipids in the tapetal cells. In sporogenous cell stage, anther wall contains numerous insoluble polysaccharides. However, from the sporogenous cell stage to the vacuolated microspore stage, the amount of insoluble polysaccharides in the anther wall decreases gradually. At bicellular pollen stage, tapetum degenerates completely and polysaccharides are not seen in the anther wall. Lipid bodies are observed in the cytoplasm of both middle layer and tapetal cells at tetrad stage, whereas they disappear in the vacuolated microspore stage. Compared with polysaccharides, proteins are limited in the anther wall at early stages of development. During pollen development, polysaccharides, proteins, and lipid bodies are scarce in the cytoplasm of sporogenous cells, but their amount increases at premeiotic stage. From tetrad stage to bicellular pollen stage, microspore cytoplasm contains variable amount of insoluble polysaccharide grains, lipid and protein bodies. At bicellular pollen stage, plentiful amount of starch granules are stored in the cytoplasm of the pollen grains. Proteins and lipid bodies are also present in the cytoplasm.     

云南松小孢子发生的超微结构研究

云南松(Pinus yunnanensis Fr.)小孢子囊发育早期,原生质体发生收缩、同时形成胼胝质壁。小孢子母细胞减数分裂前互相分离,并被胼胝质壁包围。在壁上有约0.2微米的小孔。四分体小孢子形成后,核被膜及高尔基体显得非常地活跃,他们可能与外壁的沉积有关。这个现象在早期四分体阶段出现。内壁的形成是在自由小孢子时期,开始高尔基体和核被膜仍较活跃,但随之下降。内质网和线粒体增多,许多来自内质网的泡囊通过质膜被排放到内壁中去。乌氏体与花粉外壁之间观察到了孢粉素带。     

华北落叶松花粉发育过程中的钙动态分布

运用焦锑酸钾沉淀法研究了华北落叶松(Larix principis-rupprechtii Mayr)小孢子发育过程中不同阶段Ca2 的分布情况.减数分裂时期,小孢子囊壁表皮和中层细胞的细胞壁及细胞间隙Ca2 分布较多,绒毡层只有外切向面的细胞膜有Ca2 分布,小孢子母细胞的各部位则很少有Ca2 ;四分体时期,包围四分小孢子的胼胝质壁上有大量的Ca2 分布,在四分孢子壁上也有较多沉淀;游离小孢子时期,钙离子在小孢子壁的分布较四分体时期有所减少,而到花粉成熟时又逐渐增多;从四分体到花粉成熟,乌氏体周围的Ca2 有增多的趋势.对四分体外壁Ca2 的大量分布与花粉壁的形成及信号物质在花粉表面贮存的关系,以及小孢子囊的外壁、绒毡层和乌氏体在Ca2 向花粉运输中所起的作用进行了讨论.     

Morphological and histochemical differentiation of the pollen wall ofBetula pendula Roth,during dormancy up to anthesis

Summary Anthers ofBetula pendula were collected at regular intervals during the dormancy period until anthesis. Ultrathin sections of maturing pollen grains were especially stained for polysaccharides and proteins and examined with TEM to determine whether structural or/and chemical changes in the pollen wall occur during the dormancy period of the plant life cycle. At the beginning of the dormancy period, the microspore wall consists of a well developed tectum, columellae and a foot layer. Spinules and supratectal elements are prominent. Microchannels are present in the tectum but not obvious in the foot layer. Some of the columellae are not clearly connected with the foot layer, but some connections are evident. Pores are filled with a thick fibrillar network flocculent material. The cytoplasm is packed with starch grains and lipid globules. The stainability for acidic and neutral polysaccharides and protein was tested, and variations in the pollen wall are illustrated. As temperature increased towards the end of dormancy and before anthesis there is obvious differentiation in the morphology of the pollen wall. The granular fibrillar layer beneath the pore and the Zwischenkörper are the most variable part of the wall. Different histochemical reactions observed in different layers at the aperture sites indicate different functions of these layers.     

芝麻核雄性不育系ms86-1微粉发生的细胞学观察

芝麻(Sesamum indicum)核雄性不育系ms86-1姊妹交后代表现为可育、部分不育(即微粉)及完全不育(简称不育)3种类型。不同育性类型的花药及花粉粒形态差异明显。Alexander染色实验显示微粉植株花粉粒外壁为蓝绿色, 内部为不均一洋红色, 与可育株及不育株花粉粒的染色特征均不相同。为探明芝麻微粉发生机理, 在电子显微镜下比较观察了可育、微粉、不育类型的小孢子发育过程。结果表明, 可育株小孢子母细胞减数分裂时期代谢旺盛, 胞质中出现大量脂质小球; 四分体时期绒毡层细胞开始降解, 单核小孢子时期开始出现乌氏体, 成熟花粉时期花粉囊腔内及花粉粒周围分布着大量乌氏体, 花粉粒外壁有11–13个棱状凸起, 表面存在大量基粒棒, 形成紧密的覆盖层。不育株小孢子发育异常显现于减数分裂时期, 此时胞质中无脂质小球出现, 细胞壁开始积累胼胝质; 四分体时期绒毡层细胞未见降解; 单核小孢子时期无乌氏体出现; 成熟花粉时期花粉囊腔中未发现正常的乌氏体, 存在大量空瘪的败育小孢子, 外壁积累胼胝质, 缺乏基粒棒。微粉株小孢子在减数分裂时期可见胞质内有大量脂质小球, 四分体时期部分绒毡层发生变形, 单核小孢子时期有部分绒毡层开始降解; 绒毡层细胞降解滞后为少量发育进程迟缓的小孢子提供了营养物质, 部分小孢子发育为正常花粉粒; 这些花粉粒比较饱满, 表面有少量颗粒状突起, 但未能形成覆盖层, 花粉囊腔中及小孢子周围存在少量的乌氏体。小孢子形成的育性类型与绒毡层降解是否正常有关。     

华北落叶松花粉发育过程中的钙动态分布

运用焦锑酸钾沉淀法研究了华北落叶松(Larixprincipis-rupprechtiiMayr)小孢子发育过程中不同阶段Ca2 的分布情况。减数分裂时期,小孢子囊壁表皮和中层细胞的细胞壁及细胞间隙Ca2 分布较多,绒毡层只有外切向面的细胞膜有Ca2 分布,小孢子母细胞的各部位则很少有Ca2 ;四分体时期,包围四分小孢子的胼胝质壁上有大量的Ca2 分布,在四分孢子壁上也有较多沉淀;游离小孢子时期,钙离子在小孢子壁的分布较四分体时期有所减少,而到花粉成熟时又逐渐增多;从四分体到花粉成熟,乌氏体周围的Ca2 有增多的趋势。对四分体外壁Ca2 的大量分布与花粉壁的形成及信号物质在花粉表面贮存的关系,以及小孢子囊的外壁、绒毡层和乌氏体在Ca2 向花粉运输中所起的作用进行了讨论。     

POLLEN GRAIN DEVELOPMENT AND TAPETAL CHANGES IN STRELITZIA REGINAE (STRELITZIACEAE)

The proexine that forms within the callosic envelope before the end of the microspore tetrad period is thick (about 1 μm) and exceptionally complex. It has components equatable with tectum, columellae, and a nexine that includes lamellar zones. All these components persist in the exine although late in development they become difficult to recognize because this exine is reduced in thickness, apparently by stretching, to a maximum of 0.2 μm. Strelitzia is an example of an exine template, with receptors for sporopollenin, that is not maintained during development. The Strelitzia microspore surface changes from an exine like that on an interaperture sector to the channeled intinelike system common for the apertures of pollen grains. The exine on sterile grains gives what may be a rare view of a stabilized immature exine. The mature exine on viable pollen grains resembles this early exine only in the most impressionistic way. Tapetal cells go through at least one cycle of hyperactivity, dedifferentiation, mitosis, and then again hyperactivity before they finally decline.     

百合花药壁层的发育及组织化学研究

对生长在陕西留坝的百合的花药壁层发育过程,特别是绒毡层的发育做了形态学观察。其结果是：百合花药壁层的发育方式为基本型。花药绒毡层属腺质绒毡层类型。在单细胞花粉阶段后期,部分花粉粒壁一侧凹陷时,绒毡层细胞内切向面上出现乌氏体。随着发育阶段的推移,乌氏体的数量有所增加。在光学显微镜下观察：每个乌氏体只有一个乌氏体芯。在乌氏体出现时,也可观察到花粉外壁外层的出现。到二细胞花粉时,花药开裂之前,绒毡层细胞     

Subunits of forming pollen exine and Ubisch bodies as seen in freeze substitutedLedebouria socialis Roth (Hyacinthaceae)

Summary High-pressure freezing/freeze substitution/TEM was employed to investigate anthers of the monocotyledonous angiospermLedebouria socialis Roth (Hyacinthaceae) during early tetrad stage. The initials of the outer sporopollenous pollen wall stratum (=sexine) and of the homologous tapetal products (=Ubisch bodies) are composed of highly regular subunits: clustered globules with a constant diameter of approximately 28 nm. The clusters develop within diffuse accumulations of electron-dense material. This process, interpreted as sporopollenin polymerization, does not necessarily depend on the presence of membrane-bound enzymes. Immunogold labeling with JIM 5 and JIM 7 antibodies revealed that the primexine as well as the dissolving tapetal cell walls, the sites of sexine and Ubisch body formation, respectively, contain un-esterified and methyl-esterified pectins.Abbreviations E-PTA ethanolic phosphotungstic acid - PA periodic acid - UA/Pb uranyl acetate/lead     

LP28, a lily pollen-specific LEA-like protein, is located in the callosic cell wall during male gametogenesis

. LP28, a pollen-specific LEA-like protein identified in Lilium longiflorum purportedly related to the desiccation tolerance of pollen, was localized during male gametogenesis using immuno-electron microscopy. At premeiotic interphase, LP28 label is absent from the microsporocyte. LP28 label was first detected in the cell wall of the microsporocyte at meiotic prophase I. LP28 gradually increased as the cell wall thickened. In the dyad, after the first meiotic division, LP28 label also appeared in the septum. In the tetrad, after the second meiotic division, LP28 was detected throughout the cell wall, including the septa. Immunolabeling of callose during meiosis indicated that the appearance and localization of LP28 was very similar to that of callose. After the microspores were released from the tetrad by digesting the callosic cell wall, LP28 was not found in the microspores. In bicellular pollen, just after microspore mitosis, LP28 appeared in the generative cell wall, which also consisted of callose. After pollen germination, LP28 also accumulated in the callosic layer of the elongated pollen tube wall and the callose plug. Thus, LP28 colocalized with the callosic cell wall during male gametogenesis. The possible role of LP28 with respect to wall formation during meiosis and pollen development is discussed.     

Pollen wall and tapetum development in Plantago major L. (Plantaginaceae): assisting self-assembly

We have attempted to elucidate the underlying mechanisms of sporoderm development and pattern determination in Plantago major through a detailed ontogenetic study, using transmission electron microscopy (TEM) and scanning electron microscopy (SEM). We aim to compare our observations and interpretation with those on other species. Our study of sporoderm development in Plantago from the early tetrad stage to mature pollen grains has shown that pure physical processes, including self-assembly, which are not under direct genetic control, play an important role and represent evidently one of the instruments of evolution. Our observations fit well with the sequence of self-assembling micellar mesophases and show reiteration of some of them, confirming our self-assembly hypothesis. Some attention was also paid to the possible role of rough and smooth endoplasmic reticulum in the cortical cytoplasm of the developing microspores. The tapetum and Ubisch bodies development are also traced. The importance of detailed ontogenetic studies for understanding the establishment of complex pollen walls in any species and for understanding mechanisms underlying sporoderm development was demonstrated. We also present a simulation, obtained in vitro experiments by self-assembly, mimicking pollen grain of Plantago major. It is clear that, in pollen wall development, biological processes and purely physical factors work in tandem.     

The Ultrastructural Aspect of Tapetum and Ubisch Bodies in Anemarrhena asphodeloides

From ontogeny of tapetum in Anemarrhena asphodeloides, the ultrastructnral features of tapetal cells are as follows: 1. The profuse rough endoplasmic reticula are often closely associated with lipid bodies and vesicles, and linking each other into compound organelles. This is one of the striking features in Anemarrhena tapetal cell. 2. After meiosis of the micro- spore mother cell, the tapetal cytoplasm contains a large number of vesicles, in which the electron opaque substances are accumulated. Then they fuse to form a large zone of storage material similar to lipid bodies. Before accumulation of opaque material, these vesicles in the tapetal cytoplasm are larger than those in elaioplast (see Plate II, Fig. 2). 3. During stage of pollen maturation the tapetal cytoplasm becomes disorganized and the cells are almost occupied by the elaioplasts at various degree of development. On the basis of the report of Dickinson (1973), the formation of a pollen coatings of Lilium is different from that of Raphanus. The osmiophilic bodies in the former have originated from membrane lamellae or membranous system of plastid, and those in the latter are formed from the plastid vescles. It is intereting to note that the mode of origin of the plastid osmiophilic bodies in Anemarrhena is rather similar to that of Raphanus than to Lilium. About the origin of the pro-Ubisch bodies in tapetal cytoplasm of Anemarrhena studies revealed that a large number of the medium electron dense bodies appear in the tapetal cytoplasm. This is the first sign of the formation of the pro-Ubisch bodies and its character is very similar to spherosome in many respects. From many ultrasections, it can be seen that the ER profile is closely associated with the pro-Ubisch bodies. Thus we can conclude that the proubisch bodies of Anemarrhena are derived from rough endoplasmic reticulum. Although Heslop-Harrison et al. (1969) has considered that the compound Ubisch bodies do not occur in Lilium, there are prominent aggregation of Ubisch bodies in Anemarrhena, same as reported in Oxalis (Cariel, 1967), Silene (Heslop-Harrison, 1963a) and Helleborus (Echlin et al., 1968). After investigation on certain angiosperm in 1972, Gupta and Nanda have reported that the peritapetal membrane belonging to tapetum of secretory type lies against the inner tang- ential wall; in the plasmodial type of tapetum, it is formed on the outer tangential wall. But in some species of Poaceae and Solanaceae, the peritapetal membrane is formed on both sides of the tapetal cells (Banerjee, 1967; Reznickov & Willemse, 1980). In the secretory tapetum of Anemarrhena, the peritapetal membrane, which do not comply with the conclusion of Gupta & Nanta (1972), is formed on outer tangential wall.