紫萁孢子囊发育中多糖和脂滴的细胞化学观察

采用光镜、透射电镜和细胞化学技术,对紫萁孢子囊发育过程中孢壁的超微结构和孢子囊内多糖和脂滴的分布及其动态变化进行研究,以探讨紫萁孢子囊发育过程中多糖和脂滴的代谢特征,为蕨类孢子发生的研究提供基础资料。结果表明:(1)紫萁孢子囊由1层囊壁细胞、2层绒毡层和产孢组织构成。(2)紫萁孢子壁由发达而分2层的外壁(外壁内层和外壁外层)和薄的不连续的周壁构成,由外壁形成棒状纹饰的轮廓;孢子外壁内层由多糖类物质构成,外壁外层和周壁均含有脂类物质。(3)在紫萁孢原细胞中观察到少量脂滴;随着紫萁孢壁的形成,囊壁细胞中淀粉粒的大小逐渐变小、数目先增加后减少,它们转运到内层绒毡层原生质团并转化为孢粉素前体物质,再穿过原生质团内膜表面进入囊腔,成为孢粉素团块或以小球形式填加到孢子表面形成孢壁。(4)紫萁孢子囊将多糖类营养物质转化为脂类,以脂滴的形式储藏在孢子中。     

从无性生殖分析蕨类植物紫萁的原始特征

蕨类植物无性生殖过程中有诸多重要的分类和演化特征,利用光镜和扫描电镜观察紫萁科(Osmundaceae)代表植物——紫萁(Osmunda japonica Thunb.)孢子囊的形态和孢子形态,以及表面纹饰的形成过程。结果显示,紫萁具有如下原始特征:①孢子囊大型,无囊群盖,具盾状环带,孢子叶上的孢子囊同时发育,孢子囊纵向开裂;②孢子囊中孢子数量多;③孢子同型,具三裂缝,为辐射对称的四面体型;④孢子表面由外壁构成的纹饰形成过程复杂。从无性生殖角度显示紫萁科在真蕨类植物中古老的演化地位。     

麻疯树花药发育过程中Ca2+的分布特征

采用超薄切片技术,在透射电镜下观察麻疯树(Jatropha curcasL.)花药发育过程中Ca2 的分布特征。在孢原细胞时期的花药中几乎看不到Ca2 沉淀,但花药维管束周围的细胞中有较多的Ca2 沉淀;到小孢子母细胞时期,细胞质中Ca2 沉淀依然较少,绒毡层壁上Ca2 沉淀明显增多;四分体形成时,小孢子细胞质和绒毡层细胞质中出现了较多的Ca2 沉淀;在小孢子发育早期,细胞质中Ca2 沉淀增加不明显,花粉壁部位累积有很多的Ca2 沉淀,绒毡层中Ca2 沉淀数量达到最多;到小孢子发育晚期,小孢子大液泡的液泡膜上有大量的Ca2 沉淀,绒毡层中Ca2 沉淀明显减少;随着二胞花粉中的大液泡消失,细胞质中积累淀粉粒以后,花粉中看到的Ca2 沉淀极少,同时,在花药维管束周围的薄壁细胞中,又出现了较多的Ca2 沉淀,表明花粉对Ca2 的需求可能降低。麻疯树花药发育过程中钙的动态分布特征暗示着钙参与了调控花粉发育过程,Ca2 的运输途径是由药隔薄壁组织运输到绒毡层,再进一步转移到小孢子表面和细胞质中,整个花药发育过程中,Ca2 沉淀表现为少—增加—减少的变化趋势。     

天麻消化紫萁小菇及蜜环菌过程中细胞超微结构变化的研究

本文对天麻种子消化入侵的紫萁小菇菌丝及营养繁殖茎消化蜜环菌过程中,细胞超微结构的变化进行了研究。观察结果表明:紫萁小菇侵入种胚后,染菌胚细胞的细胞器逐渐消失,其细胞质产生囊状体起消化菌丝的作用,存在于胚细胞中的紫萁小菇菌丝有脱壁或失去细胞质成为空腔等变化;种子萌发形成的原球茎消化紫萁小菇的方式同胚萌发阶段类同。蜜环菌侵入原球茎分化的营养繁殖茎后,皮层细胞产生消化酶类颗粒或囊状体包围并分解蜜环菌菌丝;被皮层细胞消化的菌丝残物或部分菌丝进入皮层内面的大型细胞,此时大型细胞的代谢功能显著增强,该细胞中的各种水解酶颗粒及液泡等完成对菌体物质的最终同化。紫萁小菇及蜜环菌先后在天麻有性繁殖和无性繁殖阶段侵染供给其营养,但菌丝被消化过程中的细胞形态变化、被消化方式不完全一致。     

莴苣花药发育过程中钙的分布特征

减数分裂前,莴苣花药中的钙颗粒很少。减数分裂后,花药绒毡层细胞中的钙颗粒明显增加, 同时在花药药室基质中也出现许多细小的钙颗粒。刚从四分体中释放出的小孢子内钙颗粒很少,伴随着花粉外壁物质在小孢子表面的沉积,钙颗粒开始积累在花粉壁部位。随后,小孢子中开始出现钙颗粒。当小孢子开始形成液泡后,钙颗粒向其中聚集,伴随着小液泡融合成大液泡,体积较大的钙颗粒主要集中在液泡中,而细胞质基质中的钙颗粒很少。随着二胞花粉中的大液泡消失,花粉细胞质中的钙颗粒变得很少。在以后的发育中,只有花粉壁中积累较多的钙颗粒。在莴苣花药发育过程中,钙与绒毡层细胞的退化和小孢子液泡形成以及二胞花粉中大波泡的消失有关。而花粉外壁表面积累丰富的钙与以后花粉的萌发有关。     

含笑花药发育的超微结构研究

对含笑花药发育中的超微结构变化进行观察,结果显示:(1)花粉发育中有三次液泡变化过程——第一次是小孢子母细胞在形成时内部出现了液泡,这可能与胼胝质壁的形成有关;第二次是在小孢子母细胞减数分裂之前,细胞内壁纤维素降解区域形成液泡,它的功能可能是消化原有的纤维素细胞壁;第三次是在小孢子液泡化时期,形成的大液泡将细胞核挤到边缘,产生极性。(2)含笑花粉在小孢子早期形成花粉外壁外层,花粉外壁内层在小孢子晚期形成,而花粉内壁是在二胞花粉早期形成;花粉成熟时,表面上沉积了绒毡层细胞的降解物而形成了花粉覆盖物。研究认为,含笑花粉原外壁的形成可能与母细胞胼胝质壁有关,而由绒毡层细胞提供的孢粉素物质按一定结构建成了花粉覆盖物。     

红盖鳞毛蕨孢子囊早期发育与质体分化的研究

利用光学显微镜和透射电子显微镜观察了红盖鳞毛蕨(Dryopteris erythrosora(Eaton)O.Ktze.)孢子囊的发育及在此期间质体的分化过程。研究表明:(1)红盖鳞毛蕨孢子囊的发育类型属于薄囊蕨型;(2)绒毡层为混合型,即内层绒毡层为原生质团型,外层绒毡层为腺质型;(3)孢子囊原始细胞中的质体通过3条路径分化,其一,原始细胞中含淀粉粒的质体通过分裂分配到下方细胞,继而进入孢子囊柄;其二,原始细胞分裂产生的新生质体被分配到上方细胞,进而被分配到除顶细胞外的原基细胞中,顶细胞将含淀粉粒的质体通过分裂分配到外套层原始细胞中;其三,顶细胞也将具淀粉粒的质体通过分裂分配到内部细胞,使分裂产生的孢原细胞和绒毡层原始细胞具新生质体;造孢细胞和孢子母细胞的质体具淀粉粒,孢子母细胞还具油体,新生孢子中具造粉体和油体;两层绒毡层具新生质体,随着退化外层绒毡层出现造粉体,内层绒毡层出现油体;(4)红盖鳞毛蕨与少数被子植物小孢子发育阶段质体分化模式类似,由前质体分化为造粉体再到油体。研究结果为蕨类植物质体在孢子囊发育过程不同组织细胞中的差异分化提供了新观察资料,为蕨类植物发育生物学和系统演化研究提供科学依据。     

蕨类植物孢子与种子植物花粉萌发的比较

蕨类植物孢子与种子植物花粉在有性生殖过程中都具有重要的作用。花粉作为种子植物的雄配子体, 通过萌发后极性生长的花粉管将精细胞送到胚囊完成受精作用。蕨类植物孢子作为配子体的原始细胞, 通过不对称的有丝分裂产生一大一小两个细胞, 小细胞萌发出极性生长的假根, 大细胞继续分裂发育为原叶体(配子体)。成熟的花粉和蕨类植物孢子都是代谢高度静止的细胞, 两者的萌发过程不仅都受到各种不同环境因子的影响, 而且在信号转导、极性建立和能量代谢等方面可能有着相似的调控机制。本文综述了蕨类植物孢子和种子植物花粉萌发过程的差异和保守性特征。     

莴苣花药发育过程中钙的分布特征

减数分裂前,莴苣花药中的钙颗粒很少。减数分裂后,花药绒毡层细胞中的钙颗粒明显增加。同时在花药药室基质中也出现许多细小的钙颗粒。刚从四分体中释放出的小孢子内钙颗粒很少。伴随着花粉外壁物质在小孢子表面的沉积,钙颗粒开始积累在花粉壁部位。随后。小孢子中开始出现钙颗粒。当小孢子开始形成液泡后,钙颗粒向其中聚集,伴随着小液泡融合成大液泡。体积较大的钙颗粒主要集中在液泡中,而细胞质基质中的钙颗粒很少。随着二胞花粉中的大液泡消失,花粉细胞质中的钙颗粒变得很少。在以后的发育中,只有花粉壁中积累较多的钙颗粒。在莴苣花药发育过程中,钙与绒毡层细胞的退化和小孢子液泡形成以及二胞花粉中大液泡的消失有关。而花粉外壁表面积累丰富的钙与以后花粉的萌发有关。     

蕨类植物孢子与种子植物花粉萌发的比较

蕨类植物孢子与种子植物花粉在有性生殖过程中都具有重要的作用。花粉作为种子植物的雄配子体,通过萌发后极性生长的花粉管将精细胞送到胚囊完成受精作用。蕨类植物孢子作为配子体的原始细胞,通过不对称的有丝分裂产生一大一小两个细胞,小细胞萌发出极性生长的假根,大细胞继续分裂发育为原叶体（配子体）。成熟的花粉和蕨类植物孢子都是代谢高度静止的细胞,两者的萌发过程不仅都受到各种不同环境因子的影响,而且在信号转导、极性建立和能量代谢等方面可能有着相似的调控机制。本文综述了蕨类植物孢子和种子植物花粉萌发过程的差异和保守性特征。     

The tapetum inSchizaea pectinata (Schizaeaceae) and a comparison with the tapetum inPsilotum nudum (Psilotaceae)

A combination tapetum consisting of a cellular, parietal component and a plasmodial component occurs inSchizaea pectinata. A single, tapetal initial layer divides to form an outer parietal layer which maintains its cellular integrity until late in spore wall development. The inner tapetal layer differentiates into a plasmodium which disappears after the outer exospore has developed. In the final stages of spore wall development, granular material occurs in large masses and is dispersed as small granules throughout the sporangial loculus. No tapetal membrane develops. Comparisons are drawn with the combination tapetum found inPsilotum nudum.     

Ultrastructure of microsporogenesis and microgametogenesis inArabidopsis thaliana (L.) Heynh. ecotype Wassilewskija (Brassicaceae)

Summary The process of microsporogenesis and microgametogenesis was studied at the ultrastructural level in wild-typeArabidopsis thaliana ecotype Wassilewskija to provide a basis for comparison with nuclear male-sterile mutants of the same ecotype. From the earliest stage studied to mature pollen just prior to anther dehiscence, microsporocyte/microspore/pollen development follows the general pattern seen in most angiosperms. The tapetum is of the secretory type with loss of the tapetal cell walls beginning at about the time of microsporocyte meiosis. Wall loss exhibits polarity with the tapetal protoplasts becoming located at a distance from the inner tangential walls first, followed by an increase in distance from the radial walls beginning at the interior edge and progressing outward. The inner tangential and radial tapetal walls are completely degenerated by the microspore tetrad stage. Unlike other members of the Brassicaceae that have been studied, the tapetal cells ofA. thaliana Wassilewskija also lose their outer tangential walls, and secretion occurs from all sides of the cells. Exine wall precursors are secreted from the tapetal cells in a process that appears to involve dilation of individual endoplasmic reticulum cisternae that fuse with the tapetal cell membrane and release their contents into the locule. Following completion of the exine, the tapetal cell plastids develop membranebound inclusions with osmiophilic and electron-transparent regions. The plastids undergo ultrastructural changes that suggest breakdown of the inclusion membranes followed by release of their contents into the locule prior to the complete degeneration of the tapetal cells.     

The tapetum and systematics in monocotyledons

This paper critically reviews the homologies and distribution of tapetum types in monocotyledons, in relation to their systematics. Two main types of tapetum are widely recognised: secretory and plasmodial, although intermediate types occur, such as the “invasive” tapetum described inCanna. In secretory tapeta, a layer of cells remains intact around the anther locule, whereas in the plasmodial type a multinucleate tapetal plasmodium is formed in the anther locule by fusion of tapetal protoplasts. In invasive tapeta, the cell walls break down and tapetal protoplasts invade the locule without fusing to form a plasmodium. When examining tapetum type, it is often necessary to dissect several developmental stages of the anthers. Secretory and plasmodial tapeta are both widely distributed in monocotyledons and have probably evolved several times, although there may be some systematic significance within certain groups. Among early branching taxa,Acorus andTofieldia have secretory tapeta, whereas Araceae and Alismatales are uniformly plasmodial. The tapetum is most diverse within Commelinanae, with both secretory and plasmodial types, and some Zingiberales have an invasive tapetum. Lilianae (Dioscoreales, Liliales, and Asparagales) are almost uniformly secretory.     

Electron Microscopy of the Tapetum Lucidum of the Cat

The fine structure of the tapetum of the cat eye has been investigated by electron microscopy. The tapetum is made up of modified choroidal cells, seen as polygonal plates grouped around penetrating blood vessels which terminate in the anastomosing capillary network of the choriocapillaris. The tapetal cells are rectangular in cross-section, set in regular brick-like rows, and attain a depth of some thirty-five cell layers in the central region. This number is gradually reduced peripherally, and is replaced at the margin of the tapetum by normal choroidal tissue. The individual cells are packed with long slender rods 0.1 µ by 4 to 5 µ. The rods are packed in groups and with their long axes oriented roughly parallel to the plane of the retinal surface. Each cell contains several such groups. Cells at the periphery or in the outer layers of the tapetum are frequently seen to contain both tapetal rods and melanin granules, the latter typical of the choroidal melanocytes. Also melanocyte granules may have intermediate shapes. These observations plus the similar density of the two inclusions lead to the belief that the tapetal rods may be melanin derivatives. A fibrous connective tissue layer lies between the tapetum and the retina. The subretinal capillary network, the choriocapillaris, rests on this layer and is covered by the basement membrane of the retinal epithelium. The cytoplasm of the retinal epithelium exhibits marked absorptive modifications where it comes in contact with the vessels of the choriocapillaris. This fibrous layer and the basement membrane of the retinal epithelium apparently comprise the structural elements of Bruch's membrane.     

The fine structure of the adepidermal reticulum in the basal membrane of the skin of the newt,Triturus

The fine structure of the tapetum of the cat eye has been investigated by electron microscopy. The tapetum is made up of modified choroidal cells, seen as polygonal plates grouped around penetrating blood vessels which terminate in the anastomosing capillary network of the choriocapillaris. The tapetal cells are rectangular in cross-section, set in regular brick-like rows, and attain a depth of some thirty-five cell layers in the central region. This number is gradually reduced peripherally, and is replaced at the margin of the tapetum by normal choroidal tissue. The individual cells are packed with long slender rods 0.1 micro by 4 to 5 micro. The rods are packed in groups and with their long axes oriented roughly parallel to the plane of the retinal surface. Each cell contains several such groups. Cells at the periphery or in the outer layers of the tapetum are frequently seen to contain both tapetal rods and melanin granules, the latter typical of the choroidal melanocytes. Also melanocyte granules may have intermediate shapes. These observations plus the similar density of the two inclusions lead to the belief that the tapetal rods may be melanin derivatives. A fibrous connective tissue layer lies between the tapetum and the retina. The subretinal capillary network, the choriocapillaris, rests on this layer and is covered by the basement membrane of the retinal epithelium. The cytoplasm of the retinal epithelium exhibits marked absorptive modifications where it comes in contact with the vessels of the choriocapillaris. This fibrous layer and the basement membrane of the retinal epithelium apparently comprise the structural elements of Bruch's membrane.     

Colchicine inhibits plasmodium formation and disrupts pathways of sporopollenin secretion in the anther tapetum ofTradescantia virginiana L.

Summary During an earlier investigation, microtubules were observed at the periphery of invasion processes in the developing syncytial tapetum ofTradescantia virginiana L. They were also associated with membranous sacs that accumulate adjacent to tetrads, with putative fusion sites where the tapetal plasmodium is initiated, and, in postmeiotic stages, with the perispore membrane that encloses the developing spore cells. Colchicine was administered to developing flower buds to investigate the roles of these microtubules. The results indicate that microtubules neither initiate nor guide the tapetal invasion of the loculus. The treatments, however, resulted in absence of cell coat from invasion processes and prevention of cell fusion. They also inhibited polarized migration of membrane sacs and removed the associated microtubules. The development of an organized secretory apparatus at the perispore membrane was disrupted, with subsequent disordered deposition of sporopollenin in the extracellular spaces of the partially-fused plasmodium. The results suggest that microtubules participate in the formation and internal spatial organization of the tapetal plasmodium, and establishment of a secretory surface that normally produces sporopollenin at the tapetum-microspore interface.     

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.     

A Comparative Study of Anther and Pollen Development in Male Fertile and Male. Sterile Green Onion (Allium fistulosum L.)

Anther and pollen development in male-fertile and male-sterile green onions was studied. In the male-fertile line, both meiotic microspore mother ceils and tetrads have a callose wall. Mature pollen grains are 2-celled. The elongated generative cell with two bended ends displays a PAS positive cell wall. The tapetum has the character of both secretory and invasive types. From microspore stage onwards, many oil bodies or masses accumulate in the cytoplasm of the tapetal cells. The tapetum degenerates at middle 2-celled pollen stage. In male-sterile line, meiosis in microspore mother cells proceeds normally to form the tetrads. Pollen abortion occurs at microspore with vacuole stage. Two types of pollen abortion were observed. In type I, the protoplasts of the microspores contract and gradually disintegrate. At the same time the cytoplasm of microspores accumulates oil bodies which remain in the empty pollen. The tapetal cells behave normally up to the microspore stage and early stage of microspore abortion, but contain fewer oil bodies or masses than those in the male-fertilt line. At late stage of microspore abortion, three forms of the tapetal ceils can be observed: (1) the tapetal cells with degenerating protoplasts become flattened, (2) the tapetal cells enlarge but protoplasts retractor, (3) the cells break down and tile middle layer enlarges. In type Ⅱ, the cytoplasm degenerates earlier than the nucleus of the microspores and no protoplast is found in the anther locule. There are fibrous thickenings iii the endothecium of both types. It is difficult to verify whether the tapetum behavior and pollen abortion is the cause or the effect.     

An ultrastructural,cytochemical and immunofluorescence study of postmeiotic development of plasmodial tapetum inTradescantia virginiana L. and its relevance to the pathway of sporopollenin secretion

Summary Establishment of a tapetal plasmodium in postmeiotic stages in anther locules ofTradescantia virginiana encloses the tetrads in membrane-limited compartments. The perispore membrane (PSM), around each tetrad, is derived from composite tapetal cell plasma membranes. The tapetum acquires an abundance of ER and ribosomes and by the late tetrad stage the PSM and its underlying cytoplasm exhibit specialized features, studied here by ZnIO impregnation, osmium maceration, application of indirect immunofluorescence employing antitubulin, conventional thin sectioning and the Thiéry reaction. These features include: labyrinthine convolutions of the PSM resulting from migration of membranous sacs and their partial fusion to the PSM, an intimate relationship of tubular ER with the convoluted PSM, and microtubules underlying the PSM and among the membranous sacs. At the same time membrane-bound granules, comparable to but smaller and simpler than tapetal orbicules of secretory tapeta, form in the convolutions. It is postulated that the ER supplies precursors of sporopollenincontaining parts of the spore wall, that the PSM-associated microtubules stabilise the whole secretory apparatus at the tapetum-spore interface, and that the precursors are expelled into the lumen bounded by the PSM and then accreted upon the orbicule-like granules or the developing spore wall. With dissolution of the callosic wall, the plasmodium invades the intermicrosporal spaces of late tetrads, the PSM unfolding its elaborations and becoming closely appressed to the exinous surfaces of individual spores. Microtubules, although present during this phase of invasion, do not seem to propel the invasion processes and may have roles in shape maintenance. During pollen mitosis and enlargement the tapetal cytoplasm accumulates lipidic globules. A late phase of Golgi activity precedes accumulation of vesicles or vacuoles near the spores, these being bounded by single or multiple tripartite membranes. With anther desiccation, portions of plasmodium are deposited on the pollen surface in the form of tryphine, the deposits containing stacked membrane-like bilayers.