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.     

Cytoskeleton,cell surface and the development of invasive plasmodial tapetum inTradescantia virginiana L.

Summary The anther tapetum inTradescantia virginiana L. is of the invasive plasmodial type: the cells lose their walls during early spore meiosis and develop long invasion processes which invade the loculus to penetrate spaces between the sporogenous cells. Fusion to form a syncytium is delayed and conventional ultra-thin sections and the Thiéry reaction reveal the presence of a loose fibrillar extracellular cell coat on the free surfaces of tapetal cells and their invasion processes. Cell fusion involves formation of apposition areas characterized by an absence of cell coat and the local appearance of microtubular arrays. Conspicuous membrane sacs, associated closely with microtubules, were found to migrate to and accumulate at the plasma membranes near the fusion sites and sporogenous cells. Microtubules are always present in the cortical regions of the tapetal cells and their invasion processes. It is surmised that microtubules are not responsible either for initiating or guiding tapetal invasion of the loculus; instead they may help to sustain the form of the invasion processes, help in the migration of membrane sacs, and participate in cell fusion. The cell coat disappears with syncytium formation towards the end of meiosis, and the developing spore cells become surrounded by a perispore membrane, which, derived from the original plasma membranes and augmented by membrane sacs, forms labyrinthine membrane reservoirs that are described further in the accompanying paper.     

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。     

蕨类植物紫萁绒毡层细胞凋亡的细胞学特征

绒毡层凋亡过程是小孢子发生中的重要事件,以往的研究主要集中在被子植物,蕨类植物尚未见此方面的报道。该研究首次采用透射电镜和免疫荧光技术对蕨类植物紫萁(Osmunda japonica Thunb.)绒毡层细胞凋亡的细胞学过程进行了观察,以明确紫萁绒毡层细胞的发育类型和凋亡特征,为蕨类植物绒毡层细胞凋亡的深入研究以及孢子发育研究提供依据。结果显示：(1)紫萁的绒毡层属于复合型,即外层绒毡层为分泌型,该层细胞发育过程中液泡化,营养物质被吸收;内层绒毡层为原生质团型,经历了细胞凋亡的过程。(2)绒毡层内层细胞在凋亡过程中细胞壁和细胞膜降解,细胞质浓缩且空泡化;细胞核内陷、变形,染色质浓缩凝聚,形成多数小核仁,DAPI荧光由强变弱;线粒体、质体、内质网、高尔基体等细胞器逐渐退化,液泡中多包含纤维状物、絮状物、黑色嗜锇颗粒和小囊泡等;出现多泡体、多膜体和细胞质凋亡小体,上述特征与种子植物绒毡层凋亡特征基本一致。(3)与种子植物相比,紫萁绒毡层的细胞凋亡开始得早,在整个凋亡过程中没有核凋亡小体的产生;除了产生孢粉素外,绒毡层细胞内产生了大量的丝状物质、絮状物质和电子染色暗的颗粒物,这些物质可能用于...     

ULTRASTRUCTURAL STUDY ON MICROSPORE WALL MORPHOGENESIS IN ISOETES JAPONICA (ISOETACEAE)

Spore wall morphogenesis of the microspore of Isoetes japonica was studied by transmission electron microscopy. The microspore wall consists of four layers: the perispore, outer exospore, inner exospore, and endospore. The perispore consists of electron-dense materials. The exospore is divided into outer and inner sections, with a large gap between the two. The outer exospore appears as an undulating plate consisting of tripartite lamellae with homogeneous sporopollenin. The inner exospore consists of an accumulation of tripartite lamellae on the microspore cell membrane. Immediately after meiosis, the tripartite lamellae of the outer exospore forms around the microspore. The lamellated inner exospore forms next, which adheres to the cell membrane of the microspore. The deposition of homogeneous sporopollenin material on the tripartite lamellae causes the plates of the outer exospore to thicken. Some homogeneous material may also be deposited on the inner exospore. Lastly, the electron-dense perispore is deposited on the outer exospore, and the electron-lucent endospore forms beneath the inner exospore. We conclude that the lamellae of the outer exospore, inner exospore, and endospore are formed and derived, in that order, from the gametophytic microspore cytoplasm. The homogeneous sporopollenin material of the outer exospore and perispore may be derived from the sporophytic tapetal cytoplasm.     

Tapetal Organization During Sporogenesis in Psilotum nudum

Stages in the differentiation of the tapetum of Psilotum nudumare described. Two concurrently occurring components of thetapetum can be recognized. A plasmodial tapetum with associatedfunctional nuclei develops within the sporangial loculus duringthe early stages of differentiation, appears to remain viablefor several months, that is during the entire period of sporogenesis,and undergoes reorganization on three occasions. During MeiosisI groups of spore mother cells are enclosed in clear areas withinthe plasmodium: by the end of Meiosis II each tetrad is isolatedin a plasmodial chamber; and, finally, mature spores are enclosedwithin individual tapetal chambers. Typically enlarged cellsare present during the development of a cellular, parietal tapetum.A sporopollenin-containing layer or tapetal membrane characteristicof a secretory tapetum develops on the inner tangential walland lines the surface of the loculus. This tapetal membranepersists even after dehiscence of the sporangium. These observationsare discussed in relation to previously published conflictingdata and may be relevant to the arguments concerning the relationshipof the Psilotaceae to the Filicales. Psilotum nudum, light microscopy, parietal tapetum, plasmodial tapetum, tapetal membrane, tapetal reorganization, sporogenesis, sporopollenin     

Development and Histochemical Observations of Tapetum and Peritapetal Membrane in Anther of Pulsatilla chinensis

Tapetum of Pulsatilla chinensis is of secretory type. Its development proceeds rapidly in following sequence: (1) The stage of initiation-differentiation. At this stage cytological and histochemical features have been described in detail in this paper. (2) The stage of growth- synthesis: This stage appears to be the most important anabolic phase during the development of the tapetum. The salient features are that the tapetal cells become relatively enlarged and form two polyploid nuclei or aberrent polyploid nuclei resulting in synthetizing maximum proteins, fluorescing substances and maximum fluorescent Pro-Ubisch bodies in the tapetal cytoplasm. (3) The stage of secretion-disorganization: After the disintegration of the tapetal wall the enlarged naked cells appear at once. This is an important secretion period in which Pro-Ubisch bodies as well as all other fluorescing substances, carbohydrate or some enzymes are released into anther loculus. The naked cell layer becomes disorgnized until the beginning divition of the pollen grains into two ceils. As to peritapetal membrane of P. chinensis, mainly based on the membrane being on the outer side of the tapetum enclosing both the pollen, tapetal cytoplasm and Ubisch bodies, and the cellular configurations facing the pollen, Authors postulate that peritapetal membrane might be survival of the cytoplasmic membrane of tapetal cells. However, the peritapetal membrane of P. chinensis is similar to that of plasmodial, tapetum reported in certain Compositae and that of secretory tapetum reported in Pinus banksiana. Heslop-Harrison and Gupta et al. had conceded that the tapetal and peritapetal membrane belong to the general class of sporopollenin. On the contrary in P. chinensis the sporopollenin property of peritapetal membrane is only confined to its inner surface. But the thin mem- brane itself with the reticulate sporopollenin attched on its inner side appears negative staining reactions for sporopollenin though it has an ability to resist the acetolysis as well. In P. chinensis the Ubisch body is short necked flask shaped and their size is very similar. Ubisch body is either single or 2–5 in a group, resulting in compound bodies. When the Pro-Ubisch body is still within the tapetal cell it shows positive fluorescent reaction, while it eomletely unstains with Teluidine blue O. So Authors infer that the sporopollenin precur- sors may have permeated through Pro-Ubisch bodies. Finally, How sporopollenin precursor is synthesized in the tapetal cells, transported to pollen locula and polymerized into the sporopollenin on pollen, Ubisch body and peritapetal membrane? Future works along these problems may yield fruitful results.     

Development and cell surface of a non-syncytial invasive tapetum inCanna: Ultrastructural,freeze-substitution,cytochemical and immunofluorescence study

Summary The anther ofCanna indica L. ×C. sp. hybrid contains a hitherto uncharacterized non-syncytial, invasive category of tapetum. With the onset of prophase I the tapetal walls are dissolved and the released protoplasts migrate into the loculus, where they stay discrete. Concomitant with the dissolution of walls the tapetal protoplasts develop a 17 nm thick extracellular granulo-fibrillar cell coat. This feature develops in the synchronous phase of tapetal development. The cell coat reacts positively with ruthenium red, potassium ferrocyanide, ConA-FITC and in the Thiéry reaction. Immunofluorescence microscopy using anti-tubulin revealed that even after the migration of tapetal cells into the loculus, the microtubules retain a predominant orientation in the cell cortex, probably derived from that in the original tapetal walled cells. This order is lost during late post-meiotic stages when the cells distort and can produce amoeboid processes. The microtubule orientation is correlated with that of the cell coat fibrils. Tapetal cells vary in ultrastructure and the density of cell coat fibrils after their migration into the loculus, but the cell coat persists until the cells degenerate. It is surmised that development of the cell coat relates to the lack of cell fusion and that the cortical microtubules help to sustain cell form. During post-meiotic stages the free tapetal cells develop massive peripheral arrays of interconnected ER cisternae, probably as part of a secretory apparatus which matures when the spores are producing their ornamented walls. Buds grown in colchicine solution showed accumulation of sporopolleninlike granules in all extracellular spaces of the anther cavity.     

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.     

Chemical agents that inhibit pollen development: effects of the phenyl-cinnoline carboxylates SC-1058 and SC-1271 on the ultrastructure of developing wheat anthers (Triticum aestivum L. var Yecora rojò)

Summary Phenylcinnoline carboxylate compounds SC-1058 and SC-1271 cause complete male sterility in wheat when applied at suitable dosages at the pre-meiotic stage of anther development. Anthers from treated and untreated plants were compared using light and electron microscopy from the pre-meiotic stage through the formation of nearly mature pollen. Overall anther development is gradually slowed in treated plants and pollen development is generally arrested in the late prevacuolate or early vacuolate microspore stage, although the first pollen mitosis does sometimes occur. The sporopollenin-containing exine walls are thinner, and show abnormally developed foot and tectum layers with sparse connecting baculi. Microspore cytoplasm degenerates and the cells eventually collapse. At the early, prevacuolate, free microspore stage treated tapetal cells hypertrophy, expanding into the locule. They contain abnormally large vacuoles that appear to form from the fusion of secretory vesicles, and some vacuoles contain electrondense deposits. The sporopollenin-containing orbicular wall and Ubisch bodies are retarded in their development and are structurally deformed. Acetolysis of whole anthers and of thick sections shows that the sporopollen-in-containing structures of treated materials are greatly reduced in thickness and are less rigid than in the control. We conclude that application of these compounds causes interference with the secretory function of tapetal cells which supplies sporopollenin cell-wall polymers to the exine of the microspores and to the tapetal orbicular wall and associated Ubisch bodies. Interference with the tapetal secretion of other nutrients required for microspore development is strongly suggested.     

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.     

The Changes in the Tapetum of Pinus banksiana Accompanying Formation and Maturation of the Pollen

As meiosis is completed, and following the synthesis of lipidduring meiotic prophase, the tapetum begins to form precursorsof sporopollenin. These accumulate in cisternae of the endoplasmicreticulum, resembling large dictyosome vesicles. They are releasedfrom the tapetal protoplasts intact, but rupture in the loculus.The liberated precursors polymerize either on lipid dropletsin the expanded tapetal walls, forming the orbicules, or onthe lipid layer surrounding the loculus, forming the secondcomponent of the peritapetal membrane. On rupture of the callosewall condensation also proceeds on the walls of the meiospores,already coated with a thin layer of sporopollenin synthesizedby the spore itself. The tapetal protoplasts expand considerablyduring synthesis of the precursors. Wide channels also formbetween the protoplasts, and the nuclei undergo irregular divisions. Ribosomes are conspicuous in the tapetal cytoplasm during thesporopollenin synthesis, but protein levels are low. It is proposedthat protein is exported to the loculus and untimately incorporatedinto the developing microspores. In the final phase of microsporogenesis the tapetum fragments,and parts move into the loculus.Protein levels in the tapetumare now high, possible indicating the massive synthesis of hydrolaseswhich accomplish the dissolution of the tissue. Removal of thelipid component of the peritapetal membrane precedes the desiccationof the anther. The surfaces of the mature pollen lack organizedor irregular deposits of tapetal debris.     

Secretory tapetum of Brassica oleracea L.: polarity and ultrastructural features

Summary The ultrastructure of the secretory, binucleate tapetum of Brassica oleracea in the micro spore mother cell (MMC) stage through to the mature pollen stage is reported. The tapetal cells differentiate as highly specialized cells whose development is involved in lipid accumulation in their final stage. They start breaking down just before anther dehiscence. Nuclei with dispersed chromatin, large nucleoli and many ribosomes in the cytoplasm characterize the tapetal cells. The wall-bearing tapetum phase ends at the tetrade stage. The dissolution of tapetal walls begins from the inner tangential wall oriented towards the loculus and proceeds gradually along the radial walls to the outer tangential one. The plasmodesmata transversing the radial walls between tapetal cells persist until the mature microspore, long after loss of the inner tangential wall. After wall dissolution, the tapetal protoplasts retain their integrity and position within the anther locule. The tapetal cell membrane is in direct contact with the exine of the microspores/pollen grains and forms tubular evaginations that increase its surface area and appear to be involved in the translocation of solutes from the tapetal cells to the microspores/ pollen grains. The tapetal cells exhibit a polarity expressed by spatial differentiation in the radial direction.     

乌蕨孢子壁的形成和发育

利用光镜、扫描电镜和透射电镜对鳞始蕨科（Lindsaeaceae）乌蕨（Stenoloma chusanum Ching）孢壁的形成和发育进行了研究。结果表明乌蕨孢子两侧对称、单裂缝,表面具疣状纹饰。孢壁由内壁、外壁和周壁三部分构成。外壁在四分体阶段已基本形成,其表面光滑,质地均匀,由孢粉素形成。周壁是由绒毡层残余物在外壁表面沉积形成,可分为周壁内层、周壁中层和周壁外层三部分。在周壁中层与外层之间有一层均匀的空间。最后,本文探讨了孢壁的形成和发育规律,研究结果对揭示孢子纹饰和孢壁各层的形成过程、来源和稳定性有重要的意义,并为孢粉学和系统学研究提供基础资料。     

ESCRT components ISTL1 andLIP5 are required for tapetal function and pollen viability

Pollen wall assembly is crucial for pollen development and plant fertility. The durable biopolymer sporopollenin and the constituents of the tryphine coat are delivered to developing pollen grains by the highly coordinated secretory activity of the surrounding tapetal cells. The role of membrane trafficking in this process, however, is largely unknown. In this study, we used Arabidopsis thaliana to characterize the role of two late-acting endosomal sorting complex required for transport (ESCRT) components, ISTL1 and LIP5, in tapetal function. Plants lacking ISTL1 and LIP5 form pollen with aberrant exine patterns, leading to partial pollen lethality. We found that ISTL1 and LIP5 are required for exocytosis of plasma membrane and secreted proteins in the tapetal cells at the free microspore stage, contributing to pollen wall development and tryphine deposition. Whereas the ESCRT machinery is well known for its role in endosomal trafficking, the function of ISTL1 and LIP5 in exocytosis is not a typical ESCRT function. The istl1 lip5 double mutants also show reduced intralumenal vesicle concatenation in multivesicular endosomes in both tapetal cells and developing pollen grains as well as morphological defects in early endosomes/trans-Golgi networks, suggesting that late ESCRT components function in the early endosomal pathway and exocytosis.

Endosomal sorting complex required for transport proteins ISTL1 and LIP5 are required for exocytosis of both plasma membrane and secreted proteins in tapetal cells during microspore formation.     

The rôle of the tapetum in the formation of sporopollenin-containing structures during microsporogenesis in Pinus banksiana

Summary In the microsporangium of Pinus the outer layer of the peritapetal membrane and the pro-orbicular cores are not only formed in a similar manner, but are composed of apparently identical materials. Precursors for this lipoidal material are produced by the tapetal protoplasts, as are the precursors of sporopollenin. Production the precursors is sequential and appears to involve different cytoplasmic structures.The sporopollenin synthesised by the tapetum condenses upon the pro-orbicular cores, the peritapetal membrane, the exine initials and, on fragmentation of the tapetum, parts of the disintegrating cytoplasm. The evident unpolarised nature of the tapetal protoplasts, and the sequential nature of the synthesis of the lipoid and the sporopollenin by them, may point to orbicule formation in gymnosperms being a necessary by-product of the development of the peritapetal membrane.     

云南松小孢子发生过程中绒毡层细胞的超微结构研究

云南松(Pinus yunnanensis Fr.)在小孢子囊发育早期,绒毡层原生质体发生收缩,并伴随着细胞壁厚度的增加。脂肪微滴和孢粉素物质沉积而形成周缘绒毡层膜。随着孢粉素物质的产生,绒毡层细胞质明显地液泡化。孢粉素物质在绒毡层细胞膨大的内质网槽库中形成,随后被排放到近邻的小液泡内或游离于细胞质中。孢粉素物质也可在特化的含片层的质体中形成,孢粉素依附在片层膜上,或释放到细胞质中。     

Microspore and tapetal development in Echinodorus cordifolìus (Alismaceae)

In the microspore tetrad period the exine begins as rods that originate from the plasma membrane. These rods are exine units that on further development become columellae as well as part of the tectum, foot layer and “transitory endexine”. The primexine matrix is very thin in the future sites of the pores. At these sites the plasma membrane and its surface coating (glycocalyx) are without exine units and adjacent to the callose envelope. The exine around the aperture margin is characterized by units of reduced height. After the exine units and primexine matrix have become ca 0.2 μm in height a fibrillar zone forms under the aperture margin. It is the exine units around the aperture that are templates for exine processes on apertures of mature pollen. Oblique sections of the early exine show that the tectum consists of the distal portions of close-packed exine units. The exine enlarges in the free microspore period but initially its substructure (tectum, columellae, foot layer and transitory endexine) is not homogeneous and unit structures are visible until after the vacuolate microspore period. There are indications of a commissural line/plane (junction plane) which separates the foot layer from the endexine during early development. Our observations of development in Echinodorus pollen extend a growing number of reports of “transitory endexines” in monocot pollen. The exine unit-structures become 0.2 μm or more in diameter and many columellae are composed of only one exine unit. Spinules become exceptionally tall, many protruding ca 0.7 μm above the level of the tectum as units only ca 0.1 μm in diameter. The outer portion of the tectum fills in around spinules and by maturity they are microechinate with their bases spread out to ca 1 μm or more. Unit structures can be seen with SEM in mature pollen following oxidation by plasma ashing and in the tapetum these units are arranged both radially, as in spinules, and parallel with the tapetal surfaces. There are clear indications of such an arrangement of units in untreated fresh pollen. Units comprising the basal part of the exine are not completely fused by sporopollenin accumulated during development. This would seem to be a characteristic feature, based on published work, of the alismacean pollen. Our use of a tracer shows, however, that there is considerable space within or between exine structure of mature Echinodorus pollen. Based upon the ca 0.1 μm size of exine-units formed early in development and exine components seen after oxidative treatment it seems that the early (primary) accumulated sporopollenin has greater resistance to oxidation than sporopollenin added, secondarily, around and between units later in development. Both primarily and secondarily accumulated sporopollenin are resistant to acetolysis but published work indicates that acetolysis alters exine material. At the microspore tetrad time and until the vacuolate stages tapetal cells are arranged as in secretory tapetums. During early microspore stages there are orbicules at the inner surface of tapetal cells. At free microspore period tapetal cells greatly elongate into the loculus and surround the microspores. By the end of the microspore vacuolate period tapetal cells release their cellular contents and microspores are for a time enveloped by tapetal organelles and translocation material.     

Cytokinesis in microspore mother cells of Impatiens sultani

Summary Cytokinesis in Impatiens sultani microspore mother cells is simultaneous. It starts with the formation of small ingrowths of the surrounding callosic wall. Next, an incomplete cell plate is formed by fusion of small dictyosome vesicles. The cell plate consists of a network of anastomosing tubules and sacs. Aggregates of fusing vesicles are associated with bundles of microtubules, which are oriented perpendicular to the plane of the future cell walls. In the sacculate parts of the cell plate, some callose is deposited, while the associated microtubules disappear. The cell walls ultimately develop by enlargement of the previously formed wall ingrowths, which successively incorporate the elements of the cell plate. The enlargement and thickening of the walls is not accompanied by a further fusion and incorporation of dictyosome vesicles.     

Development of the pollen grain and tapetum of wheat (Triticum aestivum) in untreated plants and plants treated with chemical hybridizing agent RH0007

Summary A study of pollen development in wheat was made using transmission electron microscopy (TEM). Microspores contain undifferentiated plastids and mitochondria that are dividing. Vacuolation occurs, probably due to the coalescence of small vacuoles budded off the endoplasmic reticulum (ER). As the pollen grain is formed and matures, the ER becomes distended with deposits of granular storage material. Mitochondria proliferate and become filled with cristae. Similarly, plastids divide and accumulate starch. The exine wall is deposited at a rapid rate throughout development, and the precursors appear to be synthesized in the tapetum. Tapetal cells become binucleate during the meiosis stage, and Ubisch bodies form on the plasma membrane surface that faces the locule. Tapetal plastids become surrounded by an electron-translucent halo. Rough ER is associated with the halo around the plastids and with the plasma membrane. We hypothesize that the sporopollenin precursors for both the Ubisch bodies and exine pollen wall are synthesized in the tapetal plastids and are transported to the tapetal cell surface via the ER. The microspore plastids appear to be involved in activities other than precursor synthesis: plastid proliferation in young microspores, and starch synthesis later in development. Plants treated with the chemical hybridizing agent RH0007 show a pattern of development similar to that shown by untreated control plants through the meiosis stage. In the young microspore stage the exine wall is deposited irregularly and is thinner than that of control plants. In many cases the microspores are seen to have wavy contours. With the onset of vacuolation, microspores become plasmolyzed and abort. The tapetal cells in RH0007-treated locules divide normally through the meiosis stage. Less sporopollenin is deposited in the Ubisch bodies, and the pattern is less regular than that of the control. In many cases, the tapetal cells expand into the locule. At the base of one of the locules treated with a dosage of RH0007 that causes 95% male sterility, several microspores survived and developed into pollen grains that were sterile. The conditions at the base of the locule may have reduced the osmotic stress on the microspores, allowing them to survive. Preliminary work showed that the extractable quantity of carotenoids in RHOOO7-treated anthers was slightly greater than in controls. We concluded that RH0007 appears to interfere with the polymerization of carotenoid precursors into the exine wall and Ubisch bodies, rather than interfering with the synthesis of the precursors.