Ultrastructural and autoradiographic studies of non-generative cells in the antheridium of Chara vulgaris. I. Manubria

During the development of an antheridium DNA content in manubria gradually increases to 8C-16C level. 3H-thymidine incorporation into the nuclei of the manubria lasts till the stage of quantitative predominance of the 16 celled antheridial filaments. The nucleus of the manubria is characterized by the low content of the condensed chromatin and the presence of nucleoli with the nucleolonema-like structure the number of which increases from 6-8 to 32-38 along with the increase of DNA content in a nucleus. In the cytoplasm of the manubria there are numerous secretive vesicles filled with fine-granular substance discharged outside plasmalemma, active Golgi apparatus, well-developed rough ER, numerous polysomes, mitochondria with the condensed structure and plastids with granar and inter-granar thylakoids as well as plastoglobules which increase in number and size along with the development of the antheridium. During spermiogenesis the cells are vacuolated, the number of the secretive vesicles decreases whereas the electron density of their content increases, smooth ER appears while rough ER is reduced. The manubria actively incorporate 3H-uridine, 3H-tryptophane and 3H-leucine. The increase of the incorporation activity is gradual in the period of increasing polyploidy of the manubria and rapid during the initiation of the spermatozoid differentiation. It has been suggested that the manubria should play an important role in the process of spermatogenesis and the induction of spermatozoid differentiation.     

Biological role of endoreplication in the process of spermatogenesis inChara vulgaris L.

Summary During cell division in antheridial filaments ofChara vulgaris an increase in DNA content occurs in both shield cells and manubria within an antheridium, reaching 16C–64C and 8C–32C levels, respectively. Endoreplication ceases prior to the formation of spermatids and initiation of spermiogenesis, probably as a result of symplasmic isolation of the antheridium from the thallus. As the DNA content of the nuclei increases, the shield cells³H-leucine incorporation increases, and they grow intensively in the tangential plane. Translation decreases considerably after termination of shield cell growth. DNA content of mature manubria is half of that in shield cells, although their size is 10 times that of manubria. Translational activity of manubria also increases as DNA content rises and cells grow. However, during spermiogenesis, this activity remains at its maximum, which is associated with the secretory function of the manubria. Spermiogenesis is also accompanied by far-reaching ultrastructural changes within the manubrial cytoplasm.The level of endopolyploidy in both shield cells and manubria of antheridia formed in the spring is higher by one replication cycle, than in autumnal antheridia. AMO-1618, at a concentration of 10^–5M reduces the DNA content in the autumnal manubria. The higher the manubrial level of endopolyploidy in spermiogenesis, the greater their size, and the higher the translational activity and number of joined spermatids. The number of spermatozoids in the antheridium is also positively correlated with the internal volume of an antheridium, which is itself dependent on the endopolyploidy level of shield cells.The results obtained confirm the assumption that endoreplication favours the higher growth dynamics and potential translational activity, which occurs in the dynamic growth phase only in shield cells, while in manubria, i.e. cells producing substances necessary to spermatozoids development, it remains high until the end of spermiogenesis.     

Ultrastructural and autoradiographic studies of non-generative cells in the antheridium of Chara vulgaris. II. Capitular cells

In young antheridia, the structure of capitular cells is typical of meristematic cells. The cytoplasm is characterized by poorly developed ER system, numerous free ribosomes, active Golgi apparatus and plastids at the stage of proplastids. In the period of mitotic divisions, i.e. during formation of the initial cells of antheridial filaments, the nuclei of capitular cells have a changing structure. When capitular cells stop budding leading to the formation of successive antheridial filaments. DNA content in the nucleus is at 2C-4C level. The nucleolus with nucleolonema-like structure becomes gradually smaller in the course of the development of the anteheridium. During spermiogenesis capitular cells are vacuolated, cytoplasm contains numerous polysomes, mitochondria assume condensed structure, the incorporation of 3N-uridine and of labelled aminoacids increases. It has been suggested that capitular cells collaborate with other antheridial cells in the regulation of the course of spermiogenesis.     

Symplasmic isolation ofChara vulgaris antheridium and mechanisms regulating the process of spermatogenesis

Summary The antheridium ofChara vulgaris L. is connected by plasmodesmata with the thallusvia a basal cell. Prior to the initiation of spermatozoid differentiation these plasmodesmata are spontaneously broken, resulting in symplasmic isolation of the antheridium.Premature plasmolytically evoked symplasmic isolation of the antheridium leads to a 2–4 fold reduction in the length of antheridial filaments and the elimination of 1–2 cell cycles from the first stage of spermatogenesis.Autoradiographic and cytophotometric studies have shown that, as a result of induced symplasmic isolation of the antheridium, endomitotic DNA synthesis was blocked both in the young manubria (after 24 hours) and in the capitular cells (after 48 hours). In the antheridial filaments DNA synthesis was inhibited together with either elimination of divisions and induction of spermatid differentiation or developmental block. We propose that breakage of plasmodesmata connecting the antheridium with the thallus is a signal which releases, in all antheridia, mechanisms that (i) block endomitotic DNA synthesis in the manubria, (ii) restrict the growth rate and the divisions of antheridial filament cells, and (iii) induce spermiogenesis in these antheridia in which the manubria attained the sufficient level of polyploidy.This work is supported by the Polish Academy of Sciences within the project CPBP 04.01.5.05.     

Zostera capensis setchell: III. Some aspects of wall ingrowth development in leaf blade epidermal cells

Summary The development of wall ingrowths in leaf blade epidermal cells of the marine angiospermZostera capensis was studied by electron microscopy. Prior to the appearance of ingrowths long profiles of endoplasmic reticulum cisternae become arranged peripherally closely following the contours of the walls. The plasmalemma assumes a wavy appearance and in regions where wall ingrowths first start forming (i.e., along the radial, inner tangential and transverse walls) the plasmalemma becomes separated from the walls by an undulating extracytoplasmic space. Small, irregular projections of secondary wall material make their appearance here. Paramural bodies, dictyosomes, endoplasmic reticulum (ER) and possibly also microtubules seem to be closely associated with the initiation and subsequent development of wall projections. As the cells mature, new ingrowths arise in a centrifugal direction along the radial and transverse walls. When wall ingrowths reach a certain stage of their development, mitochondria become strongly polarized towards them and become closely associated with the plasmalemma which ensheaths the ingrowths. There is often also a close association between ER cisternae and the involuted plasmalemma of the wall projections. Initially ingrowths are slender, curved structures, but become more complex as the cells mature. Ingrowths are most extensively developed along the inner tangential and transverse walls. As epidermal cells age there is a loss of wall material from the ingrowths. The probable significance of the formation of wall ingrowths in the epidermal cells is also discussed.     

Dynamic microtubules under the radial and outer tangential walls of microinjected pea epidermal cells observed by computer reconstruction

By microinjecting rhodamine-conjugated pig brain tubulin into living pea stem epidermal cells it has been possible to follow cortical microtubules beneath the outer tangential wall (OTW) as they re-orientate from a transverse to a longitudinal alignment. Earlier immunofluorescence studies on fixed material have shown that parallel cortical microtubules circumnavigate the cell forming apparently continuous arrays which are transverse, oblique or longitudinal to the cell's long axis. If the array re-orientates as a whole then microtubules along the radial walls would be expected to share the alignment of those on the tangential walls. There are, however, reports that microtubules beneath the outer tangential wall have a different orientation from microtubules at the radial cell walls, raising important questions about the construction and behaviour of the array. Using computer-rotated stacks of optical sections collected by confocal scanning laser microscopy it has been possible to display the microtubules along radial as well as tangential walls of the same microinjected cells. These observations demonstrate for living epidermal cells that when microtubules are aligned longitudinally at the outer epidermal wall they remain oblique or transverse at the radial walls. The array may not therefore re-orientate as a whole but seems to undergo re-organization on only one cell face. However, despite the differing angles between the OTW and radial walls microtubules still form patterns which at the level of the confocal microscope are continuous from one cell face to another, around the cell.
It is concluded that some organizing principle attempts to establish overall organization at the cellular level but that this can be perturbed by local re-organization of dynamic microtubules in subcellular domains. This study emphasizes the importance of the outer epidermal wall and its associated cytoskeleton in initiating changes in the direction of cell expansion.     

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.     

Cytochemical studies on the antheridial mucilage and changes in its concentration and amount during the spermatogenesis in Chara vulgaris L.

The internal space of the antheridium in Chara vulgaris L. is filled with the PAS-positive mucilage which is of pectic nature. Morphometric and cytophotometric measurements on the semithin sections indicate that the concentration and amount of PAS-positive polysaccharides: 1) increase during the time of antheridial growth accompanying the phase of antheridial filament divisions, 2) these parameters have the maximum after spermatid formation and at the beginning of their differentiation, i.e. spermiogenesis, 3) both concentration and amount of this substance decrease at the end of spermiogenesis. A decrease in mucilage concentration is also observed in the young antheridia after 3 days of continuous darkness. The results suggest that PAS-positive mucilagenous material is a nutritive substance, accumulated in the first phase of antheridial development and utilized mainly in spermiogenesis. These substances may also be used up in the young antheridia during the lack of energy supply. The autoradiographic studies with the use of a 3H-glucose and 3H-galactose mixture seem to confirm these suggestions.     

Cell sizes and DNA level in antheridial filaments in relation to the initiation of spermatozoid differentiation in Chara vulgaris L

The observations carried out indicate that the exclusion of the S phase initiation from the course of telophase of the last mitotic division in the antheridial filaments of Chara vulgaris, leading to the formation of spermatids is not a simple result of the cell size reduction, gradually accomplished in the course of the successive cell cycles (of S+G2+M type). This critical moment of spermatogenesis is probably induced by the regulators operating at the level of an antheridium. In the conditions of the long (3-5 days) darkness resulting in the cell cycle arrest in antheridial filaments at the early stage of G2 phase there is detected the operation of some additional mechanisms synchronizing spermatogenesis, which enable some retarded antheridial filaments to pass the critical control points and to enter into the process of spermiogenesis insensitive to the lack of the light. The initiation of the differentiation is accomplished either after the cell division induced by the hypothetic inductors of spermiogenesis or -- more rarely -- with omitting mitosis, i.e. in the cells containing 2C DNA.     

GA3 content in antheridia of Chara vulgaris at the proliferative stage and in spermiogenesis estimated by capillary electrophoresis

In male sex organs of Chara vulgaris L., the gibberellic acid (GA3), was identified by capillary zone electrophoresis. The antheridia at cell division stage of antheridial filaments leading to formation of spermatids contain 0.09 microg GA3 per antheridium, i.e. 5.3 times more than antheridia at differentiation stage of spermatozoids (spermiogenesis). Spermiogenesis is not regulated by gibberellins.     

THE OCCURRENCE AND PHYLOGENETIC SIGNIFICANCE OF A MULTILAYERED STRUCTURE IN COLEOCHAETE SPERMATOZOIDS

Spermatozoid-forming cells of Coleochaete scutata were found in packets of four arranged in concentric internal bands. Spermatozoids, which occur singly in antheridial cells, are spherical to ovoid, approximately 7 μm long by about 3.9 μm wide. As compared to relatively unspecialized zoospores, male gametes undergo a number of specialized cellular changes during development. The spherical nuclei and cytoplasm of mature spermatozoids are increased in density. Posterior plastids are reduced and contain large starch grains. Many small mitochondria are clustered near the cell anterior. The plasmalemma is covered with a layer of flattened, diamond-shaped scales, while body scales of zoospores are pyramidal. The two flagella of both zoospores and spermatozoids are covered with flattened, diamond-shaped scales and hairs. The spermatozoids contain an anterior multilayered structure (MLS) structurally similar to, though smaller than, the MLS observed in zoospores. An asymmetrical cytoskeleton consisting of a band of 30–45 microtubules extends from the MLS down one side of the spermatozoid close to the plasmalemma. An immature MLS was observed in an early stage of spermatozoid development. The finding of an MLS and asymmetrical cytoskeleton in specialized male gametes as well as relatively unspecialized zoospores of Coleochaete strengthens assumptions of homology between MLSs of green algal reproductive cells and those found in flagellated spermatozoids of archegoniate plants. The structure of the spermatozoid of Coleochaete supports the hypothesis that this alga may be relatively close to the phylogenetic line which led directly to archegoniates.     

Pollen and Tapetum Development in Male Fertile Rosmarinus Officinalis L. (Lamiaceae)

The development of microspores/pollen grains and tapetum was studied in fertile Rosmarinus officinalis L. (Lamiaceae). Most parts of the cell walls of the secretory anther tapetum undergo modifications before and during meiosis: the inner tangential and radial cell walls, and often also the outer tangential and radial wall, acquire a fibrous appearance; these walls become later transformed into a thin poly-saccharidic film, which is finally dissolved after microspore mitosis. Electron opaque granules found within the fibrous/lamellated tapetal walls consist of sporopollenin-like material, but cannot be interpreted as Ubisch bodies. The middle lamella and the primary wall of the outer tangential and radial tapetal walls remain unmodified, but get covered by an electron opaque, sporopollenin-like layer. Pollenkitt is formed only by lipid droplets from the ground plasma and/or ER profiles, the plastids do not form pollenkitt precursor lipids. Tapetum maturation (“degeneration”) does not take place before late vacuolate stage.

The apertures are determined during meiosis by vesicles or membrane stacks on the surface of the plasma membrane. The procolumellae are conical, but at maturity the columellae are more cylindrical in shape. The columellar bases often fuse, but a genuine foot layer is lacking. The formation of the endexine starts with sporopollenin-accumulating white lines adjacent to the columellar bases. Later, the endexine grows more irregularly by the accumulation of sporopollenin globules. In mature pollen the intine is clearly bilayered.

Generative cells (GCs) and sperm cells contain a comparatively large amount of cytoplasm, and organelles like mitochondria, dictyosomes, ER, and multi-vesicular bodies, but no plastids; GCs and sperms are separated from the vegetative cell only by two plasma membranes.     

OBSERVATIONS ON THE PHI-THICKENINGS AND CASPARIAN STRIPS IN PELARGONIUM ROOTS

An ultrastructural examination of hypodermal cell walls failed to demonstrate the presence of casparian strips as has been reported in the literature. Rather, these cells have supportive phi-thickenings which differ significantly from casparian strips. Adjacent phi-thickenings are convex-convex and stratified in transection, with an uneven surface like the rest of the phi-cell's wall. They may be unbranched or branched and in the latter case, especially, they may appear on tangential as well as radial and transverse walls. They are lignified early in development and are associated with microtubules which lie parallel to the long axis of the thickening. Further, the plasmalemma exhibits no special adherence to the thickened wall region. In each of these and other characteristics phi-thickenings contrast sharply with casparian strips.     

Plasmodesmal changes are related to different developmental stages of antheridia of Chara species

Summary During the development of the antheridia of Chara species, dynamic changes in the occurrence and ultrastructure of plasmodesmata are observed which are closely correlated to particular developmental phases and presumably regulate the morphogenetic events in the antheridia. The disappearance of plasmodesmata between shield cells and between shied cells and the basal cell leads to a cessation in symplasmic transport around the antheridum and determines its concentric or centrifugal character via centrally situated capitular cells. Unplugged plasmodesmata are present between fully synchronously developing antheridial filament cells and obviously coordinate the development of the cells. In the middle phase of spermiogenesis, rough endoplasmic reticulum in antheridial filaments passes uncompressed through wide plasmodesmata and provides an additional transport pathway for developmental control factors. Plugged plasmodesmata link cells of different types or cells of the same type which are at different phases of cell cycle and guarantee their individual development. The plugging of plasmodesmata is a reversible process that depends on the morphogenetic situation. Plasmodesmata connecting the basal cell and the subbasal cell as well as the basal cell and capitular cells are transformed successively from the simple into the complex type and might be the pathways for an import of gibberellins and nutrients into the strong sink tissues of the developing antheridium. There is a symplasmic connection between the antheridum and the thallus via a basal cell. Prior to the initiation of spermatozoid differentiation (spermiogenesis), plasmodesmata connecting the basal cell with a subbasal cell and the basal cell with capitular cells are spontaneously broken, resulting in symplasmic isolation of the antheridium that is probably a signal which triggers the induction of spermatozoid differentiation. Premature plasmolytically evoked symplasmic isolation of the antheridium leads to the elimination of 1 to 2 cell cycles from the proliferative stage of spermatogenesis. Autoradiographic studies demonstrate that both natural and induced symplasmic isolation drastically decreases the entry of isotopically labeled gibberellic acid into antheridia of Chara species that may be the consequence of the elimination of the hormone's transport through plasmodesmata.Correspondence and reprints: Department of Cytophysiology, University of ód, ulica Pilarskiego 14, 90-231 ód, Poland.Received March 11, 2002; accepted September 19, 2002; published online August 26, 2003     

The development and ultrastructure of the testa and tracheid bar inErythrina lysistemon Hutch. (Leguminosae: Papilionoideae)

Summary The development of the testa was studied inErythrina lysistemon using both light and electron microscopy. Cells of the outer epidermis of the outer integument divide anticlinally and undergo radial elongation to form a palisade layer. The outer tangential walls are thickened at an early stage, and deposition of fluted thickenings on the radial walls occurs at maturity. Palisade cells in the hilar region differentiate from sub-funicular tissue, and at maturity the outer ends of the cells undergo extensive deposition of secondary walls and associated lignification. The light line occurs at the junction between the outer, thickened portions of the cells and the inner, less thickened portions. An electron-translucent (suberised) cap develops in the outer tangential walls of the palisade cells at a late stage. Microtubules and dictyosomes are closely associated with the developing thickenings in palisade and tracheid bar, and the microtubules run parallel to the wall microfibrils. Differentiation of the tracheid bar coincides with final secondary wall deposition and lignification in the hilar palisade. The cells of the tracheid bar are dead at maturity, but are surrounded by sheaths of elongate parenchyma.     

Structure and cytochemistry of the procambium in Salix buds during dormancy and dormancy breaking

This report presents a combined investigation of ultrastructural and enzymatic changes in the procambium from late winter to early spring. In January the procambial cells of dormant Salix buds have a convoluted plasma membrane with many plasmalemmasomes, numerous lipid bodies, large stacks of rough ER and plastids surrounded by smooth ER profiles. Several small lysosomes show activity of ATPase and acid phosphatases. In addition ER, nuclear envelopes, dictyosomes, and thylakoids have ATPase activity, and ER and plasmalemma, and nuclei also show acid phosphatase activity. In February metabolism seems to increase as indicated by lysosomes with membranous formations, dilated ER, nuclear envelopes, spiny vesicles, and polysomes. ATPase activity occurs in plasmalemma and vacuoles, and acid phosphatases in the middle lamella region of walls, in plasmalemma, vacuoles, ER, and nuclei. At the end of March, when growth starts inside the buds, but before they break, the stacks of rough ER disappear, and the vacuoles coalesce. Most of the lipid bodies have disappeared and the plastids have accumulated starch. Cell division and differentiation of procambial cells to protophloem and protoxylem have started. The distribution of ATPase increases; activity is found in walls and plasmalemma, and only a few small vacuoles still have ATPase and acid phosphatase activity. Notable is the appearance of ATPase in mitochondrial cristae and nucleoli and the occurrence of rather high levels also in endomembranes and dictyosomes.     

Seasonal patterns of cell-to-cell communication in Chara corallina Klein ex Willd. II. Cell-to-cell communication during the development of antheridia

Cell-to-cell communication has been studied in lateral branches and developing antheridia of male Chara corallina plants. The moving cytoplasm is specialized to include essentially separate ascending and descending cytoplasmic streams within the inter-nodes. The neutral line which demarcates the ascending from the descending stream is established by the divisions of the nodal initial, which gives rise to both the node and internode. The ascending stream is located beneath the first-formed node-cells and the descending stream beneath the last-formed cells. The cells destined to develop into antheridia were always located on the same side as the descending internodal stream, and thus, were derived from the cells last formed during divisions of the nodal initial. Three stages of anther idial development have been defined: (1) young antheridia from the initial division of a node-cell to the formation of an octant structure; (2) maturing antheridia where differentiation into shield, manubria and capitular cells has occurred, including antheridia where an internal cavity has formed but contains filaments of less than 32 cells; and (3) mature antheridia where filaments contain more than 32 cells and spermatid production commences. Internodal cells of branches bearing young antheridia had similar characteristics to spring branches, including high plasmalemma potential differences (-217·7±31·5mV, [K⁺]_o 0·5 mol m^?3; pH 7·6) and extensive cell-to-cell communication (frequency of intercellular transport of 6 carboxyfluorescein 86%). The small probe 6 carboxy fluorescein moved into the entire young antheridium in 100% of injections. The molecular exclusion limit for internodes and the nodal complex lay between 874 and 1678Da whereas the exclusion limit for the young antheridium was smaller (between 750 and 874Da). Internodal cells of branches bearing maturing antheridia had similarly high PDs (–221·7±40mV; [K⁺]_o 0·5 mol m^?3; pH 7·6). Cell-to-cell communication between internodes bearing maturing antheridia was extensive (frequency of intercellular transport of 6 carboxyfluorescein 100%). The shield cells were isolated from the symplast of the thallus at this stage since they did not admit 6 carboxyfluorescein. Internodal cells of branches bearing only mature antheridia showed different characteristics. Intercellular communication between internodes was restricted to a level similar to that found in winter (frequency of intercellular transport of 6 carboxyfluorescein = 57%). The mature antheridium was entirely isolated from the symplast of the thallus. A period of extensive cell-to-cell communication and high PDs in internodal cells commences in vegetative lateral branches in spring, immediately before reproductive structures are initiated. These features persist throughout summer whilst reproductive structures develop, until the antheridial filaments contain 32 or more cells (mature stage), at which point spermatid production commences and the antheridium is isolated from the thallus. In autumn, following the stage of mature antheridia, no further antheridia are initiated. Internodes are subsequently vegetative throughout winter and their lateral branches are characterized by restricted cell-to-cell communication, low internodal PDs, and little obvious growth, all features consistent with winter dormancy.     

Some fine structural observations on the rhizome ofDendroligotrichum (Bryophyta)

Summary The underground portion (rhizome) of the gametophytic axis ofD. dendroides bears anatomical resemblances to a triarch dicotyledonous root. The similarities include: 1. an epidermis producing epidermal appendages; 2. a cortex with endodermoid layer; and 3. a tri-radiate arrangement of the food and water-conducting tissue. Histochemical observations reveal that the entire radial and transverse walls of the endodermoid cells are encrusted with amorphous deposits, probably of polyphenolic nature. Casparian bands are not present as reported by earlier workers. The radial walls exhibit a fine structure of alternating electron-dense and electron-opaque lamellae. In plasmolyzed cells the plasmalemma does not adhere to the radial wall. Plasmodesmatal connections were observed in the radial and outer tangential walls of the endodermoid cells, but not in the inner tangential walls. These features of the endodermoid layer ofD. dendroides are discussed in relationship to the structure and function of the endodermis of vascular plants.     

ON THE DEVELOPMENT OF MACROSCLEREIDS IN SEED COATS OF PISUM SATIVUM L.

Macrosclereid differentiation was investigated by light and electron microscopy in pea testae during the transformation of protodermal precursors to the mature sclereids. The protodermal cells divide anticlinally and elongate into the macrosclereid layer during seed coat development. Young sclereids have elongate nuclei, plastids become somewhat granal during cellular maturation, vacuolation appears to be an autolytic process, and the cells have dense arrays of endoplasmic reticulum and ribosomes. Considerable dictyosome activity and microtubule development is observed as the secondary wall is produced. Many coated vesicles are associated with and fuse with the plasmalemma. During development, the outer tangential wall area of the macrosclereids acquires a definite cuticle and subcuticular layer. Also, at this time the sclereid walls under the subcuticular layer display semicircular microfibril orientation. The sclereid walls adjacent to the hypodermis become multilayered. As the macrosclereids near maturity, the “light line” becomes discernable in the light microscope at the junction of the cellulosic tips of the macrosclereids and the subcuticular layer. This “light line” is prominent using interference optics and is an osmiophilic layer in the electron microscope. This layer may represent the suberin “caps” reported by earlier workers.     

葫芦藓精子发生过程中胞间连丝与胞质桥的超微结构

从超微结构水平上对葫芦藓(Funaria hygrometrica Hedw.)精子发生过程中胞间连接系统的结构及其变化动态进行了研究.结果表明,同一区中的相邻生精细胞由大量胞质桥相连,而不同区的细胞之间则不存在胞质桥.胞间连丝存在于套细胞之间以及套细胞与生精细胞之间,但它在生精细胞间不存在.在精子器发生的后期,当精子细胞壁开始降解时,同一个精子器中所有的精子细胞似乎都由扩大的胞质桥相互连接.胞质桥一直保持到精子分化的后期,最终精子细胞同步分化成精子.胞间连丝与胞质桥具有不同的内部结、分布以及生物发生机制,这表明它们在精子器的发育过程中可能扮演着不同的角色.