Ultrastructural and chemical changes in the cell wall of Haematococcus pluvialis (Volvocales,Chlorophyta) during aplanospore formation

Changes in the ultrastructure and chemistry of the cell wall of the unicellular volvocalean green alga Haematococcus pluvialis were investigated during the transformation of flagellates into aplanospores. The motile biflagellated state exhibited a distinct gelatinous extracellular matrix. Its ultrastructure resembled the typical volvocalean multilayered architecture with a median tripartite crystalline layer. The transformation into the non-motile cell state was characterized by formation of a new layer, a primary wall, within the extracellular matrix. During this process, the initial extracellular matrix remained intact except for the outer layers of the tripartite crystalline layer, which decomposed. Further morphogenesis of the aplanospore resulted in the formation of a voluminous multilayered cell wall. A trilaminar sheath was formed inside the primary wall and the innermost and thickest part was an amorphous secondary wall, consisting mostly of a mannan. Results obtained by staining with the fluorescent dye primuline as well as by acetolysis suggest the occurrence of sporopollenin-like material (algaenan) within the trilaminar sheath of the aplanospore cell wall. The primary wall and the outer remnants of the extracellular matrix disintegrated as the aplanospores aged, and were completely absent in the resting cell state.     

Numerical and structural changes in dictyosomes during zygospore germination ofClosterium ehrenbergii

Summary Numerical and structural changes in dictyosomes during the germination of zygospores inClosterium ehrenbergii were examined by electron microscopy. In the dormant mature zygospores, two parallel cisternac were seen which were derived from the disorganization of dictyosomes during the maturation of zygospores. After the induction of germination, the two parallel cisternae developed into dictyosomes with ten or eleven cisternae. The dictyosomes doubled in number by division every day for four days and reached, at the time of germination, a density of distribution similar to that found in the youngest zygospore. On the 4th day after the induction of germination, dictyosomes produced two kinds of vesicles which appear to be involved in the formation of new cell wall layers. The germination of the zygospore was effected by the escape of the cell covered with the new cell wall layers through the broken old cell wall layers.     

Growth,cell wall formation and differentiation in the protonema of the moss,Funaria hygrometrica: Effects of plasmolysis on the developmental program and its expression

Summary Cultivation ofFunaria protonemata under plasmolytic or slightly subplasmolytic conditions initially causes a cessation of growth which is accompanied by a transient disappearance (or strong reduction in frequency, respectively) of putative cellulose synthesizing particle rosettes in the plasma membrane. Simultaneously, the formation and exocytosis of cell wall materialsecreting Golgi vesicles is slowed down. The latter process does not become apparent for several hours, though the reduction in activity can be proved indirectly. As a consequence of the imbalance between exocytosis, cell wall material accumulates in the plasmolytic space, generally at the cell tip. This indicates that the pattern of local, polar deposition of cell wall formation and cell elongation, membrane debris as well as wall material is maintained for some time. Later, however, the whole protoplast may become covered by new wall layers. Potentially growing filament tips and the distal region of nontip cells increase in diameter after longer cultivation in subplasmolytic conditions. It is suggested that normal wall growth results from a softening of the existing wall, its stretching and simultaneous stabilization by the apposition of new wall layers. We believe that the swelling is caused by a change in the equilibrium between the obviously less affected softening process and the imperfect stabilization by new wall layers because the wall layers which are formed at reduced turgor pressure are looser than normal and may have a changed composition.Kinetin-induced buds do not develop under plasmolytic conditions. Instead, spiral filaments are formed which readily give rise to buds when the osmotic value of the (kinetin-containing) medium is normalized. The results show that plasmolysis affects the expression of the developmental program rather than its initiation or maintenance.     

Organization and chemical composition of the cell wall of gramicidin S-producing Bacillus brevis

The morphology of cells and cell walls was studied in the Bacillus brevis G.-B. R form during its growth and gramicidin S accumulation in it. The membrane apparatus became more complicated and certain other morphological changes were detected in the cells with aging. The cell wall was rather complex even in young cells and consisted of three electron-dense layers where the external and internal layers had an ordered structure. Only the external layer underwent some modifications in the course of growth and these coincided in time with the beginning of intensive gramicidine S biosynthesis. However, the three-layer structure of the cell wall and the ordered organization of the external and internal layers remained unchanged. A preparation of cell walls and preparations of their external and internal layers were isolated from cells synthesizing gramicidine S in the amount of 20 micrograms/ml of the cultural broth. An acid protein having the molecular mass of 100 kD was shown to be the major component of the external layer according to the data of electrophoresis in PAAG with SDS. The middle layer was sensitive to lysozyme, did not have a ordered structure on electron micrographs, and consisted mainly of peptidoglycan.     

Growth of the surface of Corynebacterium diphtheriae

Surface structure and growth of the surface of Corynebacterium diphtheriae mitis strain were investigated by scanning electron microscopy and the immunofluorescence technique. The surface of the cell revealed by the scanning electron microscope showed a few elevated circular zones which encompassed the cell. The cell diameter increased at this zone and this gave the club-shaped appearance to this species. The cell surface labeled with specific antibodies against the whole bacterial cell and tagged with ferritin remained at a constant length during cell division cycles and the new cell surface emerged from the polar ends of the cell. This new wall surface was completely devoid of the ferritin particles indicating that the cell wall component on the old preexistent wall was completely conserved. A similar finding was obtained by immunofluorescence microscopy. C. diphtheriae, unlike Bacillus spp., showed apical growth as has been observed in fungal cells.     

Developmental changes in cell wall structure of phloem fibres of the bamboo Dendrocalamus asper

BACKGROUND AND AIMS: Bamboo culms have excellent physical and mechanical properties, which mainly depend on their fibre content and anatomical structure. One of the features which is known to contribute to the high tensile strength in bamboo is the multilayered structure of the fibre cell wall. The aim of this study was to characterize the development of the layered structure in fibre cell walls of developing and maturing culms of Dendrocalamus asper. METHODS: Cell wall development patterns were investigated in phloem fibre caps of vascular bundles in the inner culm wall areas of Dendrocalamus asper of three different age classes (<6 months old, 1 year old, 3 years old). A combination of light microscopy and image analysis techniques were employed to measure cell wall thickness and to determine number of cell wall layers, as well as to describe the layering structure of fibre walls. Two-dimensional maps showing the distribution pattern of fibres according to the number of cell wall layers were produced. KEY RESULTS: The cell walls of fibres in phloem fibre caps located in the inner part of the culm wall of D. asper developed rapidly during the first year of growth. Six different fibre types could be distinguished based upon their cell wall layering and all were already present in the young, 1-year-old culm. In the mature stage (3 years of age) the multilayering was independent of the cell wall thickness and even the thinner-walled fibres could have a large number of wall layers. The multilayered nature of cell wall structure varied considerably between individual cells and was not exclusively related to the cell wall thickness. Nevertheless, fibres at the periphery of the fibre bundles and immediately adjacent to the phloem elements exhibited a consistent and high degree of layering in their cell walls. CONCLUSIONS: The multilayered structure of fibre cell walls was formed mainly during the first year of growth by the deposition of new wall layers of variable thickness, resulting in a high degree of heterogeneity in the layering patterns amongst individual fibres. A degree of 'order' in the distribution of multilayered fibres within the caps does exist, however, with multilayered cell walls common in fibres adjacent to phloem elements and around the edge of the fibre cap. These findings confirm the observations, primarily in Phyllostachys viridi-glaucescens. The layering structure was not found to be specifically related to the thickness of the cell wall.     

Morphological alterations of cell wall concomitant with protein release in a protein-producing bacterium, Bacillus brevis 47.

Bacillus brevis 47 secreted vast amounts of protein into the medium and had a characteristic three-layered cell wall. The three layers are designated, from the outermost to the innermost layer, as the outer wall (4.2 nm), the middle wall(8.5 nm), and the inner wall (2.1-3.7 nm). The inner wall might be a peptidoglycan layer. The fine cell wall structure was morphologically altered to various extents, depending on the growth period. At the early stationary phase of growth, cells began to shed the outer two layers of a limited area of the surface. This shedding was complete after further cell growth. The morphological alterations in the cell wall occurred concomitantly with a prominent increase in protein excretion. When protein secretion was severely inhibited by growing cells with Mg2+, morphological alterations in the cell wall were not observed, even at the late stationary phase of growth. This was also the case with a nonprotein-producing mutant, strain 47-5-25. When cells were incubated in buffers, the outer two layers of the cell wall were specifically removed, leaving cells surrounded only by the inner wall layer. The layers removed by incubation were recovered by high-speed centrifugation. This fraction consisted of two layers resembling the outer and middle wall layers. Protein secreted by B. brevis 47-5 consisted mainly of two proteins with approximate molecular weights of 150,000 and 130,000. Proteins released by incubating cells in buffers and proteins in the outer- and middle-wall-enriched fraction were also composed mainly of two proteins with the same molecular weights as those secreted into the medium. Therefore, we conclude that B. brevis 47 secretes proteins derived from the outer two layers of cell wall and these components are synthesized even after the shedding of the outer two layers.     

Localization of dibenzodioxocin substructures in lignifying Norway spruce xylem by transmission electron microscopy–immunogold labeling

The lignification process in mature Norway spruce [Picea abies (L.) H. Karsten] xylem cell walls was studied using transmission electron microscopy (TEM)–immunogold detection with a polyclonal antibody raised against a specific lignin substructure, dibenzodioxocin. The study reveals for the first time the exact location of this abundant eight-ring structure in the cell wall layers of wood. Spruce wood samples were collected in Southern Finland at the time of active growth and lignification of the xylem cell walls. In very young tracheids where secondary cell wall layers were not yet formed, the presence of the dibenzodioxocin structure could not be shown at all. During secondary cell wall thickening, the dibenzodioxocin structure was more abundant in the secondary cell wall layers than in the middle lamella. The highest number of gold particles revealing dibenzodioxocin was in the S2+S3 layer. Statistically significant differences were found in the frequency of gold particles present in various cell wall layers. For comparison, wood sections were also cut with a cryomicrotome for light and fluorescence microscopy.     

Layered distribution, according to age, within the cell wall of bacillus subtilis.

When soluble autolytic activity was added to growing cultures of a mutant possessing a reduced rate of cell wall turnover, there was a delay of more than one generation before solubilization of new cell wall began, in contrast to the immediate increase in the rate of solubilization of old cell wall. A similar delay was found before turnover of new cell wall occurred in the parent, in agreement with a previous report (Mauck et al., 1971). When sodium lauryl sulfate-inactivated cell walls were prepared, the great bulk of the wall formed a uniformly susceptible substrate to added autolytic activity. The immediate solubilization of new wall eliminates insusceptibility to autolytic enzyme as an explanation for the failure to be turned over. There were, however, major differences in the rate of solubilization of wall of different ages. During solubilization of the initial 30% of the cell wall preparation, wall two generations old was solubilized at least seven times faster than wall one-half a generation old. This result is interpreted in terms of differences in accessibility. The cell wall is seen as consisting of a series of layers, the age of which increases with the distance from the membrane, such that wall newly synthesized on the membrane passes out through the thickness of the cell wall layer during subsequent growth and only becomes susceptible to turnover as it reaches the outer surface, largely in the form of a layer, more than one generation after incorporation.     

Adhesion-reduced mutants and the wild-typeNectria haematococca: An ultrastructural comparison of the macroconidial walls

We examined the macroconidial wall layers of various strains ofNectria haematococca prior to germ tube emergence. Using freeze-substituted cells, the wall ultrastructure of an adhesion-competent wild-type strain was compared with two adhesion-reduced mutants, LE1 and LE2. At 0 h, the freshly harvested macroconidia of all strains had a similar, bilayered wall and were all nonadhesive. After 1 h, wild-type macroconidia were adhesive and their cell walls exhibited two additional layers not present at 0 h: a pellicular third layer and a thick, outermost fourth layer. Material from the fourth layer was apparently discharged into the surrounding medium. In contrast to the wild type, the mutants after 1 h were adhesion-deficient; the outermost wall layers of LE1 and LE2 differed from each other and from the wild type. There were also differences in the wall layers and extracellular matrices between the mutants and the wild type after 3- and 5-h incubations. Plasma membrane invaginations were not observed at 0 h, but were detected in both wild type and mutant macroconidia at 1, 3, and 5 h. The data demonstrate that in macroconidia ofN. haematococca (1) the wall and associated extracellular matrix undergo major morphological changes prior to germ tube emergence and (2) development of adhesiveness is correlated with the appearance of new wall layers.     

Development of thallus axes in Usnea longissima (Parmeliaceae, Ascomycota), a fruticose lichen showing diffuse growth

? Premise of the study: While cell wall thickening in plants is generally associated with tissue maturation, fungal tissues in at least two lichens continue to grow extensively while accumulating massively thickened cell walls. We examined Usnea longissima to determine how diffuse growth shapes morphological and anatomical development of thallus axes and how the highly thickened cell walls of the central cord behave in diffuse growth. ? Methods: Fresh material was examined with light and epifluorescence microscopy and conventional and low-temperature SEM. Fixed material was embedded in Spurr's resin, microtome-sectioned, and examined with TEM and light microscopy. ? Key results: Main axes consisted essentially of bare medullary cord tissue; their characteristic morphology developed by destruction of the overlying cortex and consequent stimulation of lateral branch formation. Fungal cells of the cord tissue continually deposited wall layers of electron-transparent substances and layered, electron-dense materials that include UV-epifluorescent components. Discontinuities were evident in the outermost layers; new branch cells grew through wall materials accumulated by older neighboring cells. ? Conclusions: Sustained diffuse growth of cord tissue in U. longissima underlies the structural transformation of a corticated thallus branch into a long axis. In the cord tissue, diffuse growth may be responsible for the increasingly disrupted appearance of the older, electron-dense cell wall layers, while new wall materials are laid down adjacent to the protoplast. Cell and tissue development appeared comparable to that observed previously in Ramalina menziesii, although accumulation of wall material was somewhat less extensive and with a greater proportion of electron-dense/UV-epifluorescent components.     

The initiation of cell wall synthesis in parasynchronous cultures of Schizosaccharomyces pombe

Summary Schizosaccharomyces pombe has been grown in parasynchronous culture to study the synthesis of cell wall material. After a lag period of 2.5h following inoculation the cells began to grow, as measured by optical density, dry weight and cell size. The cell number remained constant until 4.5h after inoculation when approximately 70% of the population divided synchronously. Immunofluorescence studies of the growing cells have shown that new wall material is inserted at the cell apices from 2.5 h after inoculation; this result is supported by radio-isotope labelling data which indicated that synthesis of new cell wall material also commenced 2.5 h after inoculation. The incorporation experiments also demonstrated an interruption in cell wall synthesis during the cell separation stage. The composition of the cell wall material varied during the growth cycle, with maximum nitrogen levels at inoculation and following cell division. No serological differences could be detected in the cell walls during the growth cycle.     

Ultrastructure of fibre and parenchyma cell walls during early stages of culm development in Dendrocalamus asper

BACKGROUND AND AIMS: The anatomy of bamboo culms and the multilayered structure of fibre cell walls are known to be the main determinant factors for its physical and mechanical properties. Studies on the bamboo cell wall have focussed mainly on fully elongated and mature fibres. The main aim of this study was to describe the ultrastructure of primary and secondary cell walls in culm tissues of Dendrocalamus asper at different stages of development. METHODS: The development of fibre and parenchyma tissues was classified into four stages based on light microscopy observations made in tissues from juvenile plants. The stages were used as a basis for transmission electron microscopy study on the ultrastructure of the cell wall during the process of primary and early secondary cell wall formation. Macerations and phloroglucinol-HCl staining were employed to investigate fibre cell elongation and fibre cell wall lignification, respectively. KEY RESULTS: The observations indicated that the primary wall is formed by the deposition of two distinct layers during the elongation of the internode and that secondary wall synthesis may begin before the complete cessation of internode and fibre elongation. Elongation was followed by a maturation phase characterized by the deposition of multiple secondary wall layers, which varied in number according to the cell type, location in the culm tissue and stage of shoot development. Lignification of fibre cell walls started at the period prior to the cessation of internode elongation. CONCLUSIONS: The structure of the primary cell wall was comprised of two layers. The fibre secondary cell wall began to be laid down while the cells were still undergoing some elongation, suggesting that it may act to cause the slow-down and eventual cessation of cell elongation.     

Biochemical Localization of Alkaline Phosphatase in the Cell Wall of a Marine Pseudomonad

The various layers of the cell envelope of marine pseudomonad B-16 (ATCC 19855) have been separated from the cells and assayed directly for alkaline phosphatase activity under conditions established previously to be optimum for maintenance of the activity of the enzyme. Under conditions known to lead to the release of the contents of the periplasmic space from the cells, over 90% of the alkaline phosphatase was released into the medium. Neither the loosely bound outer layer nor the outer double-track layer (cell wall membrane) showed significant activity. A small amount of the alkaline phosphatase activity of the cells remained associated with the mureinoplasts when the outer layers of the cell wall were removed. Upon treatment of the mureinoplasts with lysozyme, some alkaline phosphatase was released into the medium and some remained with the protoplasts formed. Cells washed and suspended in 0.5 M NaCl were lysed by treatment with 2% toluene, and 95% of the alkaline phosphatase in the cells was released into the medium. Cells washed and suspended in complete salts solution (0.3 M NaCl, 0.05 M MgSO(4), and 0.01 M KCl) or 0.05 M MgSO(4) appeared intact after treatment with toluene but lost 50 and 10%, respectively, of their alkaline phosphatase. The results suggest that the presence of Mg(2+) in the cell wall is necessary to prevent disruption of the cells by toluene and may also be required to prevent the release of alkaline phosphatase by toluene when disruption of the cells by toluene does not take place.     

Electron Microscopic Observations on the Structure of the Envelopes of Mature Elementary Bodies and Developmental Reticulate Forms of Chlamydia psittaci

Purified suspensions of Chlamydia psittaci were prepared from L cells. Thin sections of intact elementary bodies and intact developmental reticulate bodies and of their purified envelopes were observed by electron microscopy. In both intact organisms and partially purified envelopes, two membranous structures, each appearing in electron micrographs as two darkly stained layers, were observed. In the elementary body sections, the outer membrane was round, apparently rigid, and was not soluble in 0.5% sodium dodecyl sulfate. The inner layer was irregular in shape and was completely removed by detergent treatment. We interpret these results to indicate that the outer rigid layer of the envelope is the cell wall and the inner layer is the cytoplasmic membrane. When the fragile reticulate body envelopes were similarly studied, the outer cell wall was clearly visible, and some evidence of an inner membrane was seen. After treatment with nucleases and detergent, all evidence of inner or cytoplasmic membrane was removed, but the outer cell wall remained. Thus, it appears that the cell wall of this organism is continuous throughout the growth cycle and that the fragility and lack of rigidity of the reticulate body cell is due to changes in chemical composition or structure of the cell wall.     

Purification and Characterization of a Glycine-rich Polypeptide Tightly Bound to Cell Walls from Soybean Aleurone Layers

A part of cell walls in soybean aleurone layers remained undigested after pectinase and cellulase treatments, and the features of the undigested cell walls were similar to those of Casparian strips. Glycine-rich polypeptides (GRPP) were extracted with 0.4 n NaOH from the undigested cell walls, Casparian strip-like tissues. Approximately 6.5–kDa GRPP obtained by gel-permeation chromatography from the extract was purified by anion-exchange HPLC and reverse-phase HPLC. The major amino acids of GRPP were glycine (69%) and serine (13%). The n-terminal amino acid sequence of GRPP was the same polyglycine as 30 kDa glycine-rich protein (GRP). GRPP would participate in adhesion between neighboring cells in aleurone layers because of tight binding to the cell wall.     

Electron microscopy of sporulation inSchwanniomyces alluvius

Sporulation inSchwanniomyces alluvius appeared to be preceded by fusion of a mother and a daughter cell. Meiosis probably occurred in the mother cell and one or two spores were formed in the latter. A study of thin sections showed that the spore wall developed from a prospore wall. The mature spore wall consisted of a broad light inner layer and a thinner dark outer layer including warts. An equatorial ledge was present. During germination in the ascus, a new light inner layer was formed and the old layers of the spore wall partly broke up. Ascospores in a strain ofS. persoonii had a different wall structure in that the dark layer had changed into light areas separated by dark material which formed bulges at the surface.     

Study of cycle of cell wall assembly in Streptococcus faecalis by three-dimensional reconstructions of thin sections of cells.

A new ultrastructural method was used to study rounds of envelope synthesis that occur in Streptococcus faecalis in "growth zones" found between pairs of naturally occurring surface markers. The technique consists of producing three-dimensional reconstructions of these growth zones from the mathematical rotation, about a central axis, of measurements taken from central, longitudinal thin sections of cells. A cycle of exponential-phase envelope growth was then simulated by arranging a series of these reconstructions in increasing order of the amount of peripheral wall surface area or the amount of cell volume that each was calculated to contain. Using this simulated cycle of growth, the geometry of a single growth zone during a round of synthesis was studied. Based on this analysis, a model was developed for the assembly of the cell wall of S. faecalis. The model states that new cell wall surface is synthesized by the regulated flow of essentially two channels of cell wall precursors into a single growth zone. One channel of precursors would be involved in the assembly of a bilayered cross wall that would proceed at a fairly constant rate until the cross wall closes. The second channel of precursors would be involved in the separation of the bilayered cross wall into two segments of peripheral wall. These precursors would intercalate into and thicken the separating layers of the cross wall. The flow of precursors through this channel would be progressively reduced through a cycle. These decreases, when coupled with internal hydrostatic pressure, apparently would result in the enlarging peripheral wall becoming increasingly more curved and would also promote cell division by reducing the total amount of cell wall that must be assembled in order for septation to occur.     

Localization of acid phosphatase in Saccharomyces cerevisiae: a clue to cell wall formation.

Acid phosphatase is present in two layers of the cell envelope of Saccharomyces cerevisiae. These are separated by another layer, which is free of acid phosphatase. We have evidence that the cell wall is built up in two stages, which are independent. In the first stage, the cell wall is built up during the formation of the bud. Glucanase vesicles are involved in this process. In the second stage, a thick layer is deposited at the inside against the new cell wall. This results in the thick, rigid wall of the mature yeast cell. This latter layer is probably assembled on the outer surface of the plasmalemma.     

Lignin distribution in wood cell walls determined by TEM and backscattered SEM techniques

The lignin distribution in cell walls of spruce and beech wood was determined by high-voltage transmission-electron-microscopy (TEM) in sections stained with potassium permanganate as well as by field-emission-scanning-electron-microscopy (FE-SEM) combined with a back-scattered electron detector on mercurized specimens. The latter is a new technique based on the mercurization of lignin and the concomitant visualization of mercury by back-scattered electron microscopy (BSE). Due to this combination it was possible to obtain a visualized overview of the lignin distribution across the different layers of the cell wall. To our knowledge, this combined method was used the first time to analyse the lignin distribution in cell walls. In agreement with previous work the highest lignin levels were found in the compound middle lamella and the cell corners. Back-scattered FE-SEM allows the lignin distribution in the pit membrane of bordered pits as well as in the various cell wall layers to be shown. In addition, by using TEM as well as SEM we observed that lignin closely follows the cellulose microfibril orientation in the secondary cell wall. From these observations, we conclude that the polymerisation of monolignols is affected by the arrangement of the polysaccharides which constitute the cell wall.