The fine structure of a tri-lamellar body in various species ofAnabaena

Summary A tri-lamellar body has been observed either near or adjacent to the crosswalls in 16 out of 20 different isolates ofAnabaena examined in thin sections. These bodies appear to consist of three discoid lamellae approximately 0.3 m in diameter. The outer lamella (closest to the plasma membrane) is separated from the middle lamella by a 12 nm space and is about 8 nm in thickness. The middle and inner lamellae, spaced about 8 nm apart, are approximately 8 nm in thickness. Electron dense granules, interpreted to be -granules, are associated with the inner lamella. In different species, osmiophilic lines 3 nm wide were observed. The osmiophilic lines run at right angles to the lamellae, either between the outer and middle lamellae, between the middle and inner lamellae or between all three lamellae. In some species, osmiophilic lines are absent. Up to six tri-lamellar bodies have been observed in median longitudinal sections. Pores 20 nm in diameter and 60 nm apart were observed in layer 2 of the cell wall of all the species ofAnabaena examined. All species which had tri-lamellar bodies also had wall pores closely associated with the bodies. Wall pores were also observed in four species lacking tri-lamellar bodies. The possible role of these structures is discussed.     

Growth and gas-vacuole development in vegetative cells of Anabaena flos-aquae

Summary Gas-vacuoles consisting of collections of gas-cylinders, and continuity of the plasma membrane with lamellae, are observed at all stages of growth of Anabaena flos-aquae. In day+4 cells, increased numbers of invaginations of the plasma membrane are observed and the lamellae tend to lie parallel to the cell wall. Some evidence is presented which suggests an associated synthesis of -granules and gas-cylinders by lamellae. Features of older cells are increased numbers of gascylinders, -granules, structured granules, and large intralamellar vesicles which appear to correlate with the presence of pinkish vacuoles as observed with the light microscope. The mean percentage of the volume of cells occupied by gas-vacuoles is about 20% during exponential growth when the doubling time is 56.5 hours, increasing to 34% in day+24 cells when growth is stationary.     

Subcompartment sugar residues of gastric surface mucous cells studied with labeled lectins

Summary We examined the intracellular localization of sugar residues of the rat gastric surface mucous cells in relation to the functional polarity of the cell organellae using preembedding method with several lectins.In the surface mucous cells, the nuclear envelope and rough endoplasmic reticulum (rER) and cis cisternae of the Golgi stacks were intensely stained with Maclura pomifera (MPA), which is specific to -Gal and GalNAc residues. In the Golgi apparatus, one or two cis side cisternae were stained with MPA and Dolichos biflorus (DBA) which is specific to terminal -N-acetylgalactosamine residues, while the intermediate lamellae were intensely labeled with Arachis hypogaea (PNA) which is specific to Gal 1,3 GalNAc. Cisternae of the trans Golgi region were also stained with MPA, Ricinus communis I (RCA I) which is specific to -Gal and Limax flavus (LFA) which is specific to -NeuAc. Immature mucous granules which are contiguous with the trans Golgi lamellae were weakly stained with RCA I, while LFA stained both immature and mature granules.The differences between each lectin's reactivity in the rough endoplasmic reticulum, in each compartment of the Golgi lamellae and in the secretory granules suggest that there are compositional and structural differences between the glycoconjugates in the respective cell organellae, reflecting the various processes of glycosylation in the gastric surface mucous cells.     

Cell wall structure in the xylem parenchyma ofCryptomeria

Summary Cell wall structure in ray and axial parenchyma cells in the wood ofCryptomeria was shown to be typically crossed polylamellate and dissimilar to the characteristically layered wall of fibers and tracheids. Ray cells differed from axial cells in terms of form and also in the relative inclination of crossed microfibrillar helices in the cell wall. This feature was reflected by positive birefringence in ray cells and negative birefringence in axial cells. Localized wall thickenings,viz. transverse bars in ray cells and longitudinal ribs in axial cells, also displayed crossed polylamellate structure. This observation contrasts with the exclusively longitudinal microfibrillar orientation previously reported for longitudinal ribs in elongated parenchyma cells of primary tissue. On the basis of similar microfibrillar orientations between outer and inner wall lamellae, the cell walls ofCryptomeria parenchyma were judged to be predominantly secondary.Lignin was heterogeneously distributed in lamellate fashion and a high concentration characterized the thin middle lamella. Both types of parenchyma suggested a higher lignin content than adjacent longitudinal tracheids.     

Immunocytochemical characterization of early-developing flax fiber cell walls

Summary The deposition and formation of a thick secondary wall is a major event in the differentiation of flax (Linum usitatissimum) fibers. This wall is cellulose-rich; but it also contains significant amounts of other matrix polymers which are noncellulosic such as pectins. We have used immunocytochemical techniques with antibodies specific for various epitopes associated with either pectins or arabinogalactan proteins (AGPs) to investigate the distribution of these polymers within the walls of differentiating young fibers of 1- and 2-week-old plants. Our results show that different epitopes exhibit distinct distribution patterns within fiber walls. Unesterified pectins recognized by polygalacturonic acid-rhamnogalacturonan I (PGA/RG-I) antibodies and rhamnogalacturonan II recognized by anti-RG-II-borate complex antibodies are localized all over the secondary wall of fibers. PGA/RG-I epitopes, but not RG-II epitopes, are also present in the middle lamellae and cell junctions. In marked contrast, -(14) galactans recognized by the LM5 monoclonal antibody and AGP epitopes recognized by anti--(16) galactan and LM2 antibodies are primarily located in the half of the secondary wall nearest the plasma membrane. LM2 epitopes, present in 1-week-old fibers, are undetectable later in development, suggesting a regulation of the expression of certain AGP epitopes. In addition, localization of cellulose with the cellobiohydrolase I-gold probe reveals distinct subdomains within the secondary walls of young fibers. These findings indicate that, in addition to cellulose, early-developing flax fibers synthesize and secrete different pectin and AGP molecules.     

Environmental effects on the structure of the blue-green alga,Chlorogloea fritschii

Summary A study was made on the morphology and ultrastructure of Chlorogloea fritschii at different growth stages and under various environmental conditions. The environmental effects tested were a comparison of various light intensities, and the use of media, one with, and one without, a source of combined nitrogen. Both filamentous and endospore stages have the general ultrastructural features typical of a blue-green alga.The most marked differences found were in the arrangement of lamellae. These run parallel to the cell wall in young filaments, particularly in those grown at low light intensities. At the endospore stage these are much more scattered in arrangement.Two striking variations in this pattern were found. One cell type, possibly a spore, showed, along with other interesting features, marked reticulation of the lamellae. Material subcultured in the dark with sucrose for 3 years had the lamellae scattered throughout the cell.Differences were found also in the abundance of -granules (probable polyglucoside bodies). These differences could to a certain extent be correlated with the growth conditions used.A brief comparison of Chlorogloea with other blue-green algae is included. Based on this, tentative hypotheses are presented concerning correlations between ultrastructural features and taxonomic groupings.     

The junction between the plasma membrane and the cell wall in fern protonemal cells,as visualized after plasmolysis,and its dependence on arrays of cortical microtubules

Summary The junction between the plasma membrane and the cell wall in the subapical region of tip-growing protonemata of the fernAdiantum capillus-veneris was visualized by plasmolyzing the cells with a 1 M solution of NaCl. When the protonemata were treated with this solution, cells were rapidly plasmolyzed and the plasma membrane became detached from the cell wall around the entire periphery of the cell, with the exception of the subapex. In the subapical region, the connection between the cell wall and the plasma membrane remained undisturbed, whereas the membrane in other regions, as well as at the apex, was detached from the cell wall. As a result, the protoplasm appeared to adhere to the wall by a ringlike band of plasma membrane at the subapex. The location of the junction coincided with that of a circular array of microtubules (MTs) and microfilaments (MFs) at the cell cortex. The subapical junction disappeared when protonemata were treated with colchicine, cytochalasin B (CB), and blue-light irradiation, all of which are known to disrupt circular arrays of MTs. CB and blue light also disrupt the array of MFs but colchicine does not. Thus, the junction depends on the cortical MTs and not on the MFs. This finding indicates that the junction between the plasma membrane and the cell wall is sustained by a cortical array of MTs and suggests the presence of a specific and localized transmembrane structure.Abbreviations CB cytochalasin B - MF microfilament - MT microtubule     

A comparison of cell-wall-yielding properties for two developmental stages of Phycomyces sporangiophores

The yielding properties of the cell wall, irreversible wall extensibility (m) and yield threshold (Y), are determined for stage I sporangiophores of Phycomyces blakesleeanus from in-vivo creep experiments, and compared to the values of m and Y previously determined for stage IVb sporangiophores using the same pressureprobe method (Ortega et al., 1989, Biophys. J. 56, 465). In either stage the sporangiophore enlarges (grows) predominately in length, in a specific region termed the growing zone, but the growth rates of stage I (5–20 urn · min^–1) are smaller than those of stage IVb (30–70 m · min^–1). The results demonstrate that this difference in growth rate is the consequence of a smaller magnitude of m for stage I sporangiophores; the obtained values of P (turgor pressure), Y, and P-Y (effective turgor for irreversible wall extension) for stage I sporangiophores are slightly larger than those of stage IVb sporangiophores. Also, it is shown that the magnitude of m for the stage I sporangiophore is regulated by altering the length of the growing zone, L_g. A relationship between m and L_g is obtained which can account for the difference between values of m determined for stage I and stage IVb sporangiophores. Finally, it is shown that similar changes in the magnitude of m and (which have been used interchangeably in the literature as a measure of irreversible wall extensibility) may not always represent the same changes in the cell-wall properties.Abbreviations and Symbols L length - L_g length of growing zone - m irreversible wall extensibility - P turgor pressure - Y yield threshold - (P-Y) effective turgor for irreversible wall extension - relative irreversible wall extensibility - _g relative irreversible wall extensibility of the growing zone (m/L_g) This work was supported by National Science Foundation grant DCB-8801717 to J.K.E. Ortega.     

Das Lamellare Dünn-Dick-Muster der Chloroplasten von Chlamydomonas,Euglena, Fucus,Vaucheria

Summary As supposed in a previous paper, Heitz (1960), the lamellar thin-thick pattern is found in four algae of very different taxonomic position. It is suggested that the presence of thin and thick lamellae as well in the chloroplasts with grana as without grana, is a common, significant characteristic. Perhaps there is a functional difference between the two kinds of lamellae. The thick lamellae in the midst of the two thin lamellae in the Algae (and in the liverwort Anthoceros) are perhaps the precursors of the many thick lamellae in the so called grana of the higher plants.

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Die Arbeit wurde mit Unterstützung durch die Deutsche Forschungsgemeinschaft ausgeführt, der ich ebenso danke wie den technischen Assistentinnen Fräulein Döemer und Fräulein Möschler.     

OCCURRENCE OF TRI-LAMELLAR BODIES IN ISOLATES OF NOSTOC (CYANOPHYCEAE)1

Tri-lamellar bodies were observed in eight of 29 isolates of Nostoc examined. They appeared identical to the previously described bodies in various species of Anabaena. The bodies consist of three discoid lamellae each ca. 0.3 μm diam and 8 nm thick. The outer lamella (closest to the plasma membrane) is separated from the middle lamella by a 12 nm space whereas the middle and inner lamellae are ca. 8 nm apart. Osmiophilic striations 3 nm wide were generally observed running between the lamellae. Osmiophilic β granules were usually associated with the inner lamella. The bodies were most always located close to the plasma membrane along the longitudinal wall near the junction of the cross and longitudinal walls. In three isolates the bodies located near the cross walls were associated with gas vesicles and possessed a slightly different morphology. These tri-lamellar bodies consisted of three discoid lamellae, each ca. 2 nm thick, ca. 25 nm apart with electron dense material between the inner and middle lamellae. Pores 20 nm diam and ca. 60 nm apart were observed in layer 2 of the cell wall adjacent to the tri-lamellar bodies. These wall pores were also observed in isolates lacking tri-lamellar bodies.     

Subcellular distribution of arabinogalactan proteins in pollen grains and tubes as revealed with a monoclonal antibody raised against stylar arabinogalactan proteins

Summary Monoclonal antibody PCBC3, raised against stylar extracts fromNicotians, alata flowers, was deduced from enzyme-linked immunosorbent assays and inhibition of immuno-gold labelling on tissue sections to bind specifically to carbohydrate epitopes on arabinogalactan proteins (AGPs) but not to other arabinose-containing cell wall polysaccharides. When pollen grains ofN. tabacum were hydrated in fixative, PCBC3 bound to vesicles in the vicinity of the endoplasmic reticulum but, when grains were hydrated for 20 min in culture medium before fixation, binding was restricted to the plasma membrane. The generative-cell plasma membrane was also labelled in grains ofLycopersicon peruvianum. In pollen tubes ofN. tabacum grown in liquid culture, the AGPs detected by PCBC3 were located in several regions, including the plasma membrane, tubular-vesicular structures (plasmalemmasomes) at and under the plasma membrane, and multilamellar bodies within vacuoles, features generally associated with endocytosis. Labelling was not evident in secretory vesicles or the plasma membrane at the pollen-tube tip. The AGPs detected with PCBC3 were also present in pollen-tube walls, near the interface between the inner, callosic layer and the outer, fibrillar, pectic layer. Pollen tubes ofN. tabacum grown in medium lacking added CuSO₄ produce a wall with an abnormally thickened fibrillar layer, and this layer was uniformly labelled with PCBC3. The disposition of wall AGPs thus changes in pollen tubes of different morphologies.Abbreviations AGP arabinogalactan protein - -L-Araf -L-arabinofuranose - ELISA enzyme-linked immunosorbent assay - MAb monoclonal antibody - PBS phosphate-buffered saline     

Differentiation of the thermo-/hygrosensitive (no-pore) sensilla on the antenna of Antheraea pernyi (Lepidoptera,Saturniidae): a study of cryofixed material

Summary The morphogenesis of the thermo- and hygro-sensitive sensilla styloconica of Antheraea pernyi was studied, exclusively by cryomethods, during the second half of pupal development. The three major processes taking place during this period are (1) the differentiation of the dendritic outer segments of the sensory cells, especially of the lamellated type-2 receptor, (2) the formation of the receptor-lymph cavities, (3) the formation of tubular structures of unknown function in the inner receptor-lymph cavity, and (4) the elongation of the dendrite sheath. The formation of lamellae in the type-2 dendritic outer segment is achieved by the enfolding of its originally cylindrical cytoplasmic membrane. Autocellular junctions, previously described in the sensilla of adult animals, are found to join the forming lamellae. Close similarities between the junctions and smooth septate junctions are demonstrated. Both the extensive inner and outer receptor-lymph cavities are formed by invagination and folding of the apical cytoplasmic membranes of the three enveloping cells. Formation starts at the most apical projection of the cells and proceeds in a proximal direction. Up to 4-m-long tubular structures appear, exclusively in developmental stages, in the inner receptor-lymph cavity. They are composed of plasma membranes whose inner surface is studded with regularly spaced electron-dense particles. Contacts with the cytoplasmic membrane of the innermost enveloping cell demonstrate that the structures are composed of lipid membranes. During elongation of the dendrite sheath, which in these sensilla is apically attached to the hair wall, an 2-m-long growth-zone is observed at its proximal end. By addition of sheath-forming material to the growth-zone, the latter continuously moves proximally until the sheath is completed.     

Membrane–wall attachments in plasmolysed plant cells

Summary. Field emission scanning electron microscopy of plasmolysed Tradescantia virginiana leaf epidermal cells gave novel insights into the three-dimensional architecture of Hechtian strands, Hechtian reticulum, and the inner surface of the cell wall without the need for extraction. At high magnification, we observed fibres that pin the plasma membrane to the cell wall after plasmolysis. Treatment with cellulase caused these connecting fibres to be lost and the pinned out plasma membrane of the Hechtian reticulum to disintegrate into vesicles with diameters of 100–250nm. This suggests that the fibres may be cellulose. After 4h of plasmolysis, a fibrous meshwork that labelled with anti-callose antibodies was observed within the space between the plasmolysed protoplast and the cell wall by field emission scanning electron microscopy. Interestingly, macerase-pectinase treatment resulted in the loss of this meshwork, suggesting that it was stabilised by pectins. We suggest that cellulose microfibrils extending from strands of the Hechtian reticulum and entwining into the cell wall matrix act as anchors for the plasma membrane as it moves away from the wall during plasmolysis.Correspondence and reprints: Institute of Ecology and Conservation Biology, University of Vienna, Althanstrasse 14, 1090 Vienna, Austria.     

Ultrastructural localization of alkaline phosphatase in the hypertrophic chondrocyte of the frog

Summary The ultrastructural localization of alkaline phosphatase was studied in the hypertrophic chondrocyte of the frog (Rana temporaria) by incubating sections of glutaraldehyde fixed tissue in a medium containing sodium glycerophosphate and calcium chloride. Control specimens were incubated in substrate free medium.Alkaline phosphatase (orthophosphoric monoester phosphohydrolase) is a hight molecular weight glycoprotein that hydrolyses phosphorylated metabolites much as acid phosphatase does except that its action is optimal at an alkaline pH.The results of this investigation showed that alkaline phosphatase activity was present within the cytoplasm and around the plasma membrane of frog hypertrophic chondrocytes. Although only a small proportion of frog hypertrophic chondrocytes demonstrated enzyme activity, there was evidence that this was concentrated within Golgi lamellae and vesicles leaving other organelles unreactive. The finding of alkaline phosphatase activity within Golgi lamellae of hypertrophic chondrocytes is regarded as unusual although positive reactions within chondrocyte lysosomes have previously been reported (Doty and Schofield, 1976).     

Characterization of theGeosiphon pyriforme symbiosome by affinity techniques: confocal laser scanning microscopy (CLSM) and electron microscopy

Summary Geosiphon pyriforme represents a photoautotrophic endosymbiosis of aGlomus-like fungus with the cyanobacteriumNostoc punctiforme. The fungus forms unicellular bladders of up to 2 mm in length and 0.5 mm in diameter growing on the soil surface and harboring the endosymbioticNostoc filaments. The cyanobacteria are located in a compartment (the symbiosome) bordered by a host membrane. The space between this symbiosome membrane (SM) and theNostoc cell wall is filled with an about 30–40 nm thick layer of amorphous material, which is present also in the regions of the symbiosome where noNostoc filaments are located. At these sites the amorphous material consists of a 20–30 nm thick layer separating the SM. The region between the SM and the cyanobacterium is defined as symbiosome space (SS). Fungal bladders, hyphae and free livingNostoc were analyzed by affinity techniques as well as the material occurring in the SS. FITC-coupled lectins with sugar specificity to -D-mannosyl/-D-glucosyl (Con A), N-acetyl--D-glucosamine oligomers (WGA), -L-fucosyl (UEA-I), -D-galactosyl (RCA-120), -D-galactosyl (BS-I-B₄), N-acetyl--D-galactosamine (HPA), and sialic acid (EBL) residues were tested. WGA binding and calcofluor white staining demonstrated that the bladder wall as well as the SS contain fibrillar chitin. Of the other lectins only Con A clearly labeled the symbiosome. On the contrary, the lectin binding properties of the slime produced by free livingNostoc-colonies indicate the presence of mannose, fucose, GalNAc, sialic acid, and galactose, while chitin or GlucNAc-oligomers could not be detected. The symbiosome was also investigated electron microscopically. WGA-gold binding confirmed the presence of chitin, while a slight PATAg reaction indicated some polysaccharidic molecules within the SS. Our results show that the amorphous material within the SS contains molecules typical of the fungal cell wall and suggest that the SM is related to the fungal plasma membrane. The applied lectins all bind to the hyphal surface, indicating a high molecular complexity. Mannosyl, -galactosyl, and sialic acid residues are strongly exposed at the outer cell wall layer, whereas GlucNAc, GalNAc, and -galactosyl residues seem to be present in smaller amounts. The symbiotic interface established between the fungus andNostoc inGeosiphon shows many similarities to that occurring between fungi and root cells in arbuscular mycorrhizas.Abbreviations AM arbuscular mycorrhiza - BS-I-B₄ Bandeiraea simplicifolia lectin I isolectin B₄ - CLSM confocal laser scanning microscopy - Con A Concanavalin A - EBL elderberry bark lectin I - FITC fluorescein isothiocyanate - HPA Helix pomatia agglutinin - PATAg periodic acid-thiocarbohydrazide-Ag proteinate - SM symbiosome membrane - SS symbiosome space - RCA-120 Ricinus communis agglutinin 120 - UEA-I Ulex europaeus agglutinin I - WGA wheat germ agglutinin Dedicated to Professor Dr. Peter Sitte at the occasion of his 65th birthday     

A lamellated striated layer in the spore wall of the smut fungus Entorrhiza (Ustilaginales)

Summary The spore wall in the smut fungus Entorrhiza has been investigated, with particular reference to layer 3. The wall is stratified into four layers, numbered 1–4 from the outside to inside of the wall. Layer 3 has a lamellated or striated organization, depending on the type of specimen preparation used for examination. In this study, thin sectioning and freeze-etching methods were used in transmission electron microscopy. Layer 3 is approximately 50 nm thick and is the narrowest layer of the wall. Thin sections viewed at high magnification show a lamellated organization, consisting of alternate electron dense and translucent spaces. Usually between 16–20 lamellae form the layer, with a lamella having a thickness of about 1–2 nm. At high resolution, each electron dense lamella is resolved as a row of closely packed subunits, approximately 1.5 nm in diameter. The electron translucent lamellae probably represent mainly lipoidal material, which is extracted during specimen preparation. In freeze-etch preparations layer 3 is termed the striated layer. Fracturing exposes face views of the layer, which at low magnification has a wrinkled appearance. At high magnification, layer 3 has a structure consisting of an irregular mosaic of striations. The striations in each area of the mosaic are arranged parallel, and regularly spaced 11–13 nm apart. Each area of the mosaic is separated from an adjacent area by a small step; this represents where the plane of fracture changed to a different level within layer 3. Fracturing probably occurs in the lipoidal region of the layer, corresponding to the electron translucent lamellae seen in thin section. At high magnification, the striations are resolved into subunit-like particles, approximately 1–2 nm in diameter. Layer 3 is believed to form an impervious region in the spore wall. Layer 3 in Entorrhiza closely resembles the partition layer reported in spores of other Tilletiaceae. This demonstration of a common wall layer strengthens the relationship between Entorrhiza and the rest of the Tilletiaceae. Entorrhiza is the only smut that forms galls on host roots.     

Megaspore development in Selaginella. I. “Wicks”, their presence,ultrastructure, and presumed function

Summary Structures have been found in the locular space between the tapetal cells and megaspores in Selaginella argentea and S. kraussiana that enter the megaspore wall and extend to the plasma membrane of the megaspore cytoplasm. We have called these structures wicks. Unless special fixation procedures are used wicks are either very poorly preserved or not apparent. Wicks appear to be routes for the transport of materials from the tapetum to developing megaspores. The entry of the wicks into the megaspore wall and their passage throughout the wall implies that the megaspore wall of Selaginella is a three-dimensional mesh-work of inter-connecting spaces. Wicks have several macromolecular-sized subunits, and the results of our histochemical reactions indicated the presence of glycoprotein and/or mucopolysaccharide. X-ray microanalysis of the S. convoluta exospore showed that silicon is present in rod-shaped structures between units of the exospore in mature megaspores. Because of the size and form of the structures between the exospore units we consider that they are remnants of wicks stabilized by silicon.Present address:Cátedra de Palinologia, Museo de La Plata, Paseo del Bosque s/nro., 1900 La Plata, Argentina.     

Studies on fish scale formation and resorption

Summary Electron microscopic investigation of scales of the goldfish Carassius auratus revealed that the lamellae of fibrillary plates contain sheet-like structures composed of vertically oriented collagen fibers embedded in an organic matrix. The fibers (TC fibers) are smaller in diameter (35–45 nm) than those of the lamellae and the matrix is stained intensely with lead citrate.The sheet-like structures as well as the lamellae are formed by fibroblasts located beneath the lamellae. The orientation of the collagen fibers of the sheets and the lamellae seems to be controlled by the orientation of the ridges and invaginations of the surface of the fibroblasts.The fibrillary plate of C. auratus was found to be partially calcified. Calcification was initiated by the deposition of needle-like or flaky crystals of hydroxyapatite in the organic matrix of the sheet-like structure and proceeded into the TC fibers and the matrix region of the lamellae. The potassium pyroantimonate-osmium tetroxide method showed a heavy concentration of calcium in the osteoblasts, fibroblasts, and in the matrix regions of the fibrillary plate. Calcium-containing precipitates were also present in the hole zone of the collagen fibers in the lamellae, but the significance of this location in calcification remains to be elucidated.Contribution No. 285, Belle W. Baruch Institute for Marine Biology and Coastal Research, University of South Carolina, Columbia, South Carolina, 29208, USA     

Transmural exocytosis in maize root cap

Summary The maize root cap is a tissue known for its high production of a fucose-rich slime. At the cellular periphery, two kinds of components exist which are indistinguishable: the cell wall barrier and the slime which passes through. Two complementary probes were used, both at the light and the electron microscope level, in order to distinguish the different components. The lectinUlex europaeus agglutinin I was used as a probe targetting the slime and the enzyme cellulose 1,4--D-glucan cellobiohydrolase I was used to probe the cellulose framework. Both probes were used either alone or sequentially for double labeling. The cytochemical PATAg test was optionally used with the enzyme-gold complex labeling. After several technical improvements (multistep method, increase in accessibility), UeA I was used to follow the exocytic pathway of the slime from the Golgi apparatus to the exterior of the cell. The results indicate the occurrence of at least two populations of Golgi apparatus vesicles, and one is directly engaged in the transport of the fucoserich slime. The slime accumulated in pockets between the plasmamembrane and the outer tangential cell wall. The CBH I-gold complex showed the existence and the maintenance of a thin but continuous cellulosic layer, even when the cells slough. The double labeling showed the fucose-rich compounds within the cell wall. Data emphasize the role of the cell wall as a filtering barrier and a mechanical protection in the course of differentiation.Abbreviations CBH I EC 3.2.1.91, cellulose 1,4--D-glucan cellobiohydrolase I - CMC carboxymethyl cellulose - CPB citrate phosphate buffer - FITC fluorescein isothiocyanate - IC internal cell - PA-TAg periodic acid-thiocarbohydrazide-silver proteinate - PBS phosphate buffered saline - PC cell with accumulation pockets - PEG polyethyleneglycol - SC sloughed cell - UeA I Ulex europaeus agglutinin I - VI UeA I-labelled Golgi-derived vesicles - V2 UeA I-unlabelled Golgi-derived vesicles     

Ultrastructural aspects of cell wall synthesis inSpirogyra

Summary Filaments ofSpirogyra were fixed in 2% osmium tetroxide dehydrated in alcohol and embedded in Araldite. The fine structure of cells with regard to wall synthesis was studied. The cell wall was shown to have four layers. The inner one contains microfibrils and is considered to be the cell wall proper. The outer three layers are components of the slime layer. The innermost of these, the second layer of the wall, was shown to be between 1m to 3m and the third 0.3m to 1m. The fourth layer appears as no more than a dark black line measuring 10 nm across. In the cytoplasm two types of vesicles were seen. The largest of these has contents similar in appearance to the slime layer of the wall. This same material was also seen in the large vesicles attached to the Golgi bodies. It is suggested that the smaller vesicles are derived from the larger vesicles and later fuse with the cell membrane. The Golgi bodies were found to be fairly large measuring up to 5m across. Small electron opaque blobs and flecks on the outside of the plasmalemma and in between the microfibrils of the cell wall proper are considered to be mucilage droplets travelling to the slime layer. It cannot be excluded that some of the material of the large vesicles is released directly into the cytoplasm and is transferred without vesicles through the plasma membrane. The negative contrast appearance of the microfibrils seen in the cell wall is thought to be due to the spaces between them being filled with this electron opaque mucilage.Intercisternal rodlets measuring 2.5 nm across were seen in the Golgi bodies.Transverse microtubules were found to occur near the plasmalemma having the same orientation as some of the microfibrils.Lomasome-like structures sometimes with many 5 nm fibrils in their vicinity were seen.