An electron microscopic investigation of the surface coat of the electrocyte of Electrophorus electricus

Summary The surface coat of the electrocyte of the main electric organ of Electrophorus electricus was studied using cytochemical methods (periodic acid-silver methenamine, periodic acid-chromic acid-silver methenamine, periodic acid-thiosemicarbazide-silver proteinate, Concanavalin A — horseradish peroxidase, ruthenium red, Alcian-blue lanthanum nitrate, colloidal iron hydroxide and cationized ferritin). The surface of the electrocyte presents perpendicularly oriented tubular invaginations of the cell membrane. The fibrous coat 50–100 nm thick, penetrates into the lumen of the invaginations. It is also observed in the synaptic clefts existent in the posterior face of the electrocyte. The coating of the surface membrane gives a positive reaction with all techniques used. Binding of colloidal iron hydroxide particles was observed only in the outer layer of the coat. With the Alcian-blue lanthanum nitrate technique, microtubules were observed in the cytoplasm of the electrocyte.The results indicate that the surface coat of the electrocyte contains mucopolysaccharides, glycoproteins, acid mucopolysaccharides and anionic sites detected at low (colloidal iron hydroxyde) and neutral (cationized ferritin) pH.This work has been supported by Conselho Nacional de Desenvolvimento Cientifico e Tecnológico (CNPq), Conselho de Ensino e Pesquisa da UFRJ (CEPG) and Banco Nacional de Desenvolvimento Econômico     

Electron microscopic observations on pulmonary connective tissue stained by Ruthenium Red

Summary Ultrastructural studies on human lung were performed with special attention to the interstitial acid mucopolysaccharides by Ruthenium Red staining and several enzyme digetion tests withStreptomyces hyaluronidase, chondroitinase ABC, chondroitinase AC, heparinase, trypsin and collagenase.Periodic lateral granules on the major cross bands of collagen fibrils and amorphous coats on them became visible by Ruthenium Red staining. The surface of elastic fibres, associated microfibrils, and some fine fibrils 10–20 nm in diameter were stained. Ruthenium Red also stained the surface of fibroblast and smooth muscle cells, basement membrane and filamentous long segments. In the interstructural space, granular substances 10–80 nm in diameter and fine filaments 3–4 nm thick, which formed a fine reticular network, were clearly observed. They were not visible on the usual thin section. The granular substances were located on the cross points of the fine filaments. They spread continuously and connected with each of the cells and extracellular structures in the pulmonary interstitium. The results of the enzyme digestion tests on the Ruthenium Red-positive material are discussed.     

Some cytochemical studies on the cell surface ofAmphidinium carterae (Dinophyceae)

Summary The surface coat of the dinoflagellateAmphidinium carterae Hulburt was examined by fluorescence and transmission electron microscopy, using various fluorochromes and cationic dyes. The overall results showed cell-surface reactions typical of acid mucopolysaccharides. The cationic dye staining revealed an outer fine fibrillar layer (15–70 nm thick) overlying a dense anionic coat (40–60 nm thick) which appeared to thicken progressively with age. In general, the structure of the amphiesmal vesicles was similar to that previously described by other investigators. However, an acidic mucopolysaccharide layer was observed on the inner surface of these vesicles. Each of these structures is traversed by 1–3 pores and at least 2 types of extrusomes are formed, the spindle trichocysts and the mucocysts. Cell to cell adhesion through the surface coat was frequently observed. Evidence was also obtained for internalization of all the surface-coat markers used.This investigation forms part of a doctoral thesis submitted by the first author to the University of British Columbia, Vancouver, B.C.     

Ultrastructure of freeze-substituted hyphae of the basidiomyceteLaetisaria arvalis

Summary The ultrastructure of freeze-substituted (FS) hyphae ofLaetisaria arvalis is described and compared to that of similar hyphae preserved by conventional chemical fixation (CF). The outline of membrane-bound organelles as well as the plasma membrane was smooth in FS cells. In contrast, hyphae preserved by CF exhibited membrane profiles that were extremely irregular. Centers of presumed Golgi activity were best preserved by FS. Microvesicles, 27–45 nm diameter and hexagonal in transverse section, were observed most readily in FS cells. Filasomes (= microvesicles within a filamentous matrix) were only observed in FS cells. Apical vesicles, 70–120 nm diameter, associated with the centers of Golgi activity and within the Spitzenkörper region exhibited finely granular matrices in FS hyphae, whereas in CF hyphae the contents were coarsely fibrous and less electron-dense. Microvesicles were present at hyphal apices and regions of septa formation. Filasomes were also found at regions of septa formation as well as along lateral hyphal tip cell walls. Microvesicles, but not filasomes, were observed in membrane-bound vesicles (= multivesicular bodies) and in larger vacuoles. Filaments, 5.2–5.4 nm wide, were juxtaposed with centripetally developing septa. Cytoplasmic inclusions, 20–40 m in length, composed of bundles of 6.7–8.0 nm wide filaments were observed in both FS and CF hyphae.     

Structure of multinucleated smooth muscle cells of the ascidian Halocynthia roretzi

Summary Cells isolated from ascidian smooth muscle were about 1.5–2 mm in length. Each contained 20–40 nucle in proportion to cell length. The cytoplasm was characterized by the presence of an enormous quantity of glycogen particles, tubular elements of sarcoplasmic reticulum coupled to the cell membrane, and conspicuous contractile elements. Thick and thin filaments had diameters of about 14–16 nm and 6–7 nm, respectively. The population density of the thick filaments was much higher (mean 270/m² filament area) than in vertebrate smooth muscles. The ratio of thick to thin filaments was about 16. All the thick filaments were surrounded by a single row of 5–9 thin filaments forming a rosette, and cross-bridges with periodicities of 14.5 and 29 nm were found between them. The contractile apparatus consisted of numerous myofibrils which were arranged nearly along the cell axis and were separated from each other by a network of 10-nm filaments. The myofibrils further consisted of many irregularly arranged sarcomerelike structures, each of which was comprised of a small group of thick and thin filaments with attached dense bodies.     

The structure of Gloeobacter violaceus and its phycobilisomes

The fine structure of the atypical cyanobacterium Gloeobacter violaceus has been studied on frozen-etched replicas and compared to that of a typical unicellular strain: Synechocystis 6701. The complementary fracture faces of G. violaceus cytoplasmic membrane contain particles less numerous and more heterogenous in size than either the cytoplasmic membrane or the thylakoid membranes of Synechocystis. The most frequently observed particles of the exoplasmic fracture (EF) face of the G. violaceus cytoplasmic membrane are 11 nm in diameter and occasionally form short alignments. This particle class is similar in appearance to the numerous, aligned EF particles of Synechocystis thylakoid membranes. In replicas of cross-fractured G. violaceus, a layer 50–70 nm thick, composed of rod-like elements, underlies the inner surface of the cytoplasmic membrane. The rods, 12–14 nm in diameter, are oriented perpendicularly to the cytoplasmic membrane and show a 6 nm repeat along their length.Isolated phycobilisomes of G. violaceus appear, after fixation and negative staining, as bundles of 6 parallel rodshaped elements connected to an ill-defined basal structure. The bundles are 40–45 nm wide and 75–90 nm long. The rods are 10–12 nm in width; their length varies between 50 and 70 nm. These rods are morphologically similar to those observed at the periphery of hemidiscoidal phycobilisomes of other cyanobacteria, with a strong repeat at 6 nm intervals and a weaker one at 3 nm intervals along their length.The calculated molar ratio of phycobiliproteins in isolated G. violaceus phycobilisomes corresponds to 1:3.9:2.9 for allophycocyanin, phycocyanin and phycoerythrin respectively. When excited at 500 nm, isolated phycobilisomes exhibit a major fluorescence emission band centered at 663 nm.Abbreviations PBS phycobilisome(s) - PBP phycobiliprotein(s) - AP allophycocyanin - PC phycocyanin - PE phycoerythrin - K–PO₄ buffer KH₂PO₄ titrated with KOH to a given pH     

Structure and invasive behaviour of Plasmodium knowlesi merozoites in vitro.

The structure and invasive behaviour of extracellular erythrocytic merozoites prepared by a cell sieving method have been studied with the electron microscope. Free merozoites contain organelles similar to those described in late schizonts of Plasmodium knowlesi. Their surface is lined by a coat of short filaments. On mixing with fresh red cells, merozoites at first adhere, then cause the red cell surface to invaginate rapidly, often with the formation of narrow membranous channels in the red cell interior. As the merozoite enters the invagination it forms an attachment by its cell coat to the rim of the pit, and finally leaves this coat behind as it is enclosed in a red cell vacuole. Dense, rounded intracellular bodies then move to the merozoite periphery, and apparently rupture to cause further localized invagination of the red cell vacuole. The merozoite finally loses its rhoptries, the pellicle is reduced to a single membrane and the parasite becomes a trophozoite. Invasion is complete by 1 min after adhesion, and the trophozoite is formed by 10 min.     

Morphology and development of rhabdovirus-like particles inCuscuta odorata (Convolvulaceae) simultaneous infected with virus and mycoplasma-like organisms

Summary Electron microscopic examination ofCuscuta odorata, used for transmission trials, revealed mycoplasma-like organisms (MLO) as well as rhabdovirus-like particles, unknown toCuscuta. The virus infection is confined to certain phloem-parenchyma cells and a 1–2 cell thick layer of parenchyma cells with thickened walls surrounding the central cylinder. Virus particles, mostly bacilliform, could be detected mainly in the nucleus but also in the cytoplasm. They reach a length of 350–400 nm and a diameter of approximately 75 nm. Virus assembly takes place exclusively in the nucleus. Virus maturation occurs in membrane bound areas within the nucleus, which have no connection with the perinuclear space. Formation of nucleocapsids is always associated with a nuclear viroplasm. Envelopment of virus particles occurs in these membrane bound areas. Budding into the perinuclear space does not occur. Virus infection leads to degeneration and finally to death of the protoplast.Abbreviations cy cytoplasm - m membrane stacks - mt mitochondria - my mycoplasma-like organisms - nc nucleocapsid - ncp nucleocapsid particles - nf nuclear filaments - np nucleoplasm - nu nucleus - nvp nuclear viroplasm - oc obliterated cells - p plastid - pc passage cells - ph phloem - ps perinuclear space - spc strand of parenchymatous cells - v virus particle - x xylem     

High resolution analysis of the formation of cellulose synthesizing complexes inVaucheria hamata

Summary Ultrastructure and assembly of cellulose terminal synthesizing complexes (terminal complexes, TCs) in the algaVaucheria hamata (Waltz) were investigated by high resolution analytical techniques for freeze-fracture replication.Vaucheria TCs consist of many diagonal rows of subunits located on the inner leaflet of the plasma membrane. Each row contains about 10–18 subunits. The subunits themselves are rectangular, approx. 7×3.5 nm, and each has a single elliptical hole which may be the site of a single glucan chain polymerization. The subunits are connected with extremely small filaments (0.3–0.5 nm). Connections are more extensive in a direction parallel to the subunit rows and less extensive perpendicular to them. Nascent TC subunits are found to be packed within globules (15–20 nm in diameter) which are larger than typical intramembranous particles (IMPS are 10–11 nm in diameter) distributed in the plasma membrane. The subunits in the globule, which may be a zymogenic precursor of the TC, are generally exhibited in the form of doublets. Approximately 6 doublets are connected to a center core with small filaments. The globules are inserted into the plasma membrane together with IMPS by the fusion of cytoplasmic (Golgi derived) vesicles. Two or three globules attach to each other, unfold, and expand to form the first subunit rows of the TC on the inner leaflet of the plasma membrane. More globules attach to the structure and unfold until the nascent TC consists of a few rows of subunits. These rows are arranged almost parallel to each other. Two formation centers of subunits appear at both ends of an elongating TC. New subunits carried by the globules are added at each of these centers to create new rows until the elongating TC structure is completed. On the basis of this study, a model of TC assembly and early initiation of microfibril formation inVaucheria is proposed.Abbreviations IMPS intramembranous particles - MF microfibril - TC terminal complex     

Organization of filaments underneath the plasma membrane of developing chicken skeletal muscle cells in vitro revealed by the freeze-dry and rotary replica method

Summary Cytoskeletal organization and its association with plasma membranes in embryonic chick skeletal muscle cells in vitro was studied by the freeze-drying and rotary-shadowing method of physically ruptured cells. The cytoskeletal filaments underlying the plasma membranes were sparse in myogenic cells at the stage when cells exhibited great lipid fluidity in plasma membranes (fusion competent mononucleated myoblasts and recently fused young myotubes). Myotubes at more advanced stages of development possessed a highly interconnected dense filamentous network just underneath the cell membrane. This subsarcolemmal network was composed predominantly of 8–10 nm filaments; they were identified as actin filaments because of their decoration with myosin subfragment-1. Fine fibrils having a diameter of 3–5 nm were found on the protoplasmic surface of the plasmalemma at both the early and advanced stages of development. They were associated with the subsarcolemmal cytoskeletal filaments. Short 2–5 nm cross-linking filaments were occasionally seen between filaments in the subsarcolemmal network. We conclude that, although the subsarcolemmal cytoskeletal network contains many actin filaments, this domain appears to play some role in preserving the cell shape in the form of the membrane skeleton rather than membrane mobility.     

Electron microscopical observations on the brush border of proximal tubule cells of mammalian kidney

Summary The ultrastructure of the plasma membrane and the core of microvilli of proximal tubule cells has been investigated by electron microscopy using sectioned and negatively stained material. By the technique of negative staining, a particulated coat is disclosed on the outside of the plasma membrane of microvilli of brush borders isolated from rat, rabbit and ox. This coat is composed of 30 to 60 Å particles and is 150 to 300 Å thick and appears to be a distinguishing feature for the luminal plasma membrane (brush border) of proximal tubule cells. The plasma membrane of the basal part of tubule cells is found to be smooth. By thin sectioning, an axial bundle of 50 to 70 Å diameter filaments regularly arranged in an 1+6 configuration, one axially located filament being surrounded by a ring of six, is disclosed. The distance from the ring of filaments to the inner surface of the plasma membrane is 250–300 Å, the diameter of the ring 300 Å and the center-to-center distance between filaments 120 Å. Negative staining also discloses 60 Å filaments in microvilli of isolated brush borders. Broken off, single microvilli (fingerstalls) are observed with thin filaments projecting from their broken ends. Filaments up to 1 in length are seen. At high magnification, the filaments appear beaded and show strong resemblance with actin filaments isolated from skeletal muscle. Based on present evidence, it is postulated that microvilli constituting renal brush borders possess contractile properties, which may play a role in the absorption process operating at the luminal part of the cells.The authors are indebted to Miss Kirsten Sjöberg for skilled technical assistance, and to the Danish State Research Foundation and the Tuborg Foundation for financial support.     

Freeze-fracture observations on the plasma membrane,the cell wall and the cuticle of growing protonemata of Adiantum capillus-veneris L.

Using freeze-fracture electron microscopy we have examined the morphology of the plasma membrane and the cell wall of single-celled protonemal filaments of the fern Adiantum capillus-veneris grown under continuous red light. The surface of the protonemal cell wall is completely covered by a multilayered, lipid-like coat, probably consisting of cuticular waxes. The rhizoid seems to lack this type of coat. The cell walls of the protonemata contain 8-nm thick, randomly oriented fibrils. In rapidly growing protonemata the P-face of the plasma membrane contains both randomly distributed particles and distinct particle rosettes. The rosettes consist of six 8–9-nm-wide particles in a ring-like configaration and have an outer diameter of 24 nm. They closely resemble the particle rosettes seen on the P-face of the plasma membrane of green algae and of higher plants, which recently have been implicated in the synthesis of cellulose fibrils. Within 20 m from the tip of the protonemata, and coinciding with the region of maximal cell-wall growth and expansion and thus cellulose-fibril synthesis, the greatest density of rosettes (20/m²) is observed. Beyond 20 m from the tip this number drops rapidly to near zero at 50 m. The rosettes have a tendency to form small, irregular clusters, but only very rarely are three or more rosettes found in a row or in a geometrical pattern. Our measurements of the size and the density of the randomly distributed plasma membrane particles indicate that the tip region must be specialized with respect to other plasma-membrane activities as well. Thus the tip region contains not only the highest density of randomly destributed intramembrane particles, but also particles of different sizes than those found elsewhere in the plasma membrane.     

Ultrastructure of the synaptic ribbons in photoreceptor cells of Rana catesbeiana revealed by freeze-etching and freeze-substitution

Summary The three-dimensional structure of synaptic ribbons in photoreceptor cells of the frog retina was studied with freeze-etching and freeze-substitution methods, combined with a rapid-freezing technique. Although the synaptic ribbon consisted of two electron-dense plaques bisected by an electron-lucent layer in conventional thin sections, such lamellar nature was not so evident in freeze-etched replicas. The cytoplasmic surfaces of the synaptic ribbon presented an extremely regular arrangements of small particles 4–6 nm in diameter. Fine filaments 8–10 nm in diameter and 30–50 nm in length connected synaptic vesicles and the ribbon surface. These connections were mediated by large particles on both ends of the filaments. Approximately 3–5 filaments attached to one synaptic vesicle. Synaptic ribbons were anchored to a characteristic meshwork underlying the presynaptic membrane via another group of similar fine filaments. The meshwork seemed to be an etched replicated image of the presynaptic archiform density observed in thin sections.     

Electron microscopic analysis of lymphocyte fibrillar elements during the redistribution of surface receptors

Filaments 5 nm thick, located throughout the cytoplasm mainly along the surface, are observed in intact lymphocytes. In the control glycerinized lymphocytes, besides the above filaments aggregations of filaments nearly 3 nm in diameter were found. After the treatment of cells by antimurine serum or ferritin-conjugated concanavalin A, some fibrillar structures are observed mainly in the cap region in the form of filaments 5-6 nm of thickness, radially directed towards the plasma membrane. After glycerinization, three types of filaments are observed being, respectively, near 3, 5-6 and almost 8 nm in diameter. Two latter types of filaments are decorated by S1-myosine fragments which indicates their actine nature. Differences in the character and distribution of myofibrils in the cytoplasm of intact cells and cells with caps may witness in favour of their involvement in the processes associated with redistribution of surface receptors.     

Spatial organization and fine structure of the cortical filament layer in normal locomoting Amoeba proteus

Summary The fine structural organization of a cortical filament layer in normal locomoting Amoeba proteus was demonstrated using improved fixation and embedding techniques. Best results were obtained after application of PIPES-buffered glutaraldehyde in connection with substances known to prevent the depolymerization of F-actin, followed by careful dehydration and freeze-substitution.The filament layer is continuous along the entire surface; it exhibits a varying thickness depending on the cell polarity, measuring several nm in advancing regions and 0.5–1 m in retracting ones. Two different types of filaments are responsible for the construction of the layer: randomly distributed thin (actin) filaments forming an unordered meshwork beneath the plasma membrane, and thick (myosin) filaments mostly restricted to the uroid region in close association with F-actin.The cortical filament layer generates the motive force for amoeboid movement by contraction at posterior cell regions and induces a pressure flow that continues between the uroid with a high hydrostatic pressure and advancing pseudopodia with a low one. The local destabilization of the cell surface as a precondition for the formation of pseudopodia is enabled by the detachment of the cortical filament layer from the plasma membrane. This results in morphological changes by the active separation of peripheral hyaloplasmic and central granuloplasmic regions.     

The formation and development of cellulose-synthesizing linear terminal complexes (TCs) in the plasma membrane of the marine red algaErythrocladia subintegra Rosenv.

Summary The formation and development of linear terminal complexes (TCs), the putative cellulose synthesizing units of the red algaErythrocladia subintegra Rosenv., were investigated by a freeze etching technique using both rotary and unidirectional shadowing. The ribbon-like cellulose fibrils ofE. subintegra are 27.6 ± 0.8 nm wide and only 1–1.5 nm thick. They are synthesized by TCs which are composed of repeating transverse rows formed of four particles, the TC subunits. About 50.4 ± 1.7 subunits constitute a TC. They are apparently more strongly interconnected in transverse than in longitudinal directions. Some TC subunits can be resolved as doublets by Fourier analysis. Large globular particles (globules) seem to function as precursor units in the assembly and maturation of the TCs. They are composed of a central hole (the core) with small subunits forming a peripheral ridge and seem to represent zymogenic precursors. TC assembly is initiated after two or three gobules come into close contact with each other, swell and unfold to a nucleation unit resembling the first 2–3 transverse rows of a TC. Longitudinal elongation of the TC occurs by the unfolding of globules attached to both ends of the TC nucleation unit until the TC is completed. The typical intramembranous particles observed inErythrocladia (unidirectional shadowing) are 9.15 ± 0.13 nm in diameter, whereas those of a TC have an average diameter of 8.77 ± 0.11 nm. During cell wall synthesis membranes of vesicles originating from the Golgi apparatus and which seem to fuse with the plasma membrane contain large globules, 15–22 nm in diameter, as well as tetrads with a particle diameter of about 8 nm. The latter are assumed to be involved in the synthesis of the amorphous extracellular matrix cell wall polysaccharides. The following working model for cellulose fibril assembly inE. subintegra is suggested: (1) the ribbon-like cellulose fibril is synthesized by a single linear TC; (2) the number of glucan chains per microfibril correlates with the number of TC subunits; (3) a single subunit synthesizes 3 glucan chains which appear to stack along the 0.6 nm lattice plane; (4) lateral aggregation of the 3-mer stacks leads to the crystalline microfibril.Dedicated to Prof. Dr. Dr. h.c. Eberhard Schnepf on the occasion of his retirement     

Organization of cytoskeleton during the tentacle contraction and cytostome movement in the dinoflagellate Noctiluca scintillans McCartney

Summary Electron microscopy of Noctiluca scintillans reveals that the cytoskeleton of the tentacle involved in the motor action of the prey capture consists of three characteristic elements: a deformable peripheral fibrillo-granular ectosarc, abundant underlying microtubules organized in several rows on the convex side, and helicoid filaments about 8 nm in diameter organized into striated myonemes. Microtubules of the external row are crossed-linked with each other by fibrous elements 5 nm in diameter and 10–15 nm long, their links with the second row result in a Y-shaped binding. Bonds of the other rows are linked to each other irregularly between those of the same row. Striated myonemes are regularly inserted between the rows of microtubules on the ectosarc and between its pleats, joining together in a knot of disarrayed filaments with multidirectional orientation in the central axis of the tentacle. Striation of myonemes is based on an alternation of thick striae (TS) 40 nm wide with a periodicity of about 200 nm, and of some intermediary fine striae (FS) 10 nm wide. The events during tentacle contraction are: (1) Rotation of the tentacle, bringing the convex side to the inner side of it. Here, large numbers of microtubules have been visualized by optical immunocytochemistry after labelling with Paramecium antitubulin antiserum. (2) Increase of pleat amplitude (200–300 nm to 600 nm) in concomitance with a decrease of its period (500–700 nm to 250 nm). (3) Apparent modification of the microtubule orientation. (4) Transformation of some TS in several FS without modification of the striation periodicity.Near the cytostome, the cytoskeleton consists of a number quantity of microtubules underlying a non-pleated ectosarc and long tracts of contractile myonemes formed by 6-nm helicoid filaments linking the internal side of the cytostome of the supporting rod. Semirelaxed myonemes show an alternation of fine striae (FS) 35 nm wide between two clear areas (CA) with a periodicity of about 300 nm, plus an incipient dark area (DA) lying between them; together they are transformed into a thick stria (TS) during maximal contraction; the striation periodicity thus decreases by one half. These two systems are compared with one another and with other motile systems.     

A new cell wall structure in a symbiotic and a free-living strain of the blue-green alga genus Chroococcidiopsis (Pleurocapsales)

Freeze etching studies in a symbiotic and a freeliving strain of Chroococcidiopsis revealed a specific layer in the outer cell wall not described so far from Cyanophyta. The layer showed a complex organisation: The main unit are ribbons, 2–3 nm thick, striated at right angle to the longitudinal axis. They are interwoven to a patchwork-like leaflet. The ribbons are virtually composed of globular particles associated in parallel rows. The cytoplasmic membrane and the cell walls of the symbiotic and the free-living strain were compared.Abbreviations cm cytoplasmic membrane - CW 1,2,3 cell wall layer 1,2,3 - EF exoplasmic fracture face - PF protoplasmic fracture face     

Fine structure and distribution of contractile layers inAmoeba proteus preincubated at high temperature

Summary Ultrastructural and immunocytochemical studies allow the localization and identification of a microfilament cortex in heat-shockedAmoeba proteus at different stages of recovery to room temperature. Immediately after heating the cortex is in close contact with the cytoplasmic face of the plasma membrane; however, during cooling it detaches from the membrane and shifts toward the cell centre thus separating a region of peripheral hyaloplasm from central granuloplasm. After polymerization of a new submembrane cortex several detachment and reformation cycles rhythmically repeated for 2–3 hours until a multitude of stratified layers has been formed in the hyaloplasm.Electron micrographs reveal that the cortical layer at the plasma membrane is merely composed of a network of actin filaments, whereas the retracted contractile layers in the hyaloplasm and at the granuloplasmic border contain both, thick and thin filaments often arranged in bundles. The heat-shock induced activities of the microfilament cortex are based on the highly contractile properties of this system in conjunction with controlled displacements in the equilibrium between F- and G-actin.     

Cellulose microfibril assembly inErythrocladia subintegra Rosenv.: An ideal system for understanding the relationship between synthesizing complexes (TCs) and microfibril crystallization

Summary The marine red algaErythrocladia subintegra synthesizes cellulose microfibrils as determined by CBH I-gold labelling, X-ray and electron diffraction analyses. The cellulose microfibrils are quite thin, ribbon-like structures, 1–1.5 nm in thickness (constant), and 10–33 nm in width (variable). Several laterally associated minicrystal components contribute to the variation in microfibrillar width. Electron diffraction analysis suggested a uniplanar orientation of the microfibrils with their (101) lattice planes parallel to the plasma membrane surface of the cell. The linear particle arrays bound in the plasma membrane and associated with microfibril impressions recently demonstrated inErythrocladia have been shown in this study to be the cellulose-synthesizing terminal complexes (TCs). The TCs appear to be organized by a repetition of transverse rows consisting of four TC subunits, rather than by four rows of longitudinallyarranged TC subunits. The number of transverse rows varied between 8–26, corresponding with variation in the length of the TCs and the width of the microfibrils. The spacings between the neighboring transverse rows are almost constant being 10.5–11.5 nm. Based on the knowledge thatAcetobacter, Vaucheria, andErythrocladia synthesize similar thin, ribbon-like cellulose microfibrils, the structural characteristics common to the organization of distinctive TCs occurring in these three organisms has been discussed, so that the mode of cellulose microfibril assembly patterns may be deciphered.