Electron Microscopy of Young Candida albicans Chlamydospores

One- to three-day-old cultures of Candida albicans bearing chlamydospores were grown and harvested by a special technique, free of agar, and prepared for ultramicrotomy and electron microscopy. These young chlamydospores exhibited a subcellular structure similar to that of the yeast phase, e.g., cytoplasmic membrane, ribosomes, and mitochondria. Other structural characteristics unique to chlamydospores were a very thick, layered cell wall, the outer layer of which was continuous with the outer layer of the suspensor cell wall and was covered by hair-like projections; membrane bound organelles; and large lipoid inclusions. Only young chlamydospores less than 3 to 4 days old exhibited these ultrastructural characteristics.     

Structure of Micrococcus denitrificans and M. halodenitrificans Revealed by Freeze-etching

S ummary . After freeze-etching, cells of Micrococcus denitrificans and M. halodenitrificans revealed structures similar to those observed in ultrathin sections. Both organisms had a similar cell wall structure. The cell wall was double layered, the smooth surface of which had a delicate granular structure. The cytoplasmic membrane was in 2 parts, both covered with spherical particles 8–12 nm diam. The cytoplasmic membrane possessed rod-shaped invaginations (100–300 × 30–50 nm). The cytoplasm of both species contained inclusions of poly-β-hydroxybutyric acid.     

Ultrastructural studies on the membrane systems and cell inclusions of the filamentous prochlorophyte Prochlorothrix hollandica

The outer membrane of Prochlorothrix hollandica is covered with a network of fine fibrils on its surface and separated from the cytoplasmic membrane by an electrondense peptidoglycan layer (8 to 20 nm thick). The thylakoid membranes are arranged in stacked and unstacked regions which present four characteristic fracture faces with different numbers and sizes of intramembrane particles. Cell inclusions such as polyhedral bodies (carboxysomes), ribosomes, and polyphosphate granules were found in Prochlorothrix hollandica. Another type of cell inclusions was identified by its characteristic shape (a cylindre with conical caps) and a regular striation as gas vesicles. It is concluded that the organism is in its morphological structure similar to the cyanobacteria.Abbreviations C carboxysome - CM cytoplasmic membrane - EF_s, EF_u exoplasmic fracture face of stacked and unstacked membrane area, respectively - ES exoplasmic surface - PF_s, PF_u plasmic fracture face of stacked and unstacked membrane area, respectively - PG peptidoglycan layer - TM thylakoid membrane Dedicated to Prof. Dr. D. Peters, Hamburg, on the occasion of his 75th birthday     

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.     

Ultrastructure of the Membrane System in Lactobacillus plantarum

Electron microscopic study of Lactobacillus plantarum revealed mesosomes in different stages of maturation and structural relation with other cell organelles. Small, immature mesosomes were bounded by a prominent electron-dense layer with another extremely faint layer on the outside. This corresponds to the appearance of the cytoplasmic membrane. Large mature mesosomes were surrounded by a triple-layered unit membrane having electron-opaque layers of approximately equal density, suggesting that the composition of the boundary membrane alters during development of this structure. Three-dimensional observations derived from serial sections indicated that mesosomes always maintain a connection between the cytoplasmic membrane and the comparable layers of their boundary. The cytoplasmic membrane also consisted of a triple-layered unit membrane, the innermost layer of which was less electron-opaque and was usually hidden by the relatively dense background of the cytoplasm. The innermost layer of the cytoplasmic membrane was most clearly seen in plasmolyzed cells. Only mature mesosomes made distinct contacts with, or were partially immersed in, the nucleoplasm. The boundary of such mesosomes frequently seemed to be discontinuous, suggesting that the mesosome interior was in direct contact with the nucleoplasm. Mesosomes involved in cross-wall formation at a division plane increased in size and passed through a sequence of positions which led ultimately to an association with the nucleoplasms of the daughter cells. The inner surface of the cell wall was lined by a thin, electron-dense layer whose composition and function are unknown. Under the cultural conditions used, this organism regularly contained a polyphosphate granule.     

Evidence for an S-layer protein pool in the peptidoglycan of Bacillus stearothermophilus.

Intact cells of Bacillus stearothermophilus PV72 revealed, after conventional thin-sectioning procedures, the typical cell wall profile of S-layer-carrying gram-positive eubacteria consisting of a ca. 10-nm-thick peptidoglycan-containing layer and a ca. 10-nm-thick S layer. Cell wall preparations obtained by breaking the cells and removing the cytoplasmic membrane by treatment with Triton X-100 revealed a triple-layer structure, with an additional S layer on the inner surface of the peptidoglycan. This profile is characteristic for cell wall preparations of many S-layer-carrying gram-positive eubacteria. Among several variants of strain PV72 obtained upon single colony isolation, we investigated the variant PV72 86-I, which does not exhibit an inner S layer on isolated cell walls but instead possesses a profile identical to that observed for intact cells. In the course of a controlled mild autolysis of isolated cell walls, S-layer subunits were released from the peptidoglycan of the variant and assembled into an additional S layer on the inner surface of the walls, leading to a three-layer cell wall profile as observed for cell wall preparations of the parent strain. In comparison to conventionally processed bacteria, freeze-substituted cells of strain PV72 and the variant strain revealed in thin sections a ca. 18-nm-wide electron-dense peptidoglycan-containing layer closely associated with the S layer. The demonstration of a pool of S-layer subunits in such a thin peptidoglycan layer in an amount at least sufficient for generating one coherent lattice on the cell surface indicated that the subunits must have occupied much of the free space in the wall fabric of both the parent strain and the variant. It can even be speculated that the rate of synthesis and translation of the S-layer protein is influenced by the packing density of the S-layer subunits in the periplasm of the cell wall delineated by the outer S layer and the cytoplasmic membrane. Our data indicate that the matrix of the rigid wall layer inhibits the assembly of the S-layer subunits which are in transit to the outside.     

Fine Structure of Strictly Anaerobic,Non-Spore-Forming,Gram-Negative Bacilli

The fine structure of a strain of Bacteroides insolitus has been studied by ultrathin sectioning and electron microscopy. Logarithmically growing cells were fixed both by osmic acid and potassium permanganate, and embedded in Epon. Thin sections were stained with uranyl acetate and examined. The periphery of the cell was composed of a wavy three-layered outer membrane (ca. 80 A), an intermediate layer (50–200 A), and three layered cytoplasmic membrane (ca. 80 A). Single or double bridges which connected the outer membrane with the cytoplasmic membrane were observed. Invagination of the cytoplasmic membrane was observed in no occasion. Independent, distinct, and uniform particles were not the main component of the cytoplasm. The cytoplasm was filled with more or less beaded reticulum-like structures. The nucleoplasm with fine fibrils was mainly dispersed continuously in rather regular cubic masses in an intermediate region between the center and the periphery of the cell. Contacts of the nucleoplasm with the cytoplasmic membrane were occasionally observed.     

PARTICIPATION OF THE CYTOPLASMIC MEMBRANE IN THE GROWTH AND SPORE FORMATION OF BACILLI

A polyester embedding technique was used to study the early stages of spore formation in members of the genus Bacillus in order to investigate further the origin and nature of the initial spore septum and the resulting forespore envelope. Whereas previously, with a methacrylate procedure, this layer had appeared to be continuous with the cell wall, this study reveals it as a double layer of cytoplasmic membrane. Perisporal, membranous organelles connected both to the developing forspore envelope and to the cytoplasmic membrane were encountered in the four species studied. Similar organelles were prominent during growth at the sites of transverse septa formation. These were connected to, or continuous with, the cytoplasmic membrane and often adherent to the chromatin bodies of the dividing bacilli.     

Function of the syndecan-4 cytoplasmic domain in oligomerization and association with α-actinin in turkey muscle satellite cells

Syndecan-4 (S4) is a cell membrane heparan sulfate proteoglycan that plays a role in satellite cell mediated myogenesis. S4 modulates the proliferation of myogenic satellite cells, but the mechanism of how S4 functions during myogenesis is not well understood. In other cell systems, S4 has been shown to form oligomers in the cell membrane and interact through its cytoplasmic domain with the cytoskeletal protein α-actinin. This study addressed if S4 forms oligomers and interacts with α-actinin in muscle. The S4 cytoplasmic domain was found to interact with α-actinin in a phosphatidylinositol-4,5-bisphosphate dependent manner, but did not associate with vinculin. Through confocal microscopy, both S4 and syndecan-4 without the cytoplasmic domain were localized to the cell membrane. Although the cytoplasmic domain was necessary for the interaction with α-actinin, S4 oligomer formation occurred in the absence of the cytoplasmic domain. These data indicated that S4 function in skeletal muscle is mediated through the formation of oligomers and interaction with the cytoskeletal protein α-actinin.     

Electron microscopy of the cell envelope of Ferrobacillus ferrooxidans prepared by freeze-etching and chemical fixation techniques

Remsen, C. C. (Swiss Federation Institute of Technology, Zurich, Switzerland), and D. G. Lundgren. Electron microscopy of the cell envelope of Ferrobacillus ferrooxidans prepared by freeze-etching and chemical fixation techniques. J. Bacteriol. 92:1765-1771. 1966.-A comparison was made of the fine structure of the cell envelope of the gram-negative bacterium Ferrobacillus ferrooxidans when cells were prepared for microscopy by freeze-etching and chemical fixation techniques. Cell envelopes of chemically fixed cells appeared as five separate layers distinguishable by their location and electron density. Frozen-etched cells showed a three-layered complex with each layer measuring approximately 100 A in thickness. The latter technique is considered to be "artifact-free" and, as a technique, yields purely morphological information on the natural state. The three layers revealed by freeze-etching are: the outer layer, a lipoprotein-lipopolysaccharide layer; the middle layer, a layer composed of globular protein attached to fibrillar mucopeptide; and the innermost layer, the cytoplasmic membrane. The latter was covered with 100 to 120 A particles. The relationship of the aforementioned layers to those seen in chemically fixed cells is discussed.     

Immunocytochemical Identification and Localization of Active and Inactive alpha-Amylase and Pullulanase in Cells of Clostridium thermosulfurogenes EM1

Clostridium thermosulfurogenes EM1 formed blebs, i.e., protrusions still in contact with the cytoplasmic membrane, that originated from the cytoplasmic membrane during growth in batch culture and continuous culture. They could be observed squeezed between the cell wall and cytoplasmic membrane in cells with seemingly intact wall layers (surface layer and peptidoglycan layer) as well as in cells with wall layers in different states of degradation caused by phosphate limitation or high dilution rates. Blebs were found to turn into membrane vesicles by constriction in cases when the cell wall was heavily degraded. Bleb and vesicle formation was also observed in the absence of substrates that induce alpha-amylase and pullulanase synthesis. No correlations existed between bleb formation and the presence of active enzyme. Similar blebs could also be observed in a number of other gram-positive bacteria not producing these enzymes, but they were not observed in gram-negative bacteria. For immunoelectron-microscopic localization of alpha-amylase and pullulanase in C. thermosulfurogenes EM1, two different antisera were applied. One was raised against the enzymes isolated from the culture fluid; the other was produced against a peptide synthesized, as a defined epitope, in analogy to the N-terminal amino acid sequence (21 amino acids) of the native extracellular alpha-amylase. By using these antisera, alpha-amylase and pullulanase were localized at the cell periphery in samples taken from continuous culture or batch culture. In samples prepared for electron microscopy by freeze substitution followed by ultrathin sectioning, blebs could be seen, and the immunolabel pinpointing alpha-amylase enzyme particles was seen not only randomly distributed in the cell periphery, but also lining the surface of the cytoplasmic membrane and the blebs. Cells exhibiting high or virtually no enzyme activity were labeled similarly with both antisera. This finding strongly suggests that alpha-amylase and pullulanase may occur in both active and inactive forms, depending on growth conditions.     

Freeze-Etch Study of Pseudomonas aeruginosa: Localization Within the Cell Wall of an Ethylenediaminetetraacetate-Extractable Component

A freeze-etch study of normal cells of Pseudomonas aeruginosa and of cells after incubation with ethylenediaminetetraacetate (EDTA) and tris(hydroxymethyl)aminomethane (Tris) was performed. When cells were freeze-etched without a cryoprotective agent, a smooth outer cell wall layer, which showed a regular array of subunits, and the presence of flagella and pili were observed. These features were not observed in cells freeze-etched after cryoprotection with glycerol. Four fracture surfaces, which resulted from splitting down the center of the outer wall membrane and of the inner cytoplasmic membrane, were revealed in freeze-etched glycerol-protected cells. The murein layer was seen in profile between the outer cell wall membrane and the cytoplasmic membrane. Spherical units and small rods composed of the spherical units were observed in the inner layer of the outer cell wall membrane. These spherical units appeared to be attached to, or embedded in, the inner face of the outer layer of the outer cell wall membrane. These spherical units were removed from cells on exposure to EDTA-Tris, resulting in cells that were osmotically fragile. The spherical units were detected via electron microscopy of negatively stained preparations in the supernatant fluid of cellular suspensions treated with EDTA-Tris. Upon addition of Mg(2+), the spherical units were reaggregated into the inner layer of the outer cell wall membrane and the cells were restored to osmotic stability. The spherical units were shown to consist primarily of protein. These data are thought to represent the first ultrastructural demonstration of reaggregation of cell wall components within a living cell system.     

Ultrastructure of Bacterial Cells Infected with Bacteriophage PM2, a Lipid-containing Bacterial Virus

The cytological pattern of infection of a host pseudomonad with PM2, a lipid-containing bacterial virus, was investigated by electron microscopy. Normal and infected cells frequently contain a myelin figure, which is found in the nucleoid region or at the periphery of the cell. The most striking finding in this investigation was that completed virions are found in the cell adjacent to or in association with the cytoplasmic membrane. This localization is precise; virions are not found elsewhere in infected cells. The completed virions occasionally appear to be attached to the cytoplasmic membrane. The virus contains a darkly staining core surrounded by a tripartite envelope of a thickness of approximately 70 A, which is identical to the thickness of the cytoplasmic membrane. Lysing cells appear to undergo extensive damage of the cytoplasmic membrane prior to rupture of the L layer of the cell wall.     

Die Feinstruktur der Zellwand und Cytoplasmamembran von Clostridium nigrificans,dargestellt mit Hilfe der Gefrierätz- und Ultradünnschnittechnik

Zusammenfassung Der mit Hilfe der Gefrierätztechnik dargestellte Feinbau der Zellwand und Cytoplasmamembran von Clostridium nigrificans wurde mit den Ergebnissen der chemischen Fixation verglichen. Die Zellwand von chemisch fixierten Zellen zeigt einen Aufbau aus drei stark und zwei schwach elektronenstreuenden Schichten, wobei die innerste, der Cytoplasmamembran angrenzende Schicht nicht immer darstellbar ist. Die Cytoplasmamembran hat eine asymmetrische Elementarmembran-Struktur. Mit Hilfe der Gefrierätztechnik konnte die Zellwand in drei Schichten aufgespalten werden: Einer äußeren aus globulären, rechtwinkelig geordneten, etwa 9 nm messenden Partikeln aufgebauten Schicht und zwei darunter liegenden, 15 und 5 nm dicken Schichten. Die Cytoplasmamembran wird in jungen Kulturen vollkommen, in alten teilweise mit 5–15 nm großen Teilchen bedeckt. An Stellen wo die Teilchen abgespalten wurden oder entsprechend locker angeordnet waren, konnte die Oberfläche der Cytoplasmamembran sichtbar gemacht werden. Sie ist sowohl auf der der Zellwand als auch auf der dem Cytoplasma zugekehrten Seite mit systemlos verteilten, scheinbar verschieden tief eingebetteten Teilchen bedeckt.

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The fine structure of the cell wall and cytoplasmic membrane of Clostridium nigrificans demonstrated by means of freeze-etching and chemical fixation techniques

Summary A comparison was made between the results obtained using the freeze-etching technique in demonstrating the fine structure of the cell wall and the cytoplasmic membrane of Clostridium nigrificans with those using the chemical fixation technique. In chemically fixed cells, the cell wall appears to consist of three dense layers separated by two layers of low electron scattering power, whereby it is not always possible to observe that layer immediately bordering on the cytoplasmic membrane. The cytoplasmic membrane has an asymmetrical unit membrane structure. It was possible, to separate the cell wall in three distinct layers using the freeze-etching technique. The outermost is composed of globular, rectangularly arranged particles, approximataly 9 nm in size, the two inner layers are 15 and 5 nm wide respectively. The cytoplasmic membrane is covered with particles 5 to 15 nm in size, in younger cultures completely, in older cultures partially. On those places where the particles have been split off or where they are loosly arranged, it was possible to observe the surface of the cytoplasmic membrane. It appears to be covered with unsystematically scattered particles imbedded at different depths, not only on that side turned to the cell wall but also on that facing the cytoplasm.

     

Ultrastructural characteristics of the human synoviocytes

The purpose of this study was to identify, by the scanning electron microscopy, the behaviour of the different cell types in the normal human synovial intima, in order to obtain information useful for interpreting pathological changes in the synovium. Our observations revealed that, in numerous areas of the synovial membrane (adipose or fibrous type), the synoviocytes were dispersed and the intercellular matrix, covered only by the cytoplasmic processes of cells deeply located, was in direct contact with the joint cavity. In the areolar type of the synovium the synoviocytes were more numerous; they tended to concentrate to give the appearance of a continuous tissue; but between the cells very large intercellular spaces were usually present. In this latter membrane type we identified the two main cellular types of the synoviocytes: A and B. B-synoviocytes were the predominant cell type of the synovium. These cells were characterized by long cytoplasmic processes, perpendicularly directed towards the joint cavity. Both the cellular body and the cytoplasmic processes were covered by small blebs and vesicles of various size. The A-synoviocytes were a small minority, rarely dispersed between the B-synoviocytes. They were characterized by numerous membrane infoldings which delimited intracellular canaliculi of various depth. Our ultrastructural observations demonstrated that, in normal conditions, the B-synoviocyte must be considered as a constitutive element which characterized the synovial intima, responsible for the specific structure of the interstitial tissue and for the regulation of the composition of the synovial fluid.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ultrastructural organization of Alicyclobacillus tolerans strain K1T cells

Electron microscopy examinations of thin sections and freeze-fracture replicas revealed the specific ultrastructural features of Alicyclobacillus tolerans strain K1(T). In particular, the cell wall displayed an ultrastructure typical of gram-positive bacteria and consisted of a thin murein layer (50-60 A in thickness); cells exhibited a surface S-layer constituted by large hexagonally packed (p6-symmetry) rod-shaped subunits of 150-160 A in diameter and 200 A in height. In the cytoplasmic membrane, there were intramembrane vesicular structures that sometimes appeared as large leaflets in the central part. The cytoplasm contained numerous vesicular inclusions covered with a monolayered wall, dissimilar to bilamellar lipid membranes. Endospore coats displayed an intricate structure and consisted of three thick layers; the outer layer had an unusual fine structure; the exosporium was also found.     

Analysis of cytoplasmic membrane proteome of Streptococcus pneumoniae by shotgun proteomic approach

In this study, cytoplasmic membrane proteins of S. pneumoniae strain R6 (ATCC BBA-255) were effectively separated from cell wall or extracellular proteins by sodium carbonate precipitation (SCP) and ultracentrifugation. Forty seven proteins were analyzed as cytoplasmic membrane proteins from the 260 proteins identified by the shotgun proteomic method using SDS-PAGE/LC/MS-MS. ABC transporters for metabolites such as metals, oligopeptides, phosphate, sugar, and amino acids, and membrane proteins involved in phosphotransferse systems, were identified as the predominant and abundant, cytoplasmic membrane proteins that would be essential for nutrient uptake, antibiotic resistance and virulence mechanisms. Our result supports that gel-based shotgun proteomics combined with sodium carbonate precipitation and ultracentrifugation is an effective method for analysis of cytoplasmic membrane proteins of S. pneumoniae.     

Ultracytochemical localization of ATP-hydrolysing activity in vegetative cells, spores and isolated cytoplasmic membranes of Bacillus subtilis 168

The localization of ATP-hydrolysing activity in vegetative cells, spores and isolated membranes of Bacillus subtilis 168 was studied by a cytochemical method combined with electron microscopy. The activity was located mainly in the cytoplasmic membrane and the mesosomes, and was also found in the inner layer of the cell wall facing the cytoplasmic membrane. Activity was also detected in the cross-membranes of dividing cells and in spore coats. The product of the reaction was observed either as fine electron-dense granules incorporated into the membranes, or as high-contrast lead precipitates on the surfaces of the membranes.     

The fine structure of Micrococcus cyaneus

Summary Micrococcus cyaneus (strain CCM 856) was studied by electron microscopy of thin sections. The cells exhibit different forms (spherical, flattened and pear-shaped) varying in size from 0.6 to 1.1 m. The cell wall consists of one layer 40 to 60 nm thick, the surface of which is covered with, or expands as, a fuzzy material. The cytoplasmic membrane has an asymmetric triple-layered structure with a thickness varying from 8 to 10 nm, and infolds into the cytoplasm as intracytoplasmic membrane systems with configuration, size and number dependent on the fixation conditions. The shape and arrangement of the cells of M. cyaneus differs from that of other micrococci and therefore its taxonomic status should be re-evaluated.     

Ultrastructure of the cell walls of two closely related clostridia that possess different regular arrays of surface subunits.

Cell walls of Clostridium thermohydrosulfuricum and C. thermosaccharolyticum have a two-layered structure, consisting of a thin, lysozyme-sensitive murein layer and a surface (S) layer composed of hexagonally or tetragonally arranged subunits. The subunits can be removed from the murein layer by treatment of cell wall preparations, are composed of a fragile, pH-sensitive monolayer of macromolecular subunits. In both organisms the first stage of the cell division process involves only the plasma membrane and the murein layer. During the subsequent cell separation, a surplus of S-layer subunits appears at the site of division, and consequently the newly formed cell poles remain completely covered by the s layer throughout the separation process. In autolyzed cells an additional layer of subunits assembles on extended areas of the inside of the mucopeptide layer. These observations indicate that the biological function of the S layer depends on its ability to maintain a complete covering of the cell surface at all stages of cell growth and division.