Fine structures of the capsules of Klebsiella pneumoniae and Escherichia coli K1.

The fine structures of the capsules of Klebsiella pneumoniae and Escherichia coli were determined by the rapid-freezing technique. The capsular layer was seen as a densely packed accumulation of fine fibers. The thickness of the capsule was approximately 160 nm in K. pneumoniae and less than 10 nm in E. coli K1. Two layers were observed in the Klebsiella capsule in which the arrangements of the fibers were different. The inner layer of the capsule was formed by a palisade of thick and dense bundles of the fibers standing at right angles on the surface of the outer membrane. In the outer layer these thick bundles of fibers loosened into fine fibers which spread over the bacterial surface, forming a fine network structure.     

Freeze-fracture studies on Pneumocystis carinii. I. Structural alteration of the pellicle during the development from trophozoite to cyst

Pneumocystis carinii has generally been distinguished in three developmental stages, namely, trophozoite, precyst and cyst. The fine structure of the pellicle--the plasma membrane and the outer layer existing outside this plasma membrane--of each stage was studied by freeze-fracture technique. By this technique, P. carinii was cleaved through the cytoplasm or through the hydrophobic region of the plasma membrane, and the cross-fractured face of the outer layer was revealed on the replicas. The outer layer, which is electron-dense in the thin section, consisted of numerous fine granules about 15 nm in diameter in freeze-fracture images, whereas the electron-lucent middle layer which appeared in the precyst and cyst was less granular. Measurement of the intramembranous particles (IMP) also was carried out. The number of IMP per square micrometer of the plasma membrane of the trophozoite was 1,512 +/- 125 on the P face and 417 +/- 44 on the E face. In the precyst, the IMP density decreased, and 1,037 +/- 56 on the P face and 262 +/- 22 on the E face. In the cyst, it further decreased, nd 875 +/- 59 and 150 +/- 20 respectively. It is generally assumed that the density of IMP is related to the physiological activity of the cell membrane, so that the present results obtained in P. carinii suggest that the trophozoite is the most active stage, and that metabolic activity of the pellicle gradually decreases with the progress of development to the precyst then to the cyst.     

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.     

Cross wall synthesis and the arrangement of the wall polymers in the cell wall of Staphylococcus spp

The growing process and the fine structure of the cross wall of Staphylococcus were investigated by electron microscopy. Examination of the tangentially sectioned cross wall revealed that it was initially synthesized as a thin cell wall layer by an invaginated cytoplasmic membrane. The wall thickness soon increased by additional synthesis of the wall from the cytoplasmic membrane located at the side region of the cross wall. Scanning electron microscopic observation of sodium dodecyl sulfate-treated and mechanically separated cross walls revealed that the outer surface of the cross wall exhibits regular circular structures and the inner surface showed has an irregular surface. This indicates that cell wall materials were arranged in a regular circular manner in the initially synthesized thin layer. It is conceivable that in Staphylococcus spp. two cell wall synthesizing systems are present: wall-elongation synthesis in which wall materials are arranged in a regular circular manner and wall-thickening synthesis in which wall materials are arranged in an irregular manner.     

Ultrastructure of the cell wall of a Synechocystis strain

The ultrastructure of the cell wall of a Synechocystis strain, isolated from the Gulf of Finland, was studied using several electron microscopic techniques. This cyanobacterium has numerous projections which were observed to penetrate the cell wall complex. An additional layer (AL) was associated with the outer membrane. An additional external wall layer (EL) was connected to the outer membrane complex by thin fibers as revealed by ruthenium red staining. A hexagonal arrangement of the subunits in the additional external wall layer with a lattice constant of 15.5 nm was found.     

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.     

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.     

Cellular organization and peritrophic membrane formation in the cardia (Proventriculus) of Drosophila melanogaster

The peritrophic membrane of Drosophila melanogaster consists of four layers, each associated with a specific region of the folded epithelial lining of the cardia. The epithelium is adapted to produce this multilaminar peritrophic membrane by bringing together several regions of foregut and midgut, each characterized by a distinctively differentiated cell type. The very thin, electron-dense inner layer of the peritrophic membrane originates adjacent to the cuticular surface of the stomadeal valve and so appears to require some contribution by the underlying foregut cells. These foregut cells are characterized by dense concentrations of glycogen, extensive arrays of smooth endoplasmic reticulum, and pleated apical plasma membranes. The second and thickest layer of the peritrophic membrane coalesces from amorphous, periodic acid-Schiff-positive material between the microvilli of midgut cells in the neck of the valve. The third layer of the peritrophic membrane is composed of fine electron-dense granules associated with the tall midgut cells of the outer cardia wall. These columnar cells are characterized by cytoplasm filled with extensive rough endoplasmic reticulum and numerous Golgi bodies and by an apical projection filled with secretory vesicles and covered by microvilli. The fourth, outer layer of the peritrophic membrane originates over the brush border of the cuboidal midgut cells, which connect the cardia with the ventriculus.     

THE FINE STRUCTURE OF CHONDROCOCCUS COLUMNARIS : I. Structure and Formation of Mesosomes

Cells of Chondrococcus columnaris were sectioned and examined in the electron microscope after fixation by two different methods. After fixation with osmium tetroxide alone, the surface layers of the cells consisted of a plasma membrane, a dense layer (mucopeptide layer), and an outer unit membrane. The outer membrane appeared distorted and was widely separated from the rest of the cell. The intracytoplasmic membranes (mesosomes) appeared as convoluted tubules packaged up within the cytoplasm by a unit membrane. The unit membrane surrounding the tubules was continuous with the plasma membrane. When the cells were fixed with glutaraldehyde prior to fixation with osmium tetroxide, the outer membrane was not distorted and separated from the rest of the cell, structural elements (peripheral fibrils) were seen situated between the outer membrane and dense layer, and the mesosomes appeared as highly organized structures produced by the invagination and proliferation of the plasma membrane. The mesosomes were made up of a series of compound membranes bounded by unit membranes. The compound membranes were formed by the union of two unit membranes along their cytoplasmic surfaces.     

Location of the Fracture Faces Within the Cell Envelope of Acinetobacter Species Strain MJT/F5/5

The cell wall of the gram-negative bacterium Acinetobacter species strain MJT/F5/5 shows in thin section an external “additional” layer, an outer membrane, an intermediate layer, and a dense layer. Negatively stained preparations showed that the additional layer is composed of hexagonally arranged subunits. In glycerol-treated preparations, freeze-etching revealed that the cell walls consist of four layers, with the main plane of fracture between layers cw 2 and cw 3. The surface of [Formula: see text] 2 consisted of densely packed particles, whereas [Formula: see text] 3 appeared to be fibrillar. In cell envelopes treated with lysozyme by various methods, the removal of the dense layer has detached the outer membrane and additional layer from the underlying layers, as shown in thin sections. When freeze-etched in the absence of glycerol, these detached outer membranes with additional layers fractured to reveal both the faces [Formula: see text] 2 and [Formula: see text] 3 with their characteristic surface structures, and, in addition, both the external and internal etched surfaces were revealed. This experiment provided conclusive evidence that the main fracture plane in the cell wall lies within the interior of the outer membrane. This and other evidence showed that the corresponding layers in thin sections and freeze-etched preparations are: the additional layer, cw 1; the outer membrane, cw (2 + 3); and the intermediate and dense layers together from cw 4. Because of similarities in structure between this Acinetobacter and other gram-negative bacteria, it seemed probable that the interior of the outer membrane is the plane most liable to fracture in the cell walls of most gram-negative bacteria.     

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 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.     

Synthesis and turnover of the regularly arranged surface protein of Acinetobacter sp. relative to the other components of the cell envelope.

The formation of the components of the cell envelope of Acinetobacter sp. 199A was investigated by measuring the incorporation of [3H]leucine into protein, [14C]galactose into lipopolysaccharide, 32P into phospholipid, and [3H]diaminopimelic acid into peptidoglycan. Whereas the lipopolysaccharide and intrinsic protein of the outer membrane were stable, some of the regularly arranged surface protein, the alpha-protein, was lost into the growth medium. Only newly synthesized alpha-protein was lost. The peptidoglycan of the murein layer was also labile. Selective inhibition of the formation of individual components of the cell envelope with penicillin, chloramphenicol, and bacitracin showed that incorporation of protein into the outer membrane required the simultaneous formation of complete lipopolysaccharide. The converse was not true: protein synthesis was not required for lipopolysaccharide incorporation. Formation of the outer membrane and the murein layer proceeded independently.     

The fine structure of Chromatium buderi

Summary The fine structure of the phototrophic sulfur bacterium Chromatium buderi was studied in ultrathin sections and freeze-etch preparations.In addition to an intracytoplasmic membrane system common to all species of the Chromatiaceae, C. buderi contained extended lamellar membrane structures possibly due to too high light intensities during growth. The cell wall of C. buderi was found to be covered by a honeycomb-like outer layer consisting of macromolecular wine-glass shaped subunits 60–80 nm by 60 nm in size. This outer cell wall layer appears to be a typical property of the large cell Chromatium species.Contribution No. 3008 of the Woods Hole Oceanographic Institution.     

Fine Structure of Thermus aquaticus, an Extreme Thermophile

Electron microscopic studies using thin sections revealed that Thermus aquaticus has a structure similar to that of most other gram-negative bacteria. The cell envelope is tripartite: plasma membrane, thin middle layer, and a thicker and irregular outer layer. The outer layer appears to be joined to the plasma membrane by a series of connections and, when seen in tangential section, the outer layer appears as a series of parallel bands. The cell division mechanism resembles that of typical gram-negative bacteria. Large spherical bodies designated “rotund bodies” are formed as a result of the association of a number of separate cells. In this association the outer envelope layers of the cells fuse and pull away from the middle layer. The rotund body thus appears as a series of rods, usually lying in parallel around the periphery of the sphere, completely connected by means of the fused outer layer.     

Structure of the cell envelope of Halobacterium halobium

The structure of the isolated cell envelope of Halobacterium halobium is studied by X-ray diffraction, electron microscopy, and biochemical analysis. The envelope consists of the cell membrane and two layers of protein outside. The outer layer of protein shows a regular arrangement of the protein or glycoprotein particles and is therefore identified as the cell wall. Just outside the cell membrane is a 20 A-thick layer of protein. It is a third structure in the envelope, the function of which may be distinct from that of the cell membrane and the cell wall. This inner layer of protein is separated from the outer protein layer by a 65 A-wide space which has an electron density very close to that of the suspending medium, and which can be etched after freeze-fracture. The space is tentatively identified as the periplasmic space. At NaCl concentrations below 2.0 M, both protein layers of the envelope disintegrate. Gel filtration and analytical ultracentrifugation of the soluble components from the two protein layers reveal two major bands of protein with apparent mol wt of approximately 16,000 and 21,000. At the same time, the cell membrane stays essentially intact as long as the Mg++ concentration is kept at treater than or equal to 20 mM. The cell membrane breaks into small fragments when treated with 0.1 M NaCl and EDTA, or with distilled water, and some soluble proteins, including flavins and cytochromes, are released. The cell membrane apparently has an asymmetric core of the lipid bilayer.     

S-layer protein transport across the cell wall of Corynebacterium glutamicum: in vivo kinetics and energy requirements

Corynebacteria are Gram-positive bacteria with a very peculiar cell envelope structure as it is constituted of an inner membrane and an outer membrane-like structure. Protein secretion in Corynebacterium glutamicum was studied in vivo, using the S-layer protein PS2 as a model. We show that different variants of PS2 protein are exported through the whole cell envelope with a half-life ranging between 2 and 4 min, by a two-step mechanism. The first step, which is over after about 1.5 min, is ATP- and proton motive force-dependent and may correspond to translocation across the inner membrane via the 'Sec' machinery. The second step, across the cell wall and the outer mycolate layer, is rapid but independent of energy sources. This very efficient secretion process across the mycolate layer raises the question of the existence in this layer of a specific machinery.     

Studies on the deoxyribonucleic acid-bearing portion of the cell envelope of Escherichia coli.

The envelope components of nuclear bodies which were obtained from Escherichia coli W7 by a mild lysis method were investigated. By using 2,6-diaminopimelic acid (DAP) as precursor which is incorporated only into peptidoglycan in this strain it was found that the particles contained about 14% of the murein layer of the cell. The percentage of phosphatidylethanolamine was enriched at the cost of the other phospholipids in the nuclear bodies compared to whole cells. If lipids were labelled with 3H-palmitic acid the cytoplasmic and the outer membrane could be found after isopycnic centrifugation; however, when the cells were incubated with chloramphenicol, only the outer membrane was seen. The peptidoglycan and the proteins could be assigned only to the outer membrane. The DNA is also bound to the outer membrane. From these results it was concluded that (1) in all lysis methods the cytoplasmic membrane is more easily dissolved than the outer layers of the envelope, and (2) that there is a firm binding between DNA and the outer membrane in vivo.     

Nature of the regions involved in the insertion of newly synthesized protein into the outer membrane of Escherichia coli

Outer membrane proteins are synthesized by cytoplasmic membrane-bound polysomes, and inserted at insertion sites which cover about 10% of the total outer membrane when cells grow with a generation time of 1 h. A membrane fraction enriched in outer membrane insertion regions was isolated and partly characterized. The rate at which newly inserted proteins are transferred from such insertion regions into the rest of the outer membrane was found to be very fast; the new protein content of insertion regions and that of the remaining outer membrane equilibrate completely within about 20 s at 25°C.Given the rather rigid structure of the outer membrane and the multiple interactions between outer membane components and the murein layer, lateral diffusion of newly inserted proteins from insertion sites to the remaining outer membrane is not likely to explain this rapid equilibration. Instead, the data support a model in which mobile insertion regions move along the cell surface, leaving behind stationary, newly inserted outer membrane proteins.     

Fine structure of the cell envelope layers of Flexibacter polymorphus.

Electron microscopy of the filamentous gliding marine bacterium Flexibacter polymorphus demonstrated that the cell envelope consists of an electron-dense intermediate layer located between two unit-type membranes: an outer membrane, presumably of lipopolysaccharide, and an inner cytoplasmic membrane. Separation of living filaments into single cells by lysozyme suggests that a peptidoglycan moiety, possibly corresponding to the intermediate layer, might be situated between the two membranes. Cell division proceeds by invagination of the cytoplasmic membrane and intermediate layer forming a transverse septum. Cells generally fail to separate after the division process, so that a common outer membrane encloses all of the cells in a single filament. There is a continuous layer of macromolecular cup-shaped elements ('goblets') attached to the outermost surface of the lipopolysaccharide membrane. Tangential thin sections, as well as negatively stained preparations of envelope fragments (produced by sonication of autolyzed cells), showed that the goblets are arranged in a close-packed hexagonal array. The presence of electron-dense structures located between the outer and inner membranes, and exhibiting the same periodicity as the goblets, suggests that some part of the goblets penetrates the outer membrane and extends across the periplasmic space to the dense intermediate layer or cytoplasmic membrane. Spontaneous autolysis in aging cultures is accompanied by the formation and release into the culture medium of large numbers of outer membrane vesicles coated with globlets. A tentative reconstruction of the envelope of F. polymorphus, based on the fine-structural data, is presented.