The ultrastructural organization of Brucella L forms and revertant cultures

The submicroscopic organization of Brucella cells in the process of L-transformation and reversion has been studied. As revealed in this study, at its initial stages L-transformation is accompanied by the loss of cell-wall peptidoglycan and by considerable polymorphism of Brucella cells. Further stages are characterized by the presence of a great number of closed annular membrane structures both in the cytoplasm and outside the cells. At late stages of L-transformation the destruction of the cytoplasm and the cells has been found to occur. In revertant cultures the restoration of the cell wall has been noted.     

Fine structure of sporulation in Bacillus cereus grown in a chemically defined medium

Ellar, D. J. (Syracuse University, Syracuse, N.Y.), and D. G. Lundgren. Fine structure of sporulation in Bacillus cereus grown in a chemically defined medium. J. Bacteriol. 92:1748-1764. 1966.-A study was made of the fine structure of sporulating cells of Bacillus cereus grown in a chemically defined medium. The developmental stages of sporulation occurred in a fairly synchronous manner and were complete by 14 hr. This time period was shortened when spore wall peptide components were added to the medium, but the addition had no effect upon fine structure except to thicken the cell wall. Sporulation could be separated into six morphological stages which generally agreed with those published for other sporulating bacteria. The initiation of the spore (forespore) septum takes the form of an inward folding of the cytoplasmic membrane toward the pole of the cell. The inward folding forms a characteristic Y-shaped membrane structure enclosing an area within which vesicles are found. These vesicles comprise the perisporal mesosome of the cell. The membranes on opposite sides of the cell progress toward the cell center where they fuse to form the double unit membrane of the spore septum. As the proliferation of the spore septum continues, the vesicular areas move towards the pole. The end result is a double forespore membrane which completely encloses a part of the vegetative cell's chromatin. Sporal mesosomes, as well as membrane vesicles, are involved in the proliferation of the forespore. Vesicles are generally bounded by a single unit membrane, whereas in the sporal mesosomes several unit membranes are arranged concentrically. The latter become associated with the segregation of a portion of the nuclear material into the forespore region of the cell.     

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.     

Variation in the Fine Structure of a Marine Achromobacter and a Marine Pseudomonad Grown Under Selected Nutritional and Temperature Regimes

Certain features of the fine structure of a marine achromobacter and a marine pseudomonad were dependent upon the conditions of growth. Cells of achromobacter grown at 10 C in a low peptone-seawater (SW) medium displayed the characteristic morphology of the achromobacter: a regularly undulant outer element of the cell wall and a planar inner element, tightly packed ribonucleoprotein (RNP) particles in the cytoplasm, deoxyribonucleic acid (DNA) disposed in a lobate manner, and dense inclusion bodies. Few mesosomes, however, were seen. Cells of achromobacter grown at 10 C in a high peptone-SW medium had larger and more highly organized mesosomes. At 22 C, in a low peptone-SW medium, no mesosomes were seen, but the inclusions were more frequently seen and were larger in the achromobacter cells. At 22 C, in a high peptone-SW medium, these cells revealed the greatest variation in cellular morphology. They contained both small and large mesosomes, or no mesosomes, and both small and large inclusions, or no inclusions. Pseudomonad cells at 10 C in a low peptone-SW medium revealed a typical gram-negative morphology: double-layered, irregularly undulant cell wall; more nearly planar cytoplasmic membrane; densely stained, lightly packed RNP particles; finely fibrillar, axially disposed DNA; simple mesosomes. At 10 C, in a high peptone-SW medium, pseudomonad cells revealed associated strands of material and intracytoplasmic ringlike structures. At 22 C, in a low peptone-SW medium, pseudomonad cells had a more undulant cell-wall and a more nearly planar cytoplasmic membrane. At 22 C, in a high peptone-SW medium, these cells revealed prominent blebs of the cell wall.     

Formation and structure of mesosomes in Myxococcus xanthus

Summary Vegetative cells of Myxococcus xanthus, strain FB, were found to contain numerous small mesosomes distributed throughout the cell. They persisted in the cell as long as the cells were maintained on casitone-agar. When these cells were transferred into casitone-broth and grown under aeration large mesosomes were newly formed at the division plane during the first and second cell division after transfer. After four to six more generations when transferred a second time into fresh casitone broth mesosomes were no longer detectable in the cells but reappeared when the cells were retransferred onto casitone-agar.A low oxygen concentration in the medium caused the formation of an unidentified factor found to be responsible for the formation of mesosomes in cells of colonies or in a liquid medium.The shape of the mesosomes seems not to be predetermined but depends upon the inhomogeneity of cytoplasm and nucleoids into which they intrude. In some large mesosomes the infolded membrane consisted of five layers, one dense layer alternating with a translucent one with dense layers limiting the membrane. The width of these membranes was 120 A instead of 160 A as could be expected for two merged triple-layered cytoplasmic membranes each measuring about 80 A. A large poly-phosphate granule was found to be enclosed by a mesosome.     

Morphologic characteristics of the large bodies in cultures of the L-forms of bacteria according to scanning electron microscope studies]

Large bodies appear at the time of protoplast and spheroplast formation and are revealed at all the L-transformation stages and at the initial stage of reversion. They can be represented both by a single giant cell and by a conglomerate of different cells connected with one another. They are not only spheroid, but can be of the most varied shape, and structurally they are connected with other L-colony elements: filamentous structures, spheroid cells, elementary bodies and the so-called acellular material. At the early L-transformation stage the large bodies probably appear as a result of coalescence of lysed cells and represent polygenome formations. Elementary bodies and spheroid cells form within the large bodies and on their surface at the late stage of L-transformation. In case of reversion bacterial cells form from them.     

Ultrastructure of L forms. IV. L forms of nonagglutinating vibrios]

A study was made of the ultrastructure of stable L-forms of Nag vibrios aged 24 hours. Cells of all types of the L-forms had cytoplasmic membranes, and a three-layered structure, which was found not everywhere. Externally of the cytoplasmic membrane, in some areas of the individual cells there were revealed a plastic layer of cell wall and a basal membrane. However, in difference to bacterial forms of the vibryos, rigidity of the cell wall was disturbed, and the links between the cell wall and the cytoplasmic membrane were indetectable. There were regularly revealed lamellar of myelin-like membranous structures in the cytoplasm, which did not occur in bacterial forms, and also lamellar mesosomes. The latter were found in the sites of cell division. Viability of small bodies as the minimal reproductive forms of the L-cultures is confirmed by the presence in them of a nucleoid and of the binary division.     

Mesosomes in Escherichia coli

When Escherichia coli was grown in a synthetic medium and fixed with osmium, sections of the cells revealed clearly defined mesosomes. These mesosomes appeared to develop, in dividing cells, as coiled infoldings of the cytoplasmic membrane. Mature mesosomes formed a link between the cytoplasmic membrane and the nucleus of the cell. The arrangement of the mesosomes in dividing cells led to the hypothesis that division of the nucleus in these cells is accomplished by two separate polar mesosomes. One mesosome is derived from the parent cell and is present at one pole of the daughter cell. The other is freshly synthesized at or near the newly forming pole of the daughter cell. While the old mesosome remains attached to the chromosome received from the parent cell, the newly synthesized mesosome becomes attached to and initiates replication of the new chromosome. As the cell grows and elongates, the two mesosomes, attached to their respective chromosomes move apart, thus effecting nuclear division.     

Effect of chromosomal breaks induced by x-irradiation on the number of mesosomes and the cytoplasmic organization of Streptococcus faecalis

A model which explains mesosome formation via a contraction of the cytoplasm and nucleoid when bacteria are physiologically disturbed was tested by: (1) X-irradiation of unfixed cells of Streptococcus faecalis to produce chromosomal breaks and to remove DNA attached to the cell membrane; (2) subsequent determination of the number of irradiated cells in which mesosomes (using electron microscopy) and central density changes (using phase-contrast microscopy) could be visualized after fixative was added. Results obtained by exposure of cells to doses up to 1100 krads before fixation indicated that: (1) the number of cells with central mesosomes was reduced proportional to the decrease in the molecular weight of the DNA due to double-strand breaks: (2) the number of cells with total (central plus peripheral) mesosomes and the number of cells with peripheral mesosomes were both reduced proportional to the removal of DNA attached to the cell membrane (M band); (3) the nucleoid became more diffusely organized. Exposure of cells to doses greater than 1100 krads before fixation resulted in: (1) an increase in the number of cells with central and peripheral mesosomes (compared to cells exposed to lower dosages); (2) a return to the centralized, dense nucleoid seen in unirradiated cells.These results suggest that mesosomes are formed when localized sites on the cell membrane are pulled from close contact with the cell wall into the cytoplasm by the action of a cross-linking fixative via the aggregation of intracytoplasmic components such as DNA. This model considers the attachment of DNA and/or other cytoplasmic components to the membrane as an intrinsic part of its mechanism. The formation of central and peripheral mesosomes in unirradiated and X-irradiated cells are contrasted.     

N-acetylmuramyl-L-alanine amidase of Bacillus licheniformis and its L-form

A cell wall lytic enzyme has been demonstrated to be a component of the membrane of Bacillus licheniformis NCTC 6346 and an l-form derived from it. The lytic enzyme, characterized as an N-acetylmuramyl-l-alanine amidase, is solubilized from membranes by nonionic detergents. Ionic detergents inactivate the enzyme. In the bacterium the specific activities of amidase and d-alanine carboxypeptidase in mesosomes are approximately 65% of those in membranes. Selective transfer of lytic enzyme from nongrowing L-forms, L-form membranes, and protoplasts to added walls occurred after mixing, and 31 to 77% of the enzyme lost from L-form membranes was recovered on the walls. Membranes isolated from L-forms growing in the presence of added walls contained as little as 13% of the amidase found in membranes of a control culture. These results have been interpreted as showing that in vivo the amidase is "bound" to the surface of the bacterial cell membrane in such a location that it can be readily accessible to the cell wall.     

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

The cell division of a strain of Bacteroides convexus was examined by the ultrathin sectioning and the electron microscopy. The cell division was initiated by the invagination of the cytoplasmic membrane from the opposite sites at the middle of the cell. The constriction of the cell wall also occurred simultaneously or soon after the initiation of the invagination of the cytoplasmic membrane. A short septum structure similar to those of gram positive bacteria originated within the base of mesosome. The two mesosomes arising from the opposite sites fused at the center of the cell. After the tips of invaginating outer membrane reached to the middle between cell center and original outer membrane, the mesosomes were reduced gradually and finally disappeared. In this stage of the cell division, a transverse septum was usually completed. The invagination of the outer membrane proceeded progressively and finally fused at the center of the division plane.     

Bacterial mesosomes: Real structures of artifacts?

The ultrastructural study of membrane organization in gram-positive bacteria related to the OsO₄ fixation conditions revealed that large, complex mesosomes are observed only when the bacteria are subjected to an initial fixation with 0.1% OsO₄ in the culture broth, as in the prefixation step of the Ryter-Kellenberger procedure. Evidence was obtained suggesting that the large mesosomes are produced by this prefixation. The kinetic study of the membrane morphological alterations occurring during the prefixation of Bacillus cereus with 0.1% OsO₄ in the culture broth showed that the amount of mesosome material increases linearly from zero to a maximum observed at 1.7 min of prefixation and that at about this time a maximum is reached for the number of mesosomes per unity of cell area and for the average individual mesosome area. The large mesosomes observed in gram-positives fixed by the complete Ryter-Kellenberger procedure would be the result of the membrane-damaging action of 0.1% OsO₄. Such damaging action was deduced from the observation that 0.1% OsO₄ quickly lyses protoplasts and induces a quick and extensive leakage of intracellular K⁺ from B. cereus and Streptococcus faeculis. In support of that interpretation is the observation that in bacteria subjected to several membrane-damaging treatments, mesosome-like structures are seen after three different fixation procedures. In bacteria initially fixed with 1% OsO₄, 4% OsO₄ or 2.5% glutaraldehyde, no large, complex mesosomes are observed, small and simple invaginations of the cytoplasmic membrane being present. The size of these minute mesosomes is inversely proportional that causes of fixation. Uranyl acetate was found among the studied fixatives the one to the rate the least damage to bacterial membranes. This fixative satisfactorily preserves protoplasts. In bacteria initially fixed with uranyl acetate no mesosomes were found. The results of the present work throw serious doubts on the existence of mesosomes, both large and small, as real structures of bacterial cells. It is proposed that a continuous cytoplasmic membrane without infoldings (mesosomes) would be the real pattern of membrane organization in gram-positives.     

Spores of microorganisms

Spores ofBacillus cereus (strain NCIB 8122) were germinated in a synthetic germination limited medium (GL-medium), which permitted germination but did not make the termination of post-germinative development possible. Incorporation of¹⁴C-diaminopimelic acid into the newly formed cell wall was followed in this culture. Morphological changes were studied by optical and electron microscopy. Germination was associated with the usual germination changes,i.e. depolymerization of the “bulky” cortex, differentiation of nuclear structure and mesosomes and ribosomes in the cytoplasm. At this stage the spore protoplast is surrounded by several layers: exosporium, laminated coat with four layers, residual spore wall and the protoplast membrane. During incubation in this limited medium the residual wall layer thickens and the nuclear structure, mesosomes and ribosomes were not more detectable. After enrichment of the GL medium (shift up) the thick-walled cells can form additional cell wall material, elongate and an atypical septum formation can occur. The cell wall material forms local thickenings. On long-term cultivation in the GL medium some of the cells in the GL medium lyze. If, in the course of 3–6 h the cells are transferred from the GL-medium to a solid complex medium (Difco Nutrient Agar) the thickwalled cells are transformed into dividing cells. When the cells are transferred later, their colony-forming ability rapidly decreases. The decrease of viability of the thick-walled cells derived directly from spores after their germination in the limited medium indicates that these cellular forms probably do not represent more stable cellular types that would be of considerable importance for survival of the populat ion of bacilli.     

Comparative ultrastructure of selected oral streptococci: thin-sectioning and freeze-etching studies.

The ultrastructure of Streptococcus mutans, serotypes a-e, S. sanguis, S. mitis, and S. salivarius HHT, were examined by the techniques of thin-sectioning and freeze-etching. The cell walls varied in width between 15 and 46 nm and were covered with an electron-dense fibrillar or fuzz layer. The cytoplasmic membrane was in close association with numerous mesosomes which were, in turn, either closely associated or in contact with the bacterial chromosome. In freeze-etch replicas, the outermost layer of the cell wall was fibrous, and the cytoplasmic membrane was covered with particles composed of several subunits. Both particle-clusters and particle-free areas occurred on the surfaces of the cytoplasmic membrane, as well as a crystalline array in the ground plasm of the cell.     

THE MEMBRANE SYSTEM OF STREPTOMYCES CINNAMONENSIS

The plasma membrane bounding the cytoplasm immediately inside the hyphal wall of Streptomyces cinnamonensis may not retract from the hyphal wall. When it does retract from the wall, it appears as a single dark line in some sections and as 2 dark lines separated by a light zone in others. The membrane system consists of mesosomes and endomembrane structures. The mesosomes are those membrane structures whose derivatives appear to be the plasma membrane. The endomembrane structures, in the present report, are those that appear to have been derived from either the cytoplasm or the limiting membranes of the pre-existing membrane structures. All membranes seem capable of proliferation, a mechanism obviously responsible for the growth of the individual membrane structures and for the origin of many new ones. The mesosomes, according to their limits, are of 2 distinct types, the open mesosomes and the closed mesosomes. The open mesosomes are partially enclosed by limiting membranes, leaving the unenclosed sides limited by the wall. These mesosomes, when old, usually in aerial hyphae, may become attached to the wall and somewhat deleted from their limiting membranes. The individual membranes in their interior may appear disfigured. The closed mesosomes are completely surrounded by the limiting membranes. These mesosomes, as well as endomembrane structures, retain their original positions in the cytoplasm even in the older aerial hyphae, and the membranes in their interior usually remain practically as distinct in the aerial hyphae as they are in the substratal hyphae. New mesosomes and endomembrane structures are being formed continuously as the mycelium develops. The mesosomes, as a rule, occupy more or less the peripheral regions of the cytoplasm, while the endomembrane structures distribute themselves widely in the cytoplasm and also in the nucleoids. The appearance of the unit membranes, being double-layered (2 dark lines separated by a light line), is not consistent. The membranes as a whole are more resistant to degeneration than the cytoplasm and the nucleoids.     

STRUCTURAL FEATURES OF MESOSOMES (CHONDRIOIDS) OF BACILLUS SUBTILIS AFTER FREEZE-ETCHING

Freeze-etched cells of Bacillus subtilis have been studied with the electron microscope. The outer surface of the plasma membrane, i.e. the side facing the cell wall, is covered with numerous granules and short strands, each measuring approximately 50 A in diameter. These strands are occasionally seen to enter the cell wall. The inner surface of the plasma membrane, i.e. the side facing the cytoplasm, appears to be sparsely dotted with small particles measuring about 50 A. The envelope of mesosomes differs from the plasma membrane. Blunt protrusions arise from its outer surface; the inner surface appears smooth. Stalked particles, as described by other investigators after negative staining with phosphotungstic acid, were not observed on any membrane surface in our material. Preparations were also made of specimens prefixed in osmium tetroxide prior to freeze-etching. Under these conditions the bacterial membranes appeared to be surprisingly well preserved. In contrast to directly frozen, unfixed cells, some osmium tetroxide-fixed preparations showed a differentiation in cytoplasm and nucleoplasm, which made it possible to observe the close association of the mesosome with the latter.     

Bacteria-shaped Gymnoplasts (Protoplasts) of Bacillus subtilis

Addition of glucose to the medium in which Bacillus subtilis was grown lowered the pH and increased the amount of lysylphosphatidylglycerol relative to the phosphatidylglycerol content of the membrane fraction. This change in phospholipid composition was accompanied by changes in the shape and behavior of the gymnoplasts obtained by cell wall removal with lysozyme. These gymnoplasts appeared to retain most of their original cell shape and internal organization, often with preservation of the mesosomes. Cells harvested from neutral growth medium gave the usual spherical gymnoplasts. In a hypotonic medium, the spherical gymnoplasts lysed rapidly, whereas the rod-like gymnoplasts lost only part of their cell content while showing a tendency to preserve the original shape. This type of gymnoplast could not be produced from cells grown in neutral medium by simply raising the magnesium concentration. When this was done the gymnoplasts assumed bizarre shapes; they became compact and susceptible to the tonicity of the medium. Gymnoplasts or protoplasts, produced from bacilli exposed to low pH values, were found not to conform to the formulations on "protoplasts" given in 1958 by 13 authors. Cells exposed to a low environmental pH during growth seemed to possess a more rigid membrane structure than cells grown at neutral pH.     

Bacterial mesosomes: Method dependent artifacts

The occurrence of mesosomes was investigated during septum formation of vegetative and sporulating cells of Bacillus cereus. It has been demonstrated that bacterial mesosomes which are considered by numerous microbiologists as an integrated constituent of Gram positive bacteria, are in reality artifacts arising during the preparation for electron microscopy. The conventional fixation methods allowed enough time for the cytoplasmic membrane to react to the changed conditions and to form the typical pocket-like membrane invaginations. With cryofixation followed by freeze-substitution it was shown in ultrathin sections that mesosomes do not occur. The extremely rapid freezing and the substitution of the ice by an organic solvent containing the fixative prevented the formation of membraneous artifacts.Non-standard abbreviations OsO₄ osmium tetroxide - UO₂Ac uranylacetate - PHB poly--hydroxy-butyric acid - M mesosome - CW cell wall - CM cytoplasmic membrane - PF plasmatic fracture of the cytoplasmic membrane     

Effects of lemongrass oil on the morphological characteristics and peptidoglycan synthesis of Escherichia coli cells

The antibacterial effect of lemongrass oil, obtained from the aerial part of Cymbopogon citratus, on cells of Escherichia coli was investigated by electron microscopy and by measuring cell wall formation. Two strains of E. coli K-12 were used, one of which required diaminopimelic acid in the growth medium for its murein formation. Lemongrass oil was found to elicit morphological changes like filamentation, inhibition of septum formation, spheroplast formation, production of 'blisters', 'bulges' or mesosomes, as well as lysis and development of abnormally shaped cells. The incorporation of radioactively labelled diaminopimelic acid into the cell wall murein of strain W7, was inhibited by lemongrass oil in a dose dependent way. The sequence of changes induced by lemongrass oil on bacterial cell morphology and also its interference with murein synthesis in E. coli cells were interpreted to involve the penicillin binding proteins PBP 2 and PBP 3.     

Relationship between the DNA content and mesosome number in cells of Bacillus.

In cells of Bacillus there is evidence that deoxyribonucleic acid forms an association with some membranous structure within the cell, possibly mesosomes. Cells of varieties of Bacillus cereus and Bacillus subtilis were examined to see if any quantitative relationship existed between the numbers of mesosomes and DNA content. No direct relationship could be domonstrated. However, cells of Bacillus cereus var. alesti A(-) maintained a characteristic and constant DNA content and number of mesosomes regardless of growth conditions. During sporulation, a variant of A(-), termed A(-)3, SEQUESTERS ITS DNA at both ends of the cell, leaving a small amount of DNA but no mesosomes in the center compartment. Since this center compartment is capableof growth and division upon replacement in fresh medium (rejuventation) it was examinedfor mesosome content as DNA synthesis and division were initiated. In most cells, acentral mesosome was formed at the site of cell septum formation; however, the presenceof a mesosome was not an absolute prerequisite for cell division. We propose that atthe onset of cell growth, mesosomes primarily function in the process of cell septum formation. As growth and division proceed, mesosomes are produced in characteristicnumbers and may act as the site of DNA synthesis and (or) segregation.