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.     

Nuclear and cell division in Bacillus subtilis Antibiotic-induced morphological changes

Incubation of Bacillus subtilis after outgrowth from spores in the presence of four different antibiotics in two different concentrations, showed that septation can occur without termination of nuclear division. Septation is then only partially uncoupled from the normal division cycle. Observations on location and development of mesosomes in the presence of the antibiotics, made in three-dimensional cell reconstructions, suggest that the mesosome plays a role in the normal coordination between nuclear and cell division, and may explain the partial independence between these two processes in B. subtilis.with technical assistance of Catherine J. SchaapThis work has been presented in part at the A.S.M. Conference on Bacilli: Biochemical Genetics, Physiology and Industrial Applications; 6–9 Aug, 1975, Ithaca, N.Y.     

Fine Structure of Bacillus megaterium During Synchronous Growth

A fine-structure study of synchronously dividing Bacillus megaterium revealed the sequence of events involved in the division of the cell. First, a mesosome develops as a concentric fold of the plasma membrane at the site of septum formation. The mesosome contains membrane-bound vesicular structures, 300 to 500 A in diameter, plus a large membrane-bound structure, 2,000 A in diameter. These larger vesicles are peculiar to mesosomes in this stage of division and are not observed in the mesosomes involved in spore septum formation. The transverse septum originates within the mesosome and remains enclosed during its subsequent growth across the cell. An intimate association is observed between mesosome vesicles, mesosome membrane, and the growing edge of the transverse septum. Prior to completion of the septum, the membranes bounding the mesosome fuse, and further wall thickening occurs within the structure formed by this fusion. At this time, the septum only equals the parent cell wall in thickness. The doubling in thickness of the septum, which is required for the production of two normal daughter cell walls, occurs during a second phase of wall thickening, which is characterized by the appearance of a constriction at the base of the septum. As the constriction widens, the wall in this region thickens, forming the typical rounded poles of the daughter cells. Capsular synthesis at the poles occurs during this second phase of wall thickening. Throughout the division process, the nuclear material appears to be associated at one end with a mesosome at or near the pole of the cell and at the other end to the mesosome involved in septum formation. This association frequently takes the form of a stalklike extension of the mesosome penetrating into the chromatin fibrils.     

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.     

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.     

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.     

Phosphorylation of D-glucose in Escherichia coli mutants defective in glucosephosphotransferase, mannosephosphotransferase, and glucokinase.

The morphology of nucleoids and mesosomes of Bacillus subtilis in stationary-and lag-phase cultures was studied by making three-dimensional cell reconstructions in plastic of electron micrographs of serial sections. In cells from stationary cultures, the dormant nucleoids are frequently, but not always, spherical and the mesosomes are small and compact. It is suggested that the spherical nucleoids represent the resting stage in which replication and segregation have been completed. In cells from lag-phase cultures, the compact mesosomes develop into an elaborate system of tubes and wider sacs which become wrapped around the elongating nucleoids and invade the nucleoplasm in preparation for division.     

Electron Microscope and Autoradiographic Study of Ultrastructural Aspects of Competence and Deoxyribonucleic Acid Absorption in Bacillus subtilis: Localization of Uptake and of Transport of Transforming Deoxyribonucleic Acid in Competent Cells

With the aid of serial-section electron microscopy two types of mesosomes can be distinguished in cells of competent cultures of Bacillus subtilis: (i) mesosomes connected to the plasma membrane only (plasma membrane mesosomes) and (ii) mesosomes which extend from the plasma membrane into the nuclear bodies (nuclear mesosomes). Contrary to plasma membrane mesosomes, nuclear mesosomes are absent from the tip zones. Electron microscopic autoradiography of sections of Bacillus subtilis cells exposed to [(3)H]thymidine-labeled transforming deoxyribonucleic acid (DNA) for a short period of time shows that the DNA becomes associated with mesosomes. As a function of time the DNA migrates towards the nucleoids. Transport of DNA is completed within 15 to 60 min after termination of DNA uptake. During its migration the DNA continues to be associated with mesosomes, presumably with nuclear mesosomes. DNA initially associated with plasma membrane mesosomes of the tip zones is probably transported first towards the middle zones peripherally and from there towards the nucleoids.     

Variations in chloroplast nucleoid number during the cell cycle in the algaScenedesmus quadricauda grown under different light conditions

Summary Synchronous cultures of the green algaScenedesmus quadricauda were grown at different mean irradiances (ranging from 15 Wm^–2 to 130Wm^–2). At each irradiance, the algae were exposed to illumination regimes which differed in light duration and dark intervals (222 to 240 hours). The cells from these cultures were sampled during their cycles, stained with DAPI and the number of nuclei and chloroplast nucleoids estimated.The nucleoids divided semisynchronously in steps which represented doublings in their number. For each doubling a constant amount of light energy (defined as the product of irradiance and light duration) had to be converted by the cells to become committed to this division. The times to the start of the nucleoid divisions were therefore inversely proportional to the irradiances applied and the final number of nucleoids was proportional to the light duration.Temporal relationships between nuclear and nucleoid divisions were also light dependent. Shortage of light energy caused delay in nucleoid division. The cell division rate was higher than the rate of nucleoid division and consequently, the cells tended to decrease their nucleoid number with decreasing irradiance. With increasing irradiance the start of nucleoid division was gradually shifted toward the beginning of the cell cycle. The rate of nucleoid division exceeded the rate of nuclear and cellular division, thus with increasing irradiance cells with increasing numbers of nucleoids were formed.Abbreviations DAPI 46-diamidino-2-phenylindole - pt-DNA chloroplast DNA     

Gelatin-induced Reversion of Protoplasts of Bacillus subtilis to the Bacillary Form: Electron-microscopic and Physical Study

Protoplasts of Bacillus subtilis plated on SD medium form L colonies in quantitative yield and propagate in the L form indefinitely. L bodies or protoplasts placed in 25% gelatin medium form bacillary colonies. Details of the reversion of naked bodies to the walled form are reported. In 25% gelatin medium, reversion begins earlier (about 50% reversion in 4 hr) than the multiplication of bacilli. Thus, virtually all the observed bacillary forms are themselves revertants and not the offspring of a few growing clones. The optimal temperature for reversion is 26 C in 25% gelatin. When cells reverting at 26 C are warmed to 40 C for 3 min, reversion is delayed markedly, whereas viability is unaffected. For electron microscopy, a dense protoplast inoculum was placed on a gelatin surface, incubated, and then fixed in situ. There was no multiplication, but crowding delayed reversion markedly. Successive events of reversion are as follows. The loose nucleoid of the protoplasts condenses in response to the gelatin medium and condenses further and further as reversion proceeds. A thin coat of wall develops around the bodies of various sizes and shapes and then increases uniformly in thickness until a wall of normal aspect is formed. Rod-shaped cells grow out from these bodies-sometimes in several directions at once. A few mesosomes begin to appear only after a thin coat of wall has been formed. These are dense, atypical structures compartmented by membranes. They are located at the cell periphery and do not seem to be in contact with the nucleoids. Quantitative estimates showed that only 20 to 25% of revertant cells or cells grown on gelatin contain even a single mesosome. The others have no mesosome at all. Mesosomes thus do not appear to play a significant role in reversion, and normal mesosome functions must presumably be performed elsewhere in the cell in gelatin-grown bacilli. The role of cell wall, its synthesis, and its chemical nature in successive steps in reversion are discussed.     

Nucleoid-independent identification of cell division sites in Escherichia coli

The mechanism used by Escherichia coli to determine the correct site for cell division is unknown. In this report, we have attempted to distinguish between a model in which septal position is determined by the position of the nucleoids and a model in which septal position is predetermined by a mechanism that does not involve nucleoid position. To do this, filaments with extended nucleoid-free regions adjacent to the cell poles were produced by simultaneous inactivation of cell division and DNA replication. The positions of septa that formed within the nucleoid-free zones after division was allowed to resume were then analyzed. The results showed that septa were formed at a uniform distance from cell poles when division was restored, with no relation to the distance from the nearest nucleoid. In some cells, septa were formed directly over nucleoids. These results are inconsistent with models that invoke nucleoid positioning as the mechanism for determining the site of division site formation.     

Division of chloroplast nucleoids and replication of chloroplast DNA during the cell cycle ofDunaliella salina grown under blue and red light

Summary Synchronous cultures of the algaDunaliella salina were grown in blue or red light. The relationships between replication of chloroplast DNA, cell size, cell age and the number of chloroplast nucleoids were studied. The replication of chloroplast DNA and the division of chloroplast nucleoids occurred in two separate periods of the chloroplast cycle. DNA replication was concomitant with that in the nucleocytoplasmic compartment but nucleoid division occurred several hours earlier than nuclear division. Red-light-grown cells were bigger and grew more rapidly than those grown in blue light. In newly formed daughter cells, the chloroplast nucleoids were small and spherical and they were localized around the pyrenoid. During the cell cycle they spread to other parts of the chloroplast. The number of DNA molecules per nucleoid doubled during DNA replication in the first third of the cell cycle but decreased several hours later when the nucleoids divided. Their number was fairly constant independent of the different light quality. Cells grown in red light replicated their chl-DNA and divided their nucleoids before those grown in blue light and their daughter cells possessed about 25 nucleoids as opposed to 15.Abbreviations DAPI 4,6-diamidino-2-phenylindole - chl-DNA chloroplast DNA - PAR photosynthetically active radiation     

Analysis of nucleoid morphology during germination and outgrowth of spores of Bacillus species

After a few minutes of germination, nucleoids in the great majority of spores of Bacillus subtilis and Bacillus megaterium were ring shaped. The major spore DNA binding proteins, the alpha/beta-type small, acid-soluble proteins (SASP), colocalized to these nucleoid rings early in spore germination, as did the B. megaterium homolog of the major B. subtilis chromosomal protein HBsu. The percentage of ring-shaped nucleoids was decreased in germinated spores with lower levels of alpha/beta-type SASP. As spore outgrowth proceeded, the ring-shaped nucleoids disappeared and the nucleoid became more compact. This change took place after degradation of most of the spores' pool of major alpha/beta-type SASP and was delayed when alpha/beta-type SASP degradation was delayed. Later in spore outgrowth, the shape of the nucleoid reverted to the diffuse lobular shape seen in growing cells.     

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.     

Electron Microscope and Autoradiographic Study of Ultrastructural Aspects of Competence and Deoxyribonucleic Acid Absorption in Bacillus subtilis: Ultrastructure of Competent and Noncompetent Cells and Cellular Changes During Development of Competence

By means of electron microscope autoradiography of component cultures of Bacillus subtilis exposed to [(3)H]thymidine-labeled transforming deoxyribonucleic acid competent and noncompetent cells can be distinguished. Competence is not limited to a specific phase of the cell division cycle. With serial section electron microscopy of competent and noncompetent cells, two types of mesosomal structures are observed: mesosomes connected to the plasma membrane only (plasma membrane mesosomes) and mesosomes which are additionally connected to the nuclear bodies (nuclear mesosomes). The two types show different cellular distributions. Especially the number of nuclear mesosomes is higher in competent than in noncompetent cells. This, and the observation that the increase and decrease of competence is correlated with both the number of cells carrying nuclear mesosomes and the number of nuclear mesosomes per cell, suggests that mesosomes are involved in the acquisition of competence.     

Mesosome Structure in Chromobacterium violaceum

Exponentially growing cells of the gram-negative bacterium Chromobacterium violaceum demonstrate invaginations of the cytoplasmic membrane with a high frequency. These invaginations conform to the ultrastructural appearance of mesosomes of gram-positive bacteria. As many as four mesosomes are observed per cell, each of which may increase the total membrane surface of the cell by 30%. Washing of cells in dilute tris(hydroxymethyl)aminomethane buffer effects a distension of the mesosome "neck" and/or cytoplasmic membrane clarifying the association of the mesosome to the cytoplasmic membrane. Plasmolysis effects an eversion of the mesosome into the plasmolysis vacuole.     

Increased cytoplasm viscosity hampers aggregate polar segregation in Escherichia coli

In Escherichia coli, under optimal conditions, protein aggregates associated with cellular aging are excluded from midcell by the nucleoid. We study the functionality of this process under sub‐optimal temperatures from population and time lapse images of individual cells and aggregates and nucleoids within. We show that, as temperature decreases, aggregates become homogeneously distributed and uncorrelated with nucleoid size and location. We present evidence that this is due to increased cytoplasm viscosity, which weakens the anisotropy in aggregate displacements at the nucleoid borders that is responsible for their preference for polar localisation. Next, we show that in plasmolysed cells, which have increased cytoplasm viscosity, aggregates are also not preferentially located at the poles. Finally, we show that the inability of cells with increased viscosity to exclude aggregates from midcell results in enhanced aggregate concentration in between the nucleoids in cells close to dividing. This weakens the asymmetries in aggregate numbers between sister cells of subsequent generations required for rejuvenating cell lineages. We conclude that the process of exclusion of protein aggregates from midcell is not immune to stress conditions affecting the cytoplasm viscosity. The findings contribute to our understanding of E. coli's internal organisation and functioning, and its fragility to stressful conditions.     

Mesosomes associated with hydrogen peroxide in bacteria

Mesosomes are unique membranous structures in bacteria. It is recognized that the mesosomes should be involved in several fundamental processes. The structure and behaviour of mesosomes have been studied and largely identified, while new evidences of mesosome function have been strikingly obtained. Our previous studies confirmed that hydrogen peroxide is involved in mesosomes formation during cell injury and cell division processes. Mesosome formation is always accompanied by excessive H₂O₂ accumulation. Furthermore, our recent data showed that mesosomes could not only enrich the excess H₂O₂, but also bring the H₂O₂ outside of the cells injured by antibiotics. It is a possibility that the enrichment of H₂O₂ in mesosomes might be a mechanism of drug resistance of bacteria. This article describes the bacterial mesosome and its functions as well as the involvement of hydrogen peroxide in mediating these functions.     

Partitioning, Movement, and Positioning of Nucleoids in Mycoplasma capricolum

The nucleoids in Mycoplasma capricolum cells were visualized by phase-combined fluorescence microscopy of DAPI (4', 6-diamidino-2-phenylindole)-stained cells. Most growing cells in a rich medium had one or two nucleoids in a cell, and no anucleate cells were found. The nucleoids were positioned in the center in mononucleoid cells and at one-quarter and three-quarters of the cell length in binucleoid cells. These formations may have the purpose of ensuring delivery of replicated DNA to daughter cells. Internucleoid distances in binucleoid cells correlated with the cell lengths, and the relationship of DNA content to cell length showed that cell length depended on DNA content in binucleoid cells but not in mononucleoid cells. These observations suggest that cell elongation takes place in combination with nucleoid movement. Lipid synthesis was inhibited by transfer of cells to a medium lacking supplementation for lipid synthesis. The transferred cells immediately stopped dividing and elongated while regular spaces were maintained between the nucleoids for 1 h. After 1 h, the cells changed their shapes from rod-like to round, but the proportion of multinucleoid cells increased. Inhibition of protein synthesis by chloramphenicol induced nucleoid condensation and abnormal positioning, although partitioning was not inhibited. These results suggest that nucleoid partitioning does not require lipid or protein synthesis, while regular positioning requires both. When DNA replication was inhibited, the cells formed branches, and the nucleoids were positioned at the branching points. A model for the reproduction process of M. capricolum, including nucleoid migration and cell division, is discussed.     

Transversion of cell polarity from bi- to multipolarity is the mechanism determining multiple spore formation in Anaerobacter polyendosporus PS-1T

The number of spores formed in a single cell of Anaerobacter polyendosporus PS-1^T is significantly influenced by the composition of nutrient media. Depending on carbohydrate concentration in synthetic medium, the number of spores may vary from one or two to as many as five to seven. Investigation of spore formation process by fluorescence and electron microscopy revealed that on media with 0.5–1.0% glucose or galactose most of vegetative cells remained rod-shaped after cessation of cell division in the culture. The nucleoids of these cells were localized at cell poles close to the polar site of the cytoplasmic membrane. Fore-spores were formed at one or both of these poles. A satellite nucleoid (operator) was observed close to each forespore. In the variant with bipolar organization of mother cells, only one or two spores per cell were formed. In the second variant of culture development, when the cells were grown at low galactose concentrations (0.1–0.3%), most of vegetative cells increased in volume and became oval or spherical after cessation of cell division in the culture. Epifluorescence microscopy with nucleic acid-specific fluorochromes (DAPI and acridine orange) revealed the presence of multiple (six to nine) nucleoids in these cells. The nucleoids were located at the cell periphery in close contact with the cytoplasmic membrane. These nucleoids became the centers (poles) for forespore formation. Thus, in the early stationary phase transversion from bipolar to multipolar cells occurred. Cessation of cell division combined with continuing replication of the nucleoids resulted in formation on multinuclear cells. The multiplicity of nucleoides and multipolarity of these cells were prerequisites determining endogenous polysporogenesis, occurring as synchronous formation of three to seven twin spores in many of the oval and spherical cells.