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.     

Expression of a Bacillus megaterium sporulation-specific gene during sporulation of Bacillus subtilis

The gene for the Bacillus megaterium spore C protein, a sporulation-specific gene, has been transferred into Bacillus subtilis. The B. megaterium gene was expressed little, if at all, during log-phase and early-stationary-phase growth, but was expressed during sporulation with the same kinetics as and at a level similar to that of the analogous B. subtilis genes. This finding is most consistent with the regulation of this class of genes by a mechanism of positive control.     

Fine structure of mesosomal involvement during Bacillus macerans sporulation.

The ultrastructure of endospore formation in Bacillus macerans ATCC 8244 is characterized by the examination of thin sections of cells grown synchronously in a defined medium. For the most part, sporulation in this organism proceeds as described in other Bacillus species. However, unusually extensive mesosomal involvement occurs during the early stages of sporulation, through the completion of engulfment. A large mesosome is associated with spore septum formation and a portion of this mesosome is included in the developing forespore. As engulfment continues, the forespore mesosome moves to the apex of the cell and participates in the completion of the double forespore membrane. This participation is morphologically similar to mesosome involvement in division and spore septation and seems to comprise a second sporal septation process. Based on this study, it is suggested that the mesosome functions to facilitate the "fusion" of membranes thought to occur during cell division and sporulation.     

Comparison of various properties of low-molecular-weight proteins from dormant spores of several Bacillus species.

Several properties of the major proteins degraded during germination of spores of Bacillus cereus, Bacillus megaterium, and Bacillus subtilis have been compared. All of the proteins had low molecular weights (6,000 to 13,000) and lacked cysteine, cystine, and tryptophan. The proteins could be subdivided into two groups: group I (B. megaterium A and C proteins, B. cereus A protein, and B. subtilis alpha and beta proteins) and group II (B. cereus and B. megaterium B proteins and B. subtilis gamma protein). Species in group II had lower levels of (or lacked) the amino acids isoleucine, leucine, methionine, and proline. Similarly, proteins in each group were more closely related immunologically. However, antisera against a B. megaterium group I protein cross-reacted more strongly with the B. megaterium group II protein than with group I proteins from other spore species, whereas antisera against the B. megaterium group II protein cross-reacted most strongly with B. megaterium group I proteins. Analysis of the primary sequences at the amino termini and in the regions of the B. cereus and B. subtilis proteins cleaved by the B. megaterium spore protease revealed that the B. cereus A protein was most similar to the B. megaterium A and C proteins, and the B. cereus B protein and the B. subtilis gamma protein were most similar to the B. megaterium B protein. However, amino terminal sequences within one group of proteins varied considerably, whereas the spore protease cleavage sites were more highly conserved.     

Proteolytic processing of the protease which initiates degradation of small, acid-soluble proteins during germination of Bacillus subtilis spores.

Degradation of small, acid-soluble spore proteins during germination of Bacillus subtilis spores is initiated by a sequence-specific protease called GPR. Western blot (immunoblot) analysis of either Bacillus megaterium or B. subtilis GPR expressed in B. subtilis showed that GPR is synthesized at about the third hour of sporulation in a precursor form and is processed to an approximately 2- to 5-kDa-smaller species 2 to 3 h later, at or slightly before the time of accumulation of dipicolinic acid by the forespore. This was found with both normal levels of expression of B. subtilis and B. megaterium GPR in B. subtilis, as well as when either protein was overexpressed up to 100-fold. The sporulation-specific processing of GPR was blocked in all spoIII, -IV, and -V mutants tested (none of which accumulated dipicolinic acid), but not in a spoVI mutant which accumulated dipicolinic acid. The amino-terminal sequences of the B. megaterium and B. subtilis GPR initially synthesized in sporulation were identical to those predicted from the coding genes' sequences. However, the processed form generated in sporulation lacked 15 (B. megaterium) or 16 (B. subtilis) amino-terminal residues. The amino acid sequence surrounding this proteolytic cleavage site was very homologous to the consensus sequence recognized and cleaved by GPR in its small, acid-soluble spore protein substrates. This observation, plus the efficient processing of overproduced GPR during sporulation, suggests that the GPR precursor may autoproteolyze itself during sporulation. During spore germination, the GPR from either species expressed in B. subtilis was further processed by removal of one additional amino-terminal amino acid (leucine), generating the mature protease which acts during spore germination.     

Effect of Low Temperature on the Growth and Fine Structure of Bacillus subtilis

Logarithmically growing cultures of Bacillus subtilis transferred from 37 to 15 C present atypical growth curves, and ultrathin sections of such cells reveal structural modifications involving mesosome deterioration and double cell wall formation. After a time, optical density and viable count increase, and cells regain the appearance typical of control cells, indicating a recovery from thermal stress. Subcultures of such recovered cells continue to grow well at 15 C. Cultures transferred from 37 to 12 C show atypical growth and fine structure, although no recovery from this stress is seen. Cultures previously grown at 15 C continue to grow at 12 C, and, furthermore, do not show the ultrastructural alterations seen in similar cells with a 37 C thermal history. The results of these studies suggest that low temperatures induce structural modifications in B. subtilis, that the response of a population to thermal stress may change during the period of the stress, and that thermal history may influence the response of a population to thermal stress.     

Gene dosage effect on the expression of the delta-endotoxin genes of Bacillus thuringiensis subsp. kurstaki in Bacillus subtilis and Bacillus megaterium

Significant differences in expression of the delta-endotoxin genes cryA1 and cryA2 of Bacillus thuringiensis subsp. kurstaki were observed in B. subtilis and B. megaterium. The cryA1 gene was expressed when present on a high-copy-number (hcn) vector in B. megaterium but not in B. subtilis. The cryA2 gene was expressed in both hosts, but at a higher level in B. megaterium. Expression of the cryA2 gene in B. megaterium was better from a hcn vector than from a low copy number vector. Inhibition of sporulation was observed when the toxin genes were present on hcn plasmids in B. subtilis while no such effect was evident in B. megaterium. In addition, there was a significant reduction in copy numbers in both B. subtilis and B. megaterium when delta-endotoxin genes or a spoVG promoter-containing fragment of DNA were cloned into hcn plasmids.     

Construction of self-disruptive Bacillus megaterium in response to substrate exhaustion for polyhydroxybutyrate production

In order to establish a novel recovery system for polyhydroxyalkanoates, a self-disruptive strain of Bacillus megaterium that responds to substrate exhaustion was constructed. A gene cassette carrying the lysis system of Bacillus amyloliquefaciens phage - holin and endolysin - was inserted into the Escherichia coli- Bacillus subtilis shuttle vector pX under the control of a xylose-inducible expression system, xylR-xylA '. In this system, the expression of a target gene is induced by xylose but inhibited by glucose, which acts as an anti-inducer. B. megaterium was transformed with pX conveying the phage lysis system, which was integrated into the amyE locus of chromosomal DNA of B. megaterium by homologous recombination. The lysis system caused self-disruption of the transformant cells effectively even when expression of the lysis genes was induced during stationary phase. For the production of polyhydroxybutyrate (PHB), the transformant was grown in a medium containing glucose as a substrate in the presence of xylose. When the glucose concentration approached zero, self-disruption was spontaneously induced, releasing intracellularly accumulated PHB into the culture broth. This system realizes timely cell disruption immediately after the PHB content in the cell reaches a maximum level.     

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.     

Acid-soluble spore proteins of Bacillus subtilis

Acid-soluble spore proteins (ASSPs) comprise about 5% of the total protein of mature spores of different Bacillus subtilis strains. They consist of three abundant species, alpha, beta, and gamma, four less abundant species, and several minor species, alpha, beta, and gamma make up about 18, 18 and 36%, respectively, of the total ASSPs of strain 168, have molecular weights of 5,900, 5,9000, and 11,000, respectively, and resemble the major (A, C, and B) components of Bacillus megaterium ASSPs in several respects, including sensitivity to a specific B. megaterium spore endopeptidase. However, they have pI's of 6.58, 6.67, and 7.96, all lower than those of any of the B. megaterium ASSPs. Although strains varied in the proportions of different ASSPs, to overall patterns seen on gel electrophoresis are constant. ASSPs are located interior to the cortex, presumably in the spore cytoplasm, and are synthesized during sporulation and degraded during germination.     

Electron microscopic studies on protoplast release from I.C.A.-1.65 line (I.F.C.-1.65 line) of Bacillus subtilis cells.

Under lysozyme action a minicell-forming line (I.C.A.-1.65) of B. subtilis releases protoplasts. The main cytologic events which proceed protoplast releasing are described. Different areas of the cell wall prove a remarkable difference in their sensitivity to enzymatic lysozyme action. Central areas of the cell wall are most sensitive and the polar areas are most resistant. Mesosomal vesicles and tubules are extruded and released together with other cytoplasmic extrusion during the protoplasting process. The cell wall of minicells does not prove resistance particularities to lysozyme action. The minicells release protoplasts.     

Morphological Alterations in Bacillus megaterium as Produced by Aflatoxin B1

Morphologically abnormal cells were produced by Bacillus megaterium NRRL B-1368 in response to aflatoxin B(1). Filamentous forms were characterized by early granulation and unusually large and numerous deposits of poly-beta-hydroxybutyric acid within the cells. Pantoyl lactone was without effect as a reversing agent for the observed inhibition of cell septum formation. B. megaterium cells and spores produced on toxic (3.8 mug of aflatoxin B(1) per ml) and nontoxic Trypticase Soy Broth and Trypticase Soy Agar (TSA) were observed by using phase contrast and electron microscopy. Transfer of aberrant forms to nontoxic TSA yielded macrocolonies with daughter cells morphologically indistinguishable from untreated cells. Agar slide cultures of filamentous cells transferred to nontoxic TSA indicated that normal cells were formed. Electron photomicrographs showed a decreased number of mesosomes in filamentous cells as compared to control cells. There were no observable morphological differences in spores formed on toxic or nontoxic TSA.     

Nuclear and cell division in Bacillus subtilis: cell development from spore germination.

The changes in the morphology of the nucleoids and the mesosomes in Bacillus subtilis cells during synchronous outgrowth after spore germination were followed in large-scale three-dimensional cell reconstructions. Shortly after outgrowth of the cell begins in Spizizen medium with glucose, the mesosome becomes an elongated structure in close contact with a rounded nucleoid. When nuclear replication reaches full activity, the mesosome develops into a single, complicated versatile system, with tubules that traverse the cytoplasm and have elaborations in and near the nucleoplasm. Later the system may retract to form large rounded mesosomes; the tubules and strings of vesicles within these mesosomes probably have been collected from the cytoplasm. Shortly after the first cell division, both sister cells have two nucleoids, but with longer generation times induced by growth in media containing acetate instead of glucose; these sister cells have only one nucleoid each. In acetate-grown cells rounded nucleoids that have no contact with a mesosome may represent nucleoids in a temporary stage of rest. On the other hand, the nucleoids of cells growing in glucose-containing medium are always penetrated by mesosomal material, superficially or deeply. Since the mesosome appears capable of traversing the nuclear fibrils, and even reaching the last strands connecting the dividing nucleoids, it is suggested that this organelle may play a vital role in the Bacillus division cycle.     

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.     

Expression of Bacillus megaterium and Bacillus subtilis small acid-soluble spore protein genes during stationary-phase growth of asporogenous B. subtilis mutants

The small acid-soluble spore proteins alpha and beta were not detected during stationary-phase growth of asporogenous Bacillus subtilis mutants blocked in stages 0, II, or III, but mutants blocked in stages IV or V accumulated nearly wild-type levels of these small acid-soluble spore proteins. Similar results were obtained when production of Bacillus megaterium C protein (also a small acid-soluble spore protein), as well as alpha and beta, were monitored in these mutants containing a recombinant plasmid carrying the B. megaterium C protein gene. The only exception was a spo0H mutant which synthesized a small amount of C protein, but no alpha or beta.     

Isolation of recombination-defective and UV-sensitive mutants of Bacillus megaterium.

Mutants of Bacillus megaterium QMB1551 sensitive to mitomycin C or methyl methanesulfonate were isolated and characterized phenotypically. Cell survival after UV-light and gamma-ray exposure was determined, as was transductional recombination. Of the mutants tested, three were sensitive to UV but remained recombination proficient. The UV-sensitive mutants were also reduced in host cell reactivation. At least three mutants had undetectable transduction frequencies, i.e., less than 0.3 to 1.3% of the parental strain frequencies, and so appear to be recombination deficient. Sensitivities of these mutant strains to UV light and gamma radiation were compared with those of parental B. megaterium as well as parental, recE4, recA1, uvrA19, and uvrB109 strains of Bacillus subtilis. In each case, the strains of B. megaterium, including the parental strains, showed a higher percentage of cell survival than B. subtilis.     

Efficient cloning in Bacillus megaterium: comparison to Bacillus subtilis and Escherichia coli cloning hosts

Quantitative cloning efficiencies for B. megaterium, B. subtilis , and E. coli were compared. Transformation of B. megaterium is less efficient than transformation of B. subtilis or E. coli . The frequency of recombinant clones was equal in E. coli and B. megaterium ; both somewhat higher than in B. subtilis . Equivalent average insert sizes were found in B. megaterium and E. coli clones, but significantly smaller inserts were obtained in B. subtilis clones. Clones obtained and propagated in B. megaterium were structurally stable when grown under plasmid selection.     

Fracture mechanics modeling of popping event during daughter cell separation

Most bacteria cells divide by binary fission which is part of a bacteria cell cycle and requires tight regulations and precise coordination. Fast separation of Staphylococcus Aureus (S. Aureus) daughter cells, named as popping event, has been observed in recent experiments. The popping event was proposed to be driven by mechanical crack propagation in the peripheral ring which connected two daughter cells before their separation. It has also been shown that after the fast separation, a small portion of the peripheral ring was left as a hinge. In the article, we develop a fracture mechanics model for the crack growth in the peripheral ring during S. Aureus daughter cell separation. In particular, using finite element analysis, we calculate the energy release rate associated with the crack growth in the peripheral ring, when daughter cells are inflated by a uniform turgor pressure inside. Our results show that with a fixed inflation of daughter cells, the energy release rate depends on the crack length non-monotonically. The energy release rate reaches a maximum value for a crack of an intermediate length. The non-monotonic relationship between the energy release rate and crack length clearly indicates that the crack propagation in the peripheral ring can be unstable. The computed energy release rate as a function of crack length can also be used to explain the existence of a small portion of peripheral ring remained as hinge after the popping event.