Characterization of cell cycle events during the onset of sporulation in Bacillus subtilis.

To elucidate the process of asymmetric division during sporulation of Bacillus subtilis, we have measured changes in cell cycle parameters during the transition from vegetative growth to sporulation. Because the propensity of B. subtilis to grow in chains of cells precludes the use of automated cell-scanning devices, we have developed a fluorescence microscopic method for analyzing cell cycle parameters in individual cells. From the results obtained, and measurements of DNA replication fork elongation rates and the escape time of sporulation from the inhibition of DNA replication, we have derived a detailed time scale for the early morphological events of sporulation which is mainly consistent with the cell cycle changes expected following nutritional downshift. The previously postulated sensitive stage in the DNA replication cycle, beyond which the cell is unable to sporulate without a new cell cycle, could represent a point in the division cycle at which the starved cell cannot avoid attaining the initiation mass for DNA replication and thus embarking on another round of the cell cycle. The final cell cycle event, formation of the asymmetric spore septum, occurs at about the time in the cell cycle at which the uninduced cell would have divided centrally, in keeping with the view that spore septation is a modified version of vegetative division.     

Requirement for peptidoglycan synthesis during sporulation of Bacillus subtilis.

Cultures of Bacillus subtilis were treated during sporulation with antibiotics (bacitracin and vancomycin) that affect peptidoglycan synthesis. The cells were resistant to the effects of the antibiotics only when the drugs were added about 2 h after the beginning of sporulation. This was about 1 h later than the escape time of a temperature-sensitive sporulation mutant that is unable to complete prespore septation. Similar experiments were done with a mutant temperature sensitive for peptidoglycan synthesis. This showed an escape curve similar to that shown by the antibiotics. When sporulating cells were treated with antibiotics, they produced alkaline phosphatase earlier than normal. Enzyme production was unaffected by inhibition of deoxyribonucleic acid synthesis but was inhibited by chloramphenicol. Sporulation mutants that are unable to make alkaline phosphatase under normal conditions were able to make it in the presence of bacitracin. The alkaline phosphatase made under these conditions was under "sporulation-type" control since its synthesis was repressible by casein hydrolysate and unaffected by inorganic phosphate. When cells were treated with bacitracin in the growth medium as well as in the sporulation medium, alkaline phosphatase synthesis was at the same level as in an untreated control. A number of other antibiotics and surfactants were tested for the ability to cause premature production of the phosphatase of those tested, only taurodeoxycholate whowed this behavior. Moreover, incubation of cells with taurodeoxycholate in the growth medium as well as in the sporulation medium prevented premature enzyme production.     

Motility of Bacillus subtilis during growth and sporulation.

The change of motility and the presence of flagella were followed throughout growth and sporulation in a standard sporulating strain and in 19 cacogenic sporulation mutants of Bacillus subtilis. For the standard strain, the fraction of motile cells decreased during the developmental period to less than 10% at T4. Motility was lost well before the cells lose their flagella. Conditions reducing the decrease of motility also reduced sporulation: motile cells never contained spores. The decrease of motility was not coupled with a decrease in the cellular concentration of adenosine 5'-triphosphate or a decline in oxygen consumption, but an uncoupling agent immediately destroyed motility at any time. Apparently, motility decreased during development because it became increasingly uncoupled from the energy generating systems of the cell. The motility of sporulation mutants decreased after the end of growth at the same time as or earlier than the motility of the standard strain; the early decrease of motility in an aconitase mutant, but not that in an alpha-ketoglurate dehydrogenase mutant, could be avoided by addition of L-glutamate. Sporulation or related events such as extracellular antibiotic or protease production were not needed for the motility decline.     

Cloning of an early sporulation gene in Bacillus subtilis.

A 0.8-megadalton BglII restriction fragment of Bacillus licheniformis cloned into the BglII site of plasmid pBD64 can complement spo0H mutations of Bacillus subtilis. The clone was isolated by selecting for the Spo+ phenotype and antibiotic resistance, using the helper system described by Gryczan et al. (Mol. Gen. Genet. 177:459-467, 1980). The insert is functional in both orientations and thus presumably has its own promoter. A deletion generated within the 0.8-megadalton insert by HindIII restriction and subsequent religation eliminates the ability of the cloned fragment to complement spo0H mutations. The cloned B. licheniformis deoxyribonucleic acid segment specifies the synthesis, in minicells, of a polypeptide of approximately 27,000 daltons. This protein is observed with both orientations, but not when the HindIII deletion is present in the cloned B. licheniformis chromosomal fragment. We have also demonstrated that ribonucleic acid complementary to the cloned B. licheniformis sporulation gene is transcribed in B. licheniformis both during vegetative growth and sporulation.     

Chromosome strand segregation during sporulation in Bacillus subtilis

After the initiation of spore formation in Bacillus subtilis, the products of the final round of DNA replication segregate into two cells, i.e. the prespore and the mother cell. The prespore, which is known to contain a single completed chromosome, develops into a mature endospore which can be readily separated from mother cells and non-sporulating cells on the basis of its resistance properties. We have used a procedure originally developed to label the terminus region of the B. subtilis chromosome to specifically label the newly synthesized strands of DNA during the final round of DNA replication before sporulation. We have purified prespore DNA and used strand-specific probes to measure the radioactivity incorporated. The results show that the sister chromosomes segregate at random into the prespore. This result has implications for the segregation of chromosomes during vegetative growth and for the generation of cellular asymmetry during sporulation.     

Antibiotic-resistant mutants of Bacillus subtilis conditional for sporulation.

Among spontaneously occurring antibiotic-resistant mutants of Bacillus subtilis 168 we have identified a sub-class that is conditionally sporulative. Mutants in this sub-class are resistant to antibiotic during vegetative growth but are sensitive during sporulation. Mutants conditionally-resistant to erythromycin, kanamycin, spectinomycin, and streptomycin have been isolated and characterized by phase contrast microscopy and with respect to their ability to synthesize heat-resistant endospores or the sporulation-associated enzyme alkaline phosphatase. The results suggest that several entirely different genetic lesions may result in this single phenotype. This group includes mutants whose properties suggest that both th 30S and 50S ribosomal subunits may be altered concomitant with early spore specific metabolism. The blockage imposed by antibiotic may be at or near Stage 2 of sporulation.     

Alcohol-resistant sporulation mutants of Bacillus subtilis.

About 80% of Bacillus subtilis cells form spores when grown in nutrient broth. In medium containing various short-chain aliphatic alcohols, the frequency of sporulation was reduced to 0.5%. Mutants sporulated in the presence of alcohols at a frequency of 30 to 40%. Sporulation in the wild-type cells was sensitive to alcohol at the beginning of sporulation (stage zero). Sensitivity to alcohol in the mutants was also at stage zero, even though the sensitivity was considerably reduced. This sensitivity of sporulation to alcohol is the phenotypic expression of a genetic locus designated ssa. Mutations at this locus lead to a decreased sensitivity of sporulation to alcohol without modifying the sensitivity of growth. Genetic analysis by transduction was bacteriophage PBS1 revealed that ssa mutations are near the previously described spo0A locus. ssa mutants also differ from wild-type cells in the composition of membrane phospholipids. The relative amount of phosphatidylglycerol increased, whereas the relative amount of phosphatidylethanolamine and lysylphosphatidylglycerol decreased relative to the proportions in the wild type. The distribution of fatty acids in membrane lipids is the same as in the wild type. No differential sensitivity of phospholipid metabolism to alcohol could be detected in the mutant. This work therefore reveals that the extensive, pleiotropic changes in the membranes of ssa mutants are the phenotypic reflection of alterations at a specific gene locus.     

Extracellular exonuclease as a stage 0 biochemical marker in Bacillus subtilis sporulation.

Calcium-dependent exonuclease activity was produced by sporulating cells of Bacillus subtilis 168. Nuclease activity was released into the culture medium at approximately the same time as sporulation proteases, and production of these enzymes was tied to DNA replication. Results suggest that nuclease production is a function of the spo0H locus.     

Proteins that interact with GTP during sporulation of Bacillus subtilis.

During sporulation of Bacillus subtilis, several proteins were shown to interact with GTP in specific ways. UV light was used to cross-link [alpha-32P]GTP to proteins in cell extracts at different stages of growth. After electrophoresis, 11 bands of radioactivity were found in vegetative cells, 4 more appeared during sporulation, and only 9 remained in mature spores. Based on the labeling pattern with or without UV light to cross-link either [alpha-32P]GTP or [gamma-32P]GTP, 11 bands of radioactivity were apparent guanine nucleotide-binding proteins, and 5 bands appeared to be phosphorylated and/or guanylated. Similar results were found with Bacillus megaterium. Assuming that GTP might be a type of signal for sporulation, it could interact with and regulate proteins by at least three mechanisms.     

Decadent sporulation mutants of Bacillus subtilis.

In decadent sporulation mutants, sporulating populations are heterogeneous: the cells reach successive chemical and physical resistances with progressively decreasing frequencies. Each decadent mutant can be characterized by the shape and slope of the curve describing the frequency of cells resistant to various agents ('the resistance spectrum'). In some mutants the resistance spectrum decreases progressively from xylene resistance to heat resistance; in other mutants it decreases rapidly between octanol resistance and chloroform resistance. Electron microscopy showed that in two mutants the majority of the cells are blocked at stages III and IV; the number of cells that develop further to reach successive morphological stages falls off progressively. In two other mutants most cells reach stage V. Cortexless spores are also frequent. One of the decadent mutations, SpoL1, was localized between aroD and acf. The phenotype of decadent mutants is discussed in terms of sequential gene activation.     

New transfer ribonucleic acid species during sporulation of Bacillus subtilis.

The transfer ribonucleic acid (tRNA) populations from log-phase cells, sporulating cells (stage III), and dormant spores were compared by tRNA-deoxyribonucleic acid hybridization techniques. New tRNA species not found in log-phase cells were observed in stage III cells. Some of the tRNA made during sporulation were also present in dormant spores. Although the role and function of these new tRNA species cannot be ascribed directly to the sporulation process, their presence indicates that new tRNA genes can be transcribed during sporulation and suggests that translational control may be exerted during sporulation by tRNA.     

Structural analysis of Bacillus subtilis spore peptidoglycan during sporulation

A major structural element of bacterial endospores is a peptidoglycan (PG) wall. This wall is produced between the two opposed membranes surrounding the developing forespore and is composed of two layers. The inner layer is the germ cell wall, which appears to have a structure similar to that of the vegetative cell wall and which serves as the initial cell wall following spore germination. The outer layer, the cortex, has a modified structure, is required for maintenance of spore dehydration, and is degraded during spore germination. Theories suggest that the spore PG may also play a mechanical role in the attainment of spore dehydration. Inherent in one of these models is the production of a gradient of cross-linking across the span of the spore PG. We report analyses of the structure of PG found within immature, developing Bacillus subtilis forespores. The germ cell wall PG is synthesized first, followed by the cortex PG. The germ cell wall is relatively highly cross-linked. The degree of PG cross-linking drops rapidly during synthesis of the first layers of cortex PG and then increases two- to eightfold across the span of the outer 70% of the cortex. Analyses of forespore PG synthesis in mutant strains reveal that some strains that lack this gradient of cross-linking are able to achieve normal spore core dehydration. We conclude that spore PG with cross-linking within a broad range is able to maintain, and possibly to participate in, spore core dehydration. Our data indicate that the degree of spore PG cross-linking may have a more direct impact on the rate of spore germination and outgrowth.