Genetic Analysis of Pleiotropic Negative Sporulation Mutants in Bacillus subtilis

Genetic studies were undertaken on 14 pleiotropic negative sporulation mutants. These mutants (spoA) which are blocked early in the sporulation process were found to map near the terminus of the Bacillus subtilis chromosome in a region enriched in genes involved in spore formation. Two- and three-factor crosses by transduction and transformation led to the conclusion that the pleiotropic spoA mutations formed a linked cluster. The genetic distance across the cluster calculated from transformation data was compatible with the mutant sites defining a single gene. Suppressor studies revealed that either a nonsense or missense mutation in the spoA locus generated a pleiotropic negative phenotype. It was concluded that the locus codes for a protein, and the absence of this protein is responsible for the pleiotropic phenotype.     

Sporulation of Bacillus subtilis in Continuous Culture

Sporulation of Bacillus subtilis 168 was studied in chemostat cultures. Sporulation occurred at high frequency under limitation of growth by glucose or the nitrogen source in minimal medium, whereas rates of sporulation were low for Mg(2+), phosphate, citrate, or tryptophan limitation. Sporulation was found at all growth rates tested, and the incidence of spores increased with decrease in growth rate of the culture. Within the range of growth rates up to the maximum obtainable with the defined medium, no threshold effect of growth rate on sporulation was observed. By studying transient states, it was possible to determine the time taken for the appearance of a refractile spore after initiation of a cell to sporulation. Under conditions of glucose limitation, cells were found to be committed to sporulation as soon as they were initiated. In nitrogen-limited cultures, however, a partial relief of nitrogen limitation prevented the development of spores during the first hour after initiation. The results of experiments with multistep changes in dilution rate of a chemostat culture indicate that initiation to sporulation is probably restricted to a particular point in the cell division cycle.     

Sporulation in Bacillus subtilis. Morphological changes

1. When Bacillus subtilis was grown in a medium in which sporulation occurred well-defined morphological changes were seen in thin sections of the cells. 2. Over a period of 7.5hr. beginning 2hr. after the initiation of sporulation the following major stages were observed: axial nuclear-filament formation, spore-septum formation, release of the fore-spore within the cell, development of the cortex around the fore-spore, the laying down of the spore coat and the completion of the corrugated spore coat before release of the spore from the mother cell. 3. The appearance of refractile bodies and 2,6-dipicolinic acid and the development of heat-resistance began between 5 and 6.5hr. after initiation of sporulation. 4. The appearance of 2,6-dipicolinic acid and the onset of refractility appeared to coincide with a diminution of electron density in the spore core and cortex. 5. Heat-resistance was associated with the terminal stage, the completion of the spore coat. 6. The spore coat was composed of an inner and an outer layer, each of which consisted of three or four electron-dense laminae. 7. Serial sections through cells at an early stage of sporulation showed that the membranes of each spore septum were always continuous with the membranes of a mesosome, which was itself in close contact with the bacterial or spore nucleoid. 8. These changes were correlated with biochemical events occurring during sporulation.     

Protease Activities During the Course of Sporulation in Bacillus subtilis

Three proteolytic enzymes have been isolated from sporulating cultures of Bacillus subtilis. These activities were, respectively, a protease inhibited by ethylenediaminetetraacetic acid (EDTA) but not phenylmethylsulfonyl fluoride (PMSF), a protease active on both protein and ester substrates, and an ester-active enzyme with low activity on proteins. The latter two enzymes were inhibited by PMSF but not by EDTA. The specific activity of each was determined both intra- and extra-cellularly during growth and sporulation in a single-defined medium. All three enzymes were shown to exhibit a rapid increase in specific activity at a time coinciding with the appearance of refractile bodies in cells.     

Metabolism of Sulfur Compounds in Bacillus subtilis during Sporulation

Metabolism of various sulfur compounds in Bacillus subtilis during growth and sporulation was investigated by use of tracer techniques, in an attempt to clarify the mechanism involved in the formation of cystine rich protein of the spore coat.

Methionine, homocysteine, cystathionine, cysteine and some inorganic sulfur compounds (sulfate, sulfite and thiosulfate) were utilized by this organism as sulfur sources for its growth and sporulation. Biosynthesis of methionine from sulfate during growth was more or less inhibited by the addition of cysteine, homocysteine or cystathionine to the culture.

It is suggested from these results that in Bacillus subtilis methionine is synthesized from sulfate through cysteine, cystathionine and homocysteine as is the case in Salmonella or Neurospora. The results also suggest that the metabolism of sulfur-containing amino acids in Bacillus subtilis is strongly regulated by methionine and homocysteine.     

Sporulation promoting factor in vegetative cells of Bacillus subtilis

A simple experimental system for detection of sporulation promoting factors was presented. This system showed that there was a sporulation promoting factor in the vegetative cells of Bacillus subtilis cultivated on nutrient agar for 9 hr (at stage T0). The factor was partially purified from the sonicate of vegetative cells by ethanol fractionation, gel filtration, chromatography and preparative gel electrophoresis, and it was identified as manganese-containing protein.     

Sporulation in Bacillus subtilis. The role of exoprotease

1. Intracellular turnover of protein was measured in wild-type Bacillus subtilis, which produces exoprotease at stage I in the sporulation process. Protein is degraded at a rate of 8–10%/hr. 2. As a result of this turnover, the proteins of the mother cell are extensively degraded and resynthesized by about 6hr., so that the later stages of spore formation occur in a cytoplasm containing mainly `new' protein. 3. The same protease appears to be responsible both for the intracellular turnover of protein and for extracellular proteolytic activity. In mutants that have lost the exoenzyme the intracellular protein is stable for many hours. In addition, these mutants fail to produce antibiotic and are asporogenous. When the exoprotease is regained as a result of back-mutation all the lost capacities of the cell are restored together. 4. Protease activity also accounts for the change in antigenic pattern of extracts of cells sampled during sporulation. Immunoelectrophoresis shows that, in the wild-type, the antigens characteristic of the vegetative cell have largely disappeared after a few hours; in the proteaseless mutants the vegetative-cell pattern is conserved. Apart from changing the protein pattern of the cell the protease could also have the function of removing protein inhibitors of sporulation. Other possible interpretations of the results are discussed.     

Sporulation and regulation of homoserine dehydrogenase in Bacillus subtilis

Homoserine dehydrogenase in dialyzed cell extracts of Bacillus subtilis 168 was studied, particularly with regard to inhibition, repression, and level of activity as a function of stage of development (growth and sporulation). It was assayed in the "forward direction" using L-aspartic semialdehyde and NADPH as substrates. Of the potentials inhibitors tested, only cysteine and NADP were found to be effective. Both L- and D-cysteine were equally effective. Therefore, the physiological significance of cysteine as an inhibitor is somewhat questionable. Amino acids involved in repression of homoserine dehydrogenase included methionine, isoleucine, possibly threonine, and one or more unidentified components of Casamino acids. The specific activity of homoserine dehydrogenase was highest during the exponential phase of growth and declined steadily during the stationary phase of growth. The low specific activity during late sporulation may favor preferential funnelling of L-aspartic semialdehyde into the lysine pathway, where it is needed for synthesis of large amounts of dipicolinic acid and diaminopimelic acid.     

Selectivity in Protein Degradation during Sporulation of Bacillus subtilis

The breakdown of cellular protein was investigated in Bacillus subtilis labeled with glycine-2-³H or L-phenylalanine-U-¹⁴C at different stages of vegetative growth and sporulation. In cells labeled with l-phenylalanine-U-¹⁴C, multiple protein turnover was observed. However, in cells labeled with glycine-2-³H, the patterns of protein turnover were quite different in the stages of growth and sporulation; proteins which were labeled at the early stationary phase were degraded rapidly, but those labeled at the late sporulation stage were hardly degraded. It was found that glycine incorporated into cells at the late sporulation stage was mainly utilized for biosynthesis of the spore coat protein. These data suggest that the spore coat protein which contains relatively large amounts of glycine is little subject to further degradation.     

Ornithine Decarboxylase Activity during Sporulation of Bacillus subtilis

A simple method for overproduction of a target protein by genetic engineering techniques has been established. This method involves rearranging the target gene, which contains a ribosome binding sequence for expression, in plurally repeated form, and inserting it in a 3′ lower part of promoters.

The chloramphenicol acetyltransferase (CAT) structural gene was used to demonstrate the validity of this method. E. coli harboring a CAT expression plasmid, pUS(CAT)₁, which had one inserted CAT gene, was able to produce CAT at the level of only 4% of the total cellular protein according to densitometric scanning on Coomassie-blue-stained SDS-polyacrylamide gel and had the CAT activity of 3.9 × 10³ units/mg protein. However, E. coli harboring a CAT expression plasmid, pUS(CAT)₄, which had inserted four directly repeated copies of the CAT gene, could synthesize CAT up to 16% of the total cellular protein and had the CAT activity of 2.8 × 10⁴ units/mg protein. This suggests that this method should be useful for overproducing many important peptides or proteins in bacteria.     

Potassium Content During Growth and Sporulation in Bacillus subtilis

Vegetative and sporulating cells of Bacillus subtilis retain a higher level of internal potassium than do nonsporulating stationary-phase cells. The addition of manganese to nonsporulating stationary-phase cells, at concentrations required for sporulation, rapidly stimulates uptake and net accumulation of potassium and induces sporulation.     

Ultrastructural Analysis of Sporulation in a Conditional Serine Protease Mutant of Bacillus subtilis

The morphological characteristics of wild-type Bacillus subtilis and a temperature-sensitive serine protease derivative have been observed during vegetative and sporulation time periods. At 30 C wild-type and mutant cells grow and sporulate identically. At 47.5 C wild-type and mutant cells grow identically, but the mutant cells are blocked at stage 0 or I in the sporulation sequence. Wild-type cells sporulate normally at 47.5 C.     

Overexpression of the PepF Oligopeptidase Inhibits Sporulation Initiation in Bacillus subtilis

The yjbG gene encoding the homologue of the PepF1 and PepF2 oligoendopeptidases of Lactococcus lactis (Monnet et al., J. Biol. Chem. 269:32070-32076, 1994; Nardi et al., J. Bacteriol. 179:4164-4171, 1997) has been identified in Bacillus subtilis as an inhibitor of sporulation initiation when present in the cells on a multicopy plasmid. Genetic analysis suggested that the inhibitory effect is due to hydrolysis of the PhrA peptide in a form as small as the pentapeptide (ARNQT). Inactivation of PhrA results in deregulation of the RapA phosphatase and thus dephosphorylation of the Spo0F approximately P response regulator component of the phosphorelay for sporulation initiation. When overexpressed, the B. subtilis PepF is most likely hydrolyzing additional peptides of the Phr family, as is the case for PhrC involved in control of competence development. Chromosomal inactivation of the yjbG/pepF gene did not give rise to any detectable phenotype. The function of PepF in B. subtilis remains unknown. Limited experiments with a yjbG paralogue called yusX indicated that a frameshift is present, making the corresponding gene product inactive.