Molecular cloning of the spo0B sporulation locus in bacteriophage lambda

The stage 0 sporulation locus spo0B has been mapped by transformation between the pheA and spoIVF loci. Analysis of the behavior of alleles of the spo0B locus in trpE26 merodiploid strains indicates that all of the known alleles of this locus comprise a single complementation group. The spoIVF88 mutation was found to reside in a separate complementation group. The chromosomal region surrounding and including the spo0B locus was cloned in the lambda vector Charon 4A. Extensive restriction endonuclease analyses of the inserts in these phage revealed that an EcoRI fragment of DNA of 2.3 kilobases had transforming activity for spo0B mutations. Examination of the physical and genetic maps of the locus suggested that the entire spo0B locus is contained within this fragment. Subcloning of restriction endonuclease fragments of the lambda inserts and transformation analyses allowed assignment of surrounding genetic loci to specific DNA fragments.     

Altered arrangement of proteins in the spore coat of a germination mutant of Bacillus subtilis

Spores produced by a mutant of Bacillus subtilis were slow to develop their resistance properties during sporulation, and were slower to germinate than were wild-type spores. The coat protein composition of the mutant spores, as analysed by SDS-PAGE, was similar to that of the wild-type spores. However, one of the proteins (mol. wt 12000) which is normally present in the outer-most layers of mature wild-type spores and which is surface-exposed, was assembled abnormally into the coat of the mutant spores and not surface-exposed. The mutation responsible for this phenotype (spo-520) has been mapped between pheA and leuB on the B. subtilis chromosome, and was 47% cotransformable with leuB16. This mutation, and three others closely linked to it, define a new sporulation locus, spoVIB, which is involved in spore coat assembly. The phenotype of the mutant(s) supports the contention that spore germination and resistance properties may be determined by the assembly of the coat.     

Role of the Bacillus subtilis gsiA gene in regulation of early sporulation gene expression.

The Bacillus subtilis gsiA operon was induced rapidly, but transiently, as cells entered the stationary phase in nutrient broth medium. A mutation at the gsiC locus caused sporulation to be defective and expression of gsiA to be elevated and prolonged. The sporulation defect in this strain was apparently due to persistent expression of gsiA, since a gsiA null mutation restored sporulation to wild-type levels. Detailed mapping experiments revealed that the gsiC82 mutation lies within the kinA gene, which encodes the histidine protein kinase member of a two-component regulatory system. Since mutations in this gene caused a substantial blockage in expression of spoIIA, spoIIG, and spoIID genes, it seems that accumulation of a product of the gsiA operon interferes with sporulation by blocking the completion of stage II. It apparently does so by inhibiting or counteracting the activity of KinA.     

Bacteriophage PMB12 conversion of the sporulation defect in RNA polymerase mutants of Bacillus subtilis.

The pseudotemperate phage PMB12 was isolated from soil on the basis of its ability to enhance the rate of sporulation of Bacillus subtilis 168. PMB12 was subsequently shown to convert the sporulation defect in two genetically distinct classes of sporulation mutants. One class includes those rifampin-resistant mutants that are also spore-negative (mutated at the rif locus). The other class includes a strain carrying the sporulation mutation spoCM-1. The spoCM-1 mutation is linked to cysA15 by PBS1 transduction but is distinct from the rif locus. Several other sporulation mutants were not converted by PMB12. PMB12 is related to phage PBS1. However, PBS1 did not convert the above sporulation mutants. The replication of PBS2, a clear-plaquing derivative of PBS1, is rifampin insensitive, apparently due to a phage-induced rifampin-insensitive RNA polymerase. PMB12 replication is also rifampin insensitive.     

Isolation and Characterization of a Temperature-sensitive Sporulation Mutant of Bacillus subtilis

Temperature-sensitive sporulation mutants were isolated spontaneously from Bacillus subtilis 168 TT by a sequential transfer method. A representative mutant strain, ts32, was characterized in detail. The mutant grew normally at 30°C and 42°C, but did not sporulate at 42°C. Electron microscopic observation and physiological analysis showed that the mutant was blocked at stage 0-1 of sporulation. Genetic analysis suggested that the mutation was located at the spo0B locus on the B. subtilis chromosome. Temperature-shift experiments clearly showed that the spo0B gene product functions only at the beginning of sporulation.     

The spoIIN279(ts) mutation affects the FtsA protein of Bacillus subtilis.

The spo-279(ts) mutation, originally thought to be located in the spoIIG operon of Bacillus subtilis, has been mapped in close proximity but outside of the spoIIG locus. This mutation defines a new gene, spoIIN, located midway between the spoIIG and the spoVE loci, and whose product is required for successful completion of the asymmetric septation step. The spoIIN locus was cloned using a combination of 'walking steps' upstream from the spoIIG region and hybridization screening of a bacteriophage lambda library. Sequencing of DNA fragments able to rescue the spoIIN279(ts) mutation revealed that the spoIIN locus is identical with the B subtilis counterpart of the Escherichia coli ftsA gene. After cloning the ftsA region from a strain containing the spoIIN279(ts) mutation we found that this mutation converts the ninth residue of the FtsA protein from serine to asparagine. The spoIIN279(ts) mutation, which is recessive, leads to filamentation during growth at 42 degrees C and causes defective formation of the sporulation septum at this non-permissive temperature. The FtsA protein is therefore required for proper cell septation, both during vegetative growth and sporulation. Possible additional roles of FtsA during sporulation are discussed.     

Use of a lacZ gene fusion to determine the dependence pattern of sporulation operon spoIIA in spo mutants of Bacillus subtilis

A spoIIA::lacZ gene fusion has been used to investigate the dependence pattern of expression of the spoIIA operon during sporulation in Bacillus subtilis. beta-Galactosidase activity, encoded by the hybrid gene, begins to appear about 30 to 60 min after the induction of sporulation. spoIIA expression is dependent upon the products of all of the known spoO loci but on none of the 'later' loci tested. The beta-galactosidase activity falls after 1.5 h in Spo+ cells and in late-blocked mutants, but continued accumulation of the enzyme occurs in certain stage II mutants. Kinetic experiments suggest that the fall in activity may be, in part, the result of regulation at the level of translation. Mutations in several loci, spo0J, spoIIIF and spoVIC, delay expression of the operon by 1-3 h. The significance of these results in terms of models for the control of gene expression during sporulation is discussed.     

Extracellular manganese-stimulated deoxyribonuclease as a marker event in sporulation of Bacillus subtilis.

A considerable amount of Mn2+-stimulated DNAase (deoxyribonuclease) activity is released by Bacillus subtilis 168 during sporulation in a glucose-deficient medium; much smaller amounts are released during starvation for phosphate or nitrogen. Protein synthesis is required. Two forms of evidence are presented that production of the DNAase is associated with events late in stage II of sporulation. 19 Thymidine starvation, which inhibits the biochemical events associated with sporulation, also inhibits release of the DNAase. 2. Several asporogenous mutants blocked at stage II or earlier and unable to produce alkaline phosphatase (a stage-II event) do not produce the enzyme. Mutants blocked towards the end of stage II or later produce both enzymes. During sporulation of the wild-type strain, the DNAase appears about 1 h after alkaline phosphatase. The results suggest that production of the DNAase is controlled by a still-undiscovered stage-II genetic locus.     

spoVIC, a new sporulation locus in Bacillus subtilis affecting spore coats, germination and the rate of sporulation

A mutation near cysB on the Bacillus subtilis chromosome marks a new sporulation locus, spoVIC. It causes spores to germinate more slowly than those of the wild-type under all conditions and, from indirect evidence, it does not appear to alter the affinity for the germinant L-alanine. The mutant spores have some deficiency of coat proteins (particularly the alkalisoluble coat protein, Mr = 12 000) and the spore coat layers are disorganized. The mutant strain grows normally and sporulates normally until stage II, after which its sporulation is delayed by about 2 h compared to that of the wild-type. This delay results in the prolonged synthesis of some coat proteins and the late synthesis of others. The abnormal coat may be the cause of the germination deficiency. A double mutant strain carrying the spoVIC610 mutation together with gerE36 sporulates slowly. Its spores have very little coat protein, are sensitive to heat, lysozyme and organic solvents, but germinate as well as the strain carrying the spoVIC mutation alone. The role of the spore coat in germination is discussed in the light of these findings.     

The oligopeptide transport system of Bacillus subtilis plays a role in the initiation of sporulation

Bacillus subtilis spo0K mutants are blocked at the first step in sporulation. The spo0K strain was found to contain two mutations: one was linked to the trpS locus, and the other was elsewhere on the chromosome. The mutation linked to trpS was responsible for the sporulation defect (spo-). The unlinked mutation enhanced this sporulation deficiency but had no phenotype on its own. The spo- mutation was located in an operon of five genes highly homologous to the oligopeptide transport (Opp) system of Gram-negative species. Studies with toxic peptide analogues showed that this operon does indeed encode a peptide-transport system. However, unlike the Opp system of Salmonella typhimurium, one of the two ATP-binding proteins, OppF, was not required for peptide transport or for sporulation. The OppA peptide-binding protein, which is periplasmically located in Gram-negative species, has a signal sequence characteristic of lipoproteins with an amino-terminal lipo-amino acid anchor. Cellular location studies revealed that OppA was associated with the cell during exponential growth, but was released into the medium in stationary phase. A major role of the Opp system in Gram-negative bacteria is the recycling of cell-wall peptides as they are released from the growing peptidoglycan. We postulate that the accumulation of such peptides may play a signalling role in the initiation of sporulation, and that the sporulation defect in opp mutants results from an inability to transport these peptides.     

Regulatory gene of phenylalanine biosynthesis (pheR) in Salmonella typhimurium

4-Fluorophenylalanine-resistant mutants of Salmonella typhimurium were isolated in which synthesis of chorismate mutase P-prephenate dehydratase (specified by pheA) was highly elevated. Transduction analysis showed that the mutation affecting pheA activity was not linked to pheA, and conjugation and merodiploid analysis indicated that it was in the 95- to 100-min region of the Salmonella chromosome. Evidence is presented for the hypothesis that the mutation responsible for constitutivity of chorismate mutase P-prephenate dehydratase occurred in pheR, a gene specifying a cytoplasmic product that affected pheA. pheR mutants were found to carry a second mutation, tyrO. The tyrO mutation acts cis to cause increased levels of the tyrosine biosynthetic enzymes 3-deoxy-d-arabinoheptulosonate 7-phosphate synthetase (tyr) and prephenate dehydrogenase, but it has no effect on regulation of pheA.     

Isolation and characterization of fusidic acid-resistant, sporulation-defective mutants of Bacillus subtilis.

Fusidic acid-resistant, sporulation-defective mutants were isolated from Bacillus subtilis 168 thy trp. About two-thirds of the fusidic acid-resistant (fusr) mutants were defective in sporulation ability and fell into three classes with respect to sporulation character. The representative mutants FUS426 and FUS429 were characterized in detail. FUS426 [fusr spo (Ts)], a temperature-sensitive sporulation mutant, grew well at 30 and 42 degrees C but did not sporulate at 42 degrees C. FUS429 [fusr spo (Con)], conditional sporulation mutant, grew and sporulated normally in the absence of fusidic acid, but its sporulation and growth rates decreased in the presence of fusidic acid, depending on the concentration of the drug. Although electron microscopic observation showed that both mutants were blocked at stage I of sporulation, the physiological analyses indicate that these mutants belong to the SpoOB class. Both mutants formed a thickened cell wall as compared with that of the parental strain. Genetic and in vitro protein synthesis analyses led to the conclusion that the sporulation-defective character of mutants FUS426 and FUS429 resulted from an alteration in elongation factor G caused by a single lesion in the fus locus. The possible role of elongation factor G in sporulation is discussed.     

Identification and characterization of sporulation gene spoVS from Bacillus subtilis.

We report the identification and characterization of an additional sporulation gene from Bacillus subtilis called spoVS, which is induced early in sporulation under the control of sigma H. We show that spoVS is an 86-codon-long open reading frame and is capable of encoding a protein of 8,796 Da which exhibits little similarity to other proteins in the databases. Null mutations in spoVS have two contrasting phenotypes. In otherwise wild-type cells they block sporulation at stage V, impairing the development of heat resistance and coat assembly. However, the presence of a spoVS mutation in a spoIIB spoVG double mutant (which is blocked at the stage [II] of polar septation) acts as a partial suppressor, allowing sporulation to advance to a late stage. The implications of the contrasting phenotypes are discussed in the context of the formation and maturation of the polar septum.     

Pulsed-field gel electrophoresis indicates genotypic heterogeneity among Campylobacter upsaliensis strains

Abstract A non-flocculent strain of Saccharomyces cerevisiae was selected after EMS mutation of a flocculent and heterozygous FLO1 locus diploid. The analysis of 25 asci from this diploid showed in all cases segregation 0F:4NF, thus confirming that it was probably affected in the desired gene. After sporulation and dissection of asci, three haploid strains were chosen, which were altered in the locus FLO1 . Crossing these three strains with two other ones having markers for ADE1 and pho11::LEU2 , we could map the mutation at ca. 4.3 cM and ca. 37.7 cM from the PHO11 and ADE1 loci respectively.