Nucleotide sequence of sporulation locus spoIIA in Bacillus subtilis

We have determined a sequence of 2073 bp from two recombinant plasmids carrying the whole spoIIA locus from Bacillus subtilis, the expression of which is required for spore formation. The sequence contains three long open reading frames (ORFs), each of them being preceded by a ribosome binding site. These three putative proteins (mol. wts 13100, 16300 and 22200) are likely to be expressed and are probably encoded on the same mRNA. The stop codon of ORF1 overlaps with the start codon of ORF2 suggesting that there might be translational coupling between the two ORFs. Although some known promoter sequences were found, the only one upstream from the first open reading frame is about 260 bp from it.     

The Bacillus subtilis spoIIA locus is expressed at two times during sporulation

Abstract The Bacillus subtilis spoIIA and spoIIAB genes were fused to the Escherichia coli lacZ gene on a novel integrational plasmid vector. The constructs were integrated into the B. subtilis chromosome, and used to show that the spoIIA locus was expressed at two times during sporulation.     

Effects of transition mutations in the regulatory locus spoIIA on the incidence of sporulation in Bacillus subtilis

We have determined the changes in DNA sequence corresponding to three mutations in the promoter-proximal open reading frame of spoIIA, a locus that regulates sporulation in Bacillus subtilis. All three mutations prevent the synthesis of two sporulation-associated enzymes, but they differ in their effects on spore incidence. We now find that mutation spo-42, which allows spores to be produced at a low incidence, is a transition that changes Gly95 to Asp in the protein encoded by the open reading frame. Mutation spo-69, which blocks sporulation entirely, consists of two transitions: these change Gly62 to Asp and Ala1 16 to Thr. Mutation sas-1, which partially suppresses spo-69, is also a transition: this changes residue 62 (which had become Asp as a result of the spo-69 mutation) to Asn.     

Isolation and characterization of a recombinant plasmid carrying a functional part of the Bacillus subtilis spoIIA locus

Plasmid pHM2 consists of a 3.3 kb insert of Bacillus subtilis DNA in the chimeric plasmid pHV33, and can replicate in Escherichia coli and B. subtilis. In B. subtilis, pHM2 complements the defects resulting from mutations spo-42, spo-50, spo-69 and sas-1 in the spoIIA locus. This complementation can occur in recE4 strains where recombination of the plasmid with the chromosome is prevented, and the chromosome retains the mutant allele. Thus the plasmid carries a functional part of the spoIIA locus; it does not contain the complete locus as it cannot complement several other spoIIA mutations. It is likely that the locus is complex, containing at least two genes.     

Synthesis of spoIIA and spoVA mRNA in Bacillus subtilis

The expression of the spoIIA and spoVA sporulation loci of Bacillus subtilis was examined by using DNA-RNA hybridization to detect the time of appearance of their corresponding mRNA molecules in wild-type and asporogenous mutants of B. subtilis. From the size of the mRNA molecules it is clear that both the spoIIA and spoVA loci are polycistronic operons. Neither of the mRNA molecules is polyadenylated. The results also indicate the spoIIA operon is regulated by two promoters which become functional at different times.     

Variety of sporulation phenotypes resulting from mutations in a single regulatory locus, spoIIA, in Bacillus subtilis

Closely linked mutations in either of the two putative genes of the sporulation locus spoIIA can affect, in quite diverse ways, spore incidence, the production of alkaline phosphatase and DNAase, and the stability of the cells in sporulation medium. It is concluded that the locus has a regulatory function affecting the activation or induction of at least two, and possibly more, sporulation-associated operons.     

The divIVA minicell locus of Bacillus subtilis.

The Bacillus subtilis divIVA1 mutation causes misplacement of the septum during cell division, resulting in the formation of small, circular, anucleate minicells. This study reports the cloning and sequence analysis of 2.4 kb of the B. subtilis chromosome including the divIVA locus. Three open reading frames were identified: orf, whose function is unknown; divIVA; and isoleucyl tRNA synthetase (ileS). We identified the point mutation in the divIVA1 mutant allele. Inactivation of divIVA produces a minicell phenotype, whereas overproduction of DivIVA results in a filamentation phenotype. Mutants with mutations at both of the minicell loci of B. subtilis, divIVA and divIVB, possess a minicell phenotype identical to that of the DivIVB- mutant. The DivIVA-mutants, but not the DivIVB- mutants, show a decrease in sporulation efficiency and a delay in the kinetics of endospore formation. The data support a model in which divIVA encodes the topological specificity subunit of the minCD system. The model suggests that DivIVA acts as a pilot protein, directing minCD to the polar septation sites. DivIVA also appears to be the interface between a sporulation component and MinCD, freeing up the polar septation sites for use during the asymmetric septation event of the sporulation process.     

Genetic analysis of the flaA locus of Bacillus subtilis.

We isolated two clones of recombinant lambda bacteriophage with overlapping inserts of Bacillus subtilis chromosomal DNA corresponding to part of the flaA locus. The flaA4 and flaA15 mutations were localized on the physical map by marker rescue experiments. The flaA locus and the flaB (sigD) gene were mapped in transduction crosses, and the order glnA polC flaB flaA was determined. FlaB was linked to polC in transformation crosses.