AbrB is a regulator of the sigma(W) regulon in Bacillus subtilis

The Bacillus subtilis global regulator AbrB was found to negatively control expression of sigW and genes of the sigma(W) regulon. AbrB bound to DNA regions in the autoregulatory sigW promoter and to some, but not all, of the other sigma(W)-dependent promoters in B. subtilis. Defects in antibiotic resistance properties caused by spo0A mutations are at least partially correlated with AbrB repression of the sigma(W) regulon.     

FosB, a cysteine-dependent fosfomycin resistance protein under the control of sigma(W), an extracytoplasmic-function sigma factor in Bacillus subtilis

We demonstrate that the Bacillus subtilis fosB(yndN) gene encodes a fosfomycin resistance protein. Expression of fosB requires sigma(W), and both fosB and sigW mutants are fosfomycin sensitive. FosB is a metallothiol transferase related to the FosA class of Mn(2+)-dependent glutathione transferases but with a preference for Mg(2+) and L-cysteine as cofactors.     

Mutations in multidrug efflux homologs, sugar isomerases, and antimicrobial biosynthesis genes differentially elevate activity of the sigma(X) and sigma(W) factors in Bacillus subtilis

The sigma(X) and sigma(W) extracytoplasmic function sigma factors regulate more than 40 genes in Bacillus subtilis. sigma(W) activates genes which function in detoxification and the production of antimicrobial compounds, while sigma(X) activates functions that modify the cell envelope. Transposon mutagenesis was used to identify loci which negatively regulate sigma(W) or sigma(X) as judged by up-regulation from the autoregulatory promoter site P(W) or P(X). Fourteen insertions that activate P(W) were identified. The largest class of insertions are likely to affect transport. These include insertions in genes encoding two multidrug efflux protein homologs (yqgE and yulE), a component of the oligopeptide uptake system (oppA), and two transmembrane proteins with weak similarity to transporters (yhdP and yueF). Expression from P(W) is also elevated as a result of inactivation of at least one member of the sigma(W) regulon (ysdB), an ArsR homolog (yvbA), a predicted rhamnose isomerase (yulE), and a gene (pksR) implicated in synthesis of difficidin, a polyketide antibiotic. In a parallel screen, we identified seven insertions that up-regulate P(X). Remarkably, these insertions were in functionally similar genes, including a multidrug efflux homolog (yitG), a mannose-6-phosphate isomerase gene (yjdE), and loci involved in antibiotic synthesis (srfAB and possibly yogA and yngK). Significantly, most insertions that activate P(W) have little or no effect on P(X), and conversely, insertions that activate P(X) have no effect on P(W). This suggests that these two regulons respond to distinct sets of molecular signals which may include toxic molecules which are exported, cell density signals, and antimicrobial compounds.     

Effects of amino acid substitutions in the promoter -10 binding region of the sigma A factor on growth of Bacillus subtilis.

On the bases of structural and functional information about the Bacillus subtilis sigma A protein and the techniques of site-directed mutagenesis, we constructed a B. subtilis sigA mutant (DB1005) which grows normally at 37 degrees C but is sensitive to higher temperatures. DNA sequencing analyses revealed that DB1005 has Ile-198-->Ala and Ile-202-->Ala amino acid substitutions in the alpha-helix of the 2.4 region of the sigma A protein. Western blotting (immunoblotting) revealed that this mutant sigma A protein is stable at both 37 and 49 degrees C. These results suggest that Ile-198 and Ile-202 separately or in combination are critical for the sigma A protein to be functional at the restrictive temperature.     

MinJ (YvjD) is a topological determinant of cell division in Bacillus subtilis

In Bacillus subtilis, FtsZ ring formation and cell division is favoured at the midcell because the inhibitor proteins MinC and MinD are indirectly restricted to the cell poles by the protein DivIVA. Here we identify MinJ, a topological determinant of medial FtsZ positioning that acts as an intermediary between DivIVA and MinD. Due to unrestricted MinD activity, cells mutated for minJ exhibited pleiotropic defects in homologous recombination, swarming motility and cell division. MinJ restricted MinD activity by localizing MinD to the cell poles through direct protein-protein interaction. MinJ itself localized to cell poles in a manner that was dependent on DivIVA. MinJ is conserved in other low G+C Gram-positive bacteria and may be an important component of cell division site selection in these organisms.