Regulatory overlap and functional redundancy among Bacillus subtilis extracytoplasmic function sigma factors

Bacillus subtilis encodes seven extracytoplasmic function (ECF) sigma factors that regulate partially overlapping regulons related to cell envelope homeostasis and antibiotic resistance. Here, we investigated their physiological role by constructing a mutant set of single, double, triple, and quadruple ECF sigma factor deletions in the undomesticated B. subtilis strain NCIB3610. This mutant set was subsequently screened for defects in motility, multicellular differentiation, and sensitivity to more than 200 chemicals by using Phenotype MicroArrays. A quadruple mutant strain, harboring deletions of the sigV, sigY, sigZ, and ylaC gene, behaved indistinguishably from the wild-type strain, indicative of either regulatory redundancy or very specific functions of these four ECF sigma factors. In contrast, a triple mutant, inactivated for the sigM, sigW, and sigX genes (but none of the corresponding double mutants), showed a biphasic growth behavior and a complete loss of multicellular differentiation, as judged by both colony formation and the inability to form a pellicle. This triple mutant also displayed a greatly increased sensitivity to detergents and several cell wall antibiotics including beta-lactams, polymyxin B, and d-cycloserine. In several cases, these antibiotic-sensitive phenotypes are significantly enhanced in the triple mutant strain relative to strains lacking only one or two sigma factors.     

Regulation of the Bacillus subtilis bcrC bacitracin resistance gene by two extracytoplasmic function sigma factors

Bacitracin resistance is normally conferred by either of two major mechanisms, the BcrABC transporter, which pumps out bacitracin, or BacA, an undecaprenol kinase that provides C(55)-isoprenyl phosphate by de novo synthesis. We demonstrate that the Bacillus subtilis bcrC (ywoA) gene, encoding a putative bacitracin transport permease, is an important bacitracin resistance determinant. A bcrC mutant strain had an eightfold-higher sensitivity to bacitracin. Expression of bcrC initiated from a single promoter site that could be recognized by either of two extracytoplasmic function (ECF) sigma factors, sigma(X) or sigma(M). Bacitracin induced expression of bcrC, and this induction was dependent on sigma(M) but not on sigma(X). Under inducing conditions, expression was primarily dependent on sigma(M). As a consequence, a sigM mutant was fourfold more sensitive to bacitracin, while the sigX mutant was only slightly sensitive. A sigX sigM double mutant was similar to a bcrC mutant in sensitivity. These results support the suggestion that one function of B. subtilis ECF sigma factors is to coordinate antibiotic stress responses.     

Identification of Bacillus subtilis sigma-dependent genes that provide intrinsic resistance to antimicrobial compounds produced by Bacilli

Bacillus subtilis produces many antibiotics of varying structures and specificity. Here we identify a prominent role for sigma(W), an extracytoplasmic function (ECF) sigma factor, in providing intrinsic resistance to antimicrobial compounds produced by other Bacilli. By using a panel of B. subtilis mutants disrupted for each of the 30 known sigma(W)-dependent operons we identified resistance genes for at least three different antimicrobial compounds. The ydbST and fosB genes contribute to resistance to antimicrobial compound(s) produced by B. amyloliquefaciens FZB42, the yqeZyqfAB operon provides resistance to the SPbeta prophage-encoded bacteriocin sublancin, and the yknWXYZ operon and yfhL provide resistance to the antimicrobial peptide SdpC. YfhL encodes a paralogue of SdpI, a membrane protein that provides immunity to SdpC. In competition experiments, we identify sigma(W) as a key factor in allowing B. subtilis to resist antibiotic killing and encroachment by competing strains. Together with the previous observation that sigma(W) provides inducible resistance against the Streptomyces antibiotic fosfomycin, these studies support the notion that sigma(W) controls an antibiosis regulon important in the microbial ecology of soil bacteria.     

Identification of two genes encoding putative new members of the ECF subfamily of eubacterial RNA polymerase sigma factors in Clostridium acetobutylicum

Two genes from Clostridium acetobutylicum DSM 792 were identified which are predicted to encode new members of the ECF subfamily of eubacterial RNA polymerase sigma factors. The sigX gene has the potential to encode a 184-amino acid protein with a molecular mass of 21,870 Da and with the highest overall similarity to Fecl of Escherichia coli (27 % identical residues). The second gene, which is predicted to encode an alternative sigma factor of the ECF subfamily, is the previously described orf2 gene (Gerischer and Dürre, 1990) located in the adc gene region of C. acetobutylicum. The deduced protein of orf2 has significant similarity to SigX of C. acetobutylicum (22 % identical residues) and shares structural features with other alternative sigma factors. Therefore, it is proposed to rename orf2 as sigY. Analysis of the phylogenetic relationship revealed that SigX from C. acetobutylicum, together with sigmaE from Streptomyces coelicolor and SigX from Bacillus subtilis, form a gram-positive cluster within the ECF subfamily and that SigY from C. acetobutylicum together with UviA from Clostridium perfringens, form a separate cluster located between the gram-positive cluster and the sporulation sigma factor sigmaH from B. subtilis.     

The single extracytoplasmic-function sigma factor of Xylella fastidiosa is involved in the heat shock response and presents an unusual regulatory mechanism

Genome sequence analysis of the bacterium Xylella fastidiosa revealed the presence of two genes, named rpoE and rseA, predicted to encode an extracytoplasmic function (ECF) sigma factor and an anti-sigma factor, respectively. In this work, an rpoE null mutant was constructed in the citrus strain J1a12 and shown to be sensitive to exposure to heat shock and ethanol. To identify the X. fastidiosa sigma(E) regulon, global gene expression profiles were obtained by DNA microarray analysis of bacterial cells under heat shock, identifying 21 sigma(E)-dependent genes. These genes encode proteins belonging to different functional categories, such as enzymes involved in protein folding and degradation, signal transduction, and DNA restriction modification and hypothetical proteins. Several putative sigma(E)-dependent promoters were mapped by primer extension, and alignment of the mapped promoters revealed a consensus sequence similar to those of ECF sigma factor promoters of other bacteria. Like other ECF sigma factors, rpoE and rseA were shown to comprise an operon in X. fastidiosa, together with a third open reading frame (XF2241). However, upon heat shock, rpoE expression was not induced, while rseA and XF2241 were highly induced at a newly identified sigma(E)-dependent promoter internal to the operon. Therefore, unlike many other ECF sigma factors, rpoE is not autoregulated but instead positively regulates the gene encoding its putative anti-sigma factor.     

Expression in Bacillus subtilis of the Bacillus thuringiensis cryIIIA toxin gene is not dependent on a sporulation-specific sigma factor and is increased in a spo0A mutant.

Expression of the Bacillus thuringiensis cryIIIA gene encoding a Coleoptera-specific toxin is weak during vegetative growth and is activated at the onset of the stationary phase. cryIIIA'-'lacZ fusions and primer extension analysis show that the regulation of cryIIIA expression is similar in Bacillus subtilis and in B. thuringiensis. Activation of cryIIIA expression was not altered in B. subtilis mutant strains deficient for the sigma H and sigma E sporulation-specific sigma factors or for minor sigma factors such as sigma B, sigma D, or sigma L. This result and the nucleotide sequence of the -35 and -10 regions of the cryIIIA promoter suggest that cryIIIA expression might be directed by the E sigma A form of RNA polymerase. Expression of the cryIIIA'-'lacZ fusion is shut off after t2 (2 h after time zero) of sporulation in the B. subtilis wild-type strain grown on nutrient broth sporulation medium. However, no decrease in cryIIIA-directed beta-galactosidase activity occurred in sigma H, kinA, or spo0A mutant strains. Moreover, beta-galactosidase activity was higher and remained elevated after t2 in the spo0A mutant strain. beta-Galactosidase activity was weak in abrB and spo0A abrB mutant strains, suggesting that AbrB is responsible for the higher level of cryIIIA expression observed in a spo0A mutant. However, both in spo0A and spo0A abrB mutant strains, beta-galactosidase activity remained elevated after t2, suggesting that even in the absence of AbrB, cryIIIA expression is controlled through modulation of the phosphorylated form of Spo0A. When the cryIIIA gene is expressed in a B. subtilis spo0A mutant strain or in the 168 wild-type strain, large amounts of toxins are produced and accumulate to form a flat rectangular crystal characteristic of the coleopteran-specific B. thuringiensis strains.     

The Bacillus subtilis sigmaW anti-sigma factor RsiW is degraded by intramembrane proteolysis through YluC

The Bacillus subtilis sigma(W) regulon is induced by different stresses such as alkaline shock, salt shock, phage infection and certain antibiotics that affect cell wall biosynthesis. The activity of the alternative, extracytoplasmic function (ECF) sigma factor sigma(W) is modulated by a specific anti-sigma factor (RsiW or YbbM) encoded by the rsiW (ybbM) gene located immediately downstream of sigW. The RsiW membrane topology was determined, and a specific reporter system for RsiW function was constructed. Experiments using the yeast two-hybrid system suggested a direct interaction of sigma(W) with the cytoplasmic part of RsiW. Analysis of truncated forms of the RsiW protein revealed that sigma(W) induction by alkaline shock is dependent on both the transmembrane and the extracytoplasmic domain of RsiW. Western blot and pulse-chase experiments demonstrated degradation of RsiW after an alkaline shock. A B. subtilis mutant strain deleted for the Escherichia coli yaeL orthologue yluC, encoding a transmembrane protease, was defective in inducing a sigma(W)-controlled promoter after alkaline shock and accumulated a membrane-bound truncated form of RsiW, suggesting that the activity of sigma(W) is controlled by the proteolysis of RsiW by at least two different proteolytic steps.     

GeneChip expression analysis of the VqsR regulon of Pseudomonas aeruginosa TB

Two interlinked quorum sensing circuits, las and rhl, which control pathogenesis of Pseudomonas aeruginosa are further modulated by numerous regulators, including VqsR (virulence and quorum sensing regulator). High-density oligonucleotide microarrays were used to compare the global expression profile of a wild-type and VqsR mutant in ABC minimal medium. The expression of a large group of metabolic genes, ECF sigma factors as well as of many quorum-sensing genes previously not assigned to VqsR-regulon was found to be affected by the disruption of vqsR.     

Heterologous expression of the Oceanobacillus iheyensis SigW and its anti-protein RsiW in Bacillus subtilis

Pairs of the ECF sigma factor and its anti-sigma factor, SigW and RsiW, of Bacillus-related species that inhabit extreme environments were heterologously expressed in B. subtilis. All the RsiWs, membrane proteins, failed to fill their function of repressing cognate SigW activity, despite their close structural similarities. Particularly, uncontrolled expression of Oceanobacillus iheyensis OISigW due to abortive OIRsiW was harmful to B. subtilis. Analysis of revertants of this growth defect and site-directed mutagenesis indicated that the insertion of six and a minimum of three hydrophobic amino acid residues occurring in the transmembrane region allowed OIRsiW to function as anti-OISigW. Subcellular localization of OIRsiW was detected by immunoblot analysis, suggesting that both the wild-type and the mutant form of OIRsiW were localized to the membrane. An appropriate length of a transmembrane region required for proper integration into the membrane after translocation might vary among these Bacillus-related species.