Transcriptomic and Phenotypic Characterization of a Bacillus subtilis Strain without Extracytoplasmic Function σ Factors

Bacillus subtilis encodes seven extracytoplasmic function (ECF) σ factors. Three (σM, σW, and σX) mediate responses to cell envelope-active antibiotics. The functions of σV, σY, σZ, and σYlaC remain largely unknown, and strong inducers of these σ factors and their regulons have yet to be defined. Here, we define transcriptomic and phenotypic differences under nonstress conditions between a strain carrying deletions in all seven ECF σ factor genes (the Δ7ECF mutant), a ΔMWX triple mutant, and the parental 168 strain. Our results identify >80 genes as at least partially dependent on ECF σ factors, and as expected, most of these are dependent on σM, σW, or σX, which are active at a significant basal level during growth. Several genes, including the eps operon encoding enzymes for exopolysaccharide (EPS) production, were decreased in expression in the Δ7ECF mutant but affected less in the ΔMWX mutant. Consistent with this observation, the Δ7ECF mutant (but not the ΔMWX mutant) showed reduced biofilm formation. Extending previous observations, we also note that the ΔMWX mutant is sensitive to a variety of antibiotics and the Δ7ECF mutant is either as sensitive as, or slightly more sensitive than, the ΔMWX strain to these stressors. These findings emphasize the overlapping nature of the seven ECF σ factor regulons in B. subtilis, confirm that three of these (σM, σW, and σX) play the dominant role in conferring intrinsic resistance to antibiotics, and provide initial insights into the roles of the remaining ECF σ factors.