Involvement and necessity of the Cpx regulon in the event of aberrant β‐barrel outer membrane protein assembly

The Cpx and σ^E regulons help maintain outer membrane integrity; the Cpx pathway monitors the biogenesis of cell surface structures, such as pili, while the σ^E pathway monitors the biogenesis of β‐barrel outer membrane proteins (OMPs). In this study we revealed the importance of the Cpx regulon in the event of β‐barrel OMP mis‐assembly, by utilizing mutants expressing either a defective β‐barrel OMP assembly machinery (Bam) or assembly defective β‐barrel OMPs. Analysis of specific mRNAs showed that ΔcpxR bam double mutants failed to induce degP expression beyond the wild type level, despite activation of the σ^E pathway. The synthetic conditional lethal phenotype of ΔcpxR in mutant Bam or β‐barrel OMP backgrounds was reversed by wild type DegP expressed from a heterologous plasmid promoter. Consistent with the involvement of the Cpx regulon in the event of aberrant β‐barrel OMP assembly, the expression of cpxP, the archetypal member of the cpx regulon, was upregulated in defective Bam backgrounds or in cells expressing a single assembly‐defective β‐barrel OMP species. Together, these results showed that both the Cpx and σ^E regulons are required to reduce envelope stress caused by aberrant β‐barrel OMP assembly, with the Cpx regulon principally contributing by controlling degP expression.     

The H‐NS‐like protein StpA represses the RpoS (σ38) regulon during exponential growth of Salmonella Typhimurium

StpA is a paralogue of the nucleoid‐associated protein H‐NS that is conserved in a range of enteric bacteria and had no known function in Salmonella Typhimurium. We show that 5% of the Salmonella genome is regulated by StpA, which contrasts with the situation in Escherichia coli where deletion of stpA only had minor effects on gene expression. The StpA‐dependent genes of S. Typhimurium are a specific subset of the H‐NS regulon that are predominantly under the positive control of σ³⁸ (RpoS), CRP‐cAMP and PhoP. Regulation by StpA varied with growth phase; StpA controlled σ³⁸ levels at mid‐exponential phase by preventing inappropriate activation of σ³⁸ during rapid bacterial growth. In contrast, StpA only activated the CRP‐cAMP regulon during late exponential phase. ChIP‐chip analysis revealed that StpA binds to PhoP‐dependent genes but not to most genes of the CRP‐cAMP and σ³⁸ regulons. In fact, StpA indirectly regulates σ³⁸‐dependent genes by enhancing σ³⁸ turnover by repressing the anti‐adaptor protein rssC. We discovered that StpA is essential for the dynamic regulation of σ³⁸ in response to increased glucose levels. Our findings identify StpA as a novel growth phase‐specific regulator that plays an important physiological role by linking σ³⁸ levels to nutrient availability.     

Non-specific, general and multiple stress resistance of growth-restricted Bacillus subtilis cells by the expression of the σB regulon

Bacillus subtilis cells respond almost immediately to different stress conditions by increasing the production of general stress proteins (GSPs). The genes encoding the majority of the GSPs that are induced by heat, ethanol, salt stress or by starvation for glucose, oxygen or phosphate belong to the σ^B-dependent general stress regulon. Despite a good understanding of the complex regulation of the activity of σ^B and knowledge of a very large number of general stress genes controlled by σ^B, first insights into the physiological role of this non-specific stress response have been obtained only very recently. To explore the physiological role of this regulon, we and others identified σ^B-dependent general stress genes and compared the stress tolerance of wild-type cells with mutants lacking σ^B or general stress proteins. The proteins encoded by σ^B-dependent general stress genes can be divided into at least five functional groups that most probably provide growth-restricted B. subtilis cells with a multiple stress resistance in anticipation of future stress. In particular, sigB mutants are impaired in non-specific resistance to oxidative stress, which requires the σ^B-dependent dps gene encoding a DNA-protecting protein. Protection against oxidative damage of membranes, proteins or DNA could be the most essential component of σ^B-mediated general stress resistance in growth-arrested aerobic Gram-positive bacteria. Other general stress genes have both a σ^B-dependent induction pathway and a second σ^B-independent mechanism of stress induction, thereby partially compensating for a σ^B deficiency in a sigB mutant. In contrast to sigB mutants, null mutations in genes encoding those proteins, such as clpP or clpC, cause extreme sensitivity to salt or heat.     

Gene position within a long transcript as a determinant for stochastic switching in bacteria

How cultures of genetically identical cells bifurcate into distinct phenotypic subpopulations under uniform growth conditions is an important question in developmental biology of relevance even to relatively simple developmental systems, such as spore formation in bacteria. A growing Bacillus subtilis culture consists of either cells that are motile and can swim or cells that are non‐motile and are chained together. In this issue of Molecular Microbiology, Cozy and Kearns show that the probability of a cell to become motile depends on the position of the sigD gene within the long (27 kb) motility operon. sigD encodes the alternative sigma factor σ^D that, together with RNA polymerase, drives expression of genes required for cell separation and the assembly of flagella. sigD is the penultimate gene of the B. subtilis motility operon and, in the control strain approximately, 70% of the cells are motile. When sigD was moved upstream within the operon, a larger fraction of cells became motile (up to 100%). This study highlights that the position of a gene within an operon can have a large impact on the control of gene expression. Furthermore, it suggests that RNA polymerase processivity or mRNA turnover can play important roles as sources of noise in bacterial development, and that gene position might be an unrecognized and possibly widespread mechanism to regulate phenotypic variation.     

Contributions of the σW, σM and σX regulons to the lantibiotic resistome of Bacillus subtilis

In Bacillus subtilis, the extracytoplasmic function (ECF) σ factors σ^M, σ^W and σ^X all contribute to resistance against lantibiotics. Nisin, a model lantibiotic, has a dual mode of action: it inhibits cell wall synthesis by binding lipid II, and this complex also forms pores in the cytoplasmic membrane. These activities can be separated in a nisin hinge‐region variant (N20P M21P) that binds lipid II, but no longer permeabilizes membranes. The major contribution of σ^M to nisin resistance is expression of ltaSa, encoding a stress‐activated lipoteichoic acid synthase, and σ^X functions primarily by activation of the dlt operon controlling d ‐alanylation of teichoic acids. Together, σ^M and σ^X regulate cell envelope structure to decrease access of nisin to its lipid II target. In contrast, σ^W is principally involved in protection against membrane permeabilization as it provides little protection against the nisin hinge region variant. σ^W contributes to nisin resistance by regulation of a signal peptide peptidase (SppA), phage shock proteins (PspA and YvlC, a PspC homologue) and tellurite resistance related proteins (YceGHI). These defensive mechanisms are also effective against other lantibiotics such as mersacidin, gallidermin and subtilin and comprise an important subset of the intrinsic antibiotic resistome of B. subtilis.     

MicA sRNA links the PhoP regulon to cell envelope stress

Numerous small RNAs regulators of gene expression exist in bacteria. A large class of them binds to the RNA chaperone Hfq and act by base pairing interactions with their target mRNA, thereby affecting their translation and/or stability. They often have multiple direct targets, some of which may be regulators themselves, and production of a single sRNA can therefore affect the expression of dozens of genes. We show in this study that the synthesis of the Escherichia coli pleiotropic PhoPQ two‐component system is repressed by MicA, a σ^E‐dependent sRNA regulator of porin biogenesis. MicA directly pairs with phoPQ mRNA in the translation initiation region of phoP and presumably inhibits translation by competing with ribosome binding. Consequently, MicA downregulates several members of the PhoPQ regulon. By linking PhoPQ to σ^E, our findings suggest that major cellular processes such as Mg²⁺ transport, virulence, LPS modification or resistance to antimicrobial peptides are modulated in response to envelope stress. In addition, we found that Hfq strongly affects the expression of phoP independently of MicA, raising the possibility that even more sRNAs, which remain to be identified, could regulate PhoPQ synthesis.     

Shedding light on a Group IV (ECF11) alternative σ factor

This year marks the 50^th anniversary of the discovery of σ⁷⁰ as a protein factor that was needed for bacterial RNA polymerase to accurately transcribe a promoter in vitro. It was 25 years later that the Group IV alternative σs were described as a distinct family of proteins related to σ⁷⁰. In the intervening time, there has been an ever‐growing list of Group IV σs, numbers of genes they transcribe, insight into the diverse suite of processes they control, and appreciation for their impact on bacterial lifestyles. This work summarizes knowledge of the Rhodobacter sphaeroides σ^E‐ChrR pair, a member of the ECF11 subfamily of Group IV alternative σs, in protecting cells from the reactive oxygen species, singlet oxygen. It describes lessons learned from analyzing ChrR, a zinc‐dependent anti‐σ factor, that are generally applicable to Group IV σs and relevant to the response to single oxygen. This MicroReview also illustrates insights into stress responses in this and other bacteria that have been acquired by analyzing or modeling the activity of the σ^E‐ChrR across the bacterial phylogeny.