Evolution of the RpoS Regulon: Origin of RpoS and the Conservation of RpoS-Dependent Regulation in Bacteria

The RpoS sigma factor in proteobacteria regulates genes in stationary phase and in response to stress. Although of conserved function, the RpoS regulon may have different gene composition across species due to high genomic diversity and to known environmental conditions that select for RpoS mutants. In this study, the distribution of RpoS homologs in prokaryotes and the differential dependence of regulon members on RpoS for expression in two γ-proteobacteria (Escherichia coli and Pseudomonas aeruginosa) were examined. Using a maximum-likelihood phylogeny and reciprocal best hits analysis, we show that the RpoS sigma factor is conserved within γ-, β-, and δ-proteobacteria. Annotated RpoS of Borrelia and the enteric RpoS are postulated to have separate evolutionary origins. To determine the conservation of RpoS-dependent gene expression across species, reciprocal best hits analysis was used to identify orthologs of the E. coli RpoS regulon in the RpoS regulon of P. aeruginosa. Of the 186 RpoS-dependent genes of E. coli, 50 proteins have an ortholog within the P. aeruginosa genome. Twelve genes of the 50 orthologs are RpoS-dependent in both species, and at least four genes are regulated by RpoS in other γ-proteobacteria. Despite RpoS conservation in γ-, β-, and δ-proteobacteria, RpoS regulon composition is subject to modification between species. Environmental selection for RpoS mutants likely contributes to the evolutionary divergence and specialization of the RpoS regulon within different bacterial genomes.     

Antimicrobial cationic surfactant, cetyltrimethylammonium bromide, induces superoxide stress in Escherichia coli cells

Aims: To clarify whether an antibacterial surfactant, cetyltrimethylammonium bromide (CTAB), induces superoxide stress in bacteria, we investigated the generation of superoxide and hydrogen peroxide and expression of soxR, soxS and soxRS regulon genes in Escherichia coli cells with the treatment of CTAB. Methods and Results: In situ oxidative stress analyses with BES fluorescent probes revealed that generation of both superoxide and hydrogen peroxide were significantly increased with the CTAB treatment at a sublethal concentration in wild‐type strain OW6, compared with the CTAB‐resistant strain OW66. The activity of manganese–superoxide dismutase (Mn–SOD), a member of the soxRS regulon proteins, was decreased by the CTAB treatment only in strain OW6. Furthermore, quantitative real‐time PCR analyses revealed that expression of the soxRS regulon genes was not upregulated, although soxS was upregulated by the CTAB treatment in strain OW6. Conclusions: Cetyltrimethylammonium bromide treatment led E. coli cells to a generation state of superoxide and hydrogen peroxide. It was also suggested that superoxide generation was caused by inhibiting SoxS function and decreasing Mn–SOD activity. Significance and Impact of the Study: It was revealed that excess superoxide generation in bacterial cells play a key action of antibacterial surfactants.     

The Contribution of Superoxide Radical to Cadmium Toxicity in E. coli

Numerous reports suggest the involvement of oxidative stress in cadmium toxicity, but the nature of the reactive species and the mechanism of Cd-induced oxidative damage are not clear. In this study, E. coli mutants were used to investigate mechanisms of Cd toxicity. Effects of Cd on metabolic activity, production of superoxide radical by the respiratory chain, and induction of enzymes controlled by the soxRS regulon were investigated. In E. coli, the soxRS regulon controls defense against O₂·⁻and univalent oxidants. Suppression of metabolic activity, inability of E. coli to adapt to new environment, and slow cell division were among the manifestations of Cd toxicity. Cd increased production of O₂·⁻ by the electron transport chain and prevented the induction of soxRS-controlled protective enzymes, even when the regulon was induced by the redox-cycling agent, paraquat. The effect was not limited to soxRS-dependent proteins and can be attributed to previously reported suppression of protein synthesis by Cd. Increased production of superoxide, combined with inability to express protective enzymes and to replace damaged proteins by de novo protein synthesis, seems to be the main reason for growth stasis and cell death in Cd poisoning.

     

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.