Obg, an essential GTP binding protein of Bacillus subtilis, is necessary for stress activation of transcription factor sigma(B).

sigma(B), the general stress response sigma factor of Bacillus subtilis, is activated when intracellular ATP levels fall or the bacterium experiences environmental stress. Stress activates sigma(B) by means of a collection of regulatory kinases and phosphatases (the Rsb proteins), which catalyze the release of sigma(B) from an anti-sigma factor inhibitor. By using the yeast dihybrid selection system to identify B. subtilis proteins that could interact with Rsb proteins and act as mediators of stress signaling, we isolated the GTP binding protein, Obg, as an interactor with several of these regulators (RsbT, RsbW, and RsbX). B. subtilis depleted of Obg no longer activated sigma(B) in response to environmental stress, but it retained the ability to activate sigma(B) by the ATP responsive pathway. Stress pathway components activated sigma(B) in the absence of Obg if the pathway's most upstream effector (RsbT) was synthesized in excess to the inhibitor (RsbS) from which it is normally released after stress. Thus, the Rsb proteins can function in the absence of Obg but fail to be triggered by stress. The data demonstrate that Obg, or a process under its control, is necessary to induce the stress-dependent activation of sigma(B) and suggest that Obg may directly communicate with one or more sigma(B) regulators.     

The general stress protein Ctc of Bacillus subtilis is a ribosomal protein

Cells respond to stress conditions by synthesizing general or specific stress proteins. The Ctc protein of Bacillus subtilis belongs to the general stress proteins. The synthesis of Ctc is controlled by an alternative sigma factor of RNA polymerase, sigmaB. Sequence analyses revealed that Ctc is composed of two domains, an N-terminal domain similar to the ribosomal protein L25 of Escherichia coli, and a C-terminal domain. The similarity of the N-terminal domain of Ctc to L25 suggested that Ctc might be a ribosomal protein in B. subtilis. The function of the C-terminal domain is unknown. We purified Ctc to homogeneity and used the pure protein to raise antibodies. Western blot analyses demonstrate that Ctc is induced under stress conditions and can be found in ribosomes of B. subtilis. As observed for its E. coli counterpart L25, Ctc is capable of binding 5S ribosomal RNA in a specific manner. The stress-specific localization of Ctc in B. subtilis ribosomes and the sporulation defect of ctc mutants at high temperatures suggest that Ctc might be required for accurate translation under stress conditions.     

Relative levels and fractionation properties of Bacillus subtilis sigma(B) and its regulators during balanced growth and stress.

sigma B is a secondary sigma factor that controls the general stress response in Bacillus subtilis. sigma B-dependent genes are activated when sigma B is released from an inhibitory complex with an anti-sigma B protein (RsbW) and becomes free to associate with RNA polymerase. Two separate pathways, responding either to a drop in intracellular ATP levels or to environmental stress (e.g., heat, ethanol, or salt), cause the release of sigma B from RsbW. rsbR, rsbS, rsbT, and rsbU are four genes now recognized as the upstream half of an operon that includes sigB (sigma B) and its principal regulators. Using reporter gene assays, we find that none of these four genes are essential for stationary-phase (i.e., ATP-dependent) activation of sigma B, but rsbU and one or more of the genes contained within an rsbR,S,T deletion are needed for stress induction of sigma B. In other experiments, Western blot (immunoblot) analyses showed that the levels of RsbR, RsbS, Rsb, and RsbU, unlike those of the sigB operon's four downstream gene products (RsbV, RsbW, RsbX and sigma B), are not elevated during sigma B activation. Gel filtration and immunoprecipitation studies did not reveal the formation of complexes between any of the four upstream sigB operon products and the products of the downstream half of the operon. Much of the detectable RsbR, RsbS, RsbT, and RsbU did, however, fractionate as a large-molecular-mass (approximately 600-kDa) aggregate which was excluded from our gel filtration matrix. The downstream sigB operon products were not present in this excluded material. The unaggregated RsbR, RsbS, and RsbU, which were retarded by the gel matrix, elated from the column earlier than expected from their molecular weights. The RsbR and RsbS fractionation profile was consistent with homodimers (60 and 30 kDa, respectively), while the RsbU appeared larger, suggesting a protein complex of approximately 90 to 100 kDa.     

Stress activation of Bacillus subtilis sigma B can occur in the absence of the sigma B negative regulator RsbX.

Environmental stress activates sigma B, the general stress response sigma factor of Bacillus subtilis, by a pathway that is negatively controlled by the RsbX protein. To determine whether stress activation of sigma B occurs by a direct effect of stress on RsbX, we constructed B. subtilis strains which synthesized various amounts of RsbX or lacked RsbX entirely and subjected these strains to ethanol stress. Based on the induction of a sigma B-dependent promoter, stress activation of sigma B can occur in the absence of RsbX. Higher levels of RsbX failed to detectably influence stress induction, but reduced levels of RsbX resulted in greater and longer-lived sigma B activation. The data suggest that RsbX is not a direct participant in the sigma B stress induction process but rather serves as a device to limit the magnitude of the stress response.     

Blue light activates the sigmaB-dependent stress response of Bacillus subtilis via YtvA

Here we present evidence for a physiologically relevant light response mediated by the LOV domain-containing protein YtvA in the soil bacterium Bacillus subtilis. The loss and overproduction of YtvA abolish and enhance, respectively, the increase in sigma(B)-controlled ctc promoter activity at moderate light intensities. These effects were absent in the dark and in red light but present under blue-light illumination. Thus, activation of the general stress response in B. subtilis is modulated by blue light.     

A phylogenomic study of the general stress response sigma factor sigmaB of Bacillus subtilis and its regulatory proteins

Regulation of expression of the general stress regulon of Bacillus subtilis is mediated by the activation of the alternative sigma factor sigmaB. Activation of sigmaB is accomplished by a complex regulatory network involving protein-protein interactions and reversible protein phosphorylation. PSI-BLAST searches were performed and phylogenetic trees for sigmaB and its regulatory proteins were constructed. Occurrence of sigmaB is restricted to a small group of gram-positive bacteria (Bacillus, Staphylococcus, Listeria). Related sigma factors also involved in stress responses are present in Mycobacterium tuberculosis, Streptomyces species and even in cyanobacteria (Synechocystis species). Putative regulatory proteins found in several other bacterial species can be broadly catagorized into three categories: Anti sigma factors, anti-anti sigma factors and phosphatases. Anti sigma factors are able to bind to sigma factors and are also kinases of anti sigma factor antagonists. Only in their nonphosphorylated state, these antagonists are able to bind to the anti sigma factor. Phosphorylated antagonists can be dephosphorylated by PP2C phosphatases. These phosphatases are of pivotal importance for activation of the sigma factor. Different phosphatases identified in this search contain a wide variety of domains found in signal transducing proteins (PAS/PAC, GAF, REC, HATase_c, HAMP). The HATPase_c domain found in several phosphatases most probably constitutes a serine/threonine kinase domain of anti sigma factors. Such proteins are most probably bifunctional anti-anti sigma factor kinases and phosphatases. The regulatory network of anti-anti sigma factors anti sigma factors and phosphatases is probably ancient and most likely evolved from a structurally similar network found in the Deinococcus radiodurans genome. In completely sequenced genomes of several bacterial species, some elements of the network are missing. The N-terminus of RsbU, a phosphatase activated in response to environmental stress exhibits similarities to a region in the beta chain of phenylalanyl-tRNA synthetases.     

Listeria monocytogenes sigma B regulates stress response and virulence functions

While the stress-responsive alternative sigma factor sigma(B) has been identified in different species of Bacillus, Listeria, and Staphylococcus, the sigma(B) regulon has been extensively characterized only in B. subtilis. We combined biocomputing and microarray-based strategies to identify sigma(B)-dependent genes in the facultative intracellular pathogen Listeria monocytogenes. Hidden Markov model (HMM)-based searches identified 170 candidate sigma(B)-dependent promoter sequences in the strain EGD-e genome sequence. These data were used to develop a specialized, 208-gene microarray, which included 166 genes downstream of HMM-predicted sigma(B)-dependent promoters as well as selected virulence and stress response genes. RNA for the microarray experiments was isolated from both wild-type and Delta sigB null mutant L. monocytogenes cells grown to stationary phase or exposed to osmotic stress (0.5 M KCl). Microarray analyses identified a total of 55 genes with statistically significant sigma(B)-dependent expression under the conditions used in these experiments, with at least 1.5-fold-higher expression in the wild type over the sigB mutant under either stress condition (51 genes showed at least 2.0-fold-higher expression in the wild type). Of the 55 genes exhibiting sigma(B)-dependent expression, 54 were preceded by a sequence resembling the sigma(B) promoter consensus sequence. Rapid amplification of cDNA ends-PCR was used to confirm the sigma(B)-dependent nature of a subset of eight selected promoter regions. Notably, the sigma(B)-dependent L. monocytogenes genes identified through this HMM/microarray strategy included both stress response genes (e.g., gadB, ctc, and the glutathione reductase gene lmo1433) and virulence genes (e.g., inlA, inlB, and bsh). Our data demonstrate that, in addition to regulating expression of genes important for survival under environmental stress conditions, sigma(B) also contributes to regulation of virulence gene expression in L. monocytogenes. These findings strongly suggest that sigma(B) contributes to L. monocytogenes gene expression during infection.