The katX gene of Bacillus subtilis is under dual control of sigmaB and sigmaF.

The gene katX, which encodes a catalase in Bacillus subtilis, is transcribed by EsigmaF in the pre-spore. This catalase is responsible for the resistance to hydrogen peroxide shown by germinating and outgrowing spores. We demonstrated that katX is also a sigmaB-dependent general stress gene, since it is strongly induced by heat, salt and ethanol stress, as well as by energy depletion. The -10 and -35 sequences of the sigmaB- and sigmaF-dependent promoters of katX overlap, and the transcriptional start points used by EsigmaB and EsigmaF differ by only one nucleotide. Our results indicate that the level of KatX level in outgrowing spores depends mainly on EsigmaF, because sigB mutants show normal KatX activity in dormant and outgrowing spores. katX mutants also develop the non-specific resistance to oxidative stress that is typical of glucose-starved cells. Therefore, the physiological role of sigmaB-dependent katX expression remains obscure. The results indicate an overlap between the sigmaB regulon and the sigmaF regulon, and the physiological implications of this overlap are discussed.

Global analysis of the general stress response of Bacillus subtilis.

Gene arrays containing all currently known open reading frames of Bacillus subtilis were used to examine the general stress response of Bacillus. By proteomics, transcriptional analysis, transposon mutagenesis, and consensus promoter-based screening, 75 genes had previously been described as sigma(B)-dependent general stress genes. The present gene array-based analysis confirmed 62 of these already known general stress genes and detected 63 additional genes subject to control by the stress sigma factor sigma(B). At least 24 of these 125 sigma(B)-dependent genes seemed to be subject to a second, sigma(B)-independent stress induction mechanism. Therefore, this transcriptional profiling revealed almost four times as many regulon members as the proteomic approach, but failure of confirmation of all known members of the sigma(B) regulon indicates that even this approach has not yet elucidated the entire regulon. Most of the sigma(B)-dependent general stress proteins are probably located in the cytoplasm, but 25 contain at least one membrane-spanning domain, and at least 6 proteins appear to be secreted. The functions of most of the newly described genes are still unknown. However, their classification as sigma(B)-dependent stress genes argues that their products most likely perform functions in stress management and help to provide the nongrowing cell with multiple stress resistance. A comprehensive screening program analyzing the multiple stress resistance of mutants with mutations in single stress genes is in progress. The first results of this program, showing the diminished salt resistance of yjbC and yjbD mutants compared to that of the wild type, are presented. Only a few new sigma(B)-dependent proteins with already known functions were found, among them SodA, encoding a superoxide dismutase. In addition to analysis of the sigma(B)-dependent general stress regulon, a comprehensive list of genes induced by heat, salt, or ethanol stress in a sigma(B)-independent manner is presented. Perhaps the most interesting of the sigma(B)-independent stress phenomena was the induction of the extracytoplasmic function sigma factor sigma(W) and its entire regulon by salt shock.

Identification of sigma(B)-dependent genes in Bacillus subtilis using a promoter consensus-directed search and oligonucleotide hybridization.

A consensus-directed search for sigma(B) promoters was used to locate potential candidates for new sigma(B)-dependent genes in Bacillus subtilis. Screening of those candidates by oligonucleotide hybridizations with total RNA from exponentially growing or ethanol-stressed cells of the wild type as well as a sigB mutant revealed 22 genes that required sigma(B) for induction by ethanol. Although almost 50% of the proteins encoded by the newly discovered sigma(B)-dependent stress genes seem to be membrane localized, biochemical functions have so far not been defined for any of the gene products. Allocation of the genes to the sigma(B)-dependent stress regulon may indicate a potential function in the establishment of a multiple stress resistance. AldY and YhdF show similarities to NAD(P)-dependent dehydrogenases and YdbP to thioredoxins, supporting our suggestion that sigma(B)-dependent proteins may be involved in the maintenance of the intracellular redox balance after stress.