Previous studies have shown that the CcpA protein of Bacillus subtilis is a major transcription factor mediating catabolite repression. We report here whole-transcriptome analyses that characterize CcpA-dependent, glucose-dependent gene expression and correlate the results with full-genome computer analyses of DNA binding (CRE) sites for CcpA. The data obtained using traditional approaches show good agreement with those obtained using the transcriptome approach. About 10% of all genes in B. subtilis are regulated > 3x by glucose, with repressed genes outnumbering activated genes three to one. Eighty per cent of these genes depend on CcpA for regulation. Classical approaches have provided only evidence for CcpA-mediated, glucose-dependent activation or repression. We show here that CcpA also mediates glucose-independent activation or repression, and that glucose may alter either the direction or the intensity of either effect. Computer analyses revealed the presence of CRE sites in most operons subject to CcpA-mediated glucose repression, but not in those subject to glucose activation, suggesting that either secondary transcription factors regulate the latter genes or activation by CcpA involves a dissimilar binding site. Operons encoding the constituents of ABC-type transporters that are subject to CcpA-mediated glucose regulation show two distinct patterns: either all genes in the operon are regulated in parallel (the minor class) or the gene encoding the extracytoplasmic solute-binding receptor is preferentially regulated (the major class). Genes subject to CcpA-independent catabolite repression are primarily concerned with sporulation. Several transcription factors were identified that are themselves regulated by CcpA at the transcriptional level. Representative data with functionally characterized genes are presented to illustrate the novel findings. The comprehensive transcriptome data are available on our website: www.biology.uesd.edu/~MSAIER/regulation/ and also on http://www.blackwell-science.com/ products/journals/suppmat/MMI/MMI2328/MMI2328sm.htm
Salmonella typhimurium responds to a variety of environmental stresses by accumulating the alternative sigma factor σS. The repertoire of σS ‐dependent genes that are subsequently expressed confers tolerance to a variety of potentially lethal conditions including low pH and stationary phase. The mechanism(s) responsible for triggering σS accumulation are of considerable interest, because they help to ensure survival of the organism during encounters with suboptimal environments. Two genes associated with regulating σS levels in S. typhimurium have been identified. The first is clpP, encoding the protease known to be responsible for degrading σS in Escherichia coli. The second is dksA, encoding a protein of unknown function not previously associated with regulating σS levels. As predicted, clpP mutants accumulated large amounts of σS even in log phase. However, dksA mutants failed to accumulate σS in stationary phase and exhibited lower accumulation during acid shock in log phase. DksA appears to be required for the optimal translation of rpoS based upon dksA mutant effects on rpoS transcriptional and translational lacZ fusions. The region of rpoS mRNA between codons 8 and 73 is required to see the effects of dksA mutations. This distinguishes the role of DksA from that of HF‐I (hfq ) in rpoS translation, as the HF‐I target area occurs well upstream of the rpoS start codon. DksA appears to be involved in the expression of several genes in addition to rpoS based on two‐dimensional SDS–PAGE analysis of whole‐cell proteins. As a result of their effects on gene expression, mutations in clpP and dksA decreased the virulence of S. typhimurium in mice, consistent with a role for σS in pathogenesis.
The phs chromosomal locus of Salmonella typhimurium is essential for the dissimilatory anaerobic reduction of thiosulfate to hydrogen sulfide. Sequence analysis of the phs region revealed a functional operon with three open reading frames, designated phsA, phsB, and phsC, which encode peptides of 82.7, 21.3, and 28.5 kDa, respectively. The predicted products of phsA and phsB exhibited significant homology with the catalytic and electron transfer subunits of several other anaerobic molybdoprotein oxidoreductases, including Escherichia coli dimethyl sulfoxide reductase, nitrate reductase, and formate dehydrogenase. Simultaneous comparison of PhsA to seven homologous molybdoproteins revealed numerous similarities among all eight throughout the entire frame, hence, significant amino acid conservation among molybdoprotein oxidoreductases. Comparison of PhsB to six other homologous sequences revealed four highly conserved iron-sulfur clusters. The predicted phsC product was highly hydrophobic and similar in size to the hydrophobic subunits of the molybdoprotein oxidoreductases containing subunits homologous to phsA and phsB. Thus, phsABC appears to encode thiosulfate reductase. Single-copy phs-lac translational fusions required both anaerobiosis and thiosulfate for full expression, whereas multicopy phs-lac translational fusions responded to either thiosulfate or anaerobiosis, suggesting that oxygen and thiosulfate control of phs involves negative regulation. A possible role for thiosulfate reduction in anaerobic respiration was examined. Thiosulfate did not significantly augment the final densities of anaerobic cultures grown on any of the 18 carbon sources tested. On the other hand, washed stationary-phase cells depleted of ATP were shown to synthesize small amounts of ATP on the addition of formate and thiosulfate, suggesting that thiosulfate reduction plays a unique role in anaerobic energy conservation by S. typhimurium.
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