TheS subunit of RNA polymerase (encoded by the rpoS gene) is the master regulator in a complex regulatory network that controls stationary-phase induction and osmotic regulation of many genes in Escherichia coli. Here we demonstrate that the histone-like protein H-NS is also a component of this network, in which it functions as a global inhibitor of gene expression during the exponential phase of growth. On two-dimensional gels, at least 22 S -controlled proteins show increased expression in an hns mutant. H-NS also inhibits the expression of S itself by a mechanism that acts at the posttranscriptional level. Our results indicate that relief of repression by H-NS plays a role in stationary-phase induction as well as in hyperosmotic induction of rpoS translation. Whereas certain S -dependent genes (e.g., osmY) are only indirectly regulated by H-NS via its role in the control of S expression, others are also H-NS-regulated in a S -independent manner. (For this latter class of genes, rpoS hns double mutants show higher levels of expression than mutants deficient in rpoS alone.) In addition, we demonstrate that the slow-growth phenotype of hns mutants is suppressed in hns rpoS double mutants and that many second-site suppressor mutants that spontaneously arise from hns strains carry lesions that affect the expression of S . TheS subunit of RNA polymerase acts as a master regulator in a regulatory network that controls the expression of numerous stationary-phase-induced and osmotically regulated genes in Escherichia coli (11,12,15). rpoS, the structural gene for S , is itself induced during entry into the stationary phase (22,23,25,30,34,39) and in response to an increase in medium osmolarity (23). Under both conditions, control of the cellular S level is largely posttranscriptional, involving stimulation of translation (23, 30) as well as changes in S stability (23,43). So far, more than 30 genes or operons that are under direct or indirect control of S have been identified. Within this large S regulon, differential regulation has been observed for subsets of genes, for instance in response to anaerobiosis (3, 5, 6) or oxidative stress (1, 26). In addition, during entry into the stationary phase, the induction of various S -dependent genes follows different kinetics. These observations indicate that additional factors besides S participate in the fine regulation of these genes. The cyclic AMP (cAMP)-cAMP receptor protein complex (13,20,21,29,47), integration host factor (1, 20), and Lrp (20) have been identified as modulating factors in the control of various S -dependent genes. The data presently available indicate that various combinations of regulatory factors that can act either positively or negatively are used for the control of various stationary-phaseinducible genes. This regulatory strategy results in a high degree of specific fine modulation of S -controlled genes with respect to the time of induction during entry into the stationary phase and in response to additional environmental parameters.In the prese...
The cellular level of the rpoS-encoded sigmaS subunit of RNA polymerase increases in response to various stress situations that include starvation, high osmolarity, and shift to acid pH, and these different stress signals differentially affect rpoS translation and/or sigmaS stability. Here we demonstrate that sigmaS is also induced by heat shock and that this induction is exclusively due to an interference with sigmaS turnover. Some sigmaS-dependent genes exhibit similar heat shock induction, whereas others are not induced probably because they need additional regulatory factors that might not be present under conditions of heat shock or exponential growth. Despite its induction, sigmaS does not seem to contribute to heat adaptation but may induce cross-protection against different stresses. While sigmaS is not involved in the regulation of the heat shock sigma factor sigma32, the heat shock protein DnaK has a positive role in the posttranscriptional control of sigmaS. The present evidence suggests that DnaK is involved in the transduction of two of the signals that result in reduced sigmaS turnover, i.e., heat shock and carbon starvation. Heat shock induction of sigmaS also clearly indicates that a cessation of growth or even a reduction of the growth rate is not a prerequisite for the induction of sigmaS and sigmaS-dependent genes and underscores the importance of sigmaS as a general stress sigma factor.
osmY (csi-5) is a representative of a large group of sigma s-dependent genes in Escherichia coli that exhibit both stationary-phase induction and osmotic regulation. A chromosomal transcriptional lacZ fusion (csi-5::lacZ) was used to study the regulation of osmY. We show here that in addition to sigma s, the global regulators Lrp, cyclic AMP (cAMP) receptor protein-cAMP complex (cAMP-CRP), and integration host factor (IHF) are involved in the control of osmY. All three regulators negatively modulate the expression of osmY, and they act independently from sigma s. Stationary-phase induction of osmY in minimal medium can be explained by stimulation by sigma s combined with a relief of Lrp repression. Stationary-phase induction of osmY in rich medium is mediated by the combined action of sigma s, Lrp, cAMP-CRP, and IHF, with the latter three proteins acting as transition state regulators. The transcriptional start site of osmY was determined and revealed an mRNA with an unusual long nontranslated leader of 244 nucleotides. The regulatory region is characterized by a sigma 70-like -10 promoter region and contains potential binding sites for Lrp, CRP, and IHF. Whereas sigma s, Lrp, CRP, and IHF are clearly involved in stationary-phase induction, none of these regulators is essential for osmotic regulation of osmY.
osmY is a stationary phase-induced and osmotically regulated gene in Escherichia coli that requires the stationary phase RNA polymerase (Esigma(S)) for in vivo expression. We show here that the major RNA polymerase, Esigma(70), also transcribes osmY in vitro and, depending on genetic background, even in vivo. The cAMP receptor protein (CRP) bound to cAMP, the leucine-responsive regulatory protein (Lrp) and the integration host factor (IHF) inhibit transcription initiation at the osmY promoter. The binding site for CRP is centred at -12.5 from the transcription start site, whereas Lrp covers the whole promoter region. The site for IHF maps in the -90 region. By mobility shift assay, permanganate reactivity and in vitro transcription experiments, we show that repression is much stronger with Esigma(70) than with Esigma(S) holoenzyme. We conclude that CRP, Lrp and IHF inhibit open complex formation more efficiently with Esigma(70) than with Esigma(S). This different ability of the two holoenzymes to interact productively with promoters once assembled in complex nucleoprotein structures may be a crucial factor in generating sigma(S) selectivity in vivo.
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