The molecular basis of selective promoter activation by the sigmaS subunit of RNA polymerase

Different environmental stimuli cause bacteria to exchange the sigma subunit in the RNA polymerase (RNAP) and, thereby, tune their gene expression according to the newly emerging needs. Sigma factors are usually thought to recognize clearly distinguishable promoter DNA determinants, and thereby activate distinct gene sets, known as their regulons. In this review, we illustrate how the principle sigma factor in stationary phase and in stressful conditions in Escherichia coli, sigmaS (RpoS), can specifically target its large regulon in vivo, although it is known to recognize the same core promoter elements in vitro as the housekeeping sigma factor, sigma70 (RpoD). Variable combinations of cis-acting promoter features and trans-acting protein factors determine whether a promoter is recognized by RNAP containing sigmaS or sigma70, or by both holoenzymes. How these promoter features impose sigmaS selectivity is further discussed. Moreover, additional pathways allow sigmaS to compete more efficiently than sigma70 for limiting amounts of core RNAP (E) and thereby enhance EsigmaS formation and effectiveness. Finally, these topics are discussed in the context of sigma factor evolution and the benefits a cell gains from retaining competing and closely related sigma factors with overlapping sets of target genes.     

The response regulator RssB, a recognition factor for sigmaS proteolysis in Escherichia coli, can act like an anti-sigmaS factor

sigmaS (RpoS) is the master regulator of the general stress response in Escherichia coli. Several stresses increase cellular sigmaS levels by inhibiting proteolysis of sigmaS, which under non-stress conditions is a highly unstable protein. For this ClpXP-dependent degradation, the response regulator RssB acts as a recognition factor, with RssB affinity for sigmaS being modulated by phosphorylation. Here, we demonstrate that RssB can also act like an anti-sigma factor for sigmaS in vivo, i.e. RssB can inhibit the expression of sigmaS-dependent genes in the presence of high sigmaS levels. This becomes apparent when (i) the cellular RssB/sigmaS ratio is at least somewhat elevated and (ii) proteolysis is reduced (for example in stationary phase) or eliminated (for example in a clpP mutant). Two modes of inhibition of sigmaS by RssB can be distinguished. The 'catalytic' mode is observed in stationary phase cells with a substoichiometric RssB/sigmaS ratio, requires ClpP and therefore probably corresponds to sequestering of sigmaS to Clp protease (even though sigmaS is not degraded). The 'stoichiometric' mode occurs in clpP mutant cells upon overproduction of RssB to levels that are equal to those of sigmaS, and therefore probably involves binary complex formation between RssB and sigmaS. We also show that, under standard laboratory conditions, the cellular level of RssB is more than 20-fold lower than that of sigmaS and is not significantly controlled by stresses that upregulate sigmaS. We therefore propose that antisigma factor activity of RssB may play a role under not yet identified growth conditions (which may result in RssB induction), or that RssB is a former antisigma factor that during evolution was recruited to serve as a recognition factor for proteolysis.     

Identification and classification of two-component systems that affect rpoS expression in Escherichia coli

The rpoS-encoded sigmaS subunit of RNA polymerase regulates the expression of stationary phase and stress response genes in Escherichia coli. Recent study of our DNA microarray analysis suggested that the rpoS expression is affected by multiple two-component systems. In this study, we identified two-component-system mutants in which the rpoS expression increased. The regulatory manner of the systems on rpoS expression is suggested.     

Role of the response regulator RssB in σS recognition and initiation of σS proteolysis in Escherichia coli

In growing Escherichia coli cells, the master regulator of the general stress response, sigmaS (RpoS), is subject to rapid proteolysis. In response to stresses such as sudden carbon starvation, osmotic upshift or shift to acidic pH, sigmaS degradation is inhibited, sigmaS accumulates and numerous sigmaS-dependent genes with stress-protective functions are activated. sigmaS proteolysis is dependent on ClpXP protease and the response regulator RssB, whose phosphorylated form binds directly to sigmaS in vitro. Here, we show that substitutions of aspartate 58 (D58) in RssB, which result in higher sigmaS levels in vivo, produce RssB variants unable to bind sigmaS in vitro. Thus, RssB is the direct substrate recognition factor in sigmaS proteolysis, whose affinity for sigmaS depends on phosphorylation of its D58 residue. RssB does not dimerize or oligomerize upon this phosphorylation and sigmaS binding, and RssB and sigmaS exhibit a 1:1 stoichiometry in the complex. The receiver as well as the output domain of RssB are required for sigmaS binding (as shown in vivo and in vitro) and for complementation of an rssB null mutation. Thus, the N-terminal receiver domain plays an active and positive role in RssB function. Finally, we demonstrate that RssB is not co-degraded with sigmaS, i.e. RssB has a catalytic role in the initiation of sigmaS turnover. A model is presented that integrates the details of RssB-sigmaS interaction, the RssB catalytic cycle and potential stress signal input in the control of sigmaS proteolysis.     

The RNA-binding protein HF-I plays a global regulatory role which is largely, but not exclusively, due to its role in expression of the sigmaS subunit of RNA polymerase in Escherichia coli.

The hfq-encoded RNA-binding protein HF-I has long been known as a host factor for phage Qbeta RNA replication and has recently been shown to be essential for translation of rpoS, which encodes the sigmaS subunit of RNA polymerase. Here we demonstrate that an hfq null mutant does not synthesize glycogen, is starvation and multiple stress sensitive, and exhibits strongly reduced expression of representative sigmaS-regulated genes. These phenotypes are consistent with strongly reduced sigmaS levels in the hfq mutant. However, the analysis of global protein synthesis patterns on two-dimensional O'Farrell gels indicates that approximately 40% of the more than 30 proteins whose syntheses are altered in the hfq null mutant are not affected by an rpoS mutation. We conclude that HF-I is a global regulator involved in the regulation of expression of sigmaS and sigmaS-independent genes.