Interactions between the Rhodobacter sphaeroides ECF sigma factor, sigma(E), and its anti-sigma factor, ChrR

Rhodobacter sphaeroides sigma(E) is a member of the extra cytoplasmic function sigma factor (ECF) family, whose members have been shown to regulate gene expression in response to a variety of signals. The functions of ECF family members are commonly regulated by a specific, reversible interaction with a cognate anti-sigma factor. In R.sphaeroides, sigma(E) activity is inhibited by ChrR, a member of a newly discovered family of zinc containing anti-sigma factors. We used gel filtration chromatography to gain insight into the mechanism by which ChrR inhibits sigma(E) activity. We found that formation of the sigma(E):ChrR complex inhibits the ability of sigma(E) to form a stable complex with core RNA polymerase. Since the sigma(E):ChrR complex inhibits the ability of the sigma factor to bind RNA polymerase, we sought to identify amino acid substitutions in sigma(E) that altered the sensitivity of this sigma factor to inhibition by ChrR. This analysis identified single amino acid changes in conserved region 2.1 of sigma(E) that either increased or decreased the sensitivity of sigma(E) for inhibition by ChrR. Many of the amino acid residues that alter the sensitivity of sigma(E) to ChrR are located within regions known to be important for interacting with core RNA polymerase in other members of the sigma(70) superfamily. Our results suggest a model where solvent-exposed residues with region 2.1 of sigma(E) interact with ChrR to sterically occlude this sigma factor from binding core RNA polymerase and to inhibit target gene expression.     

Regulation of mycothiol metabolism by sigma(R) and the thiol redox sensor anti-sigma factor RsrA

Mycothiol (MSH) is the major thiol in Actinobacteria and plays a role analogous to that of glutathione. The biosynthetic pathway has been established in mycobacteria and is initiated by the glycosyltransferase MshA. A key mycothiol-dependent detoxification pathway utilizes the amidase (Mca) to cleave mycothiol S-conjugates to produce GlcN-Ins and a mercapturic acid excreted from the cell. How expression of mycothiol genes is regulated in mycobacteria has been unclear so the report in this issue by Park and Roe showing that in Streptomyces coelicolor the redox controlled anti-sigma factor RsrA that binds the regulator sigma(R) controls key elements of mycothiol metabolism is a major advance. Conditions that deplete thiols are shown to induce directly expression of sigR, rsrA, mshA and mca, as well as the thioredoxin reductase-thioredoxin system, generating an autoregulatory cycle that persists until the thiol-depleting condition is alleviated. Evidence for indirect induction of mshB-D to support mycothiol biosynthesis is also presented. It was shown in vitro that mycothiol, like reduced thioredoxin and dithiothreitol, can reduce oxidized RsrA to activate its binding to sigma(R). These studies establish for the first time how mycothiol metabolism is regulated to cope with stress from thiol reactive toxins.     

PCR mutagenesis identifies a polymerase-binding sequence of sigma 54 that includes a sigma 70 homology region.

Sigma 54 is a minor bacterial sigma factor that is not a member of the sigma 70 family of proteins but binds the same core RNA polymerase. Previously, we identified a region of sigma 54 that is important for binding core polymerase. In this work, PCR mutagenesis was used to identify specific amino acids important for this binding. The results show that important residues are clustered most closely in a short sequence that was previously speculated to be potentially homologous to a sequence in sigma 70. The mutagenesis also identifies important residues in the flanking hydrophobic-acidic region of sigma 54, which is absent in sigma 70. Overall, the data indicate that sigma 54 binds core polymerase through a sequence homologous to that of sigma 70 but in addition uses unique motifs to modify this interaction.