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.     

Study of the Interaction between Bacteriophage T4 asiA and Escherichia coli ς70, Using the Yeast Two-Hybrid System: Neutralization of asiA Toxicity to E. coli Cells by Coexpression of a Truncated ς70 Fragment

The interaction of T4 phage-encoded anti-sigma factor, asiA, and Escherichia coli sigma(70) was studied by using the yeast two-hybrid system. Truncation of sigma(70) to identify the minimum region involved in the interaction showed that the fragment containing amino acid residues proximal to the C terminus (residues 547 to 603) was sufficient for complexing to asiA. Studies also indicated that some of the truncated C-terminal fragments (residues 493 to 613) had higher affinity for asiA as judged by the increased beta-galactosidase activity. It is proposed that the observed higher affinity may be due to the unmasking of the binding region of asiA on the sigma protein. Advantage was taken of the increased affinity of truncated sigma(70) fragments to asiA in designing a coexpression system wherein the toxicity of asiA expression in E. coli could be neutralized and the complex of truncated sigma(70) and asiA could be expressed in large quantities and purified.