Bacteriophage T4 MotA Activator and the β-Flap Tip of RNA Polymerase Target the Same Set of σ70 Carboxyl-terminal Residues

Sigma factors, the specificity subunits of RNA polymerase, are involved in interactions with promoter DNA, the core subunits of RNA polymerase, and transcription factors. The bacteriophage T4-encoded activator, MotA, is one such factor, which engages the C terminus of the Escherichia coli housekeeping sigma factor, σ70. MotA functions in concert with a phage-encoded co-activator, AsiA, as a molecular switch. This process, termed sigma appropriation, inhibits host transcription while activating transcription from a class of phage promoters. Previous work has demonstrated that MotA contacts the C terminus of σ70, H5, a region that is normally bound within RNA polymerase by its interaction with the β-flap tip. To identify the specific σ70 residues responsible for interacting with MotA and the β-flap tip, we generated single substitutions throughout the C terminus of σ70. We find that MotA targets H5 residues that are normally engaged by the β-flap. In two-hybrid assays, the interaction of σ70 with either the β-flap tip or MotA is impaired by alanine substitutions at residues Leu-607, Arg-608, Phe-610, Leu-611, and Asp-613. Transcription assays identify Phe-610 and Leu-611 as the key residues for MotA/AsiA-dependent transcription. Phe-610 is a crucial residue in the H5/β-flap tip interaction using promoter clearance assays with RNA polymerase alone. Our results show how the actions of small transcriptional factors on a defined local region of RNA polymerase can fundamentally change the specificity of polymerase. Background: Transcriptional activators interact with RNA polymerase to redefine gene expression. Results: A phage activator engages a region of the specificity factor of E. coli RNA polymerase, which is normally bound by another portion of RNA polymerase. Conclusion: Using an activator/co-activator system, the phage hijacks the host RNA polymerase. Significance: Small transcriptional factors acting on defined local regions of RNA polymerase can fundamentally change gene expression.