SwrA extends DegU over an UP element to activate flagellar gene expression in .

UNLABELLED

SwrA activates flagellar gene expression in to increase the frequency of motile cells in liquid and elevate flagellar density to enable swarming over solid surfaces. Here we use ChIP-seq to show that SwrA interacts with many sites on the chromosome in a manner that depends on the response regulator DegU. We identify a DegU-specific inverted repeat DNA sequence and show that SwrA synergizes with phosphorylation to increase DegU DNA binding affinity. We further show that SwrA increases the size of the DegU footprint expanding the region bound by DegU towards the promoter. The location of the DegU inverted repeat was critical and moving the binding site closer to the promoter impaired transcription more that could be explained by deactivation. We conclude that SwrA/DegU forms a heteromeric complex that enables both remote binding and interaction between the activator and RNA polymerase in the context of an interceding UP element. We speculate that multimeric activators that resolve cis-element spatial conflicts are common in bacteria and likely act on flagellar biosynthesis loci and other long operons of other multi-subunit complexes.

IMPORTANCE

In Bacteria, the sigma subunit of RNA polymerase recognizes specific DNA sequences called promoters that determine where gene transcription begins. Some promoters also have sequences immediately upstream called an UP element that is bound by the alpha subunit of RNA polymerase and is often necessary for transcription. Finally, promoters may be activated by transcription factors that bind DNA specific sequences and help recruit RNA polymerase to weak promoter elements. Here we show that the promoter for the 32 gene long flagellar operon in requires an UP element and is activated by a heteromeric transcription factor of DegU and SwrA. Our evidence suggests that SwrA oligomerizes DegU over the DNA to allow RNA polymerase to interact with DegU and the UP element simultaneously. Heteromeric activator complexes are known but poorly-understood in bacteria and we speculate they may be needed to resolve spatial conflicts in the DNA sequence.