Author for correspondence: C. J. Ingham. Tel: +44 20 7589 5111. Fax: +44 20 7584 2056. e-mail: c.ingham@ic.ac.uk
aPresent ddress: Deprtment of Biology, Imperil College of Science nd Technology, Sir Alexnder Fleming Building, Imperil College Rod, London SW7 2AZ, UK.
Mutations conferring resistance to the antibiotic rifampicin (Rifr) occur at specific sites within the β subunit of the prokaryotic RNA polymerase. Rifr mutants of Escherichia coli are frequently altered in the elongation and termination of transcription. RifrrpoB mutations were isolated in Bacillus subtilis and their effects on transcription elongation factor NusG and Rho-dependent termination were investigated. RNase protection assay, Northern analysis and the expression of nusG–lacZ fusions in cells with an inducible NusG suggested the B. subtilis nusG gene was autoregulated at the level of transcription. Rifr mutations that changed residue Q469 to a basic residue (Q469K and Q469R) enhanced autoregulation of nusG. A mutant expressing a truncated form of NusG, due to a nonsense mutation within the nusG gene, was isolated on the basis of the loss of autoregulation. The mechanism of autoregulation was found to be independent both of transcription termination factor Rho and of the promoter transcribing nusG. Autoregulation required sequences within the 5′ coding sequence of the nusG gene or immediately upstream. This is the first evidence from any bacterium that Rifr RNA polymerases can display altered transcription regulation by NusG.
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