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. 1997 Aug;179(15):4676–4683. doi: 10.1128/jb.179.15.4676-4683.1997

Identification and characterization of an operon of Helicobacter pylori that is involved in motility and stress adaptation.

D Beier 1, G Spohn 1, R Rappuoli 1, V Scarlato 1
PMCID: PMC179311  PMID: 9244252

Abstract

We identified a novel stress-responsive operon (sro) of Helicobacter pylori that contains seven genes which are likely to be involved in cellular functions as diverse as chemotaxis, heat shock response, ion transport, and posttranslational protein modification. The products of three of these genes show amino acid homologies to known proteins, such as the flagellar motor switch protein CheY, a class of heat shock proteins, and the ribosomal protein L11 methyltransferase, and to a phosphatidyltransferase. In addition to containing an open reading frame of unknown function, the product of which is predicted to be membrane associated, the sro locus contains three open reading frames that have previously been described as constituting two separate loci, the ftsH gene and the copAP operon of H. pylori. Knockout mutants showed that CheY is essential for bacterial motility and that CopA, but not CopP, relieves copper toxicity. Transcriptional analyses indicated that this locus is regulated by a single promoter and that a positive effect on transcription is exerted by the addition of copper to the medium and by temperature upshift from 37 to 45 degrees C. The possible role of this locus in H. pylori virulence is discussed.

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Selected References

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