Phenotypic Switching in Mycoplasma Gallisepticum Hemadsorption is Governed by a High-frequency, Reversible Point Mutation

Overview

Journal Infect Immun

Publisher American Society for Microbiology

Specialty Allergy & Immunology

Date 2003 Feb 22

PMID 12595441

Citations 14

Authors

Florian Winner

Ivana Markova

Peter Much

Albin Lugmair

Karin Siebert-Gulle

Gunther Vogl

Renate Rosengarten

Christine Citti

Affiliations

Soon will be listed here.

Abstract

Mycoplasma gallisepticum is a flask-shaped organism that commonly induces chronic respiratory disease in chickens and infectious sinusitis in turkeys. Phenotypic switching in M. gallisepticum hemadsorption (HA) was found to correlate with phase variation of the GapA cytadhesin concurrently with that of the CrmA protein, which exhibits cytadhesin-related features and is encoded by a gene located downstream of the gapA gene as part of the same transcription unit. In clones derived from strain R(low), detailed genetic analyses further revealed that on-off switching in GapA expression is governed by a reversible base substitution occurring at the beginning of the gapA structural gene. In HA(-) variants, this event generates a stop codon that results in the premature termination of GapA translation and consequently affects the expression of CrmA. Sequences flanking the mutation spot do not feature any repeated motifs that could account for error-prone mutation via DNA slippage and the exact mechanism underlying this high-frequency mutational event remains to be elucidated. An HA(-) mutant deficient in producing CrmA, mHAD3, was obtained by disrupting the crmA gene by using transposition mutagenesis. Despite a fully functional gapA gene, the amount of GapA detected in this mutant was considerably lower than in HA(+) clonal variants, suggesting that, in absence of CrmA, GapA might be subjected to a higher turnover.

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