Abstract
The phytopathogenic enterobacterium Erwinia chrysanthemi 3937 produces five major and several secondary endo-pectate lyases encoded by the pel genes. Most of these genes are arranged in clusters on the bacterial chromosome. The genomic region surrounding the pelB-pelC cluster was supposed to be involved in the regulation of PelB and PelC synthesis. We demonstrated that the variation of pelB expression resulted from the titration of a regulatory protein by the gene adjacent to pelC. This gene was renamed pelZ since it encodes a protein of 420 amino acids with an endo-pectate lyase activity. Regulation of pelZ expression was investigated by using transcriptional fusions and a study of mRNA synthesis. Its transcription depends on different environmental conditions. It is induced in planta and in the presence of pectic catabolite products. This induction seems to be partially mediated by the KdgR protein but does not result from a direct interaction of KdgR with the pelZ 5' region. The transcription of pelZ leads to the synthesis of a monocistronic mRNA. However, the synthesis of a polycistronic mRNA from the pelC promoter, regulated by KdgR, is responsible for increased production of PelZ under inducing conditions. pelZ transcription is also controlled by pecT, which regulates some other pel genes, but it is independent of the pecS regulatory locus. The pelZ gene appears to be widespread in different strains of E. chrysanthemi. Moreover, a gene homologous to pelZ exists in Erwinia carotovora subsp. atroseptica adjacent to the cluster containing the pectate lyase-encoding genes pel1, pel2, and pel3. This conservation could reflect a significant role of PelZ in the pectinolytic system of Erwiniae. We showed pelZ is not a predominant virulence factor of E. chrysanthemi but is involved in host specificity.
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