Tetracycline regulation of genes on Bacteroides conjugative transposons

Abstract

Human colonic Bacteroides species harbor a family of large conjugative transposons, called tetracycline resistance (Tcr) elements. Activities of these elements are enhanced by pregrowth of bacteria in medium containing tetracycline, indicating that at least some Tcr element genes are regulated by tetracycline. Previously, we identified a central regulatory locus on the Tcr elements that contained two genes, rteA and rteB, which appeared to encode a two-component regulatory system (A. M. Stevens, J. M. Sanders, N. B. Shoemaker, and A. A. Salyers, J. Bacteriol. 174:2935-2942, 1992). In the present study, we describe a gene which is located downstream of rteB in a separate transcriptional unit and which requires RteB for expression. Sequence analysis of this gene showed that it encoded a 217-amino-acid protein, which had no significant sequence similarity to any proteins in the GenBank or EMBL data base. An insertional disruption in the gene abolished self-transfer of the Tcr element to Bacteroides recipients, indicating that the gene was essential for self-transfer. The disruption also affected mobilization of coresident plasmids. Mobilization frequency was reduced 100- to 1,000-fold if the recipient was Escherichia coli but was not affected to the same extent if the recipient was an isogenic Bacteroides strain. The complex phenotype of the disruption mutant suggested that the newly identified gene, like rteA and rteB, had a regulatory function. Accordingly, it has been designated rteC. Our results indicate that regulation of Tc(r) element functions is unexpectedly complex and may involve a cascade of regulators, with RteA and RteB exerting central control over secondary regulators like RteC, which in turn control subsets of Tcr element structural genes.