ABSTRACT
Pseudomonas aeruginosa shows multidrug resistance, which is mainly attributable to its expression of xenobiotic efflux pumps. However, it is unclear how silent pumps are expressed in clinical isolates. Here, we sequenced the complete genome of P. aeruginosa strain 8380, which was isolated from a human gut.
ABSTRACT
The NfxC-type mutant of Pseudomonas aeruginosa produces the MexEF-OprN efflux pump and down-regulates expression of the quorum-sensing-dependent efflux pump MexAB-OprM and production of virulence factors in the presence of an active transcriptional regulator, MexT. Consequently, these cells are resistant to chloramphenicol and hypersusceptible to ß-lactam antibiotics. An upper negative regulator, MexS, has been assumed to inactivate MexT in wild-type strains, hence shutting down production of the MexEF-OprN pump. This observation was, however, reported in only one clinical strain and not confirmed in well-characterized laboratory strains. Moreover, it is not known whether MexS is involved in the quorum-sensing-dependent regulation of virulence factor production. To assess these issues, a plasmid carrying wild-type mexS was introduced into three NfxC-type mutants from laboratory strains, which carry an impaired mexS and unimpaired mexT. Unexpectedly, all the transformants produced an increased amount of MexEF-OprN proteins. Three clinical NfxC strains were similarly transformed and although MexEF-OprN was undetectable in two of these strains, one produced an increased amount of these proteins, similar to the laboratory strains. These results were interpreted to mean that P. aeruginosa takes two separate routes in MexT-mediated regulation of mexEF-oprN expression: the MexS-bypassed pathway and MexS-mediated pathway. On the other hand, the transformants of both the laboratory and clinically derived NfxC-type cells produced increased amounts of MexAB-OprM and virulence factors, suggesting that production of these proteins occurs via the MexS-mediated pathway.
