Active efflux of antimicrobial substances is likely to be an important bacterial defense against inhibitory host factors inherent to different body sites. Two well-characterized multidrug resistance efflux systems (MtrCDE and FarAB-MtrE) exist in Neisseria gonorrhoeae, a bacterial pathogen of the human genital mucosae. In vitro studies suggest that the MtrCDE and FarAB-MtrE efflux systems protect the gonococcus from hydrophobic antimicrobial substances that are likely to be present on mucosal surfaces. Here we report that a functional MtrCDE efflux system, but not a functional FarAB-MtrE system, enhances experimental gonococcal genital tract infection in female mice. Specifically, the recovery of mtrD and mtrE mutants, but not a farB mutant, from mice inoculated with mutant or wild-type gonococci was reduced compared with that of the wild-type strain. Competitive-infection experiments confirmed the survival disadvantage of MtrCDE-deficient gonococci. This report is the first direct evidence that a multidrug resistance efflux system enhances survival of a bacterial pathogen in the genital tract. Additionally, experiments using ovariectomized mice showed that MtrCDEdeficient gonococci were more rapidly cleared from mice that were capable of secreting gonadal hormones. MtrCDE-deficient gonococci were more sensitive to nonphysiological concentrations of progesterone in vitro than were wild-type or FarAB-MtrE-deficient gonococci. These results suggest that progesterone may play an inhibitory role in vivo. However, hormonally regulated factors rather than progesterone itself may be responsible for the more rapid clearance of mtr-deficient gonococci from intact mice.Bacterial colonization of mucosal surfaces is challenged by components of the host innate immune response, including hydrophobic, membrane-damaging compounds such as bile salts, fatty acids, and antibacterial peptides. Gram-negative bacteria have evolved elaborate active efflux systems, which together with the low permeability of the outer membrane confer inherent resistance to these antimicrobial substances. One class of active efflux systems, the multidrug resistance pumps, is remarkable in the capacity to recognize structurally dissimilar substrates, including diverse antibiotics (34,35). Two such systems, namely, the mtrCDE-encoded (6, 12, 13, 36) and farAB-encoded (22) efflux systems, have been well characterized in Neisseria gonorrhoeae. Like other multidrug resistance pumps, the mtrCDE-and farAB-encoded efflux systems are composed of three components that function together to capture the substrate in the inner membrane and transport it through the periplasm and out to the external milieu via an outer membrane pore (34,49). A third efflux system that utilizes a transporter homologous to NorM of Vibrio parahaemolyticus was recently identified in N. gonorrhoeae and Neisseria meningitidis (37).The gonococcal MtrCDE ("mtr" stands for multiple transferable resistance) system is encoded by an operon consisting of three genes, mtrC, mtrD, and mtrE (11), and ...
