The mtr (multiple transferable resistance) system of Neisseria gonorrhoeae determines levels of gonococcal resistance to hydrophobic agents (HAS), including detergent-like fatty acids and bile salts that bathe certain mucosal surfaces. The genetic organization of the mtr system was determined and found t o consist of the mtrR gene, which encodes a transcriptional regulator (MtrR), and three tandemly linked genes termed mtrCD€. The mtrCD€ genes were organized in the same apparent transcriptional unit, upstream and divergent from the mtrR gene. The mtKD€-encoded proteins of N. gonorrhoeae were analogous to a family of bacterial eff luxhransport proteins, notably the MexABOprK proteins of Pseudomonas aenrginosa and the AcrAE and EnvCD proteins of Escherichia coli, that mediate resistance to drugs, dyes, and detergents. Inactivation of the mtrC gene resulted in loss of the MtrC lipoprotein and rendered gonococci hypersusceptible to structurally diverse HAS; this revealed the importance of the mtr system in determining HAR in gonococci. Further support for a role of the mtrCD€ gene complex in determining levels of HAR in gonococci was evident when transformants bearing mutations in the mtrR gene were analysed. In this respect, missense and null mutations in the mtrR gene were found to result in increased levels of MtrC and HAR. However, high levels of MtrC and HAR, similar to those observed for clinical isolates, were associated with a single bp deletion in a 13 bp inverted repeat sequence that intervened the divergent mtrR and mtrC genes. We propose that the 13 bp inverted-repeat sequence represents a transcriptional control element that regulates expression of the mtrRCDE gene complex, thereby modulating levels of gonococcal susceptibility to HAS.
Gonococcal resistance to antimicrobial hydrophobic agents (HAs) is due to energy-dependent removal ofHAs from the bacterial cell by the MtrCDE membrane-associated efflux pump. The mtrR (multiple transferrable resistance Regulator) gene encodes a putative transcriptional repressor protein (MtrR) believed to be responsible for regulation of mtrCDE gene expression. Gel mobility shift and DNase I footprint assays that used a maltose-binding protein (MBP)-MtrR fusion protein demonstrated that the MtrR repressor is capable of specifically binding the DNA sequence between the mtrR and mtrC genes. This binding site was localized to a 26-nucleotide stretch that includes the promoter utilized for mtrCDE transcription and, on the complementary strand, a 22-nucleotide stretch that contains the ؊35 region of the mtrR promoter. A single transition mutation (A3G) within the MtrR-binding site decreased the affinity of the target DNA for MtrR and enhanced gonococcal resistance to HAs when introduced into HA-susceptible strain FA19 by transformation. Since this mutation enhanced expression of the mtrCDE gene complex but decreased expression of the mtrR gene, the data are consistent with the notion that MtrR acts as a transcriptional repressor of the mtrCDE efflux pump protein genes.Resistance of Neisseria gonorrhoeae to structurally diverse hydrophobic agents (HAs) has been the subject of several recent investigations (5,6,10,20,23). Although earlier studies indicated that the mtr (multiple transferrable resistance) locus modifies the permeability barrier of the gonococcal cell envelope (3,4,13,16,22,24), more recent studies revealed that mtr encodes an energy-dependent efflux system (5,6,10,20,23). The membrane proteins (MtrC, MtrD, and MtrE) forming the efflux pump share considerable amino acid sequence similarity with other efflux proteins in Escherichia coli (12,17) and Pseudomonas aeruginosa (21). Active removal of toxic compounds by bacteria is an important mechanism of multiple antibiotic resistance (8, 17) and may confer a selective advantage on organisms, such as gonococci, when they colonize mucosal sites bathed in fluids containing antibacterial fatty acids and bile salts or encounter other environmental stresses (8,11,12,(16)(17)(18)23).Production of the MtrCDE efflux proteins is controlled at the level of transcription by both cis-and trans-acting factors involving the mtrR gene (5,6,20,23). The mtrR gene is located 250 bp upstream of the mtrCDE gene complex and transcribed divergently (5,6,20). It encodes a 210-amino-acid protein with a molecular mass of approximately 23 kDa that contains a putative helix-turn-helix motif near its N terminus (5,20,23). MtrR has considerable amino acid sequence similarities to several transcriptional repressors, most notably, the tetracycline repressor of pSC101 (1,7,20). Recent investigations have revealed that missense or deletion mutations within the mtrR coding region result in enhanced mtrCDE transcription and gonococcal resistance to HAs (6, 23). Thus, the available genetic dat...
The mfr (multiple transferable resistance) system of Neisseria gonorrhoeae mediates resistance of gonococci to structurally diverse hydrophobic agents (HAS) through an energy-dependent efflux process. Recently, complete or partial ORFs that encode membrane proteins (MtrG MtrD, MtrE) forming an efflux pump responsible for removal of HAS from gonococci were identified and appeared to constitute a single transcriptional unit. In this study, the complete nucleotide sequence of the mtrD gene was determined, permitting the characterization of the MtrD protein. The full-length MtrD protein has a predicted molecular mass of nearly 114 kDa, putatively containing a 56 amino acid signal peptide. MtrD displays significant amino acid sequence similarity to a f am i I y of cytoplasmic membrane proteins, termed resistancehodu lat ion/ division (RND) proteins, which function as energy-dependent transporters of antibacterial agents and secrete bacterial products to the extracellular fluid. The predicted topology of the MtrD transporter protein revealed 12 potential membrane-spanning domains, which were clustered within the central and Cterminal regions of the primary sequence. Loss of MtrD due to insertional inactivation of the mtrD gene rendered gonococci hypersusceptible to several structurally diverse HAS, including two fatty acids (capric acid and palmitic acid) and a bile salt (cholic acid), but not hydrophilic antibiotics such as ciprof loxacin and streptomycin. Since gonococci often infect mucosal sites rich in toxic fatty acids and bile salts, the expression of the mtr efflux system may promote growth of gonococci under hostile conditions encountered in vivo.
The capacity of Neisseria gonorrhoeae to cause disseminated gonococcal infection requires that such strains resist the bactericidal action of normal human serum. The bactericidal action of normal human serum against N. gonorrhoeae is mediated by the classical complement pathway through an antibody-dependent mechanism. The mechanism(s) by which certain strains of gonococci resist normal human serum is not fully understood, but alterations in lipooligosaccharide structure can affect such resistance. During an investigation of the biological significance of phosphoethanolamine extensions from lipooligosaccharide, we found that phosphoethanolamine substitutions from the heptose II group of the lipooligosaccharide -chain did not impact levels of gonococcal (strain FA19) resistance to normal human serum or polymyxin B. However, loss of phosphoethanolamine substitution from the lipid A component of lipooligosaccharide, due to insertional inactivation of lptA, resulted in increased gonococcal susceptibility to polymyxin B, as reported previously for Neisseria meningitidis. In contrast to previous reports with N. meningitidis, loss of phosphoethanolamine attached to lipid A rendered strain FA19 susceptible to complement killing. Serum killing of the lptA mutant occurred through the classical complement pathway. Both serum and polymyxin B resistance as well as phosphoethanolamine decoration of lipid A were restored in the lptA-null mutant by complementation with wild-type lptA. Our results support a role for lipid A phosphoethanolamine substitutions in resistance of this strict human pathogen to innate host defenses.
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