E Y Ng

Quinolone resistance mediated by norA: physiologic characterization and relationship to flqB, a quinolone resistance locus on the Staphylococcus aureus chromosome.

We identified a quinolone resistance locus, flqB, linked to transposon insertion omega 1108 and fus on the SmaI D fragment of the Staphylococcus aureus NCTC 8325 chromosome, the same fragment that contains the norA gene. S. aureus norA cloned from flqB and flqB+ strains in Escherichia coli differed only in a single nucleotide in the putative promoter region. There was no detectable change in the number of copies of norA on the chromosomes of flqB strains, but they had increased levels of norA transcripts. Cloned norA produced resistance to norfloxacin and other hydrophilic quinolones and reduced norfloxacin accumulation in intact cells that was energy dependent, suggesting active drug efflux as the mechanism of resistance. Drug efflux was studied by measurement of norfloxacin uptake into everted inner membrane vesicles prepared from norA-containing E. coli cells. Vesicles exhibited norfloxacin uptake after the addition of lactate or NADH, and this uptake was abolished by carbonyl cyanide m-chlorophenylhydrazone and nigericin but not valinomycin, indicating that it was linked to the pH gradient across the cell membrane. Norfloxacin uptake into vesicles was also saturable, with an apparent Km of 6 microM, a concentration between those that inhibit the growth of flqB and flqB+ S. aureus cells, indicating that drug uptake is mediated by a carrier with a high apparent affinity for norfloxacin. Ciprofloxacin and ofloxacin competitively inhibited norfloxacin uptake into vesicles. Reserpine, which inhibits the multidrug efflux mediated by the bmr gene of bacillus subtilis, which is similar to norA, abolished norfloxacin uptake into vesicles as well as the norfloxacin resistance of an flqB mutant, suggesting a potential means for circumventing quinolone resistance as a result of drug efflux in S. aureus. These findings indicate that the chromosomal flqB resistance locus is associated with increased levels of expression of norA and strongly suggest that the NorA protein itself functions as a drug transporter that is coupled to the proton gradient across the cell membrane. Images

Mechanisms of quinolone resistance in Escherichia coli: characterization of nfxB and cfxB, two mutant resistance loci decreasing norfloxacin accumulation.

Two genetic loci selected for norfloxacin (nfxB) and ciprofloxacin (cfxB) resistance were characterized. Both mutations have previously been shown to confer pleiotropic resistance to quinolones, chloramphenicol, and tetracycline and to decrease expression of porin outer-membrane protein OmpF. nfxB was shown to map at about 19 min and thus to be genetically distinct from ompF (21 min), and cfxB was shown to be very closely linked to marA (34 min). cfxB was dominant over cfxB+ in merodiploids, in contrast to other quinolone resistance mutations. The two loci appear to interact functionally, because nfxB was not expressed in the presence of marA::Tn5. Both nfxB and cfxB decreased the expression of ompF up to 50-fold at the posttranscriptional level as determined in strains containing ompF-lacZ operon and protein fusions. Both mutations also decreased norfloxacin accumulation in intact cells. This decrease in accumulation was abolished by energy inhibitors and by removal of the outer membrane. These findings, in conjunction with those of Cohen et al. (S. P. Cohen, D. C. Hooper, J. S. Wolfson, K. S. Souza, L. M. McMurry, and S. B. Levy, Antimicrob. Agents Chemother. 32:1187-1191, 1988), suggest a model for quinolone resistance by decreased permeation in which decreased diffusion through porin channels in the outer membrane interacts with a saturable drug efflux system at the inner membrane.

Genetics and regulation of outer membrane protein expression by quinolone resistance loci nfxB, nfxC, and cfxB.

Quinolone resistance mutations (cfxB1, marA1, and soxQ1) that reduce porin outer membrane protein OmpF map near 34 min on the Escherichia coli chromosome. Another such mutation, nfxC1, was found in strain KF131 (nfxB, 19 min). nfxC1 and cfxB1 mutants (selected with quinolones) differed slightly but reproducibly from marA1 (selected with tetracycline) and soxQ1 (selected with menadione) mutants in quinolone resistance and linkage to zdd2208::Tn10kan (33.7 min). For nfxB nfxC1 and cfxB1 mutants, as previously shown for marA mutants, resistance and reduced OmpF required the micF locus encoding an antisense RNA complementary to ompF mRNA and were associated with increased micF expression. Images

Limitations of plasmid complementation test for determination of quinolone resistance due to changes in the gyrase A protein and identification of conditional quinolone resistance locus.

Plasmid pJSW101 derived from pUC19 and carrying the wild-type gyrA gene was found to be unstable in HM72, a quinolone-resistant (QR) clinical isolate of Escherichia coli, and resulted in no change in quinolone MICs. MICs determined in the presence of ampicillin to ensure plasmid presence, however, resulted in complementation. HM72 was proved to have a gyrA mutation based on the DNA sequence of a 418-bp fragment of gyrA. DNA sequencing identified a common mutation encoding Leu-83 as the cause of QR. To identify loci other than gyrA and nfxB contributing to QR in KF111b, zgh-3075::Tn10 (67 min) in CAG12152 was transduced into KF111b. Sixteen percent of the transductants had a fourfold decrease in norfloxacin MIC, indicating the presence of a locus, nfxD, which contributes to QR. Outcross of nfxD from DH151 (gyrA nfxB nfxD zgh-3075::Tn10) resulted in 8% of the KF130 gyrA, 2% of the EN226-3 gyrA, and none of the KL16 (wild-type) transductants, with a four- to eightfold increase in norfloxacin MIC. In the presence of ampicillin, the resistance of a gyrA nfxD double mutant, DH161 nfxD gyrA (from EN226-3), was fully complemented by gyrA+. Thus, gyrA+ plasmid complementation tests for QR may be falsely negative with plasmid instability, a difficulty which may be circumvented by maintenance of plasmid selection. In addition, if nfxD-like mutations occur in gyrA clinical isolates, a positive test may overestimate the level of resistance attributable to gyrA alone.

Antagonism of wild-type and resistant Escherichia coli and its DNA gyrase by the tricyclic 4-quinolone analogs ofloxacin and S-25930 stereoisomers.

The mechanism of action of the quinolone analogs ofloxacin and S-25930, which are unusual because of the presence of a third ring with an asymmetric carbon, was studied. Drug-resistant strains of Escherichia coli were selected by serial passage in the presence of ofloxacin, and a mutation was mapped near the gyrA gene of DNA gyrase. DNA gyrase containing the A subunit purified from this strain as compared with the isogenic wild-type strain exhibited increased resistance to ofloxacin, proving that the mutation was located in the gyrA gene. For S-25930, the S stereoisomer was more potent than the R isomer in inhibiting wild-type E. coli and DNA gyrase containing an A subunit isolated from this strain. Both isomers had decreased potency against the isogenic ofloxacin-resistant (gyrA) strain and its purified enzyme, but the S isomer remained more potent than the R isomer. These studies, using a combined genetic and biochemical approach, demonstrate (i) that DNA gyrase is a target of the tricyclics ofloxacin and S-25930, (ii) that serial exposure to ofloxacin can select resistance to tricyclic quinolone agents by mutation in the gyrA gene, and (iii) that the more potent antibacterial activity of S relative to R S-25930 correlates with increased activity against DNA gyrase for both wild-type and ofloxacin-resistant (gyrA) isogenic strains.