Novel chromosomally encoded multidrug efflux transporter MdeA in Staphylococcus aureus.

Antibiotic efflux is an important mechanism of resistance in pathogenic bacteria. Here we describe the identification and characterization of a novel chromosomally encoded multidrug resistance efflux protein in Staphylococcus aureus, MdeA (multidrug efflux A). MdeA was identified from screening an S. aureus open reading frame expression library for resistance to antibiotic compounds. When overexpressed, MdeA confers resistance on S. aureus to a range of quaternary ammonium compounds and antibiotics, but not fluoroquinolones. MdeA is a 52-kDa protein with 14 predicted transmembrane segments. It belongs to the major facilitator superfamily and is most closely related, among known efflux proteins, to LmrB of Bacillus subtilis and EmrB of Escherichia coli. Overexpression of mdeA in S. aureus reduced ethidium bromide uptake and enhanced its efflux, which could be inhibited by reserpine and abolished by an uncoupler. The mdeA promoter was identified by primer extension. Spontaneous mutants selected for increased resistance to an MdeA substrate had undergone mutations in the promoter for mdeA, and their mdeA transcription levels were increased by as much as 15-fold. The mdeA gene was present in the genomes of all six strains of S. aureus examined. Uncharacterized homologs of MdeA were present elsewhere in the S. aureus genome, but their overexpression did not mediate resistance to the antibacterials tested. However, MdeA homologs were identified in other bacteria, including Bacillus anthracis, some of which were shown to be functional orthologs of MdeA.

Fluoroquinolone resistance in Streptococcus pneumoniae: evidence that gyrA mutations arise at a lower rate and that mutation in gyrA or parC predisposes to further mutation.

Fluoroquinolones are being increasingly used for acute lower respiratory tract infection where Streptococcus pneumoniae is the most important bacterial pathogen. S. pneumoniae becomes resistant to quinolone antibiotics by mutations in a small section of the parC and gyrA genes. In this study, we investigated the mutation rates and spectrum of resistance when ciprofloxacin and gemifloxacin were the selective agents. When ciprofloxacin was the selective agent, parC mutants arose at a rate of 1.1 x 10(-9) mutations per cell division. There were two double mutants: parC + gyrA and parC + gyrB, and these mutations arose in as few as five generations. When gemifloxacin was the selective agent, all but one of the colonies growing on the x2 MIC plate had no mutations in gyrA or parC. The only mutation identified was in gyrA, and it appeared at a rate of 1.6 x 10(-11). When the gemifloxacin MIC of strains with mutations in parC was determined, there was no change from the susceptible parent. These data indicate that S. pneumoniae becomes resistant to gemifloxacin through mutation in gyrA rather than parC. Because gyrA mutations arise at a lower rate than parC mutations, it is likely that resistance to gemifloxacin will emerge more slowly than is seen with those quinolones that become resistant through an initial mutation in parC. The rate at which second-step mutants emerged was 1.3 x 10(-8) for parC Serine 79 Tyrosine and 7.2 x 10(-9) for gyrA Serine 81 Phenylalanine, 12 and 450 times higher, respectively, than for first-step rates, suggesting that mutation in either gene readies the genome for further mutation.

Evolutionary barriers to quinolone resistance in Streptococcus pneumoniae.

It is assumed that bacteria always pay a significant physiological price for the acquisition of resistance to antibiotics. To test whether this was the case for a strain of Streptococcus pneumoniae that develops resistance to fluoroquinolone antibiotics, we selected resistance to these agents in a wild-type strain and measured their fitness in comparative growth experiments. The relative growth rate of a mutant strain selected on ciprofloxacin (parC Serine 79 to Tyrosine) was compared with its susceptible isogenic parent and no significant deficit was found (relative fitness 1.15 95% C.I. +/- 0.2.). A double mutant, however, had a relative fitness of 0.81 (parC Serine 79 to Tyrosine gyrA Serine 81 to Tyrosine). Mutant strains selected on gemifloxacin had only a modest increase in minimum inhibitory concentration; thus, second-round mutants were competed with a first-round gyrA Serine 81 to Tyrosine or the susceptible isogenic parent. The growth rate of three double-mutant strains parC Serine 79 to Tyrosine gyrA Serine 81 to Phenylanine, parC Serine 79 to Tyrosine, and Asparagine 83 to Phenylalanine were similar to the isogenic susceptible parent 1.16 (95% C.I. +/- 0.17), 0.99 (95% C.I. +/- 0.05), and 0.95 (95% C.I. +/- 0.05), respectively. These data suggest that mutation in the parC and gyrA genes may, on some occasions, not be associated with a physiological deficit.