Testing the mutant selection window hypothesis with Staphylococcus aureus exposed to daptomycin and vancomycin in an in vitro dynamic model

OBJECTIVES: To extend the mutant selection window (MSW) hypothesis to include antibiotics in addition to fluoroquinolones, the pharmacodynamics of daptomycin (DAP) and vancomycin (VAN) and their ability to prevent the selection of resistant Staphylococcus aureus were studied in an in vitro model that simulates antibiotic concentrations below the MIC, between the MIC and the mutant prevention concentration (MPC), and above the MPC. METHODS: Two clinical isolates of S. aureus, S. aureus 866 (MIC(DAP) 0.35, MIC(VAN) 0.7, MPC(DAP) 1.1, MPC(VAN) 2.4 mg/L) and S. aureus 10 (MIC(DAP) 1.1, MIC(VAN) 1.3, MPC(DAP) 5.5, MPC(VAN) 11 mg/L), were exposed for five consecutive days to once-daily daptomycin (half-life 9 h) and twice-daily vancomycin (half-life 6 h) at the ratio of 24 h area under the concentration-time curve (AUC24) to MIC that varied over a 16- to 30-fold range. The cumulative antimicrobial effect was expressed by its intensity (I(E)). Changes in susceptibility and numbers of surviving organisms on agar plates containing 2x and 4x MIC of daptomycin or vancomycin were monitored daily. RESULTS: The I(E)-log AUC24/MIC plots were bacterial strain- and antibiotic-independent. This allowed combination of data obtained with both antibiotics and both organisms. Based on the sigmoid relationship between I(E) and the AUC24/MIC (r2 = 0.9), the antistaphylococcal effect of the therapeutic doses of daptomycin (4 and 6 mg/kg) against a hypothetical S. aureus with MIC equal to the MIC90 (AUC24/MIC90 380 and 570 h, respectively) was predicted to be similar to the effect of two 1 g doses of vancomycin given at a 12 h interval (AUC24/MIC90 200 h). AUC24/MIC relationships of the final-to-initial MIC ratio and logarithm of the ratio of maximal-to-initial numbers of organisms resistant to 2x and 4x MIC of daptomycin or vancomycin were bell-shaped and bacterial strain- and antibiotic-independent. Based on these relationships, an AUC24/MIC ratio that protects against the selection of resistant mutants was predicted at > or = 200 h. This protective value is less than the AUC24/MIC90s provided by the 4 mg/kg dose and considerably less than the 6 mg/kg dose of daptomycin, but it is close to the AUC24/MIC90 provided by two 1 g doses of vancomycin. CONCLUSIONS: These findings support the MSW hypothesis and suggest comparable antistaphylococcal effects of clinically achievable AUC24/MIC90s of daptomycin and vancomycin but slightly better prevention against the selection of resistant S. aureus by daptomycin.     

In vitro activity of pristinamycin against methicillin-resistant Staphylococcus aureus

An agar dilution technique was used to determine the MIC of pristinamycin for 124 clinical isolates of methicillin-resistant Staphylococcus aureus. All were inhibited by less than or equal to 0.5 mg/1, quite similar to the sensitivity of a number of methicillin-sensitive strains. MICs obtained using a microdilution method were also comparable. Antagonism was seen with the combination of pristinamycin and erythromycin.     

In vitro activity of TD-6424 against Staphylococcus aureus

TD-6424, a rapidly bactericidal agent with multiple mechanisms of action, is more potent in vitro and more rapidly bactericidal than currently available agents against methicillin-susceptible and methicillin-resistant Staphylococcus aureus. TD-6424 produces a postantibiotic effect with a duration of 4 to 6 h against these organisms. The results suggest potential efficacy against susceptible and resistant strains of S. aureus.     

In vitro selection and characterization of ceftobiprole-resistant methicillin-resistant Staphylococcus aureus

Methicillin-resistant Staphylococcus aureus (MRSA) is resistant to beta-lactam antibiotics because it expresses penicillin-binding protein 2a (PBP2a), a low-affinity penicillin-binding protein. An investigational broad-spectrum cephalosporin, ceftobiprole (BPR), binds PBP2a with high affinity and is active against MRSA. We hypothesized that BPR resistance could be mediated by mutations in mecA, the gene encoding PBP2a. We selected BPR-resistant mutants by passage in high-volume broth cultures containing subinhibitory concentrations of BPR. We used strain COLnex (which lacks chromosomal mecA) transformed with pAW8 (a plasmid vector only), pYK20 (a plasmid carrying wild-type mecA), or pYK21 (a plasmid carrying a mutant mecA gene corresponding to five PBP2a mutations). All strains became resistant to BPR by day 9 of passaging, but MICs continued to increase until day 21. MICs increased 256-fold (from 1 to 256 microg/ml) for pAW8, 32-fold (from 4 to 128 microg/ml) for pYK20, and 8-fold (from 16 to 128 mug/ml) for pYK21. Strains carrying wild-type or mutant mecA developed six (pYK20 transformants) or four (pYK21 transformants) new mutations in mecA. The transformation of COLnex with a mecA mutant plasmid conferred BPR resistance, and the loss of mecA converted resistant strains into susceptible ones. Modeling studies predicted that several of the mecA mutations altered BPR binding; other mutations may have mediated resistance by influencing interactions with other proteins. Multiple mecA mutations were associated with BPR resistance in MRSA. BPR resistance also developed in the strain lacking mecA, suggesting a role for chromosomal genes.     

喹诺酮药物对环丙沙星敏感金黄色葡萄球菌防耐药突变浓度

目的测定4种喹诺酮药物对临床标本中对环丙沙星敏感金葡菌的MIC和防耐药突变浓度（mutant prevention concentration，MPC）。方法采用琼脂稀释法检测加替沙星、左氧氟沙星、帕珠沙星和环丙沙星对20株环丙沙星敏感金葡菌MPC90、MPC90／MIC90、结果加替沙星、左氧氟沙星、帕珠沙星和环丙沙星MPC90、MPC90／MIC90分别为1．2、9．2；4．0、16；4．0、16和8、16mg／L。MIC与MPC存在不一致性。少数菌能在MPC浓度下存活，但没有MIC改变。结论加替沙星较其他喹诺酮药物限制选择富集耐药突变株能力更强，不能从MIC推测MPC。     

In vitro pharmacodynamic modelling simulating free serum concentrations of fluoroquinolones against multidrug-resistant Streptococcus pneumoniae

An in vitro pharmacodynamic model was used to compare bacterial killing and the development of resistant mutants in the presence of respiratory fluoroquinolones and ciprofloxacin. Free (protein unbound) serum concentrations were simulated using peak serum concentrations and AUC(24), achieved after standard oral doses for treatment of community-acquired respiratory infections. Respiratory fluoroquinolones reduced the inoculum of isolates of multidrug-resistant Streptococcus pneumoniae below the level of detection in the model at 12 h and did not allow regrowth to occur over 48 h. In contrast, ciprofloxacin had a bacteriostatic (<3 log(10) reduction of the initial inoculum) effect, with rapid regrowth occurring over 48 h. Bacterial regrowth and the development of resistant mutants did not occur with any of the respiratory fluoroquinolones. Rapid regrowth and the development of resistant mutants, with MICs two- to eight-fold higher than the MIC before treatment, occurred with ciprofloxacin. These data suggest that the new respiratory fluoroquinolones with a free AUC(24)/MIC of 35-63 reduce the inoculum of multidrug-resistant S. pneumoniae below the level of detection without regrowth or development of resistance over 48 h. This study also demonstrated the poor activity of ciprofloxacin against S. pneumoniae.     

In vitro activity of novel rifamycins against rifamycin-resistant Staphylococcus aureus

We describe novel rifamycin derivatives (new chemical entities [NCEs]) that retain significant activity against a comprehensive collection of Staphylococcus aureus strains that are resistant to rifamycins. This collection of resistant strains contains 21 of the 26 known single-amino-acid alterations in RpoB, the target of rifamycins. Some NCEs also demonstrated a lower frequency of resistance development than rifampin and rifalazil in S. aureus as measured in a resistance emergence test. When assayed for activity against the strongest rifamycin-resistant mutants, several NCEs had MICs of 2 microg/ml, in contrast to MICs of rifampin and rifalazil, which were 512 microg/ml for the same strains. The properties of these NCEs therefore demonstrate a significant improvement over those of earlier rifamycins, which have been limited primarily to combination therapy due to resistance development, and suggest a potential use of these NCEs for monotherapy in several clinical indications.     

The anti-methicillin-resistant Staphylococcus aureus quinolone WCK 771 has potent activity against sequentially selected mutants, has a narrow mutant selection window against quinolone-resistant Staphylococcus aureus, and preferentially targets DNA gyrase

WCK 771 is a broad-spectrum fluoroquinolone with enhanced activity against quinolone-resistant staphylococci. To understand the impact of the target-level interactions of WCK 771 on its antistaphylococcal pharmacodynamic properties, we determined the MICs for genetically defined mutants and studied the mutant prevention concentrations (MPCs), the frequency of mutation, and the cidality against the wild type and double mutants. There was a twofold increase in the MICs of WCK 771 for single gyrA mutants, indicating that DNA gyrase is its primary target. All first- and second-step mutants selected by WCK 771 revealed gyrA and grlA mutations, respectively. The MICs of WCK 771 and clinafloxacin were found to be superior to those of other quinolones against strains with double and triple mutations. WCK 771 was also cidal for high-density double mutants at low concentrations. WCK 771 and clinafloxacin showed narrow mutant selection windows compared to those of the other quinolones. Against a panel of 50 high-level quinolone-resistant clinical isolates of staphylococci (ciprofloxacin MIC > or = 16 microg/ml), the WCK 771 MPCs were < or =2 microg/ml for 68% of the strains and < or =4 microg/ml for 28% of the strains. Our results demonstrate that gyrA is the primary target of WCK 771 and that it has pharmacodynamic properties remarkably different from those of quinolones with dual targets (garenoxacin and moxifloxacin) and topoisomerase IV-specific quinolones (trovafloxacin). WCK 771 displayed an activity profile comparable to that of clinafloxacin, a dual-acting quinolone with a high affinity to DNA gyrase. Overall, the findings signify the key role of DNA gyrase in determining the optimal antistaphylococcal features of quinolones.     

In vivo validation of the mutant selection window hypothesis with moxifloxacin in a murine model of tuberculosis

Combination therapy is the most effective strategy to prevent emergence of resistance during tuberculosis (TB) treatment. Another strategy, albeit theoretical, is to limit the time that drug concentrations fall in the "mutant selection window" (MSW) between the MIC and the mutant prevention concentration (MPC). Drug concentrations above the MPC prevent selective amplification of resistant mutants in vitro even with a single drug exposure. The MSW concept has been validated using fluoroquinolones against Mycobacterium tuberculosis in vitro but not in vivo. Using a mouse model in which serum moxifloxacin (MXF) concentrations were maintained above the MPC, we tested whether this strategy prevents selection of MXF-resistant mutants. Beginning 2 weeks after aerosol infection with M. tuberculosis, when the mean lung log(10) CFU count was 7.9 +/- 0.2, mice received either no treatment or MXF in the diet at 0.25% to approximate the conventional human dose or 1.5% to maintain serum concentrations above the MPC (8 microg/ml). After 56 days of treatment, lung CFU counts were 3.5 +/- 0.8 and 0.9 +/- 0.6 in 0.25% and 1.5% of the MXF-treated mice, respectively. In mice given 0.25% MXF, MXF-resistant mutants were selected by day 28 and detected in 16% (3/19) of mice tested on day 56. No selection of MXF-resistant mutants was detected in mice given 1.5% MXF. We conclude that maintaining serum concentrations of MXF above the MPC prevents selection of MXF-resistant mutants. Although this target cannot be achieved clinically with MXF, it might be possible with new fluoroquinolones with more potent activity and/or improved pharmacokinetics.     

Human serum enhances the postantibiotic effect of fluoroquinolones against Staphylococcus aureus.

The postantibiotic effect (PAE) of fluoroquinolones against Staphylococcus aureus was determined in Mueller-Hinton broth and normal human serum. At both 4X and 10X the MIC, serum significantly increased the duration of the PAE in all strains tested (P less than 0.05). Reducing the pH of the serum from 7.9 to 7.2 had no effect on the PAE. Heat treating the serum (56 degrees C, 30 min) reduced the PAE of ciprofloxacin at 10X the MIC approximately 25% (P less than 0.05). The PAE of cloxacillin was reduced approximately 80% in serum, and PAE experiments with gentamicin and cephalexin produced findings similar to those obtained with the fluoroquinolones. Serum increased the MICs of ciprofloxacin and norfloxacin less than twofold and increased the MIC of pefloxacin approximately fourfold. We conclude that normal human serum considerably increases the PAE of fluoroquinolones against S. aureus.     

In vitro activity of linezolid against Staphylococcus aureus: a population study

In our study, we aim to determine the existence of microorganisms that are heteroresistant to linezolid among Staphylococcus aureus clinical isolates in our setting between 1996 and 2002; during this period, linezolid was not used in clinical practice. There was no resistant subpopulation to 4 mg/l of linezolid in 99.4% of the strains. On the other hand, 16.46% of the strains exhibited resistant subpopulations to 4 microg/ml of vancomycin. However, the emergence of strains resistant to this drug has been described and the emergence of resistant strains should be monitored.     

In vitro evaluation of clindamycin in combination with oxacillin, rifampin, or vancomycin against Staphylococcus aureus

In a study of antibiotic combinations of clindamycin with rifampin, oxacillin, or vancomycin using the time kill-curve method, the combination of clindamycin and rifampin were sometimes synergistic (5 of 15 times), otherwise indifferent and always enhanced killing of fifteen tested Staphylococcus aureus isolates. In contrast, vancomycin and clindamycin or oxacillin and clindamycin were either indifferent or antagonistic (approximately 50%). Vancomycin alone, however, was generally as effective as the combinations of clindamycin and rifampin.     

Small-colony mutants of Staphylococcus aureus allow selection of gyrase-mediated resistance to dual-target fluoroquinolones

Fluoroquinolones acting equally through DNA gyrase and topoisomerase IV in vivo are considered desirable in requiring two target mutations for emergence of resistant bacteria. To investigate this idea, we have studied the response of Staphylococcus aureus RN4220 to stepwise challenge with sparfloxacin, a known dual-target agent, and with NSFQ-105, a more potent sulfanilyl fluoroquinolone that behaves similarly. First-step mutants were obtained with both drugs but only at the MIC. These mutants exhibited distinctive small-colony phenotypes and two- to fourfold increases in MICs of NSFQ-105, sparfloxacin, and ciprofloxacin. No changes were detected in the quinolone resistance-determining regions of the gyrA, gyrB, grlA, or grlB gene. Quinolone-induced small-colony mutants shared the delayed coagulase response but not the requirement for menadione, hemin, or thymidine characteristic of small-colony variants, a subpopulation of S. aureus that is often defective in electron transport. Second-step mutants selected with NSFQ-105 had gyrA(S84L) alterations; those obtained with sparfloxacin carried a gyrA(D83A) mutation or a novel gyrB deletion (DeltaRKSAL, residues 405 to 409) affecting a trypsin-sensitive region linking functional domains of S. aureus GyrB. Each mutation was associated with four- to eightfold increases in MICs of NSFQ-105 and sparfloxacin, but not of ciprofloxacin, which we confirm targets topoisomerase IV. The presence of wild-type grlB-grlA gene sequences in second-step mutants excluded involvement of topoisomerase IV in the small-colony phenotype. Growth revertants retaining mutant gyrA or gyrB alleles were quinolone susceptible, indicating that resistance to NSFQ-105 and sparfloxacin was contingent on the small-colony mutation. We propose that small-colony mutations unbalance target sensitivities, perhaps through altered ATP or topoisomerase levels, such that gyrase becomes the primary drug target. Breaking of target parity by genetic or physiological means eliminates the need for two target mutations and provides a novel mechanism for stepwise selection of quinolone resistance.     

Enrichment of fluoroquinolone-resistant Staphylococcus aureus: oscillating ciprofloxacin concentrations simulated at the upper and lower portions of the mutant selection window

The time inside the mutant selection window (MSW), T(MSW), appears to be less predictive of the selection of fluoroquinolone-resistant Staphylococcus aureus than is the ratio of the area under the concentration-time curve (AUC) to the MIC. This observation might be attributed to the fact that T(MSW) does not consider the actual position of simulated antibiotic concentrations inside the MSW, which also might influence the amplification of resistant mutants. To test this hypothesis, the enrichment of ciprofloxacin-resistant S. aureus was studied at ciprofloxacin (CIP) concentrations that oscillate near the mutant prevention concentration (MPC), i.e., closer to the top of the MSW ("upper case"), and closer to the MIC, i.e., at the lower limit of the MSW ("lower case") at the same T(MSW). Two methicillin-resistant strains of S. aureus, ATCC 6538 and ATCC 43300 (MICs of 0.25 and 0.5 mg/liter, respectively, and MPCs of 4 and 2 mg/liter, respectively), were exposed to twice-daily CIP treatments for three consecutive days. With S. aureus ATCC 6538, the simulated ratios of the AUC at 24 h (AUC(24)) to the MIC were 50 and 260 h (T(MSW) 75% of the dosing interval). With S. aureus ATCC 43300, the simulated AUC(24)/MICs were 30 and 100 h (T(MSW) 56%). With each organism, mutants resistant to CIP were enriched in an AUC(24)/MIC-dependent manner: the higher the AUC(24)/MIC ratio, the lower the growth on CIP-containing plates. For example, the area under the time-kill curve of mutants resistant to 4x MIC of CIP in the upper case was three times smaller than that in the lower case for both S. aureus strains. Similar differences were seen at the higher (8x MIC) and lower (2x MIC) CIP concentrations. These data highlight differences in the selection of resistant S. aureus, depending on the position of simulated concentrations inside the MSW at a given T(MSW). This explains why T(MSW)-based predictions of resistance are less accurate than those based on AUC/MIC and AUC/MPC.     

In vitro activity of AT-4140 against quinolone- and methicillin-resistant Staphylococcus aureus.

Eighty-nine clinical isolates of Staphylococcus aureus that were resistant to both ciprofloxacin (MIC, greater than or equal to 3.13 micrograms/ml) and methicillin (MIC, greater than or equal to 12.5 micrograms/ml) were divided into two groups with respect to their susceptibilities to AT-4140. Most isolates that were moderately resistant to ciprofloxacin (MICs, 3.13 to 12.5 micrograms/ml) or ofloxacin (MICs, 0.78 to 6.25 micrograms/ml) were susceptible to AT-4140 (MICs, 0.05 to 0.2 microgram/ml). Most isolates that were highly resistant to ciprofloxacin (MIC, greater than or equal to 25 micrograms/ml) or ofloxacin (MIC, greater than or equal to 12.5 micrograms/ml) were resistant to AT-4140 (MICs, 3.13 to 25 micrograms/ml). The appearance of spontaneous single-step, quinolone-resistant mutants of S. aureus P-20, a methicillin-resistant isolate, was more frequent than was that of S. aureus 209P JC-1, a susceptible laboratory strain. Spontaneous single-step, quinolone-resistant mutants of P-20 were not selected by AT-4140, and those selected by existing fluoroquinolones were susceptible to AT-4140. Spontaneous double-step, quinolone-resistant mutants of P-20 were selected by various fluoroquinolones. All second-step mutants selected by AT-4140 or ofloxacin from P-20-C, a spontaneous single-step mutant of P-20 selected by ciprofloxacin, were resistant to all the quinolones. All second-step mutants selected by nonfloxacin were resistant to all existing fluoroquinolones but were less resistant to AT-4140. There was a close resemblance between the resistance profiles of spontaneous quinolone-resistant mutants and those of clinically isolated quinolone- and methicillin-resistant S. aureus.