Pan X S, Fisher L M
Molecular Genetics Group, Department of Biochemistry, St. George's Hospital Medical School, University of London, London SW17 ORE, United Kingdom.
Antimicrob Agents Chemother. 1998 Nov;42(11):2810-6. doi: 10.1128/AAC.42.11.2810.
We examined the response of Streptococcus pneumoniae 7785 to clinafloxacin, a novel C-8-substituted fluoroquinolone which is being developed as an antipneumococcal agent. Clinafloxacin was highly active against S. pneumoniae 7785 (MIC, 0.125 microg/ml), and neither gyrA nor parC quinolone resistance mutations alone had much effect on this activity. A combination of both mutations was needed to register resistance, suggesting that both gyrase and topoisomerase IV are clinafloxacin targets in vivo. The sparfloxacin and ciprofloxacin MICs for the parC-gyrA mutants were 16 to 32 and 32 to 64 microg/ml, respectively, but the clinafloxacin MIC was 1 microg/ml, i.e., within clinafloxacin levels achievable in human serum. S. pneumoniae 7785 mutants could be selected stepwise with clinafloxacin at a low frequency, yielding first-, second-, third-, and fourth-step mutants for which clinafloxacin MICs were 0.25, 1, 6, and 32 to 64 microg/ml, respectively. Thus, high-level resistance to clinafloxacin required four steps. Characterization of the quinolone resistance-determining regions of the gyrA, parC, gyrB, and parE genes by PCR, HinfI restriction fragment length polymorphism, and DNA sequence analysis revealed an invariant resistance pathway involving sequential mutations in gyrA or gyrB, in parC, in gyrA, and finally in parC or parE. No evidence was found for other resistance mechanisms. The gyrA mutations in first- and third-step mutants altered GyrA hot spots Ser-83 to Phe or Tyr (Escherichia coli coordinates) and Glu-87 to Gln or Lys; second- and fourth-step parC mutations changed equivalent hot spots Ser-79 to Phe or Tyr and Asp-83 to Ala. gyrB and parE changes produced novel alterations of GyrB Glu-474 to Lys and of Pro-454 to Ser in the ParE PLRGK motif. Difficulty in selecting first-step gyrase mutants (isolated with 0.125 [but not 0.25] microg of clinafloxacin per ml at a frequency of 5.0 x 10(-10) to 8.5 x 10(-10)) accompanied by the small (twofold) MIC increase suggested only a modest drug preference for gyrase. Given the susceptibility of defined gyrA or parC mutants, the results suggested that clinafloxacin displays comparable if unequal targeting of gyrase and topoisomerase IV. Dual targeting and the intrinsic potency of clinafloxacin against S. pneumoniae and its first- and second-step mutants are desirable features in limiting the emergence of bacterial resistance.
我们研究了肺炎链球菌7785对克林沙星(一种新型C-8取代氟喹诺酮类药物,正被开发用作抗肺炎球菌药物)的反应。克林沙星对肺炎链球菌7785具有高度活性(MIC为0.125μg/ml),单独的gyrA或parC喹诺酮耐药性突变对此活性影响不大。需要两种突变同时存在才会产生耐药性,这表明在体内,gyrase和拓扑异构酶IV都是克林沙星的作用靶点。parC-gyrA突变体对司帕沙星和环丙沙星的MIC分别为16至32μg/ml和32至64μg/ml,但对克林沙星的MIC为1μg/ml,即在人血清中可达到的克林沙星水平范围内。肺炎链球菌7785突变体可以用克林沙星以低频率逐步筛选出来,产生第一步、第二步、第三步和第四步突变体,其对克林沙星的MIC分别为0.25、1、6和32至64μg/ml。因此,对克林沙星产生高水平耐药性需要四个步骤。通过PCR、HinfI限制性片段长度多态性分析和DNA序列分析对gyrA、parC、gyrB和parE基因的喹诺酮耐药性决定区域进行表征,结果显示存在一条不变的耐药途径,涉及gyrA或gyrB、parC、gyrA,最后是parC或parE的顺序突变。未发现其他耐药机制的证据。第一步和第三步突变体中的gyrA突变将GyrA热点Ser-83(大肠杆菌坐标)改变为Phe或Tyr,Glu-87改变为Gln或Lys;第二步和第四步parC突变改变了等效热点Ser-79为Phe或Tyr以及Asp-83为Ala。gyrB和parE的变化在ParE的PLRGK基序中产生了GyrB Glu-474至Lys和Pro-454至Ser的新改变。难以筛选出第一步gyrase突变体(每毫升用0.125[而非0.25]μg克林沙星分离得到,频率为5.0×10⁻¹⁰至8.5×10⁻¹⁰),且MIC仅小幅(两倍)增加,这表明对gyrase的药物偏好较小。鉴于特定gyrA或parC突变体的敏感性,结果表明克林沙星对gyrase和拓扑异构酶IV的靶向作用相当(即使不完全相同)。双重靶向作用以及克林沙星对肺炎链球菌及其第一步和第二步突变体的内在效力是限制细菌耐药性出现的理想特性。
