Garvey Edward P, Schwartz Benjamin, Gartland Margaret J, Lang Scott, Halsey Wendy, Sathe Ganesh, Carter H Luke, Weaver Kurt L
Department of Virology, GlaxoSmithKline Pharmaceuticals, 5 Moore Drive, Research Triangle Park, North Carolina 27709-3398, USA.
Biochemistry. 2009 Feb 24;48(7):1644-53. doi: 10.1021/bi802141y.
Two-metal binding HIV-1 integrase inhibitors (INIs) are potent inhibitors of HIV-1 in vitro and in patients. We report here for the first time the kinetics of inhibition of integrase-catalyzed strand transfer. First, the IC(50) values for each of six structurally distinct INIs decreased when a preincubation was included: S-1360 (1.3 microM vs 0.12 microM), L-731,988 (130 nM vs 9 nM), L-870,810 (130 nM vs 4 nM), raltegravir (300 nM vs 9 nM), elvitegravir (90 nM vs 6 nM), and GSK364735 (90 nM vs 6 nM). When reactions with these INIs were initiated with integrase, progress curve analyses indicated time-dependent inhibition, which could be fitted to a two-step mechanism of binding. Overall fitted K(i) values matched the IC(50) values measured with a preincubation: S-1360 (0.17 microM), L-731,988 (34 nM), L-870,810 (2.4 nM), raltegravir (10 nM), elvitegravir (4.0 nM), and GSK364735 (2.5 nM). To begin to understand the mechanism for this slow onset of inhibition and its possible impact on drug resistance, studies of resistance mutations were initiated. T66I/M154I exhibited little if any time-dependent inhibition by any of the six INIs, as measured by differences in potency upon preincubation or by progress curve analysis. These data demonstrate that slow binding is a signature of two-metal binding INIs, and that the second slow step is required for full potency. We discuss a possible structural explanation of the second slow step of inhibition and also the relationship between loss of time-dependent inhibition and drug resistance of this important new class of HIV-1 antiretroviral drugs.
双金属结合的HIV-1整合酶抑制剂(INIs)在体外和患者体内均为强效的HIV-1抑制剂。我们在此首次报告整合酶催化链转移抑制的动力学。首先,当进行预孵育时,六种结构不同的INIs中每种的IC50值均降低:S-1360(1.3微摩尔/升对0.12微摩尔/升)、L-731,988(130纳摩尔/升对9纳摩尔/升)、L-870,810(130纳摩尔/升对4纳摩尔/升)、拉替拉韦(300纳摩尔/升对9纳摩尔/升)、埃替格韦(90纳摩尔/升对6纳摩尔/升)和GSK364735(90纳摩尔/升对6纳摩尔/升)。当用整合酶启动与这些INIs的反应时,进程曲线分析表明存在时间依赖性抑制,这可以拟合为两步结合机制。总体拟合的K(i)值与预孵育时测得的IC50值相符:S-1360(0.17微摩尔/升)、L-731,988(34纳摩尔/升)、L-870,810(2.4纳摩尔/升)、拉替拉韦(10纳摩尔/升)、埃替格韦(4.0纳摩尔/升)和GSK364735(2.5纳摩尔/升)。为了开始理解这种缓慢抑制起效的机制及其对耐药性的可能影响,启动了耐药性突变研究。通过预孵育时效力的差异或进程曲线分析测量,T66I/M154I对六种INIs中的任何一种几乎均未表现出时间依赖性抑制。这些数据表明,缓慢结合是双金属结合INIs的一个特征,并且第二个缓慢步骤对于完全效力是必需的。我们讨论了抑制的第二个缓慢步骤的可能结构解释,以及这种重要的新型HIV-1抗逆转录病毒药物的时间依赖性抑制丧失与耐药性之间的关系。
