Department of Antiviral Research, MRL, West Point, PA 19486, USA.
Department of Antiviral Research, Merck Frosst Center for Therapeutic Research, Pointe-Claire - Dorval H9R 4P8, Canada.
J Antimicrob Chemother. 2018 Jan 1;73(1):109-117. doi: 10.1093/jac/dkx332.
The increasing prevalence of mutations in HIV-1 reverse transcriptase (RT) that confer resistance to existing NRTIs and NNRTIs underscores the need to develop RT inhibitors with novel mode-of-inhibition and distinct resistance profiles.
Biochemical assays were employed to identify inhibitors of RT activity and characterize their mode of inhibition. The antiviral activity of the inhibitors was assessed by cell-based assays using laboratory HIV-1 isolates and MT4 cells. RT variants were purified via avidin affinity columns.
Compound A displayed equal or greater potency against many common NNRTI-resistant RTs (K103N and Y181C RTs) relative to WT RT. Despite possessing certain NNRTI-like properties, such as being unable to inhibit an engineered variant of RT lacking an NNRTI-binding pocket, we found that compound A was dependent on Mg2+ for binding to RT. Optimization of compound A led to more potent analogues, which retained similar activities against WT and K103N mutant viruses with submicromolar potency in a cell-based assay. One of the analogues, compound G, was crystallized in complex with RT and the structure was determined at 2.6 Å resolution. The structure indicated that compound G simultaneously interacts with the active site (Asp186), the highly conserved primer grip region (Leu234 and Trp229) and the NNRTI-binding pocket (Tyr188).
These findings reveal a novel class of RT bifunctional inhibitors that are not sensitive to the most common RT mutations, which can be further developed to address the deficiency of current RT inhibitors.
HIV-1 逆转录酶(RT)中越来越多的突变导致对现有 NRTIs 和 NNRTIs 的耐药性,这凸显了开发具有新型抑制模式和独特耐药谱的 RT 抑制剂的必要性。
采用生化测定法鉴定 RT 活性抑制剂,并对其抑制模式进行特征分析。采用基于细胞的实验,使用实验室 HIV-1 分离株和 MT4 细胞评估抑制剂的抗病毒活性。通过亲和层析柱纯化 RT 变异体。
化合物 A 对许多常见的 NNRTI 耐药 RT(K103N 和 Y181C RT)的活性与野生型 RT 相当或更强。尽管具有某些 NNRTI 样特性,例如无法抑制缺乏 NNRTI 结合口袋的工程化 RT 变异体,但我们发现化合物 A 依赖于 Mg2+ 与 RT 结合。对化合物 A 的优化导致了更有效的类似物,这些类似物对 WT 和 K103N 突变病毒具有类似的活性,在基于细胞的实验中具有亚微摩尔的效力。类似物之一化合物 G 与 RT 形成复合物,并确定了其 2.6 Å 的分辨率结构。该结构表明,化合物 G 同时与活性位点(Asp186)、高度保守的引物夹区(Leu234 和 Trp229)和 NNRTI 结合口袋(Tyr188)相互作用。
这些发现揭示了一类新型 RT 双功能抑制剂,它们对最常见的 RT 突变不敏感,可以进一步开发以解决当前 RT 抑制剂的不足。
