Wensel David, Gartland Margaret, Beloor Jagadish, Shetty Kartika N, Wolf Jana, Stewart Eugene, Clark Andrew, Tenorio Allan, Krystal Mark
ViiV Healthcare, 36 E Industrial Road, Branford, CT, 06405, USA.
ViiV Healthcare, 406 Blackwell Street, Suite 300, Durham, NC, 27701, USA.
Antiviral Res. 2024 Sep;229:105953. doi: 10.1016/j.antiviral.2024.105953. Epub 2024 Jul 1.
Temsavir binds directly to the HIV-1 envelope glycoprotein gp120 and selectively inhibits interactions between HIV-1 and CD4 receptors. Previous studies identified gp120 amino acid positions where substitutions are associated with reduced susceptibility to temsavir. The mechanism by which temsavir susceptibility is altered in these envelope glycoproteins was evaluated. Pseudoviruses encoding gp120 substitutions alone (S375H/I/M/N, M426L, M434I, M475I) or in combination (S375H + M475I) were engineered on a wild-type JRFL background. Temsavir-gp120 and CD4-gp120 binding kinetics and ability of temsavir to block CD4-gp120 binding were evaluated using the purified polymorphic gp120 proteins and a Creoptix® WAVE Delta grating-coupled interferometry system. Fold-change in half-maximal inhibitory concentration (IC) in JRFL-based pseudoviruses containing the aforementioned polymorphisms relative to that of wild-type ranged from 4-fold to 29,726-fold, while temsavir binding affinity for the polymorphic gp120 proteins varied from 0.7-fold to 73.7-fold relative to wild-type gp120. Strong correlations between temsavir IC and temsavir binding affinity (r = 0.7332; P = 0.0246) as well as temsavir binding on-rate (r = -0.8940; P = 0.0011) were observed. Binding affinity of gp120 proteins for CD4 varied between 0.4-fold and 3.1-fold compared with wild-type gp120; no correlations between temsavir IC and CD4 binding kinetic parameters were observed. For all polymorphic gp120 proteins, temsavir was able to fully block CD4 binding; 3 polymorphs required higher temsavir concentrations. Loss of susceptibility to temsavir observed for gp120 polymorphisms strongly correlated with reductions in temsavir binding on-rate. Nonetheless, temsavir retained the ability to fully block CD4-gp120 engagement given sufficiently high concentrations.
替沙韦直接与HIV-1包膜糖蛋白gp120结合,并选择性抑制HIV-1与CD4受体之间的相互作用。先前的研究确定了gp120氨基酸位置,这些位置的替换与对替沙韦的敏感性降低有关。对这些包膜糖蛋白中替沙韦敏感性改变的机制进行了评估。在野生型JRFL背景上构建了单独编码gp120替换(S375H/I/M/N、M426L、M434I、M475I)或组合编码(S375H + M475I)的假病毒。使用纯化的多态性gp120蛋白和Creoptix® WAVE Delta光栅耦合干涉测量系统评估替沙韦-gp120和CD4-gp120的结合动力学以及替沙韦阻断CD4-gp120结合的能力。相对于野生型,含有上述多态性的基于JRFL的假病毒中半数最大抑制浓度(IC)的变化倍数范围为4倍至29726倍,而替沙韦对多态性gp120蛋白的结合亲和力相对于野生型gp120变化范围为0.7倍至73.7倍。观察到替沙韦IC与替沙韦结合亲和力之间存在强相关性(r = 0.7332;P = 0.0246)以及替沙韦结合速率(r = -0.8940;P = 0.0011)。与野生型gp120相比,gp120蛋白对CD4的结合亲和力在0.4倍至3.1倍之间变化;未观察到替沙韦IC与CD4结合动力学参数之间的相关性。对于所有多态性gp120蛋白,替沙韦都能够完全阻断CD4结合;3种多态型需要更高的替沙韦浓度。观察到gp120多态性对替沙韦的敏感性丧失与替沙韦结合速率降低密切相关。尽管如此,在足够高的浓度下,替沙韦仍保留完全阻断CD4-gp120相互作用的能力。
