Author: Ghosh, Arun K.; Anderson, David D.; Weber, Irene T.; Mitsuya, Hiroaki
Title: Enhancing Protein Backbone Binding—A Fruitful Concept for Combating Drugâ€Resistant HIV Cord-id: z0hxrrhy Document date: 2012_1_31
ID: z0hxrrhy
Snippet: The evolution of drug resistance is one of the most fundamental problems in medicine. In HIV/AIDS, the rapid emergence of drugâ€resistant HIVâ€1 variants is a major obstacle to current treatments. HIVâ€1 protease inhibitors are essential components of present antiretroviral therapies. However, with these protease inhibitors, resistance occurs through viral mutations that alter inhibitor binding, resulting in a loss of efficacy. This loss of potency has raised serious questions with regard to
Document: The evolution of drug resistance is one of the most fundamental problems in medicine. In HIV/AIDS, the rapid emergence of drugâ€resistant HIVâ€1 variants is a major obstacle to current treatments. HIVâ€1 protease inhibitors are essential components of present antiretroviral therapies. However, with these protease inhibitors, resistance occurs through viral mutations that alter inhibitor binding, resulting in a loss of efficacy. This loss of potency has raised serious questions with regard to effective longâ€term antiretroviral therapy for HIV/AIDS. In this context, our research has focused on designing inhibitors that form extensive hydrogenâ€bonding interactions with the enzyme’s backbone in the active site. In doing so, we limit the protease’s ability to acquire drug resistance as the geometry of the catalytic site must be conserved to maintain functionality. In this Review, we examine the underlying principles of enzyme structure that support our backboneâ€binding concept as an effective means to combat drug resistance and highlight their application in our recent work on antiviral HIVâ€1 protease inhibitors.
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