Rational design of inhibitors for drug-resistant HIV-1 aspartic protease mutants.

Drug design and discovery Pub Date : 1998-10-01
V Frecer, S Miertus, A Tossi, D Romeo
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Abstract

This report describes a method for the assessment of inhibitor binding affinities to wild type HIV-1 aspartic protease and to its drug-resistant mutant forms. We have elaborated a refined method for molecular modeling of the 3D structures of mutant enzymes and enzyme-inhibitor complexes based on the crystal structure of the wild type form, which employs a full thermodynamic cycle. Model complexes of four HIV-1 aspartic protease mutants with ten analogs of the A77003 inhibitor were considered. Predictions of inhibition efficiency, resistance potential, and hydrophilicity of the redesigned A77003 analogs were obtained by employing molecular mechanics for the evaluation of enzyme-inhibitor complexation energy and the polarizable continuum model for the estimation of solvent effects. Simple qualitative indicators for structural modifications aimed at overcoming the emergence of HIV resistance to protease inhibitors and at increasing the bioavailability of pseudopeptide inhibitors are examined. A semi-quantitative method for the description of enzyme-ligand binding and its implications for the rational design of inhibitors with higher binding affinity towards emerging HIV PR mutants is presented.

耐药HIV-1天冬氨酸蛋白酶突变体抑制剂的合理设计。
本报告描述了一种评估抑制剂与野生型HIV-1天冬氨酸蛋白酶及其耐药突变形式结合亲和力的方法。我们已经阐述了一种基于野生型晶体结构的突变酶和酶抑制剂复合物三维结构的精细分子建模方法,该方法采用了完整的热力学循环。研究了四种HIV-1天冬氨酸蛋白酶突变体与10种A77003抑制剂类似物的模型复合物。利用分子力学评价酶抑制剂络合能和极化连续体模型评价溶剂效应,对重新设计的A77003类似物的缓蚀效率、抗性电位和亲水性进行了预测。结构修饰的简单定性指标旨在克服艾滋病毒对蛋白酶抑制剂的耐药性和增加假肽抑制剂的生物利用度。提出了一种半定量方法来描述酶-配体结合及其对合理设计具有更高结合亲和力的抑制剂对新出现的HIV PR突变体的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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