Evaluation of Different Scoring Functions for Docking and Virtual Screening against GPCR Drug Targets

Proceedings of MOL2NET 2018, International Conference on Multidisciplinary Sciences, 4th edition Pub Date : 2018-12-19 DOI:10.3390/mol2net-04-06078

Tatiana F. Vieira, Rita P. Magalhães, N. Cerqueira, S. Sousa

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Abstract

Graphical Abstract Abstract. G-protein-coupled receptors (GPCRs) constitute a large family of structurally similar proteins that respond to diverse physiological and environmental stimulants and that includes many therapeutic targets. In fact, 40% of all modern medicinal drugs are thought to target G-protein-coupled receptors (GPCRs), making this large family of proteins a particular appealing target for drug discovery efforts [1, 2]. Protein-ligand docking is a computational method that tries to predict and rank the structure resulting from the association between a ligand and a target protein [3]. Virtual screening (VS) can use docking to evaluate databases with millions of compounds to identify promising new molecules that could bind to a specific target of pharmacological interest, including GPCRs [4]. This strategy if often used to limit the amount of molecules that has to be tested experimentally and to reduce the cost in the identification of new lead molecules for drug development. This work reports a detailed comparison of the popular Autodock [5] and Vina [6] software programs in

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GPCR药物靶点对接与虚拟筛选的不同评分函数评价

图形抽象抽象。g蛋白偶联受体(gpcr)构成了一个结构相似的蛋白大家族，它们对多种生理和环境刺激作出反应，并包括许多治疗靶点。事实上，40%的现代药物被认为是靶向g蛋白偶联受体(gpcr)的，这使得这一大家族的蛋白质成为药物发现工作的一个特别有吸引力的靶点[1,2]。蛋白质-配体对接(protein -ligand docking)是一种试图预测配体与靶蛋白结合产生的结构并对其进行排序的计算方法[3]。虚拟筛选(Virtual screening, VS)可以利用对接来评估包含数百万种化合物的数据库，以识别有希望与特定药理靶点结合的新分子，包括gpcr[4]。这种策略通常用于限制必须进行实验测试的分子数量，并降低识别用于药物开发的新先导分子的成本。这项工作报告了流行的Autodock[5]和Vina[6]软件程序的详细比较

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Proceedings of MOL2NET 2018, International Conference on Multidisciplinary Sciences, 4th edition

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