Combining classical molecular docking with self-consistent charge density-functional tight-binding computations for the efficient and quality prediction of ligand binding structure

Amar Y. Al-Ansi, Haorui Lu, Zijing Lin
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Abstract

To improve the successful prediction rate of the existing molecular docking methods, a new docking approach is proposed that consists of three steps: generating an ensemble of docked poses with a conventional docking method, performing clustering analysis of the ensemble to select the representative poses, and optimizing the representative structures with a low-cost quantum mechanics method. Three quantum mechanics methods, self-consistent charge density-functional tight-binding, ONIOM(DFT:PM6), and ONIOM(SCC-DFTB:PM6), are tested on 18 ligand-receptor bio-complexes. The rate of successful binding pose predictions by the proposed self-consistent charge density-functional tight-binding docking method is the highest, at 67%. The self-consistent charge density-functional tight-binding docking method should be useful for the structure-based drug design.
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结合经典分子对接与自洽电荷密度功能紧密结合计算,实现配体结合结构的高效、高质量预测
为了提高现有分子对接方法的预测成功率,提出了一种新的分子对接方法,该方法包括三个步骤:利用传统的对接方法生成对接位姿集合,对该集合进行聚类分析以选择具有代表性的位姿,并利用低成本的量子力学方法优化具有代表性的结构。在18种配体-受体生物复合物上测试了自洽电荷密度功能紧密结合、ONIOM(DFT:PM6)和ONIOM(SCC-DFTB:PM6)三种量子力学方法。所提出的自一致电荷密度功能紧密结合对接方法的结合位姿预测成功率最高,为67%。自洽电荷密度-功能紧密结合对接方法可用于基于结构的药物设计。
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来源期刊
Journal of Chemical Research-s
Journal of Chemical Research-s 化学科学, 有机化学, 有机合成
自引率
0.00%
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0
审稿时长
1 months
期刊介绍: The Journal of Chemical Research is a peer reviewed journal that publishes full-length review and research papers in all branches of experimental chemistry. The journal fills a niche by also publishing short papers, a format which favours particular types of work, e.g. the scope of new reagents or methodology, and the elucidation of the structure of novel compounds. Though welcome, short papers should not result in fragmentation of publication, they should describe a completed piece of work. The Journal is not intended as a vehicle for preliminary publications. The work must meet all the normal criteria for acceptance as regards scientific standards. Papers that contain extensive biological results or material relating to other areas of science may be diverted to more appropriate specialist journals. Areas of coverage include: Organic Chemistry; Inorganic Chemistry; Materials Chemistry; Crystallography; Computational Chemistry.
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