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通过蛋白质-配体相互作用的图匹配对对接构象进行排序:D3R 大挑战 2 中的经验教训

Ranking docking poses by graph matching of protein-ligand interactions: lessons learned from the D3R Grand Challenge 2.

机构信息

Laboratoire d'Innovation Thérapeutique, UMR 7200 CNRS-Université de Strasbourg, 67400, Illkirch, France.

Instituto de Biofísica Carlos Chagas Filho, Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil.

出版信息

J Comput Aided Mol Des. 2018 Jan;32(1):75-87. doi: 10.1007/s10822-017-0046-1. Epub 2017 Aug 1.

DOI:10.1007/s10822-017-0046-1
PMID:28766097
Abstract

A novel docking challenge has been set by the Drug Design Data Resource (D3R) in order to predict the pose and affinity ranking of a set of Farnesoid X receptor (FXR) agonists, prior to the public release of their bound X-ray structures and potencies. In a first phase, 36 agonists were docked to 26 Protein Data Bank (PDB) structures of the FXR receptor, and next rescored using the in-house developed GRIM method. GRIM aligns protein-ligand interaction patterns of docked poses to those of available PDB templates for the target protein, and rescore poses by a graph matching method. In agreement with results obtained during the previous 2015 docking challenge, we clearly show that GRIM rescoring improves the overall quality of top-ranked poses by prioritizing interaction patterns already visited in the PDB. Importantly, this challenge enables us to refine the applicability domain of the method by better defining the conditions of its success. We notably show that rescoring apolar ligands in hydrophobic pockets leads to frequent GRIM failures. In the second phase, 102 FXR agonists were ranked by decreasing affinity according to the Gibbs free energy of the corresponding GRIM-selected poses, computed by the HYDE scoring function. Interestingly, this fast and simple rescoring scheme provided the third most accurate ranking method among 57 contributions. Although the obtained ranking is still unsuitable for hit to lead optimization, the GRIM-HYDE scoring scheme is accurate and fast enough to post-process virtual screening data.

摘要

为了在 Farnesoid X 受体 (FXR) 激动剂的结合 X 射线结构和效力公开之前,预测其构象和亲和力排名,药物设计数据资源 (D3R) 提出了一个新的对接挑战。在第一阶段,36 种激动剂对接至 26 个 FXR 受体的蛋白质数据库 (PDB) 结构,然后使用内部开发的 GRIM 方法重新评分。GRIM 将对接构象的蛋白-配体相互作用模式与目标蛋白的可用 PDB 模板进行对齐,并通过图匹配方法对构象进行重新评分。与之前在 2015 年对接挑战中获得的结果一致,我们清楚地表明,GRIM 重新评分通过优先考虑已经在 PDB 中访问过的相互作用模式,提高了顶级构象的整体质量。重要的是,通过更好地定义方法成功的条件,该挑战使我们能够改进方法的适用性域。我们特别表明,在疏水性口袋中重新评分非极性配体,导致 GRIM 频繁失败。在第二阶段,根据相应的 GRIM 选择构象的吉布斯自由能,使用 HYDE 评分函数对 102 种 FXR 激动剂按亲和力递减进行排序。有趣的是,这种快速而简单的重新评分方案在 57 种贡献中提供了第三准确的排名方法。尽管获得的排名仍然不适合用于命中到先导优化,但 GRIM-HYDE 评分方案足够准确和快速,可以对虚拟筛选数据进行后处理。

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