National Key Laboratory of Green Pesticide, Key Laboratory of Pesticide & Chemical Biology of Ministry of Education, Hubei International Scientific and Technological Cooperation Base of Pesticide and Green Synthesis, College of Chemistry, Central China Normal University, Wuhan 43009, People's Republic of China.
Shanghai Key Laboratory of Molecular Catalysis and Innovative Materials, Ministry of Education (MOE) Laboratory for Computational Physical Science, Department of Chemistry, Fudan University, Shanghai 200433, People's Republic of China.
J Chem Inf Model. 2023 Aug 14;63(15):4850-4863. doi: 10.1021/acs.jcim.3c00776. Epub 2023 Aug 4.
Accurate prediction of the protein-ligand binding affinity (PLBA) with an affordable cost is one of the ultimate goals in the field of structure-based drug design (SBDD), as well as a great challenge in the computational and theoretical chemistry. Herein, we have systematically addressed the complicated solvation and desolvation effects on the PLBA brought by the difference of the explicit water in the protein cavity before and after ligands bind to the protein-binding site. Based on the new solvation model, a nonfitting method at the first-principles level for the PLBA prediction was developed by taking the bridging and displaced water (BDW) molecules into account simultaneously. The newly developed method, DOX_BDW, was validated against a total of 765 noncovalent and covalent protein-ligand binding pairs, including the CASF2016 core set, Cov_2022 covalent binding testing set, and six testing sets for the hit and lead compound optimization (HLO) simulation. In all of the testing sets, the DOX_BDW method was able to produce PLBA predictions that were strongly correlated with the corresponding experimental data ( = 0.66-0.85). The overall performance of DOX_BDW is better than the current empirical scoring functions that are heavily parameterized. DOX_BDW is particularly outstanding for the covalent binding situation, implying the need for considering an electronic structure in covalent drug design. Furthermore, the method is especially recommended to be used in the HLO scenario of SBDD, where hundreds of similar derivatives need to be screened and refined. The computational cost of DOX_BDW is affordable, and its accuracy is remarkable.
准确预测蛋白质-配体结合亲和力(PLBA)是基于结构的药物设计(SBDD)领域的最终目标之一,也是计算和理论化学领域的巨大挑战。在此,我们系统地研究了配体与蛋白质结合位点结合前后蛋白质腔中显式水分子的差异对 PLBA 的复杂溶剂化和解溶剂化效应。基于新的溶剂化模型,同时考虑桥接和取代水分子,我们开发了一种非拟合方法来预测 PLBA。新方法 DOX_BDW 经过了 765 个非共价和共价蛋白质-配体结合对的验证,包括 CASF2016 核心集、Cov_2022 共价结合测试集以及六个用于命中和先导化合物优化(HLO)模拟的测试集。在所有测试集中,DOX_BDW 方法能够产生与相应实验数据高度相关的 PLBA 预测( = 0.66-0.85)。DOX_BDW 的整体性能优于当前严重参数化的经验评分函数。对于共价结合情况,DOX_BDW 表现尤为出色,这意味着需要在共价药物设计中考虑电子结构。此外,该方法特别推荐用于 SBDD 的 HLO 场景,其中需要筛选和优化数百个类似的衍生物。DOX_BDW 的计算成本可承受,且准确性显著。
