PairMap: An Intermediate Insertion Approach for Improving the Accuracy of Relative Free Energy Perturbation Calculations for Distant Compound Transformations

IF 5.3 2区化学 Q1 CHEMISTRY, MEDICINAL

Journal of Chemical Information and Modeling Pub Date : 2025-01-12 DOI:10.1021/acs.jcim.4c0163410.1021/acs.jcim.4c01634

Kairi Furui, Takafumi Shimizu, Yutaka Akiyama, S. Roy Kimura, Yoh Terada and Masahito Ohue*,

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引用次数: 0

Abstract

Accurate prediction of the difference in binding free energy between compounds is crucial for reducing the high costs associated with drug discovery. Relative binding free energy perturbation (RBFEP) calculations are effective for small structural changes; however, large topological changes pose significant challenges for calculations, leading to high errors and difficulties in convergence. To address such issues, we propose a new approach─PairMap─that focuses on introducing appropriate intermediates for complex transformations between two input compounds. PairMap-generated intermediates exhaustively, determined the optimal conversion paths, and introduced thermodynamic cycles into the perturbation map to improve accuracy and reduce computational cost. PairMap succeeded in introducing appropriate intermediates that could not be discovered by existing simple approaches by comprehensively considering intermediates. Furthermore, we evaluated the accuracy of the prediction of binding free energy using 9 compounds selected from Wang et al.’s benchmark set, which included particularly complex transformations. The perturbation map generated by PairMap achieved excellent accuracy with a mean absolute error of 0.93 kcal/mol compared to 1.70 kcal/mol when using the perturbation map generated by the conventional Flare FEP intermediate introduction method. Moreover, in a scaffold hopping experiment conducted with the PDE5a target involving complex transformations, PairMap provided more accurate free energy predictions than ABFEP calculations, yielding more reliable results compared to experimental data. Additionally, PairMap can be utilized to introduce intermediates into congeneric series, demonstrating that complex links on the perturbation map can be resolved with minimal addition of intermediates and links. In conclusion, PairMap overcomes the limitations of existing methods by enabling RBFEP calculations for more complex transformations, further streamlining lead optimization in drug discovery.

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对图：一种提高远距离复合变换相对自由能摄动计算精度的中间插入方法

准确预测化合物之间结合自由能的差异对于降低与药物发现相关的高成本至关重要。相对束缚自由能摄动（RBFEP）计算对于微小的结构变化是有效的；然而，大的拓扑变化给计算带来了巨大的挑战，导致高误差和收敛困难。为了解决这些问题，我们提出了一种新的方法──PairMap──其重点是为两个输入化合物之间的复杂转换引入适当的中间体。pairmap详尽地生成中间体，确定最优转换路径，并将热力学循环引入扰动图以提高精度并降低计算成本。通过综合考虑中间体，PairMap成功地引入了现有简单方法无法发现的合适中间体。此外，我们使用从Wang等人的基准集中选择的9种化合物（其中包括特别复杂的转化）来评估结合自由能预测的准确性。PairMap生成的微扰图的平均绝对误差为0.93 kcal/mol，而传统的耀斑FEP中间引入法生成的微扰图的平均绝对误差为1.70 kcal/mol。此外，在涉及复杂变换的PDE5a靶点的支架跳跃实验中，PairMap提供了比ABFEP计算更准确的自由能预测，与实验数据相比，得出的结果更可靠。此外，PairMap还可以将中间体引入到同类序列中，证明了扰动图上的复杂链接可以通过最小的中间体和链接来解决。总之，PairMap克服了现有方法的局限性，使RBFEP计算能够进行更复杂的转换，进一步简化了药物发现中的先导物优化。

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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来源期刊

Journal of Chemical Information and Modeling 化学-化学综合

CiteScore

9.80

自引率

10.70%

发文量

529

审稿时长

1.4 months

期刊介绍： The Journal of Chemical Information and Modeling publishes papers reporting new methodology and/or important applications in the fields of chemical informatics and molecular modeling. Specific topics include the representation and computer-based searching of chemical databases, molecular modeling, computer-aided molecular design of new materials, catalysts, or ligands, development of new computational methods or efficient algorithms for chemical software, and biopharmaceutical chemistry including analyses of biological activity and other issues related to drug discovery. Astute chemists, computer scientists, and information specialists look to this monthly’s insightful research studies, programming innovations, and software reviews to keep current with advances in this integral, multidisciplinary field. As a subscriber you’ll stay abreast of database search systems, use of graph theory in chemical problems, substructure search systems, pattern recognition and clustering, analysis of chemical and physical data, molecular modeling, graphics and natural language interfaces, bibliometric and citation analysis, and synthesis design and reactions databases.