Effect of Water Networks On Ligand Binding: Computational Predictions vs Experiments.

IF 5.6 2区化学 Q1 CHEMISTRY, MEDICINAL

Journal of Chemical Information and Modeling Pub Date : 2024-11-22 DOI:10.1021/acs.jcim.4c01291

Tibor Viktor Szalai, Dávid Bajusz, Rita Börzsei, Balázs Zoltán Zsidó, Janez Ilaš, György G Ferenczy, Csaba Hetényi, György M Keserű

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引用次数: 0

Abstract

Rational drug design focuses on the explanation and prediction of complex formation between therapeutic targets and small-molecule ligands. As a third and often overlooked interacting partner, water molecules play a critical role in the thermodynamics of protein-ligand binding, impacting both the entropy and enthalpy components of the binding free energy and by extension, on-target affinity and bioactivity. The community has realized the importance of binding site waters, as evidenced by the number of computational tools to predict the structure and thermodynamics of their networks. However, quantitative experimental characterization of relevant protein-ligand-water systems, and consequently the validation of these modeling methods, remains challenging. Here, we investigated the impact of solvent exchange from light (H₂O) to heavy water (D₂O) to provide complete thermodynamic profiling of these ternary systems. Utilizing the solvent isotope effects, we gain a deeper understanding of the energetic contributions of various components. Specifically, we conducted isothermal titration calorimetry experiments on trypsin with a series of p-substituted benzamidines, as well as carbonic anhydrase II (CAII) with a series of aromatic sulfonamides. Significant differences in binding enthalpies found between light vs heavy water indicate a substantial role of the binding site water network in protein-ligand binding. Next, we challenged two conceptually distinct modeling methods, the grid-based WaterFLAP and the molecular dynamics-based MobyWat, by predicting and scoring relevant water networks. The predicted water positions accurately reproduce those in available high-resolution X-ray and neutron diffraction structures of the relevant protein-ligand complexes. Estimated energetic contributions of the identified water networks were corroborated by the experimental thermodynamics data. Besides providing a direct validation for the predictive power of these methods, our findings confirmed the importance of considering binding site water networks in computational ligand design.

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水网络对配体结合的影响：计算预测与实验对比

合理药物设计的重点是解释和预测治疗目标与小分子配体之间形成的复合物。水分子作为第三个经常被忽视的相互作用伙伴，在蛋白质与配体结合的热力学中发挥着至关重要的作用，影响着结合自由能的熵和焓成分，进而影响目标亲和力和生物活性。研究界已经意识到结合位点水域的重要性，预测其网络结构和热力学的计算工具的数量就证明了这一点。然而，对相关蛋白质-配体-水系统进行定量实验表征，进而验证这些建模方法，仍然具有挑战性。在这里，我们研究了从轻水（H2O）到重水（D2O）的溶剂交换的影响，从而为这些三元系统提供完整的热力学分析。利用溶剂同位素效应，我们对各种成分的能量贡献有了更深入的了解。具体来说，我们对胰蛋白酶与一系列对取代苯甲脒以及碳酸酐酶 II (CAII) 与一系列芳香族磺酰胺进行了等温滴定量热实验。发现轻水与重水的结合焓存在显著差异，这表明结合位点水网在蛋白质与配体的结合中发挥了重要作用。接下来，我们对两种概念不同的建模方法（基于网格的 WaterFLAP 和基于分子动力学的 MobyWat）进行了挑战，对相关的水网络进行了预测和评分。预测的水位置准确地再现了相关蛋白质配体复合物的现有高分辨率 X 射线和中子衍射结构中的水位置。实验热力学数据证实了对已识别水网络的能量贡献的估计。除了直接验证了这些方法的预测能力，我们的研究结果还证实了在计算配体设计中考虑结合位点水网络的重要性。

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.