Comparative Assessment of Water Models in Protein-Glycan Interaction: Insights from Alchemical Free Energy Calculations and Molecular Dynamics Simulations.

IF 5.6 2区化学 Q1 CHEMISTRY, MEDICINAL

Journal of Chemical Information and Modeling Pub Date : 2024-12-23 Epub Date: 2024-10-08 DOI:10.1021/acs.jcim.4c01361

Deng Li, Mona S Minkara

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引用次数: 0

Abstract

Accurate computational simulations of protein-glycan dynamics are crucial for a comprehensive understanding of critical biological mechanisms, including host-pathogen interactions, immune system defenses, and intercellular communication. The accuracy of these simulations, including molecular dynamics (MD) simulation and alchemical free energy calculations, critically relies on the appropriate parameters, including the water model, because of the extensive hydrogen bonding with glycan hydroxyl groups. However, a systematic evaluation of water models' accuracy in simulating protein-glycan interaction at the molecular level is still lacking. In this study, we used full atomistic MD simulations and alchemical absolute binding free energy (ABFE) calculations to investigate the performance of five distinct water models in six protein-glycan complex systems. We evaluated water models' impact on structural dynamics and binding affinity through over 5.8 μs of simulation time per system. Our results reveal that most protein-glycan complexes are stable in the overall structural dynamics regardless of the water model used, while some show obvious fluctuations with specific water models. More importantly, we discover that the stability of the binding motif's conformation is dependent on the water model chosen when its residues form weak hydrogen bonds with the glycan. The water model also influences the conformational stability of the glycan in its bound state according to density functional theory (DFT) calculations. Using alchemical ABFE calculations, we find that the OPC water model exhibits exceptional consistency with experimental binding affinity data, whereas commonly used models such as TIP3P are less accurate. The findings demonstrate how different water models affect protein-glycan interactions and the accuracy of binding affinity calculations, which is crucial in developing therapeutic strategies targeting these interactions.

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蛋白质-糖相互作用中水模型的比较评估：炼金术自由能计算和分子动力学模拟的启示。

精确的蛋白质-聚糖动力学计算模拟对于全面了解关键生物机制（包括宿主-病原体相互作用、免疫系统防御和细胞间通讯）至关重要。这些模拟（包括分子动力学（MD）模拟和炼金术自由能计算）的准确性严重依赖于适当的参数，包括水模型，因为水与聚糖羟基之间存在广泛的氢键。然而，目前仍缺乏对水模型在分子水平上模拟蛋白质-聚糖相互作用准确性的系统评估。在本研究中，我们采用全原子 MD 模拟和炼金术绝对结合自由能（ABFE）计算方法，研究了五种不同的水模型在六个蛋白质-聚糖复合体系中的表现。我们通过每个系统超过 5.8 μs 的模拟时间评估了水模型对结构动力学和结合亲和力的影响。我们的结果表明，无论使用哪种水模型，大多数蛋白质-聚糖复合物的整体结构动力学都是稳定的，而一些复合物在使用特定水模型时会出现明显的波动。更重要的是，我们发现当结合图案的残基与聚糖形成弱氢键时，其构象的稳定性取决于所选择的水模型。根据密度泛函理论（DFT）计算，水模型也会影响聚糖在结合态下的构象稳定性。通过炼金术 ABFE 计算，我们发现 OPC 水模型与实验结合亲和力数据的一致性极高，而 TIP3P 等常用模型的准确性较低。研究结果表明了不同的水模型如何影响蛋白质-糖蛋白相互作用以及结合亲和力计算的准确性，这对于开发针对这些相互作用的治疗策略至关重要。

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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.