Molecular mechanism underlying effect of D93 and D289 protonation states on inhibitor-BACE1 binding: exploration from multiple independent Gaussian accelerated molecular dynamics and deep learning.

IF 2.3 3区环境科学与生态学 Q3 CHEMISTRY, MULTIDISCIPLINARY SAR and QSAR in Environmental Research Pub Date : 2024-10-01 Epub Date: 2024-11-08 DOI:10.1080/1062936X.2024.2419911

J Du, G Xu, W Zhang, J Cong, X Si, B Wei

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Abstract

BACE1 has been regarded as an essential drug design target for treating Alzheimer's disease (AD). Multiple independent Gaussian accelerated molecular dynamics simulations (GaMD), deep learning (DL), and molecular mechanics general Born surface area (MM-GBSA) method are integrated to elucidate the molecular mechanism underlying the effect of D93 and D289 protonation on binding of inhibitors OV6 and 4B2 to BACE1. The GaMD trajectory-based DL successfully identifies significant function domains. Dynamic analysis shows that the protonation of D93 and D289 strongly affects the structural flexibility and dynamic behaviour of BACE1. Free energy landscapes indicate that inhibitor-bound BACE1s have more conformational states in the protonated states than the wild-type (WT) BACE1, and show more binding poses of inhibitors. Binding affinities calculated using the MM-GBSA method indicate that the protonation of D93 and D289 highly disturbs the binding ability of inhibitors to BACE1. In addition, the protonation of two residues significantly affects the hydrogen bonding interactions (HBIs) of OV6 and 4B2 with BACE1, altering their binding activity to BACE1. The binding hot spots of BACE1 recognized by residue-based free energy estimations provide rational targeting sites for drug design towards BACE1. This study is anticipated to provide theoretical aids for drug development towards treatment of AD.

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D93和D289质子化状态对抑制剂-BACE1结合影响的分子机制：从多个独立的高斯加速分子动力学和深度学习中探索。

BACE1一直被视为治疗阿尔茨海默病（AD）的重要药物设计靶点。该研究整合了多种独立的高斯加速分子动力学模拟（GaMD）、深度学习（DL）和分子力学一般伯恩表面积（MM-GBSA）方法，以阐明D93和D289质子化对抑制剂OV6和4B2与BACE1结合的影响的分子机制。基于 GaMD 轨迹的 DL 成功识别了重要的功能域。动态分析显示，D93 和 D289 的质子化强烈影响了 BACE1 的结构灵活性和动态行为。自由能图谱表明，与野生型（WT）BACE1 相比，抑制剂结合的 BACE1 在质子化状态下有更多的构象状态，并显示出更多的抑制剂结合姿态。用 MM-GBSA 方法计算的结合亲和力表明，D93 和 D289 的质子化高度干扰了抑制剂与 BACE1 的结合能力。此外，两个残基的质子化显著影响了 OV6 和 4B2 与 BACE1 的氢键相互作用（HBI），从而改变了它们与 BACE1 的结合活性。通过基于残基的自由能估算确认的 BACE1 结合热点为针对 BACE1 的药物设计提供了合理的靶点。这项研究有望为治疗AD的药物开发提供理论帮助。

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来源期刊

SAR and QSAR in Environmental Research 环境科学-毒理学

CiteScore

5.20

自引率

20.00%

发文量

审稿时长

>24 weeks

期刊介绍： SAR and QSAR in Environmental Research is an international journal welcoming papers on the fundamental and practical aspects of the structure-activity and structure-property relationships in the fields of environmental science, agrochemistry, toxicology, pharmacology and applied chemistry. A unique aspect of the journal is the focus on emerging techniques for the building of SAR and QSAR models in these widely varying fields. The scope of the journal includes, but is not limited to, the topics of topological and physicochemical descriptors, mathematical, statistical and graphical methods for data analysis, computer methods and programs, original applications and comparative studies. In addition to primary scientific papers, the journal contains reviews of books and software and news of conferences. Special issues on topics of current and widespread interest to the SAR and QSAR community will be published from time to time.