Machine learning, network pharmacology, and molecular dynamics reveal potent cyclopeptide inhibitors against dengue virus proteins.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Mohammed A Imam, Thamir A Alandijany, Hashim R Felemban, Roba M Attar, Arwa A Faizo, Hattan S Gattan, Vivek Dhar Dwivedi, Esam I Azhar
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Abstract

The dengue virus is a major global health hazard responsible for an estimated 390 million diseases yearly. This study focused on identifying cyclopeptide inhibitors for envelope structural proteins E, NS1, NS3, and NS5. Additionally, 5579 cyclopeptides were individually screened against the four target proteins using a machine learning-based quantitative structure-activity relationship model. Subsequently, the best 10 cyclopeptides from each protein were selected for molecular docking with their corresponding proteins. Moreover, the protein-peptide complexes with the highest affinity were subjected to a 100-ns molecular dynamics simulation. The protein-protein complexes exhibited superior structural stability and binding interactions. Based on the results of the MD simulation analyses, which included checking values for Root Mean Square Deviation, Root Mean Square Fluctuation, Principal Component Analysis (PCA), free energy landscapes, and energetic components, it was found that NS5-CP03714 complex is more stable and has stronger binding interactions than NS3-CP02054. PCA and free energy landscape plots have confirmed the higher conformational stability of NS5-CP03714. Analysis of the energetic components revealed that NS5-CP03714 (total binding energy = - 47.19 kcal/mol) exhibits more favorable interaction energies and overall binding energy compared to NS3-CP02054 (total binding energy = - 27.36 kcal/mol), suggesting a stronger and more stable formation of the complex. In addition, the drug-target network of two specific peptides (CP02950 and CP05582) and their associated target proteins were analyzed. This analysis revealed valuable information about their ability to target several proteins and their potential for broad-spectrum activity. Additional experimental investigations are necessary to validate these computational results and assess the efficacy of identified peptide inhibitors in biological systems.

Abstract Image

机器学习、网络药理学和分子动力学揭示了针对登革热病毒蛋白的强效环肽抑制剂。
登革热病毒是一种严重危害全球健康的病毒,估计每年导致 3.9 亿人患病。这项研究的重点是确定包膜结构蛋白 E、NS1、NS3 和 NS5 的环肽抑制剂。此外,利用基于机器学习的定量结构-活性关系模型,针对这四种目标蛋白单独筛选了 5579 种环肽。随后,从每种蛋白质中选出最佳的 10 种环肽与相应的蛋白质进行分子对接。此外,还对亲和力最高的蛋白-肽复合物进行了 100-ns 的分子动力学模拟。这些蛋白质-蛋白质复合物表现出卓越的结构稳定性和结合相互作用。根据 MD 模拟分析的结果(包括均方根偏差、均方根波动、主成分分析(PCA)、自由能景观和能量成分的校验值),发现 NS5-CP03714 复合物比 NS3-CP02054 更稳定,具有更强的结合相互作用。PCA和自由能图谱证实了NS5-CP03714具有更高的构象稳定性。能量成分分析表明,与 NS3-CP02054(总结合能 = - 27.36 kcal/mol)相比,NS5-CP03714(总结合能 = - 47.19 kcal/mol)表现出更有利的相互作用能和总结合能,表明复合物的形成更强、更稳定。此外,还分析了两种特定多肽(CP02950 和 CP05582)及其相关靶蛋白的药物-靶标网络。该分析揭示了有关这两种肽靶向多种蛋白质的能力及其广谱活性潜力的宝贵信息。为了验证这些计算结果并评估已鉴定的多肽抑制剂在生物系统中的功效,有必要进行更多的实验研究。
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
CiteScore
7.20
自引率
4.30%
发文量
567
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