Molecular dynamics simulations for the structure-based drug design: targeting small-GTPases proteins.

IF 6 2区医学 Q1 PHARMACOLOGY & PHARMACY Expert Opinion on Drug Discovery Pub Date : 2024-10-01 Epub Date: 2024-08-06 DOI:10.1080/17460441.2024.2387856

Angela Parise, Sofia Cresca, Alessandra Magistrato

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Abstract

Introduction: Molecular Dynamics (MD) simulations can support mechanism-based drug design. Indeed, MD simulations by capturing biomolecule motions at finite temperatures can reveal hidden binding sites, accurately predict drug-binding poses, and estimate the thermodynamics and kinetics, crucial information for drug discovery campaigns. Small-Guanosine Triphosphate Phosphohydrolases (GTPases) regulate a cascade of signaling events, that affect most cellular processes. Their deregulation is linked to several diseases, making them appealing drug targets. The broad roles of small-GTPases in cellular processes and the recent approval of a covalent KRas inhibitor as an anticancer agent renewed the interest in targeting small-GTPase with small molecules.

Area covered: This review emphasizes the role of MD simulations in elucidating small-GTPase mechanisms, assessing the impact of cancer-related variants, and discovering novel inhibitors.

Expert opinion: The application of MD simulations to small-GTPases exemplifies the role of MD simulations in the structure-based drug design process for challenging biomolecular targets. Furthermore, AI and machine learning-enhanced MD simulations, coupled with the upcoming power of quantum computing, are promising instruments to target elusive small-GTPases mutations and splice variants. This powerful synergy will aid in developing innovative therapeutic strategies associated to small-GTPases deregulation, which could potentially be used for personalized therapies and in a tissue-agnostic manner to treat tumors with mutations in small-GTPases.

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用于基于结构的药物设计的分子动力学模拟：以小型 GTP 酶蛋白为目标。

简介：分子动力学（MD）模拟可以支持基于机理的药物设计。事实上，通过捕捉生物分子在有限温度下的运动，MD 模拟可以揭示隐藏的结合位点，准确预测药物结合位置，并估算热力学和动力学，这些都是药物发现活动的关键信息。小型三磷酸鸟苷磷酸水解酶（GTPases）调节一连串的信号传导事件，影响大多数细胞过程。它们的功能失调与多种疾病有关，因此成为极具吸引力的药物靶标。小 GTP 酶在细胞过程中发挥着广泛的作用，最近批准了一种共价 KRas 抑制剂作为抗癌药物，这再次激发了人们对小分子靶向小 GTP 酶的兴趣：本综述强调了 MD 模拟在阐明小 GTP 酶机制、评估癌症相关变体的影响以及发现新型抑制剂方面的作用：MD模拟在小GTP酶中的应用体现了MD模拟在针对具有挑战性的生物分子靶点进行基于结构的药物设计过程中的作用。此外，人工智能和机器学习增强型 MD 模拟与即将到来的量子计算能力相结合，有望成为针对难以捉摸的小 GTP 酶突变和剪接变体的工具。这种强大的协同作用将有助于开发与小GTP酶失调相关的创新治疗策略，从而有可能用于个性化治疗，并以组织诊断的方式治疗小GTP酶突变的肿瘤。

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

Expert Opinion on Drug Discovery 医学-药学

CiteScore

10.20

自引率

1.60%

发文量

审稿时长

6-12 weeks

期刊介绍： Expert Opinion on Drug Discovery (ISSN 1746-0441 [print], 1746-045X [electronic]) is a MEDLINE-indexed, peer-reviewed, international journal publishing review articles on novel technologies involved in the drug discovery process, leading to new leads and reduced attrition rates. Each article is structured to incorporate the author’s own expert opinion on the scope for future development. The Editors welcome: Reviews covering chemoinformatics; bioinformatics; assay development; novel screening technologies; in vitro/in vivo models; structure-based drug design; systems biology Drug Case Histories examining the steps involved in the preclinical and clinical development of a particular drug The audience consists of scientists and managers in the healthcare and pharmaceutical industry, academic pharmaceutical scientists and other closely related professionals looking to enhance the success of their drug candidates through optimisation at the preclinical level.