Ligand-Based Approach for Multi-Target Drug Discovery: PTML Modeling of Triple-Target Inhibitors.

IF 2.9 4区 医学 Q3 CHEMISTRY, MEDICINAL Current topics in medicinal chemistry Pub Date : 2024-08-21 DOI:10.2174/0115680266325897240815112505
Valeria V Kleandrova, M Natália D S Cordeiro, Alejandro Speck-Planche
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Abstract

Background: Cancers are complex multi-genetic diseases that should be tackled in multi-target drug discovery scenarios. Computational methods are of great importance to accelerate the discovery of multi-target anticancer agents. Here, we employed a ligand-based approach by combining a perturbation-theory machine learning model derived from an ensemble of multilayer perceptron networks (PTML-EL-MLP) with the Fragment-Based Topological Design (FBTD) approach to rationally design and predict triple-target inhibitors against the cancerrelated proteins named Tropomyosin Receptor Kinase A (TRKA), poly[ADP-ribose] polymerase 1 (PARP-1), and Insulin-like Growth Factor 1 Receptor (IGF1R).

Methods: We extracted the chemical and biological data from ChEMBL. We applied the Box- Jenkins approach to generate multi-label topological indices and subsequently created the PTML-EL-MLP model.

Results: Our PTML-EL-MLP model exhibited an accuracy of around 80%. The application FBTD permitted the physicochemical and structural interpretation of the PTML-EL-MLP model, thus enabling a) the chemistry-driven analysis of different molecular fragments with a positive influence on the multi-target activity and b) the use of those favorable fragments as building blocks to virtually design four new drug-like molecules. The designed molecules were predicted as triple-target inhibitors against the aforementioned cancer-related proteins.

Conclusion: Our study envisages the capabilities of combining PTML modeling with FBTD for the generation of new chemical diversity for multi-target drug discovery in oncology research and beyond.

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基于配体的多靶点药物发现方法:三靶点抑制剂的 PTML 模型。
背景:癌症是一种复杂的多基因疾病,应在多靶点药物发现方案中加以解决。计算方法对于加速多靶点抗癌药物的发现非常重要。在这里,我们采用了一种基于配体的方法,将从多层感知器网络集合(PTML-EL-MLP)中衍生出的扰动理论机器学习模型与基于片段的拓扑设计(FBTD)方法相结合,合理地设计和预测了针对肿瘤相关蛋白--肌球蛋白受体激酶A(TRKA)、聚[ADP-核糖]聚合酶1(PARP-1)和胰岛素样生长因子1受体(IGF1R)--的三靶点抑制剂:我们从 ChEMBL 中提取了化学和生物学数据。方法:我们从 ChEMBL 中提取了化学和生物数据,并采用 Box- Jenkins 方法生成了多标签拓扑指数,随后创建了 PTML-EL-MLP 模型:结果:我们的 PTML-EL-MLP 模型显示出约 80% 的准确率。应用 FBTD 可以对 PTML-EL-MLP 模型进行物理化学和结构解释,从而能够:(a)从化学角度分析对多靶点活性有积极影响的不同分子片段;(b)利用这些有利片段作为构建模块,虚拟设计出四种新的类药物分子。所设计的分子被预测为针对上述癌症相关蛋白的三靶点抑制剂:我们的研究设想了将 PTML 建模与 FBTD 结合起来,为肿瘤学研究及其他领域的多靶点药物发现创造新的化学多样性的能力。
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
6.40
自引率
2.90%
发文量
186
审稿时长
3-8 weeks
期刊介绍: Current Topics in Medicinal Chemistry is a forum for the review of areas of keen and topical interest to medicinal chemists and others in the allied disciplines. Each issue is solely devoted to a specific topic, containing six to nine reviews, which provide the reader a comprehensive survey of that area. A Guest Editor who is an expert in the topic under review, will assemble each issue. The scope of Current Topics in Medicinal Chemistry will cover all areas of medicinal chemistry, including current developments in rational drug design, synthetic chemistry, bioorganic chemistry, high-throughput screening, combinatorial chemistry, compound diversity measurements, drug absorption, drug distribution, metabolism, new and emerging drug targets, natural products, pharmacogenomics, and structure-activity relationships. Medicinal chemistry is a rapidly maturing discipline. The study of how structure and function are related is absolutely essential to understanding the molecular basis of life. Current Topics in Medicinal Chemistry aims to contribute to the growth of scientific knowledge and insight, and facilitate the discovery and development of new therapeutic agents to treat debilitating human disorders. The journal is essential for every medicinal chemist who wishes to be kept informed and up-to-date with the latest and most important advances.
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