Identification of Selective JAK3/STAT1 and CYP34A from Pyrazolopyrimidine Derivatives: A Search for Potential Drug Targets for Rheumatoid Arthritis using In-silico Drug Discovery Techniques

Letters in Drug Design & Discovery Pub Date : 2023-08-21 DOI:10.2174/1570180820666230821102836

Abdelmoujoud Faris, Ibrahim M. Ibrahim, Souvik Chakraborty, Omkulthom Al kamaly, S. Alshawwa, Menana EL Hallaoui

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Abstract

This study aimed to discover a novel active compound capable of effectively inhibiting JAK3/STAT1 and CYP3A4 using molecular modelling techniques, with the goal of treating autoimmune diseases such as cancer and specifically rheumatoid arthritis. The study involved modelling compounds derived from pyrazolopyrimidine, followed by screening methods to identify the most promising compounds. Moreover, this study seeks to identify potential compounds that can inhibit JAK3/STAT through molecular modelling techniques and validate the stability and affinity of the predicted molecule. Various molecular modelling techniques were employed to identify potential compounds and assess the stability and affinity of the predicted molecule. A pharmacophore hypothesis was developed to obtain crucial information about the experimental series of pyrazolopyrimidine studied, which served as the basis for designing new molecules. Additionally, ADMET was utilized to predict and evaluate the pharmacokinetic properties and potential toxicity of the compound prior to synthesis or utilization. To determine the essential residues involved in the interaction between the molecule and the target JAK3 protein, the covalent docking method was applied. We further validated the binding stability of the JAK3 protein with the ligands ZINC62162141 and Tofacitinib, both of which have been approved by the FDA for JAK3/STAT inhibition., using DFT/B3LYP/6-31G molecular dynamics simulations lasting 1000 ns and MM/GBSA. During the study, we identified compounds that displayed notable activity against JAK3/STAT, specifically those containing thiadiazol, oxadiazol, and chlorophenyl groups. Additionally, the pharmacophore model, ADRRR_1, exhibited promising potential for predicting new molecules. The predicted compound, ZINC62162141, demonstrated favourable ADMET properties, including inhibition of CYP3A4. Furthermore, we assessed its binding stability to the target protein and determined its affinity for the protein-ligand complex using MMGBSA. The results of this study suggest that the compounds identified have the potential to be promising candidates for inhibiting JAK3/STAT and CYP3A4, offering potential therapeutic benefits for the treatment of rheumatoid arthritis. These findings provide a foundation for subsequent experimental validation and the development of novel drugs in this field.

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pyrazolopy嘧啶衍生物中选择性JAK3/STAT1和CYP34A的鉴定:利用计算机药物发现技术寻找类风湿关节炎的潜在药物靶点

本研究旨在利用分子建模技术发现一种能够有效抑制JAK3/STAT1和CYP3A4的新型活性化合物，目的是治疗自身免疫性疾病，如癌症，特别是类风湿性关节炎。该研究包括模拟衍生自吡唑嘧啶的化合物，然后通过筛选方法确定最有希望的化合物。此外，本研究试图通过分子建模技术鉴定可能抑制JAK3/STAT的化合物，并验证预测分子的稳定性和亲和力。各种分子建模技术被用来鉴定潜在的化合物，并评估预测分子的稳定性和亲和力。提出了药效团假说，获得了吡唑嘧啶实验系列的重要信息，为设计新分子提供了基础。此外，ADMET还用于预测和评估化合物在合成或利用前的药代动力学性质和潜在毒性。为了确定分子与目标JAK3蛋白相互作用的必要残基，采用共价对接方法。我们进一步验证了JAK3蛋白与配体ZINC62162141和Tofacitinib的结合稳定性，这两种配体都已被FDA批准用于JAK3/STAT抑制。，使用DFT/B3LYP/6-31G分子动力学模拟持续1000 ns和MM/GBSA。在研究过程中，我们发现了对JAK3/STAT具有显著活性的化合物，特别是那些含有噻二唑、恶二唑和氯苯基的化合物。此外，药效团模型ADRRR_1在预测新分子方面表现出良好的潜力。预测的化合物ZINC62162141显示出良好的ADMET特性，包括抑制CYP3A4。此外，我们评估了其与靶蛋白的结合稳定性，并使用MMGBSA测定了其对蛋白质-配体复合物的亲和力。本研究结果表明，所鉴定的化合物具有抑制JAK3/STAT和CYP3A4的潜力，为类风湿关节炎的治疗提供潜在的治疗益处。这些发现为后续的实验验证和该领域新药的开发提供了基础。

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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Letters in Drug Design & Discovery

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