通过硅学研究确定先导物:以乙酰胆碱酯酶为靶点防治阿尔茨海默病。

Dhairiya Agarwal, Sumit Kumar, Ramesh Ambatwar, Neeru Bhanwala, Lokesh Chandrakar, Gopal L Khatik
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摘要

目的:在这项工作中,我们的目标是利用 Biovia Discovery Studio 中的不同模型获得治疗阿尔茨海默病(AD)的最佳潜在小分子,从而通过硅学研究确定新的乙酰胆碱酯酶(AChE)潜在抑制剂:背景:据观察,与认知障碍相关的神经退行性疾病(如白内障)的发病率正在迅速上升。然而,我们对导致 AD 的潜在功能、结果预测因素或干预目标仍然知之甚少:本研究的目的是优化和确定针对 AChE 的先导化合物,以防治阿尔茨海默病:方法:采用不同的硅学研究方法,包括药效模型、虚拟筛选、分子对接、新进化模型和分子动力学:结果:基于配体的药效模型和三维 QSAR 药效生成确定了 AChE 抑制剂的药效特征。利用成本分析法、费舍尔随机法和测试集进一步验证了最佳药效模型。筛选出最佳药效模型与估计活性 < 1 nM 和 ADMET 参数相一致的分子,并对 12 个分子进行分子对接研究,以获得结合能。3vsp_EK8_1 的结合能最高,为 65.60 kcal/mol。进一步优化后,3v_Evo_4 分子的结合能达到 70.17 kcal/mol,更好。对 3v_evo_4 分子进行了 100 ns 的分子模拟,结果与多奈哌齐相比,3v_evo_4 分子在结合位点的稳定性更好:结论:研究发现了一种抑制 AChE 的先导化合物 3v_Evoo_4 分子,可以进一步研究将其开发成一种比现有治疗 AD 药物疗效更好的药物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Lead Identification Through In Silico Studies: Targeting Acetylcholinesterase Enzyme Against Alzheimer's Disease.

Aims: In this work, we aimed to acquire the best potential small molecule for Alzheimer's disease (AD) treatment using different models in Biovia Discovery Studio to identify new potential inhibitors of acetylcholinesterase (AChE) via in silico studies.

Background: The prevalence of cognitive impairment-related neurodegenerative disorders, such as AD, has been observed to escalate rapidly. However, we still know little about the underlying functions, outcome predictors, or intervention targets causing AD.

Objectives: The objective of the study was to optimize and identify the lead compound to target AChE against Alzheimer's disease.

Methods: Different in silico studies were employed, including the pharmacophore model, virtual screening, molecular docking, de novo evolution model, and molecular dynamics.

Results: The pharmacophoric features of AChE inhibitors were determined by ligand-based pharmacophore models and 3D QSAR pharmacophore generation. Further validation of the best pharmacophore model was done using the cost analysis method, Fischer's randomization method, and test set. The molecules that harmonized the best pharmacophore model with the estimated activity < 1 nM and ADMET parameters were filtered, and 12 molecules were subjected to molecular docking studies to obtain binding energy. 3vsp_EK8_1 secured the highest binding energy of 65.60 kcal/mol. Further optimization led to a 3v_Evo_4 molecule with a better binding energy of 70.17 kcal/mol. The molecule 3v_evo_4 was subjected to 100 ns molecular simulation compared to donepezil, which showed better stability at the binding site.

Conclusion: A lead compound, 3v_Evo_4 molecule, was identified to inhibit AChE, and it could be further studied to develop as a drug with better efficacy than the existing available drugs for treating AD.

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