Ashaimaa Y Moussa, Abdullah R Alanzi, Muhammad Riaz, Shaimaa Fayez
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Using rigid and flexible molecular docking approaches such as induced fit docking (IFD) in the binding sites of β-secretase (BACE1) and acetylcholine esterase (ACHE), promising structures were screened through high precision molecular docking compared with standard drugs donepezil and (2<i>E</i>)-2-imino-3-methyl-5,5-diphenylimidazolidin-4-one (OKK) using Maestro and Cresset Flare platforms. Molecular interactions, binding distances, and RMSD values were measured to reveal key interactions at the binding sites of the two neurodegenerative enzymes. Analysis of IFD results revealed consistent bindings of dictyoquinazol A and gensetin I in the pocket of 4ey7 while inonophenol A, ganomycin, and fornicin fit quite well in 4dju demonstrating binding poses very close to native ligands at ACHE and BACE1. Respective key amino acid contacts manifested the least steric problems according to their Gibbs free binding energies, Glide XP scores, RMSD values, and molecular orientation respect to the key amino acids. Molecular dynamics simulations further confirmed our findings and prospected these compounds to show significant <i>in vitro</i> results in their future pharmacological studies.</p>","PeriodicalId":16440,"journal":{"name":"Journal of medicinal food","volume":null,"pages":null},"PeriodicalIF":1.7000,"publicationDate":"2024-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Could Mushrooms' Secondary Metabolites Ameliorate Alzheimer Disease? 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Respective key amino acid contacts manifested the least steric problems according to their Gibbs free binding energies, Glide XP scores, RMSD values, and molecular orientation respect to the key amino acids. 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引用次数: 0
摘要
在此,我们强调在进行体外和体内研究之前采用分子建模方法的重要性,尤其是对于神经系统异常等没有公认治疗方法的疾病。阿尔茨海默病是一种神经退行性疾病,会导致不可逆的认知能力下降。我们使用 Maestro 软件中的 Qikprop 平台和 Discovery Studio 2.0 分别进行了毒性和 ADMET 研究,从过去十年中从蘑菇中分离出来的超过 45 种复审化合物中筛选出了有前景的骨架。利用Maestro和Cresset Flare平台,在β-分泌酶(BACE1)和乙酰胆碱酯酶(ACHE)的结合位点采用刚性和柔性分子对接方法,如诱导拟合对接(IFD),通过与标准药物多奈哌齐和(2E)-2-亚氨基-3-甲基-5,5-二苯基咪唑烷-4-酮(OKK)进行高精度分子对接,筛选出有前景的结构。通过测量分子相互作用、结合距离和 RMSD 值,揭示了这两种神经退行性酶结合位点的关键相互作用。对 IFD 结果的分析表明,双喹唑 A 和玄参素 I 在 4ey7 的口袋中结合一致,而 inonophenol A、甘霉素和 fornicin 与 4dju 的结合相当吻合,表明其结合位置非常接近 ACHE 和 BACE1 的原生配体。根据它们的吉布斯自由结合能、Glide XP 分数、RMSD 值以及与关键氨基酸的分子方向,相应的关键氨基酸接触表现出最少的立体问题。分子动力学模拟进一步证实了我们的发现,并期待这些化合物在未来的药理研究中显示出显著的体外结果。
Could Mushrooms' Secondary Metabolites Ameliorate Alzheimer Disease? A Computational Flexible Docking Investigation.
Herein, we highlight the significance of molecular modeling approaches prior to in vitro and in vivo studies; particularly, in diseases with no recognized treatments such as neurological abnormalities. Alzheimer disease is a neurodegenerative disorder that causes irreversible cognitive decline. Toxicity and ADMET studies were conducted using the Qikprop platform in Maestro software and Discovery Studio 2.0, respectively, to select the promising skeletons from more than 45 reviewed compounds isolated from mushrooms in the last decade. Using rigid and flexible molecular docking approaches such as induced fit docking (IFD) in the binding sites of β-secretase (BACE1) and acetylcholine esterase (ACHE), promising structures were screened through high precision molecular docking compared with standard drugs donepezil and (2E)-2-imino-3-methyl-5,5-diphenylimidazolidin-4-one (OKK) using Maestro and Cresset Flare platforms. Molecular interactions, binding distances, and RMSD values were measured to reveal key interactions at the binding sites of the two neurodegenerative enzymes. Analysis of IFD results revealed consistent bindings of dictyoquinazol A and gensetin I in the pocket of 4ey7 while inonophenol A, ganomycin, and fornicin fit quite well in 4dju demonstrating binding poses very close to native ligands at ACHE and BACE1. Respective key amino acid contacts manifested the least steric problems according to their Gibbs free binding energies, Glide XP scores, RMSD values, and molecular orientation respect to the key amino acids. Molecular dynamics simulations further confirmed our findings and prospected these compounds to show significant in vitro results in their future pharmacological studies.
期刊介绍:
Journal of Medicinal Food is the only peer-reviewed journal focusing exclusively on the medicinal value and biomedical effects of food materials. International in scope, the Journal advances the knowledge of the development of new food products and dietary supplements targeted at promoting health and the prevention and treatment of disease.