Rajib Hossain, S. Mahmud, A. B. R. Khalipha, A. S. M. Saikat, Dipta Dey, R. Khan, A. Rauf, Abdur Abdul Wadood, Humaria Rafique, Sami Bawazeer, A. A. Khalil, Z. Almarhoon, Y. Mabkhot, K. Alzahrani, M. T. Islam, K. Alsharif, H. Khan
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In this study, in-silico analysis were performed on derivatives of amentoflavone (4′, 4′′′-Dimethylamentoflavone, 4′′′, 7-Di-O-Methylamentoflavone, 4′′′′′′-methylamentoflavone, 4′-Monomethylamentoflavone, 7,4′-Dimethylamentoflavone, 7′-O-Methylamentoflavone, 7-O-methylamentoflavone, Heveaflavone, kayaflavone, and Sciadopitysin) and FDA approved anti-viral drug (camostatmesylate). All the derivatives of amentoflavone and FDA-approved anti-viral drugs were docked against SARS-CoV2 main protease (MPRO). The ten derivatives of amentoflavone showed strong interactions with the MPRO protein. In all cases, derivatives of amentoflavone showed good interaction with the targeted protein and better binding/docking score (–9.0351, –8.8566, –8.8509, –8.7746, –8.6192, –8.2537, –8.0876, –7.9501, –7.6429, and –7.6248 respectively) than FDA approved anti-viral drug. Therefore, derivatives of amentoflavone may be potent leads in drug discovery to combat HCoVs, such as SARS-CoV2. 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引用次数: 0
摘要
在全球范围内,由于迄今没有有效的药物或疫苗,新型冠状病毒(nCoV19)疫情是人类非常关注的问题。因此,开发具有抗新冠病毒潜力的药物需要时间。在这种情况下,与其他实验研究相比,计算机研究已被证明是快速、廉价和有效的。显然,天然产物在治疗不同疾病的药物开发中显示出巨大的潜力,这为抗新冠病毒药物的筛选开辟了新的领域。本研究对氨基黄酮衍生物(4,4 ',4 ' ',7- 2 - o -甲氨基黄酮,4 ' ' -甲氨基黄酮,4 ' -单甲氨基黄酮,7,4 ' -二甲氨基黄酮,7 ' - o -甲氨基黄酮,7- o -甲氨基黄酮,heve黄酮,kay黄酮和Sciadopitysin)和FDA批准的抗病毒药物(camostatmesylate)进行了硅质分析。所有阿门托黄酮衍生物和fda批准的抗病毒药物均与SARS-CoV2主蛋白酶(MPRO)对接。杏叶黄酮的10个衍生物均与MPRO蛋白有较强的相互作用。在所有病例中,阿门黄酮衍生物与目标蛋白的相互作用良好,结合/对接评分(-9.0351、-8.8566、-8.8509、-8.7746、-8.6192、-8.2537、-8.0876、-7.9501、-7.6429和-7.6248)均优于FDA批准的抗病毒药物。因此,阿门托黄酮的衍生物可能是对抗hcov(如SARS-CoV2)的药物发现的有力线索。此外,为了支持本研究的结果,需要进一步的体内研究。
Amentoflavone derivatives against SARS-CoV-2 main protease (MPRO): An in silico study
Globally, novel coronavirus (nCoV19) outbreak is a great concern to humanity owing to the unavailability of effective medication or vaccine to date. Therefore, the development of drugs having anti-COVID-19 potential is a need of time. In this milieu, in-silico studies have proven to be rapid, inexpensive and effective as compared to other experimental studies. Evidently, natural products have shown significant potential in drug development to curtail different ailments, which have opened a new horizon in the screening of anti-COVID-19 agents. In this study, in-silico analysis were performed on derivatives of amentoflavone (4′, 4′′′-Dimethylamentoflavone, 4′′′, 7-Di-O-Methylamentoflavone, 4′′′′′′-methylamentoflavone, 4′-Monomethylamentoflavone, 7,4′-Dimethylamentoflavone, 7′-O-Methylamentoflavone, 7-O-methylamentoflavone, Heveaflavone, kayaflavone, and Sciadopitysin) and FDA approved anti-viral drug (camostatmesylate). All the derivatives of amentoflavone and FDA-approved anti-viral drugs were docked against SARS-CoV2 main protease (MPRO). The ten derivatives of amentoflavone showed strong interactions with the MPRO protein. In all cases, derivatives of amentoflavone showed good interaction with the targeted protein and better binding/docking score (–9.0351, –8.8566, –8.8509, –8.7746, –8.6192, –8.2537, –8.0876, –7.9501, –7.6429, and –7.6248 respectively) than FDA approved anti-viral drug. Therefore, derivatives of amentoflavone may be potent leads in drug discovery to combat HCoVs, such as SARS-CoV2. Moreover, to support the outcomes of this study further in-vivo investigations are required.
期刊介绍:
Main Group Chemistry is intended to be a primary resource for all chemistry, engineering, biological, and materials researchers in both academia and in industry with an interest in the elements from the groups 1, 2, 12–18, lanthanides and actinides. The journal is committed to maintaining a high standard for its publications. This will be ensured by a rigorous peer-review process with most articles being reviewed by at least one editorial board member. Additionally, all manuscripts will be proofread and corrected by a dedicated copy editor located at the University of Kentucky.