揭示流感病毒的抑制潜力:基于配体的植物化学物质和蓝藻代谢物的对接、药理学、MM-GBSA 和分子动力学模拟

John Maria Jancy Rani , Karunanithi Kalaimathi , Srinivasan Prabhu , Muniappan Ayyanar , Shine Kadaikunnan , Subramaniyan Vijayakumar , Sathammai Priya , Jayasree Sheshadri , Singamoorthy Amalraj , Muthu Thiruvengadam , Stanislaus Antony Ceasar
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引用次数: 0

摘要

全球旅行和现代化带来的病毒爆发对全球健康构成了重大威胁。流感病毒,尤其是 α 流感病毒和 β 流感病毒,自古以来一直困扰着人类。尽管它们的影响由来已久,但有效的药物尚未开发出来,而且同时感染这些病毒会导致严重的健康并发症。鉴于这些挑战,本研究旨在调查来自蓝藻和草药的潜在抗病毒分子。我们利用配体对接技术进行了虚拟筛选,以确定潜在的植物化学物质和蓝藻代谢物作为进一步评估的候选物质。随后,我们利用药理模型验证了所选化合物的结合模式,并通过 MM-GBSA 计算评估了它们在病毒靶标内的结合亲和力和稳定性。在所研究的分子中,蓝藻化合物 Symplocamide A (-8.042) 在对接过程中比对接配体中的草药分子表现出显著的效果。这一发现表明它具有作为甲型流感病毒蛋白治疗剂的潜力。此外,Lyngbyastatin 3 (-8.001)、Lyngbyastatin G1 (-7.501) 和 Kempenopeptide (-6.128) 等蓝藻分子表现出更强的结合亲和力和更有力的对接得分,使它们有望在潜在的治疗应用中靶向病毒蛋白。本研究揭示了利用蓝藻分子作为新型抗流感病毒药物的可能性。最终,我们相信这项研究将成为寻找抗病毒感染引起的呼吸道疾病的创新药物的垫脚石。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Unravelling the influenza virus inhibitory potential: Ligand-based docking, pharmacophore, MM-GBSA, and molecular dynamic simulation of phytochemicals and cyanobacteria metabolites

Unravelling the influenza virus inhibitory potential: Ligand-based docking, pharmacophore, MM-GBSA, and molecular dynamic simulation of phytochemicals and cyanobacteria metabolites

Viral outbreaks facilitated by global travel and modernity pose significant threats to global health. Influenza viruses, particularly α-influenza and β-influenza strains, have been plaguing human populations since time immemorial. Despite their long-standing impact, effective drugs are yet to be developed, and co-infection with these viruses can lead to severe health complications. In light of these challenges, this study aimed to investigate the potential antiviral molecules sourced from cyanobacteria and herbs. We conducted virtual screening using ligand-based docking to identify potential phytochemicals and cyanobacterial metabolites as candidates for further evaluation. Subsequently, pharmacophore modeling was employed to validate the binding modes of the selected compounds, followed by MM-GBSA calculations to assess their binding affinities and stabilities within the viral target. Among the molecules investigated, the cyanobacterial compound Symplocamide A (−8.042) demonstrated notable outcomes in docking than the herb molecules in the docked ligand. This finding suggests its potential as a therapeutic agent against influenza A virus proteins. Additionally, cyanobacterial molecules such as Lyngbyastatins 3 (−8.001), Lyngbyastatin G1 (−7.501), and Kempenopeptide (−6.128) exhibit stronger binding affinities and more potent docking scores, making them promising candidates for targeting viral proteins in potential therapeutic applications. The present study reveals the possibility of harnessing cyanobacterial molecules as novel antiviral agents against influenza viruses. Ultimately, we believe that this research will serve as a stepping stone in the quest for innovative drugs to combat respiratory diseases caused by viral infections.

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