An in silico investigation of allosteric inhibition potential of Dihydroergotamine against Sars-CoV-2 Main Protease (MPro)

Q3 Biochemistry, Genetics and Molecular Biology Turkish Computational and Theoretical Chemistry Pub Date : 2023-01-15 DOI:10.33435/tcandtc.1121985

M. Yaşar, Ekrem Yaşar, Nuri Yorulmaz, Emin Tenekeci̇, İ. Sarpün, E. Eroglu

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Abstract

Possible allosteric inhibitors of MPro were investigated using in silico methods. To this end, FDA-approved drugs in the DrugBank database were subjected to virtual screening, and drugs that strongly bind distant from the catalytic site of MPro were identified using molecular docking. Among the identified drugs, Dihydroergotamine (DHE) was chosen for further investigation due to its highest binding score against MPro in the molecular docking experiment. The allosteric inhibition potential of DHE toward MPro was demonstrated by applying some computational tools on the trajectory files which were obtained from the Molecular Dynamics Simulations. Results support that the hydrogen bonding interactions of DHE with GLU278 and THR280, located between Protomer A and Protomer B, affect the structure of the side chain of CYS145 at the catalytic site of MPro. Considering the role of CYS145 in the catalytic cycle, this structural change is likely to be a mechanism for inhibiting MPro.

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二氢麦角胺对Sars-CoV-2主蛋白酶(MPro)变构抑制电位的计算机模拟研究

用硅片法研究了MPro可能的变构抑制剂。为此，在DrugBank数据库中对fda批准的药物进行虚拟筛选，并利用分子对接方法鉴定远离MPro催化位点的强结合药物。在已确定的药物中，二氢麦角胺(DHE)在分子对接实验中与MPro的结合得分最高，因此选择了二氢麦角胺(DHE)进行进一步研究。应用计算工具对分子动力学模拟得到的轨迹文件进行了分析，证明了DHE对MPro的变构抑制潜力。结果支持DHE与位于原聚体A和B之间的GLU278和THR280的氢键相互作用影响了MPro催化位点CYS145侧链的结构。考虑到CYS145在催化循环中的作用，这种结构变化很可能是抑制MPro的机制。

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来源期刊

Turkish Computational and Theoretical Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (miscellaneous)

CiteScore

2.40

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0.00%

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