利用分子对接、DFT和分子动力学模拟对阿莫西林及其类似物对细菌DNA旋切酶B的多药理作用进行评价

Miah Roney , Gagandeep Singh , Amit Dubey , Hemant Soni , Smriti Tandon , Cheemlapati Venkata Narasimhaji , Aisha Tufail , Moyeenul Huq Akm , Mohd Fadhlizil Fasihi Mohd Aluwi
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引用次数: 0

摘要

耐药病原体的出现和传播有所增加,导致抗微生物耐药性病例急剧上升。因此,迫切需要开发和鉴定新的抗菌药物,以对抗这种抗微生物耐药性的威胁。但这种需求并没有通过专注于一分子一靶点方法的传统药物发现来完全满足。多药生态学,即以作用于多个细胞或分子靶点的方式设计药物,是鉴定抗菌化合物的一种新方法,已经引起了人们的关注。DNA旋转酶B是参与大肠杆菌DNA复制和细胞分裂的关键蛋白之一。在本研究中,采用分子对接、结构相似性、DFT和分子动力学模拟等多种计算机方法,研究了阿莫西林及其类似物对大肠杆菌DNA聚合酶B和其他各种蛋白质的多药作用。阿莫西林及其类似物头孢克洛都倾向于破坏细菌细胞壁的合成,但这项基于计算机分析的研究表明,可能还有一种涉及大肠杆菌DNA聚合酶B的额外作用模式,可以进一步探索以设计新的双靶点抑制剂。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Polypharmacological assessment of Amoxicillin and its analogues against the bacterial DNA gyrase B using molecular docking, DFT and molecular dynamics simulation

There has been an increase in the emergence and spread of drug-resistant pathogens, leading to a steep incline in the cases of antimicrobial resistance. Due to this, there is an imperative need for the development and identification of new antimicrobials to combat this menace of antimicrobial resistance. But this need is not being completely fulfilled by conventional drug discovery focused on a one molecule-one target approach. Polypharmacology, i.e., designing a drug in a way that acts on multiple cellular or molecular targets, a new approach for the identification of antimicrobial compounds, has been gaining attention. DNA gyrase B is one of the critical proteins involved in DNA replication and cell division in E. coli. In this study, the polypharmacological effect of amoxicillin and its analogues was studied on the DNA gyrase B and various other proteins of E. coli, using multiple in silico approaches like molecular docking, structural similarity, DFT, and molecular dynamics simulation. Both amoxicillin and its analogue, Cefaclor, tend to disrupt bacterial cell wall synthesis, but this study, based on in silico analysis, suggests a probable additional mode of action involving DNA gyrase B of E. coli which can be further explored to design novel dual-target inhibitors.

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Aspects of molecular medicine
Aspects of molecular medicine Molecular Biology, Molecular Medicine
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