De novo Designing of the Antimicrobial Peptide as a Curative Agent for Methicillin-Resistant Staphylococcus aureus through a Computational Approach.

Recent advances in anti-infective drug discovery Pub Date : 2024-05-03 DOI:10.2174/0127724344297458240415113008

Priyanka Sinoliya, Pooran Singh Solanki, Ravi Ranjan Kumar Niraj, Vinay Sharma

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Abstract

Background: The emergence of resistance to multiple drugs has posed a multitude of difficulties that demand immediate attention and solutions. Multiple drug resistance arises from the accumulation of numerous genes within a single cell, each conferring resistance to a specific drug, and from the heightened expression of genes responsible for multidrug efflux pumps. These pumps effectively expel a diverse array of drugs from the cell.

Objective: The multi-drug-resistant organisms, including methicillin-resistant Staphylococcus aureus, are the hub of numerous diseases, from minute ailments to fatal diseases, like catheter infections. Nowadays, a combination of many antibiotics is given together as a multimodality therapy to cure MRSA infections. However, researchers are exploring novel approaches to find better solutions.

Methods: De novo designing of the peptide sequences has been done through an in silico tool. The peptides were further screened using different computational methods. Following this, the selection was conducted utilizing physicochemical properties as criteria. Molecular docking of the selected peptide sequence was carried out. Based on the highest docking score, the model complex was chosen for validation purposes by conducting studies through molecular dynamics simulations.

Results: A total of fifty-two novel antimicrobial peptides were designed and evaluated based on various parameters, targeting MRSA-specific proteins PBP2a and PVL toxin. Among these designed peptides, the peptide sequence VILRMFYHWAVKTNGP emerged as the optimal candidate, satisfying all the necessary parameters to be an effective antimicrobial peptide.

Conclusion: Molecular docking and MD simulation results showed that the designed peptide sequence could be the possible solution for MRSA treatment.

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通过计算方法重新设计抗菌肽作为耐甲氧西林金黄色葡萄球菌的治疗药物

背景：多种药物耐药性的出现带来了诸多困难，需要立即予以关注和解决。多重耐药性的产生是由于单个细胞内积累了大量基因，每种基因都对特定药物产生耐药性，以及负责多种药物外排泵的基因表达量增加。这些泵能有效地将多种药物排出细胞：耐多药生物（包括耐甲氧西林金黄色葡萄球菌）是众多疾病（从微小疾病到致命疾病，如导管感染）的根源。如今，人们将多种抗生素组合在一起作为多模式疗法来治疗 MRSA 感染。然而，研究人员正在探索新的方法，以找到更好的解决方案：方法：肽序列的全新设计是通过硅学工具完成的。利用不同的计算方法对多肽进行了进一步筛选。随后，以物理化学特性为标准进行筛选。对选定的多肽序列进行了分子对接。根据最高的对接得分，通过分子动力学模拟进行研究，选择模型复合物进行验证：根据各种参数，针对 MRSA 特异性蛋白 PBP2a 和 PVL 毒素，共设计和评估了 52 种新型抗菌肽。在这些设计的多肽中，多肽序列 VILRMFYHWAVKTNGP 满足成为有效抗菌肽的所有必要参数，成为最佳候选肽：分子对接和 MD 模拟结果表明，所设计的多肽序列可能是治疗 MRSA 的一种解决方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Recent advances in anti-infective drug discovery

CiteScore

1.80

自引率

0.00%

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