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呼吸道合胞病毒糖蛋白的计算机模拟比较结构与组成分析,以研究呼吸道合胞病毒A亚型稳定性和传播性的本质

In silico comparative structural and compositional analysis of glycoproteins of RSV to study the nature of stability and transmissibility of RSV A.

作者信息

Mitra Debanjan, Das Mohapatra Pradeep K

机构信息

Department of Microbiology, Raiganj University, Raiganj, WB India.

出版信息

Syst Microbiol Biomanuf. 2023;3(2):312-327. doi: 10.1007/s43393-022-00110-x. Epub 2022 May 27.

DOI:10.1007/s43393-022-00110-x
PMID:38013803
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9135598/
Abstract

The current scenario of COVID-19 makes us to think about the devastating diseases that kill so many people every year. Analysis of viral proteins contributes many things that are utterly useful in the evolution of therapeutic drugs and vaccines. In this study, sequence and structure of fusion glycoproteins and major surface glycoproteins of respiratory syncytial virus (RSV) were analysed to reveal the stability and transmission rate. RSV A has the highest abundance of aromatic residues. The Kyte-Doolittle scale indicates the hydrophilic nature of RSV A protein which leads to the higher transmission rate of this virus. Intra-protein interactions such as carbonyl interactions, cation-pi, and salt bridges were shown to be greater in RSV A compared to RSV B, which might lead to improved stability. This study discovered the presence of a network aromatic-sulphur interaction in viral proteins. Analysis of ligand binding pocket of RSV proteins indicated that drugs are performing better on RSV B than RSV A. It was also shown that increasing the number of tunnels in RSV A proteins boosts catalytic activity. This study will be helpful in drug discovery and vaccine development.

摘要

当前的新冠疫情让我们思考每年导致众多人死亡的毁灭性疾病。对病毒蛋白的分析为治疗药物和疫苗的研发提供了许多极为有用的信息。在本研究中,对呼吸道合胞病毒(RSV)的融合糖蛋白和主要表面糖蛋白的序列和结构进行了分析,以揭示其稳定性和传播率。RSV A型病毒的芳香族残基丰度最高。凯泰-杜利特尔量表显示RSV A蛋白具有亲水性,这导致该病毒的传播率更高。与RSV B型病毒相比,RSV A型病毒中的羰基相互作用、阳离子-π相互作用和盐桥等蛋白内相互作用更强,这可能导致其稳定性提高。本研究发现病毒蛋白中存在一个芳香族-硫相互作用网络。对RSV蛋白配体结合口袋的分析表明,药物对RSV B型病毒的作用比对RSV A型病毒更好。研究还表明,增加RSV A蛋白中的通道数量可提高催化活性。本研究将有助于药物研发和疫苗开发。

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