甲型流感病毒M2基因序列中双重金刚烷胺抗性突变近期上升情况的调查。

Investigation of a recent rise of dual amantadine-resistance mutations in the influenza A M2 sequence.

作者信息

Durrant Matthew G, Eggett Dennis L, Busath David D

出版信息

BMC Genet. 2015;16 Suppl 2(Suppl 2):S3. doi: 10.1186/1471-2156-16-S2-S3. Epub 2015 Apr 23.

DOI:10.1186/1471-2156-16-S2-S3

PMID:25953496

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4423576/

Abstract

BACKGROUND

The S31N amantadine-resistance mutation in the influenza A M2 sequence currently occurs more frequently in nature than the S31 wild type. Overcoming the resistance of the S31N mutation is the primary focus of M2 researchers who aim to develop novel antiviral therapies. Recent studies have noted a possible rise in frequency of the V27A/S31N double amantadine-resistance mutation in recent years. The purpose of this study is to investigate this recent rise in frequency of the double mutation and any possible bias of the other mutations toward co-occurrence with S31N or S31 strains.

RESULTS

The primary dataset used for this study was comprised of 24,152 influenza A M2 channel sequences which were downloaded from UniProt. There is an increased frequency for the S31N/V27A dual AR mutation in recent years, especially in swine. A test for difference in two proportions indicates that the V27A mutation is co-occurring with S31N more often than expected (p-value<0.001) when considering individual amino acid frequencies. At the same time, the different propensities for the V27A as compared to the V27T dual mutant may reflect differences in viral fitness or protein energetics, and this information could be exploited to focus drug development so as to reduce further drug insensitivity.

CONCLUSIONS

The development of the S31N/V27A variant in the Midwestern US swine may be a harbinger of novel human strain development. V27A/S31N is a possible path forward for the evolution of M2 which may convey a new level of drug resistance and should receive attention in drug design.

摘要

背景

甲型流感病毒M2序列中的S31N金刚烷胺耐药突变目前在自然界中出现的频率比S31野生型更高。克服S31N突变的耐药性是旨在开发新型抗病毒疗法的M2研究人员的主要关注点。最近的研究指出，近年来V27A/S31N双重金刚烷胺耐药突变的频率可能有所上升。本研究的目的是调查这种双重突变频率最近的上升情况以及其他突变与S31N或S31菌株共发生的任何可能偏差。

结果

本研究使用的主要数据集由从UniProt下载的24,152个甲型流感病毒M2通道序列组成。近年来，S31N/V27A双重耐药突变的频率有所增加，尤其是在猪身上。两项比例差异测试表明，在考虑单个氨基酸频率时，V27A突变与S31N同时出现的频率高于预期（p值<0.001）。同时，与V27T双重突变体相比，V27A的不同倾向可能反映了病毒适应性或蛋白质能量学的差异，并且可以利用这些信息来聚焦药物开发，以降低进一步的药物不敏感性。

结论

美国中西部猪中S31N/V27A变体的出现可能是新型人类毒株出现的先兆。V27A/S31N是M2进化的一条可能途径，可能会带来新的耐药水平，应在药物设计中予以关注。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6afb/4423576/41a23a5e77bf/1471-2156-16-S2-S3-1.jpg

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甲型流感病毒M2基因序列中双重金刚烷胺抗性突变近期上升情况的调查。

Investigation of a recent rise of dual amantadine-resistance mutations in the influenza A M2 sequence.

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背景

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