1998年后选择的H5N1流感病毒NS基因增强了病毒在哺乳动物细胞中的复制。

The H5N1 influenza virus NS genes selected after 1998 enhance virus replication in mammalian cells.

作者信息

Twu Karen Y, Kuo Rei-Lin, Marklund Jesper, Krug Robert M

机构信息

Institute for Cellular and Molecular Biology, University of Texas at Austin, 2500 Speedway, Austin, TX 78712, USA.

出版信息

J Virol. 2007 Aug;81(15):8112-21. doi: 10.1128/JVI.00006-07. Epub 2007 May 23.

DOI:10.1128/JVI.00006-07

PMID:17522219

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1951328/

Abstract

The NS1A proteins of human influenza A viruses bind CPSF30, a cellular factor required for the processing of cellular pre-mRNAs, thereby inhibiting the production of all cellular mRNAs, including beta interferon mRNA. Here we show that the NS1A protein of the pathogenic H5N1 influenza A/Hong Kong/483/97 (HK97) virus isolated from humans has an intrinsic defect in CPSF30 binding. It does not bind CPSF30 in vitro and causes high beta interferon mRNA production and reduced virus replication in MDCK cells when expressed in a recombinant virus in which the other viral proteins are encoded by influenza A/Udorn/72. We traced this defect to the identities of amino acids 103 and 106 in the HK97 NS1A protein, which differ from the consensus amino acids, F and M, respectively, found in the NS1A proteins of almost all human influenza A virus strains. X-ray crystallography has shown that F103 and M106, which are not part of the CPSF30 binding pocket of the NS1A protein, stabilize the NS1A-CPSF30 complex. In contrast to the HK97 NS1A protein, the NS1A proteins of H5N1 viruses isolated from humans after 1998 contain F103 and M106 and hence bind CPSF30 in vitro and do not attenuate virus replication. The HK97 NS1A protein is less attenuating when expressed in a virus that also encodes the other internal HK97 proteins and under these conditions binds to CPSF30 to a substantial extent in vivo. Consequently, these internal HK97 proteins largely compensate for the absence of F103 and M106, presumably by stabilizing the NS1A-CPSF30 complex.

摘要

人类甲型流感病毒的NS1A蛋白与CPSF30结合，CPSF30是细胞前体mRNA加工所需的一种细胞因子，从而抑制包括β干扰素mRNA在内的所有细胞mRNA的产生。在此我们表明，从人类分离出的致病性H5N1甲型流感病毒A/香港/483/97（HK97）的NS1A蛋白在与CPSF30结合方面存在内在缺陷。它在体外不与CPSF30结合，当在一种重组病毒中表达时，会导致β干扰素mRNA大量产生，并使MDCK细胞中的病毒复制减少，在该重组病毒中其他病毒蛋白由甲型流感病毒A/乌栋/72编码。我们将此缺陷追溯到HK97 NS1A蛋白中第103和106位氨基酸的特性，它们分别与几乎所有人类甲型流感病毒株的NS1A蛋白中发现的共有氨基酸F和M不同。X射线晶体学研究表明，并非NS1A蛋白CPSF30结合口袋一部分的F103和M106会稳定NS1A - CPSF30复合物。与HK97 NS1A蛋白相反，1998年后从人类分离出的H5N1病毒的NS1A蛋白含有F103和M106，因此在体外与CPSF30结合，且不会减弱病毒复制。当HK97 NS1A蛋白在一种也编码其他HK97内部蛋白的病毒中表达时，其减毒作用较小，在这些条件下，它在体内能在很大程度上与CPSF30结合。因此，这些HK97内部蛋白在很大程度上弥补了F103和M106的缺失，大概是通过稳定NS1A - CPSF30复合物来实现的。

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