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乙型流感病毒聚合酶PB2亚基识别mRNA帽结构的分子基础

Molecular Basis of mRNA Cap Recognition by Influenza B Polymerase PB2 Subunit.

作者信息

Xie Lili, Wartchow Charles, Shia Steven, Uehara Kyoko, Steffek Micah, Warne Robert, Sutton James, Muiru Gladys T, Leonard Vincent H J, Bussiere Dirksen E, Ma Xiaolei

机构信息

From the Divisions of Protein Sciences.

Structural and Biophysical Chemistry, Global Discovery Chemistry.

出版信息

J Biol Chem. 2016 Jan 1;291(1):363-70. doi: 10.1074/jbc.M115.693051. Epub 2015 Nov 11.

DOI:10.1074/jbc.M115.693051
PMID:26559973
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4697171/
Abstract

Influenza virus polymerase catalyzes the transcription of viral mRNAs by a process known as "cap-snatching," where the 5'-cap of cellular pre-mRNA is recognized by the PB2 subunit and cleaved 10-13 nucleotides downstream of the cap by the endonuclease PA subunit. Although this mechanism is common to both influenza A (FluA) and influenza B (FluB) viruses, FluB PB2 recognizes a wider range of cap structures including m(7)GpppGm-, m(7)GpppG-, and GpppG-RNA, whereas FluA PB2 utilizes methylated G-capped RNA specifically. Biophysical studies with isolated PB2 cap-binding domain (PB2(cap)) confirm that FluB PB2 has expanded mRNA cap recognition capability, although the affinities toward m(7)GTP are significantly reduced when compared with FluA PB2. The x-ray co-structures of the FluB PB2(cap) with bound cap analogs m(7)GTP and GTP reveal an inverted GTP binding mode that is distinct from the cognate m(7)GTP binding mode shared between FluA and FluB PB2. These results delineate the commonalities and differences in the cap-binding site between FluA and FluB PB2 and will aid structure-guided drug design efforts to identify dual inhibitors of both FluA and FluB PB2.

摘要

流感病毒聚合酶通过一种称为“帽抢夺”的过程催化病毒mRNA的转录,在这个过程中,细胞前体mRNA的5'-帽被PB2亚基识别,并被核酸内切酶PA亚基在帽下游10-13个核苷酸处切割。尽管这种机制在甲型流感(FluA)病毒和乙型流感(FluB)病毒中都很常见,但FluB PB2识别更广泛的帽结构,包括m(7)GpppGm-、m(7)GpppG-和GpppG-RNA,而FluA PB2则专门利用甲基化的G帽RNA。对分离的PB2帽结合结构域(PB2(cap))进行的生物物理研究证实,FluB PB2具有扩展的mRNA帽识别能力,尽管与FluA PB2相比,其对m(7)GTP的亲和力显著降低。FluB PB2(cap)与结合的帽类似物m(7)GTP和GTP的X射线共结构揭示了一种反向的GTP结合模式,这与FluA和FluB PB2共享的同源m(7)GTP结合模式不同。这些结果描绘了FluA和FluB PB2之间帽结合位点的共性和差异,并将有助于指导基于结构的药物设计,以识别FluA和FluB PB2的双重抑制剂。

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