基因工程模拟无包膜病毒进入中间产物的结构与功能。
Structure and function of a genetically engineered mimic of a nonenveloped virus entry intermediate.
机构信息
Department of Molecular Biology, The Scripps Research Institute, La Jolla, CA 92037, USA.
出版信息
J Virol. 2010 May;84(9):4737-46. doi: 10.1128/JVI.02670-09. Epub 2010 Feb 17.
Abstract
Divalent metal ions are components of numerous icosahedral virus capsids. Flock House virus (FHV), a small RNA virus of the family Nodaviridae, was utilized as an accessible model system with which to address the effects of metal ions on capsid structure and on the biology of virus-host interactions. Mutations at the calcium-binding sites affected FHV capsid stability and drastically reduced virus infectivity, without altering the overall architecture of the capsid. The mutations also altered the conformation of gamma, a membrane-disrupting, virus-encoded peptide usually sequestered inside the capsid, by increasing its exposure under neutral pH conditions. Our data demonstrate that calcium binding is essential for maintaining a pH-based control on gamma exposure and host membrane disruption, and they reveal a novel rationale for the metal ion requirement during virus entry and infectivity. In the light of the phenotypes displayed by a calcium site mutant of FHV, we suggest that this mutant corresponds to an early entry intermediate formed in the endosomal pathway.
摘要
二价金属离子是许多二十面体病毒衣壳的组成部分。禽正粘病毒(FHV)是一种小 RNA 病毒,属于正粘病毒科,它被用作一个易于研究的模型系统,用于研究金属离子对衣壳结构以及病毒-宿主相互作用生物学的影响。钙结合位点的突变影响了 FHV 衣壳的稳定性,并极大地降低了病毒的感染力,而不改变衣壳的整体结构。这些突变还通过增加其在中性 pH 条件下的暴露,改变了通常被隔离在衣壳内的膜破坏病毒编码肽γ的构象。我们的数据表明,钙结合对于维持基于 pH 的对γ暴露和宿主膜破坏的控制至关重要,并且它们揭示了病毒进入和感染性过程中金属离子需求的新原理。鉴于 FHV 的钙结合位点突变体所表现出的表型,我们推测该突变体对应于在内体途径中形成的早期进入中间产物。
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