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完整鼻病毒RNA聚合酶的晶体结构表明蛋白质引物的前端加载。

Crystal structure of complete rhinovirus RNA polymerase suggests front loading of protein primer.

作者信息

Appleby Todd C, Luecke Hartmut, Shim Jae Hoon, Wu Jim Z, Cheney I Wayne, Zhong Weidong, Vogeley Lutz, Hong Zhi, Yao Nanhua

机构信息

Valeant Pharmaceuticals International, Costa Mesa, California 92626, USA.

出版信息

J Virol. 2005 Jan;79(1):277-88. doi: 10.1128/JVI.79.1.277-288.2005.

Abstract

Picornaviruses utilize virally encoded RNA polymerase and a uridylylated protein primer to ensure replication of the entire viral genome. The molecular details of this mechanism are not well understood due to the lack of structural information. We report the crystal structure of human rhinovirus 16 3D RNA-dependent RNA polymerase (HRV16 3Dpol) at a 2.4-A resolution, representing the first complete polymerase structure from the Picornaviridae family. HRV16 3Dpol shares the canonical features of other known polymerase structures and contains an N-terminal region that tethers the fingers and thumb subdomains, forming a completely encircled active site cavity which is accessible through a small tunnel on the backside of the molecule. The small thumb subdomain contributes to the formation of a large cleft on the front face of the polymerase which also leads to the active site. The cleft appears large enough to accommodate a template:primer duplex during RNA elongation or a protein primer during the uridylylation stage of replication initiation. Based on the structural features of HRV16 3Dpo1 and the catalytic mechanism known for all polymerases, a front-loading model for uridylylation is proposed.

摘要

微小核糖核酸病毒利用病毒编码的RNA聚合酶和尿苷酸化的蛋白质引物来确保整个病毒基因组的复制。由于缺乏结构信息,这种机制的分子细节尚未得到充分理解。我们报道了人鼻病毒16 3D RNA依赖性RNA聚合酶(HRV16 3Dpol)在2.4埃分辨率下的晶体结构,这是微小核糖核酸病毒科第一个完整的聚合酶结构。HRV16 3Dpol具有其他已知聚合酶结构的典型特征,并包含一个N端区域,该区域连接手指和拇指亚结构域,形成一个完全被包围的活性位点腔,可通过分子背面的一个小通道进入。小拇指亚结构域有助于在聚合酶正面形成一个大裂缝,该裂缝也通向活性位点。该裂缝似乎足够大,能够在RNA延伸过程中容纳模板:引物双链体,或在复制起始的尿苷酸化阶段容纳蛋白质引物。基于HRV16 3Dpo1的结构特征和所有聚合酶已知的催化机制,提出了尿苷酸化的前加载模型。

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