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T7 弹射体组装:故事展开了。

T7 ejectosome assembly: A story unfolds.

作者信息

Leptihn Sebastian, Gottschalk Julia, Kuhn Andreas

机构信息

Institute of Microbiology and Molecular Biology, University of Hohenheim , Stuttgart, Germany.

出版信息

Bacteriophage. 2016 Feb 18;6(1):e1128513. doi: 10.1080/21597081.2015.1128513. eCollection 2016 Jan-Mar.

DOI:10.1080/21597081.2015.1128513
PMID:27144087
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4836469/
Abstract

T7 phage DNA is transported from the capsid into the host cytoplasm across the cell wall by an ejectosome comprised of the viral proteins gp14, gp15 and gp16. Prior to infection, these proteins form the so-called internal core in the mature virion. Gp16 was shown to associate with pure phospholipid bilayers while gp15 bound to DNA. A complex of both proteins appears as spiral-like rods in electron micrographs. It was also shown that the proteins gp15 and gp16 have the propensity to regain their full structure after thermal unfolding. From these observations it was concluded that (partial) unfolding of the proteins occurs during the translocation through the narrow portal of the phage capsid. After leaving the phage head, the proteins refold to form the ejectosome channel across the periplasm of the host. In this work, we analyzed the structure of gp15 and gp16 in presence of lipids and their stability toward chemical denaturants. A model to explain how the ejectosome might assemble in the host cell is discussed.

摘要

T7噬菌体DNA通过由病毒蛋白gp14、gp15和gp16组成的弹射体,穿过细胞壁从衣壳转运到宿主细胞质中。在感染之前,这些蛋白质在成熟病毒粒子中形成所谓的内部核心。已表明gp16与纯磷脂双层结合,而gp15与DNA结合。在电子显微镜照片中,这两种蛋白质的复合物呈现为螺旋状杆。还表明,蛋白质gp15和gp16在热变性后有恢复其完整结构的倾向。从这些观察结果得出的结论是,蛋白质在通过噬菌体衣壳狭窄的门户转运过程中发生(部分)变性。离开噬菌体头部后,这些蛋白质重新折叠,形成穿过宿主周质的弹射体通道。在这项工作中,我们分析了脂质存在下gp15和gp16的结构及其对化学变性剂的稳定性。讨论了一个解释弹射体如何在宿主细胞中组装的模型。

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