λ噬菌体主要尾部蛋白结构揭示了长尾噬菌体和VI型细菌分泌系统的共同进化。
The phage lambda major tail protein structure reveals a common evolution for long-tailed phages and the type VI bacterial secretion system.
作者信息
Pell Lisa G, Kanelis Voula, Donaldson Logan W, Howell P Lynne, Davidson Alan R
机构信息
Department of Biochemistry, University of Toronto, Medical Sciences Building, Toronto, ON M5S 1A8, Canada.
出版信息
Proc Natl Acad Sci U S A. 2009 Mar 17;106(11):4160-5. doi: 10.1073/pnas.0900044106. Epub 2009 Feb 27.
Abstract
Most bacteriophages possess long tails, which serve as the conduit for genome delivery. We report the solution structure of the N-terminal domain of gpV, the protein comprising the major portion of the noncontractile phage lambda tail tube. This structure is very similar to a previously solved tail tube protein from a contractile-tailed phage, providing the first direct evidence of an evolutionary connection between these 2 distinct types of phage tails. A remarkable structural similarity is also seen to Hcp1, a component of the bacterial type VI secretion system. The hexameric structure of Hcp1 and its ability to form long tubes are strikingly reminiscent of gpV when it is polymerized into a tail tube. These data coupled with other similarities between phage and type VI secretion proteins support an evolutionary relationship between these systems. Using Hcp1 as a model, we propose a polymerization mechanism for gpV involving several disorder-to-order transitions.
摘要
大多数噬菌体都有长尾巴,这些尾巴充当基因组传递的通道。我们报道了gpV N端结构域的溶液结构,gpV是构成非收缩性噬菌体λ尾管主要部分的蛋白质。该结构与先前解析的收缩尾噬菌体的尾管蛋白非常相似,这为这两种不同类型的噬菌体尾巴之间的进化联系提供了首个直接证据。与细菌VI型分泌系统的一个组分Hcp1也存在显著的结构相似性。Hcp1的六聚体结构及其形成长管的能力,与聚合形成尾管的gpV惊人地相似。这些数据以及噬菌体和VI型分泌蛋白之间的其他相似性,支持了这些系统之间的进化关系。以Hcp1为模型,我们提出了gpV的聚合机制,该机制涉及多个无序到有序的转变。
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