Fu Chi-yu, Morais Marc C, Battisti Anthony J, Rossmann Michael G, Prevelige Peter E
Department of Biochemistry and Molecular Genetics, University of Alabama at Birmingham, AL35294, USA.
J Mol Biol. 2007 Mar 2;366(4):1161-73. doi: 10.1016/j.jmb.2006.11.091. Epub 2006 Dec 6.
An in vitro assembly system was developed to study prolate capsid assembly of phage ø29 biochemically, and to identify regions of scaffolding protein required for its functions. The crowding agent polyethylene glycol can induce bacteriophage ø29 monomeric capsid protein and dimeric scaffolding protein to co-assemble to form particles which have the same geometry as either prolate T=3 Q=5 procapsids formed in vivo or previously observed isometric particles. The formation of particles is a scaffolding-dependent reaction. The balance between the fidelity and efficiency of assembly is controlled by the concentration of crowding agent and temperature. The assembly process is salt sensitive, suggesting that the interactions between the scaffolding and coat proteins are electrostatic. Three N-terminal ø29 scaffolding protein deletion mutants, Delta 1-9, Delta 1-15 and Delta 1-22, abolish the assembly activity. Circular dichroism spectra indicate that these N-terminal deletions are accompanied by a loss of helicity. The inability of these proteins to dimerize suggests that the N-terminal region of the scaffolding protein contributes to the dimer interface and maintains the structural integrity of the dimeric protein. Two C-terminal scaffolding protein deletion mutants, Delta 79-97 and Delta 62-97, also fail to promote assembly. However, the secondary structure and the dimerization ability of these mutants are unchanged relative to wild-type, which suggests that the C terminus is the likely site of interaction with the capsid protein.
开发了一种体外组装系统,用于从生化角度研究噬菌体φ29的长形衣壳组装,并鉴定支架蛋白发挥其功能所需的区域。拥挤剂聚乙二醇可诱导噬菌体φ29单体衣壳蛋白和二聚体支架蛋白共同组装形成颗粒,这些颗粒具有与体内形成的长形T=3 Q=5原衣壳或先前观察到的等轴颗粒相同的几何形状。颗粒的形成是一个依赖支架的反应。组装的保真度和效率之间的平衡由拥挤剂的浓度和温度控制。组装过程对盐敏感,这表明支架蛋白和衣壳蛋白之间的相互作用是静电作用。三个N端φ29支架蛋白缺失突变体Delta 1-9、Delta 1-15和Delta 1-22消除了组装活性。圆二色光谱表明,这些N端缺失伴随着螺旋度的丧失。这些蛋白无法二聚化表明,支架蛋白的N端区域有助于二聚体界面并维持二聚体蛋白的结构完整性。两个C端支架蛋白缺失突变体Delta 79-97和Delta 62-97也未能促进组装。然而,相对于野生型,这些突变体的二级结构和二聚化能力没有变化,这表明C端可能是与衣壳蛋白相互作用的位点。