Ni C Z, Syed R, Kodandapani R, Wickersham J, Peabody D S, Ely K R
Cancer Research Center, La Jolla Cancer Research Foundation, CA 92037, USA.
Structure. 1995 Mar 15;3(3):255-63. doi: 10.1016/S0969-2126(01)00156-3.
The coat protein in RNA bacteriophages binds and encapsidates viral RNA, and also acts as translational repressor of viral replicase by binding to an RNA hairpin in the RNA genome. Because of its dual function, the MS2 coat protein is an interesting candidate for structural studies of protein-RNA interactions and protein-protein interactions. In this study, unassembled MS2 coat protein dimers were selected to analyze repressor activity and virus assembly.
The crystal structure of a mutant MS2 coat protein that is defective in viral assembly yet retains repressor activity has been determined at 2.0 A resolution. The unassembled dimer is stabilized by interdigitation of alpha-helices, and the formation of a 10-stranded antiparallel beta-sheet across the interface between monomers. The substitution of arginine for tryptophan at residue 82 results in the formation of two new inter-subunit hydrogen bonds that further stabilize the dimer. Residues that influence RNA recognition, identified by molecular genetics, were located across the beta-sheet. Two of these residues (Tyr85 and Asn87) are displaced in the unliganded dimer and are located in the same beta-strand as the Trp-->Arg mutation.
When compared with the structure of the coat protein in the assembled virus, differences in orientation of residues 85 and 87 suggest conformational adjustment on binding RNA in the first step of viral assembly. The substitution at residue 82 may affect virus assembly by imposing conformational restriction on the loop that makes critical inter-subunit contacts in the capsid.
RNA噬菌体中的外壳蛋白结合并包裹病毒RNA,还通过与RNA基因组中的一个RNA发夹结构结合,作为病毒复制酶的翻译阻遏物。由于其双重功能,MS2外壳蛋白是蛋白质-RNA相互作用和蛋白质-蛋白质相互作用结构研究的一个有趣候选对象。在本研究中,选择未组装的MS2外壳蛋白二聚体来分析阻遏活性和病毒组装。
已确定一种在病毒组装方面有缺陷但仍保留阻遏活性的突变型MS2外壳蛋白的晶体结构,分辨率为2.0埃。未组装的二聚体通过α-螺旋的相互交错以及在单体之间的界面上形成一个10股反平行β-折叠而得以稳定。在第82位残基处用精氨酸取代色氨酸导致形成两个新的亚基间氢键,进一步稳定了二聚体。通过分子遗传学鉴定的影响RNA识别的残基位于β-折叠的两侧。其中两个残基(Tyr85和Asn87)在未结合配体的二聚体中发生位移,并且与色氨酸→精氨酸突变位于同一条β-链上。
与组装好的病毒中的外壳蛋白结构相比,第85和87位残基方向上的差异表明在病毒组装的第一步结合RNA时发生了构象调整。第82位残基处的取代可能通过对衣壳中形成关键亚基间接触的环施加构象限制来影响病毒组装。
