Rathinavelan Thenmalarchelvi, Im Wonpil
Department of Molecular Biosciences and Center for Bioinformatics, The University of Kansas, 2030 Becker Drive, Lawrence, Kansas 66047, USA.
J Comput Chem. 2008 Jul 30;29(10):1640-9. doi: 10.1002/jcc.20923.
Recent advances in NMR techniques to measure anisotropic spin interactions such as residual dipolar coupling (RDC) have provided better insights into protein structure as well as dynamics. Exploitation of RDC, however, still remains challenging because its successful application requires a reasonable starting model. Using the singular value decomposition method, we have recently developed an RDC restraint potential to optimally extract orientational information from RDC without the prerequisite of any structural information. In the present study, its efficacy is further illustrated by folding a beta-hairpin and alpha-helix of protein G from extended conformations with RDC restraints alone by employing the replica exchange torsion angle molecular dynamics (REX-TAMD) technique. Subsequently, the entire structure of protein G has been determined accurately using the developed fragment superposition method (FRAGSUM). In FRAGSUM, each overlapping fragments (10 amino acids long) is first folded individually by REX-TAMD, and then the common amino acids are superimposed to determine the entire structure. Because FRAGSUM does not require any additional information besides RDC, it offers a new strategy for de novo structure determination using exclusively RDC.
核磁共振(NMR)技术在测量诸如残余偶极耦合(RDC)等各向异性自旋相互作用方面的最新进展,为蛋白质结构以及动力学提供了更深入的见解。然而,RDC的利用仍然具有挑战性,因为其成功应用需要一个合理的初始模型。我们最近使用奇异值分解方法开发了一种RDC约束势,能够在无需任何结构信息的前提下,从RDC中最佳地提取取向信息。在本研究中,通过仅使用RDC约束,采用副本交换扭转角分子动力学(REX-TAMD)技术,将蛋白质G的β-发夹和α-螺旋从伸展构象折叠起来,进一步说明了该方法的有效性。随后,使用开发的片段叠加方法(FRAGSUM)准确确定了蛋白质G的整体结构。在FRAGSUM中,每个重叠片段(长度为10个氨基酸)首先通过REX-TAMD单独折叠,然后将共同的氨基酸进行叠加以确定整体结构。由于FRAGSUM除了RDC之外不需要任何额外信息,它提供了一种仅使用RDC进行从头结构测定的新策略。
