顺磁性蛋白质中居里自旋与偶极-偶极弛豫之间的交叉相关率：铈取代钙结合蛋白D9k的情况

Cross correlation rates between Curie spin and dipole-dipole relaxation in paramagnetic proteins: the case of cerium substituted calbindin D9k.

作者信息

Bertini Ivano, Cavallaro Gabriele, Cosenza Marta, Kümmerle Rainer, Luchinat Claudio, Piccioli Mario, Poggi Luisa

机构信息

Magnetic Resonance Center, University of Florence, Italy.

出版信息

J Biomol NMR. 2002 Jun;23(2):115-25. doi: 10.1023/a:1016341507527.

DOI:10.1023/a:1016341507527

PMID:12153037

Abstract

Cross correlation rates between Curie spin relaxation and H-N dipole-dipole coupling (gamma(HM,HN)CS,DD) have been determined for a calcium binding protein, Calbindin D9k, in which one of the two calcium ions is substituted with cerium(III). Gamma(HM,HN)CS,DD values depend on both the metal-to-proton distances and the M-H-N angles and can be used as an additional constraint in order to refine the solution structure of paramagnetic metalloproteins. For this purpose, we have implemented a new module (CCR-DYANA) in a version of the program DYANA (PARAMAGNETIC-DYANA), which can be used together with other paramagnetism-based constraints such as pseudocontact shifts, residual dipolar couplings and hyperfine based Karplus relationships. This integrated structure calculation protocol has the advantage that different paramagnetic-based constraints are treated by the same algorithm in a way that the efficiency of each class of constraints can be analyzed and compared.

摘要

已测定了一种钙结合蛋白Calbindin D9k的居里自旋弛豫与H-N偶极-偶极耦合（γ(HM,HN)CS,DD）之间的交叉相关率，其中两个钙离子之一被铈(III)取代。γ(HM,HN)CS,DD值取决于金属与质子的距离以及M-H-N角度，并且可以用作一种额外的约束条件，以优化顺磁性金属蛋白的溶液结构。为此，我们在DYANA程序（PARAMAGNETIC-DYANA）的一个版本中实现了一个新模块（CCR-DYANA），该模块可以与其他基于顺磁性的约束条件（如赝接触位移、剩余偶极耦合和基于超精细的Karplus关系）一起使用。这种集成的结构计算方案具有这样的优势：不同的基于顺磁性的约束条件由相同的算法处理，从而可以分析和比较每类约束条件的效率。

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顺磁性蛋白质中居里自旋与偶极-偶极弛豫之间的交叉相关率：铈取代钙结合蛋白D9k的情况

Cross correlation rates between Curie spin and dipole-dipole relaxation in paramagnetic proteins: the case of cerium substituted calbindin D9k.

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