使用扭转角分子动力学进行顺磁金属蛋白的 NMR 结构计算的伪拟氨基酸。

PSEUDYANA for NMR structure calculation of paramagnetic metalloproteins using torsion angle molecular dynamics.

机构信息

Department of Chemistry, University of Florence, I-50121 Florence, Italy.

出版信息

J Biomol NMR. 1998 Nov;12(4):553-7. doi: 10.1023/A:1008388614638.

PMID:20012764

Abstract

The program DYANA, for calculation of solution structures of biomolecules with an algorithm based on simulated annealing by torsion angle dynamics, has been supplemented with a new routine, PSEUDYANA, that enables efficient use of pseudocontact shifts as additional constraints in structure calculations of paramagnetic metalloproteins. PSEUDYANA can determine the location of the metal ion inside the protein frame and allows to define a single tensor of magnetic susceptibility from a family of conformers. As an illustration, a PSEUDYANA structure calculation is provided for a metal-undecapeptide complex, where simulated pseudocontact shifts but no NOE restraints are used as conformational constraints.

摘要

程序 DYANA 用于通过扭转角动力学模拟退火算法计算生物分子的溶液结构，现已补充了一个新例程 PSEUDYANA，该例程可有效利用赝接触位移作为顺磁金属蛋白结构计算中的附加约束。PSEUDYANA 可确定金属离子在蛋白质框架内的位置，并允许从构象族中定义单个磁各向异性张量。作为说明，提供了一个金属十一肽复合物的 PSEUDYANA 结构计算，其中使用模拟的赝接触位移，但没有 NOE 约束作为构象约束。

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使用扭转角分子动力学进行顺磁金属蛋白的 NMR 结构计算的伪拟氨基酸。

PSEUDYANA for NMR structure calculation of paramagnetic metalloproteins using torsion angle molecular dynamics.

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使用扭转角分子动力学进行顺磁金属蛋白的 NMR 结构计算的伪拟氨基酸。

PSEUDYANA for NMR structure calculation of paramagnetic metalloproteins using torsion angle molecular dynamics.

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