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同步加速器蛋白质足迹法支持ClpA通过ATP诱导的D2环移动实现底物易位。

Synchrotron protein footprinting supports substrate translocation by ClpA via ATP-induced movements of the D2 loop.

作者信息

Bohon Jen, Jennings Laura D, Phillips Christine M, Licht Stuart, Chance Mark R

机构信息

Center for Proteomics and Center for Synchrotron Biosciences, Case Western Reserve University, Cleveland, OH 44106, USA.

出版信息

Structure. 2008 Aug 6;16(8):1157-65. doi: 10.1016/j.str.2008.04.016.

DOI:10.1016/j.str.2008.04.016
PMID:18682217
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2929679/
Abstract

Synchrotron X-ray protein footprinting is used to study structural changes upon formation of the ClpA hexamer. Comparative solvent accessibilities between ClpA monomer and ClpA hexamer samples are in agreement throughout most of the sequence, with calculations based on two previously proposed hexameric models. The data differ substantially from the proposed models in two parts of the structure: the D1 sensor 1 domain and the D2 loop region. The results suggest that these two regions can access alternate conformations in which their solvent protection is greater than that in the structural models based on crystallographic data. In combination with previously reported structural data, the footprinting data provide support for a revised model in which the D2 loop contacts the D1 sensor 1 domain in the ATP-bound form of the complex. These data provide the first direct experimental support for the nucleotide-dependent D2 loop conformational change previously proposed to mediate substrate translocation.

摘要

同步加速器X射线蛋白质足迹法用于研究ClpA六聚体形成时的结构变化。ClpA单体和ClpA六聚体样品之间的相对溶剂可及性在大部分序列中是一致的,这与基于之前提出的两种六聚体模型的计算结果相符。在结构的两个部分,即D1传感器1结构域和D2环区域,数据与提出的模型有很大差异。结果表明,这两个区域可以进入其溶剂保护作用大于基于晶体学数据的结构模型中的构象。结合之前报道的结构数据,足迹数据为一个修订模型提供了支持,在该模型中,D2环在复合物的ATP结合形式下与D1传感器1结构域接触。这些数据为之前提出的介导底物转运的核苷酸依赖性D2环构象变化提供了首个直接实验支持。

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