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关于蛋白质晶体结构的可重复性:胰蛋白酶的五个原子分辨率结构

On the reproducibility of protein crystal structures: five atomic resolution structures of trypsin.

作者信息

Liebschner Dorothee, Dauter Miroslawa, Brzuszkiewicz Anna, Dauter Zbigniew

机构信息

Synchrotron Radiation Research Section, MCL, National Cancer Institute, Argonne National Laboratory, Argonne, IL 60439, USA.

出版信息

Acta Crystallogr D Biol Crystallogr. 2013 Aug;69(Pt 8):1447-62. doi: 10.1107/S0907444913009050. Epub 2013 Jul 17.

Abstract

Structural studies of proteins usually rely on a model obtained from one crystal. By investigating the details of this model, crystallographers seek to obtain insight into the function of the macromolecule. It is therefore important to know which details of a protein structure are reproducible or to what extent they might differ. To address this question, the high-resolution structures of five crystals of bovine trypsin obtained under analogous conditions were compared. Global parameters and structural details were investigated. All of the models were of similar quality and the pairwise merged intensities had large correlation coefficients. The C(α) and backbone atoms of the structures superposed very well. The occupancy of ligands in regions of low thermal motion was reproducible, whereas solvent molecules containing heavier atoms (such as sulfur) or those located on the surface could differ significantly. The coordination lengths of the calcium ion were conserved. A large proportion of the multiple conformations refined to similar occupancies and the residues adopted similar orientations. More than three quarters of the water-molecule sites were conserved within 0.5 Å and more than one third were conserved within 0.1 Å. An investigation of the protonation states of histidine residues and carboxylate moieties was consistent for all of the models. Radiation-damage effects to disulfide bridges were observed for the same residues and to similar extents. Main-chain bond lengths and angles averaged to similar values and were in agreement with the Engh and Huber targets. Other features, such as peptide flips and the double conformation of the inhibitor molecule, were also reproducible in all of the trypsin structures. Therefore, many details are similar in models obtained from different crystals. However, several features of residues or ligands located in flexible parts of the macromolecule may vary significantly, such as side-chain orientations and the occupancies of certain fragments.

摘要

蛋白质的结构研究通常依赖于从一个晶体获得的模型。通过研究该模型的细节,晶体学家试图深入了解大分子的功能。因此,了解蛋白质结构的哪些细节是可重复的,或者它们可能在多大程度上有所不同是很重要的。为了解决这个问题,比较了在类似条件下获得的五个牛胰蛋白酶晶体的高分辨率结构。研究了整体参数和结构细节。所有模型的质量相似,成对合并的强度具有较大的相关系数。结构的C(α)原子和主链原子重叠得非常好。低热运动区域中配体的占有率是可重复的,而含有较重原子(如硫)的溶剂分子或位于表面的溶剂分子可能会有显著差异。钙离子的配位长度是保守的。大部分多重构象被精修到相似的占有率,残基采用相似的取向。超过四分之三的水分子位点在0.5 Å范围内是保守的,超过三分之一在0.1 Å范围内是保守的。对组氨酸残基和羧基部分的质子化状态的研究在所有模型中都是一致的。在相同的残基上观察到了对二硫键的辐射损伤效应,且程度相似。主链键长和键角的平均值相似,与Engh和Huber的目标一致。其他特征,如肽翻转和抑制剂分子的双重构象,在所有胰蛋白酶结构中也是可重复的。因此,从不同晶体获得的模型中有许多细节是相似的。然而,位于大分子柔性部分的残基或配体的一些特征可能会有显著变化,如侧链取向和某些片段的占有率。

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