Macromolecular powder diffraction : structure solution via molecular.

J. A. Doebbler, R. Dreele
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引用次数: 2

Abstract

Macromolecular powder diffraction is a burgeoning technique for protein structure solution - ideally suited for cases where no suitable single crystals are available. Over the past seven years, pioneering work by Von Dreele et al. [1,2] and Margiolaki et al. [3,4] has demonstrated the viability of this approach for several protein structures. Among these initial powder studies, molecular replacement solutions of insulin and turkey lysozyme into alternate space groups were accomplished. Pressing the technique further, Margiolaki et al. [5] executed the first molecular replacement of an unknown protein structure: the SH3 domain of ponsin, using data from a multianalyzer diffractometer. To demonstrate that cross-species molecular replacement using image plate data is also possible, we present the solution of hen egg white lysozyme using the 60% identical human lysozyme (PDB code: 1LZ1) as the search model. Due to the high incidence of overlaps in powder patterns, especially in more complex structures, we have used extracted intensities from five data sets taken at different salt concentrations in a multi-pattern Pawley refinement. The use of image plates severely increases the overlap problem due to lower detector resolution, but radiation damage effects are minimized with shorter exposure times and the fact that the entiremore » pattern is obtained in a single exposure. This image plate solution establishes the robustness of powder molecular replacement resulting from different data collection techniques.« less
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大分子粉末衍射:通过分子构造溶液。
大分子粉末衍射是一种新兴的蛋白质结构解决技术-理想地适用于没有合适的单晶可用的情况。在过去的七年里,Von Dreele等人[1,2]和Margiolaki等人[3,4]的开创性工作已经证明了这种方法在几种蛋白质结构上的可行性。在这些初步的粉末研究中,完成了胰岛素和火鸡溶菌酶分子替代溶液到交替空间组的研究。进一步推进该技术,Margiolaki等人[5]使用多仪器衍射仪的数据对未知蛋白质结构:ponsin的SH3结构域进行了首次分子替换。为了证明使用图像板数据进行跨物种分子替换也是可能的,我们提出了使用60%相同的人类溶菌酶(PDB代码:1LZ1)作为搜索模型的蛋清溶菌酶解决方案。由于粉末模式中重叠的发生率很高,特别是在更复杂的结构中,我们在多模式Pawley细化中使用了不同盐浓度下的五个数据集的提取强度。由于探测器分辨率较低,图像板的使用严重增加了重叠问题,但由于曝光时间较短,并且在一次曝光中获得了整个»模式,因此辐射损伤效应被最小化。该图像板解决方案建立了由不同数据收集技术产生的粉末分子替换的鲁棒性。«少
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来源期刊
CiteScore
1.47
自引率
0.00%
发文量
0
审稿时长
3 months
期刊介绍: Zeitschrift für Kristallographie International journal for structural, physical, and chemical aspects of crystalline materials ISSN 0044-2968 Founded in 1877 by Paul Groth Zeitschrift für Kristallographie is one of the world’s oldest scientific journals. In original papers, letters and review articles it presents results of theoretical or experimental study on crystallography.
期刊最新文献
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