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镍调控蛋白NikR金属特异性的结构基础

Structural basis of the metal specificity for nickel regulatory protein NikR.

作者信息

Phillips Christine M, Schreiter Eric R, Guo Yayi, Wang Sheila C, Zamble Deborah B, Drennan Catherine L

机构信息

Department of Chemistry, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA.

出版信息

Biochemistry. 2008 Feb 19;47(7):1938-46. doi: 10.1021/bi702006h. Epub 2008 Jan 15.

DOI:10.1021/bi702006h
PMID:18193897
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5914170/
Abstract

In the presence of excess nickel, Escherichia coli NikR regulates cellular nickel uptake by suppressing the transcription of the nik operon, which encodes the nickel uptake transporter, NikABCDE. Previously published in vitro studies have shown that NikR is capable of binding a range of divalent transition metal ions in addition to Ni2+, including Co2+, Cu2+, Zn2+, and Cd2+. To understand how the high-affinity nickel binding site of NikR is able to accommodate these other metal ions, and to improve our understanding of NikR's mechanism of binding to DNA, we have determined structures of the metal-binding domain (MBD) of NikR in the apo form and in complex with Cu2+ and Zn2+ ions and compared them with the previously published structures with Ni2+. We observe that Cu2+ ions bind in a manner very similar to that of Ni2+, with a square planar geometry but with longer bond lengths. Crystals grown in the presence of Zn2+ reveal a protein structure similar to that of apo MBD with a disordered alpha3 helix, but with two electron density peaks near the Ni2+ binding site corresponding to two Zn2+ ions. These structural findings along with biochemical data on NikR support a hypothesis that ordering of the alpha3 helix is important for repressor activation.

摘要

在镍过量的情况下,大肠杆菌NikR通过抑制nik操纵子的转录来调节细胞对镍的摄取,nik操纵子编码镍摄取转运蛋白NikABCDE。此前发表的体外研究表明,NikR除了能结合Ni2+外,还能结合一系列二价过渡金属离子,包括Co2+、Cu2+、Zn2+和Cd2+。为了了解NikR的高亲和力镍结合位点如何容纳这些其他金属离子,并增进我们对NikR与DNA结合机制的理解,我们测定了无金属形式以及与Cu2+和Zn2+离子形成复合物的NikR金属结合结构域(MBD)的结构,并将它们与之前发表的与Ni2+结合的结构进行了比较。我们观察到,Cu2+离子的结合方式与Ni2+非常相似,呈平面正方形几何结构,但键长更长。在Zn2+存在下生长的晶体显示出一种与无金属MBD相似的蛋白质结构,其α3螺旋无序,但在Ni2+结合位点附近有两个对应于两个Zn2+离子的电子密度峰。这些结构发现以及关于NikR的生化数据支持了一个假设,即α3螺旋的有序化对阻遏物激活很重要。

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