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用于完全质子化蛋白质的共振归属和结构表征的带异核检测的快速魔角旋转核磁共振技术。

Fast magic angle spinning NMR with heteronucleus detection for resonance assignments and structural characterization of fully protonated proteins.

作者信息

Guo Changmiao, Hou Guangjin, Lu Xingyu, O'Hare Bernie, Struppe Jochem, Polenova Tatyana

机构信息

Department of Chemistry and Biochemistry, University of Delaware, Newark, DE, 19716, USA,

出版信息

J Biomol NMR. 2014 Dec;60(4):219-29. doi: 10.1007/s10858-014-9870-y. Epub 2014 Nov 9.

DOI:10.1007/s10858-014-9870-y
PMID:25381566
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4282927/
Abstract

Heteronucleus-detected dipolar based correlation spectroscopy is established for assignments of ¹H, ¹³C, and ¹⁵N resonances and structural analysis in fully protonated proteins. We demonstrate that ¹³C detected 3D experiments are highly efficient and permit assignments of the majority of backbone resonances, as shown in an 89-residue dynein light chain 8, LC8 protein. With these experiments, we have resolved many ambiguities that were persistent in our previous studies using moderate MAS frequencies and lacking the ¹H dimension. The availability of ¹H isotropic chemical shifts measured with the heteronucleus-detected fast-MAS experiments presented here is essential for the accurate determination of the ¹H CSA tensors, which provide very useful structural probe. Finally, our results indicate that ¹³C detection in fast-MAS HETCOR experiments may be advantageous compared with ¹H detection as it yields datasets of significantly higher resolution in the ¹³C dimension than the ¹H detected HETCOR versions.

摘要

基于异核检测偶极的相关光谱法被用于确定完全质子化蛋白质中¹H、¹³C和¹⁵N共振峰并进行结构分析。我们证明¹³C检测的三维实验效率很高,能够确定大多数主链共振峰,如在一个含有89个残基的动力蛋白轻链8(LC8蛋白)中所示。通过这些实验,我们解决了许多在我们之前使用中等MAS频率且缺乏¹H维度的研究中一直存在的模糊问题。此处介绍的通过异核检测快速MAS实验测量的¹H各向同性化学位移对于准确确定¹H CSA张量至关重要,¹H CSA张量提供了非常有用的结构探针。最后,我们的结果表明,快速MAS HETCOR实验中的¹³C检测可能比¹H检测更具优势,因为它在¹³C维度上产生的数据集分辨率明显高于¹H检测的HETCOR版本。

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