较大RNA寡核苷酸的分配方法：应用于一种ATP结合RNA适配体

Assignment methodology for larger RNA oligonucleotides: application to an ATP-binding RNA aptamer.

作者信息

Dieckmann T, Feigon J

机构信息

Department of Chemistry and Biochemistry, University of California, Los Angeles 90095-1569, USA.

出版信息

J Biomol NMR. 1997 Apr;9(3):259-72. doi: 10.1023/a:1018622708674.

DOI:10.1023/a:1018622708674

PMID:9204555

Abstract

The use of uniform 13C, 15N labeling in the NMR spectroscopic study of RNA structures has greatly facilitated the assignment process in small RNA oligonucleotides. For ribose spin system assignments, exploitation of these labels has followed previously developed methods for the study of proteins. However, for sequential assignment of the exchangeable and nonexchangeable protons of the nucleotides, it has been necessary to develop a variety of new NMR experiments. Even these are of limited utility in the unambiguous assignment of larger RNAs due to the short carbon relaxation times and extensive spectral overlap for all nuclei. These problems can largely be overcome by the additional use of basetype selectively 13C, 15N-labeled RNA in combination with a judicious use of related RNAs with base substitutions. We report the application of this approach to a 36-nucleotide ATP-binding RNA aptamer in complex with AMP. Complete sequential 1H assignments, as well as the majority of 13C and 15N assignments, were obtained.

摘要

在RNA结构的核磁共振光谱研究中使用均匀的13C、15N标记极大地促进了小RNA寡核苷酸的归属过程。对于核糖自旋系统的归属，这些标记的应用遵循了先前开发的用于蛋白质研究的方法。然而，对于核苷酸可交换和不可交换质子的顺序归属，有必要开发各种新的核磁共振实验。由于所有原子核的碳弛豫时间短且光谱广泛重叠，即使这些实验在明确归属较大RNA方面的效用也有限。通过额外使用碱基类型选择性13C、15N标记的RNA，并明智地使用具有碱基取代的相关RNA，这些问题在很大程度上可以得到克服。我们报告了这种方法在与AMP复合的36个核苷酸的ATP结合RNA适体上的应用。获得了完整的顺序1H归属以及大部分13C和15N归属。

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较大RNA寡核苷酸的分配方法：应用于一种ATP结合RNA适配体

Assignment methodology for larger RNA oligonucleotides: application to an ATP-binding RNA aptamer.

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