Optimizing frequency sampling in CEST experiments

IF 1.3 3区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biomolecular NMR Pub Date : 2022-10-04 DOI:10.1007/s10858-022-00403-2

Nicolas Bolik-Coulon, D. Flemming Hansen, Lewis E. Kay

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引用次数: 2

Abstract

For the past decade chemical exchange saturation transfer (CEST) experiments have been successfully applied to study exchange processes in biomolecules involving sparsely populated, transiently formed conformers. Initial implementations focused on extensive sampling of the CEST frequency domain, requiring significant measurement times. Here we show that the lengthy sampling schemes often used are not optimal and that reduced frequency sampling schedules can be developed without a priori knowledge of the exchange parameters, that only depend on the chosen B₁ field, and, to a lesser extent, on the intrinsic transverse relaxation rates of ground state spins. The reduced sampling approach described here can be used synergistically with other methods for reducing measurement times such as those that excite multiple frequencies in the CEST dimension simultaneously, or make use of non-uniform sampling of indirectly detected time domains, to further decrease measurement times. The proposed approach is validated by analysis of simulated and experimental datasets.

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优化CEST实验中的频率采样

在过去的十年里，化学交换饱和转移(CEST)实验已经成功地应用于研究生物分子中涉及稀疏的、瞬态形成的构象的交换过程。最初的实现侧重于CEST频域的广泛采样，需要大量的测量时间。在这里，我们证明了通常使用的冗长采样方案并不是最优的，并且可以在没有交换参数先验知识的情况下开发降低频率的采样计划，交换参数仅取决于所选择的B1场，并且在较小程度上取决于基态自旋的固有横向弛豫速率。这里描述的减少采样方法可以与其他减少测量时间的方法协同使用，例如同时激发CEST维度中的多个频率的方法，或者利用间接检测的时域的非均匀采样，以进一步减少测量时间。仿真和实验数据验证了该方法的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomolecular NMR 生物-光谱学

CiteScore

6.00

自引率

3.70%

发文量

审稿时长

6-12 weeks

期刊介绍： The Journal of Biomolecular NMR provides a forum for publishing research on technical developments and innovative applications of nuclear magnetic resonance spectroscopy for the study of structure and dynamic properties of biopolymers in solution, liquid crystals, solids and mixed environments, e.g., attached to membranes. This may include: Three-dimensional structure determination of biological macromolecules (polypeptides/proteins, DNA, RNA, oligosaccharides) by NMR. New NMR techniques for studies of biological macromolecules. Novel approaches to computer-aided automated analysis of multidimensional NMR spectra. Computational methods for the structural interpretation of NMR data, including structure refinement. Comparisons of structures determined by NMR with those obtained by other methods, e.g. by diffraction techniques with protein single crystals. New techniques of sample preparation for NMR experiments (biosynthetic and chemical methods for isotope labeling, preparation of nutrients for biosynthetic isotope labeling, etc.). An NMR characterization of the products must be included.