Fluorine NMR study of proline-rich sequences using fluoroprolines

Q3 Physics and Astronomy

Magnetic resonance (Gottingen, Germany) Pub Date : 2021-07-12 DOI:10.5194/mr-2021-54

Davy Sinnaeve, Abir Ben Bouzayene, Emile Ottoy, Gert-Jan Hofman, É. Erdmann, B. Linclau, I. Kuprov, J. Martins, V. Torbeev, B. Kieffer

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引用次数: 3

Abstract

Abstract. Proline homopolymer motifs are found in many proteins; their peculiar conformational and dynamic properties are often directly involved in those proteins' functions. However, the dynamics of proline homopolymers is hard to study by NMR due to lack of amide protons and small chemical shift dispersion. Exploiting the spectroscopic properties of fluorinated prolines opens interesting perspectives to address these issues. Fluorinated prolines are already widely used in protein structure engineering – they introduce conformational and dynamical biases – but their use as 19F NMR reporters of proline conformation has not yet been explored. In this work, we look at model peptides where Cγ-fluorinated prolines with opposite configurations of the chiral Cγ centre have been introduced at two postions in distinct polyproline segments. By looking at the effects of swapping these (4R)- and (4S)-4-fluoroprolines witin the polyproline segments, we were able to separate the intrinsic conformational properties of the polyproline sequence from the conformational alterations instilled by fluorination. We assess the fluoroproline 19F relaxation properties, and exploit the latter in elucidating binding kinetics to the SH3 domain.

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利用氟脯氨酸对富含脯氨酸序列的氟NMR研究

摘要脯氨酸同源聚合物基序存在于许多蛋白质中；它们独特的构象和动力学特性通常直接参与这些蛋白质的功能。然而，由于缺乏酰胺质子和小的化学位移分散，脯氨酸均聚物的动力学很难通过NMR进行研究。利用氟化脯氨酸的光谱性质为解决这些问题开辟了有趣的前景。含氟脯氨酸已经被广泛用于蛋白质结构工程——它们引入了构象和动力学偏差——但它们作为脯氨酸构象的19F NMR报告子的用途尚未被探索。在这项工作中，我们观察了模型肽，其中具有手性Cγ中心相反构型的Cγ-氟化脯氨酸被引入不同的多肽片段的两个位置。通过观察将这些（4R）-和（4S）-4-氟脯氨酸与聚脯氨酸片段交换的效果，我们能够将聚脯氨酸序列的内在构象性质与氟化引起的构象变化分离开来。我们评估了氟脯氨酸19F的弛豫特性，并利用后者阐明了与SH3结构域的结合动力学。

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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