Biradicals based on PROXYL containing building blocks for efficient dynamic nuclear polarization in biotolerant media

IF 2.624
Kevin Herr , Mark V. Höfler , Henrike Heise , Fabien Aussenac , Felix Kornemann , David Rosenberger , Martin Brodrecht , Marcos de Oliveira Jr. , Gerd Buntkowsky , Torsten Gutmann
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Abstract

A versatile strategy for synthesizing tailored peptide based biradicals is presented. By labeling the protected amino acid hydroxyproline with PROXYL via the OH functionality and using this building block in solid phase peptide synthesis (SPPS), the obtained peptides become polarization agents for DNP enhanced solid-state NMR in biotolerant media. To analyze the effect of the radical position on the enhancement factor, three different biradicals are synthesized. The PROXYL spin-label is inserted in a collagen inspired artificial peptide sequence by binding through the OH group of the hydroxyproline moieties at specific position in the chain. This labeling strategy is universally applicable for any hydroxyproline position in a peptide sequence since solid-phase peptide synthesis is used to insert the building block. High performance liquid chromatography (HPLC) and mass spectrometry (MS) analyses show the successful introduction of the spin label in the peptide chain and electron paramagnetic resonance (EPR) spectroscopy confirms its activity. Dynamic nuclear polarization (DNP) enhanced solid-state nuclear magnetic resonance (NMR) experiments performed on frozen aqueous glycerol-d8 solutions containing these peptide radicals show significantly higher enhancement factors of up to 45 in 1H→13C cross polarization magic angle spinning (CP MAS) experiments compared to an analogous mono-radical peptide including this building block (ε ≈ 14). Compared to commercial biradicals such as AMUPol for which enhancement factors > 100 have been obtained in the past and which have been optimized in their structure, the obtained enhancement up to 45 for our biradicals presents a significant progress in radical design.

Abstract Image

基于含 PROXYL 构建模块的双烯类化合物,可在生物耐受介质中实现高效动态核极化
本文介绍了一种合成基于肽的定制双激肽的多功能策略。通过羟基官能团用 PROXYL 标记受保护的氨基酸羟脯氨酸,并在固相肽合成(SPPS)中使用这种结构单元,得到的肽就成为了生物耐受介质中 DNP 增强固态 NMR 的极化剂。为了分析自由基位置对增强因子的影响,我们合成了三种不同的双自由基。PROXYL 自旋标签通过羟脯氨酸分子的羟基结合到链中特定位置的胶原蛋白人工肽序列中。这种标记策略普遍适用于肽序列中的任何羟脯氨酸位置,因为它是通过固相肽合成来插入结构单元的。高效液相色谱(HPLC)和质谱(MS)分析表明,肽链中成功地引入了自旋标签,电子顺磁共振(EPR)光谱也证实了其活性。在含有这些肽自由基的冷冻甘油-d8 水溶液上进行的动态核偏振(DNP)增强固态核磁共振(NMR)实验表明,与包括该结构单元的类似单自由基肽(ε ≈ 14)相比,1H→13C 交叉偏振魔角旋转(CP MAS)实验的增强因子明显更高,可达 45。与过去已获得增强因子 > 100 并在结构上进行了优化的 AMUPol 等商用双肽基相比,我们的双肽基获得了高达 45 的增强,这是在自由基设计方面取得的重大进展。
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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CiteScore
1.90
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