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结合核磁共振光谱和密度泛函理论研究理解唾液酸-苯硼酸复合物的分子结构:迈向细胞膜上唾液酸的检测

Understanding the Molecular Structure of the Sialic Acid-Phenylboronic Acid Complex by using a Combined NMR Spectroscopy and DFT Study: Toward Sialic Acid Detection at Cell Membranes.

作者信息

Nishitani Shoichi, Maekawa Yuki, Sakata Toshiya

机构信息

Department of Materials Engineering Graduate School of Engineering The University of Tokyo 7-3-1 Hongo, Bunkyo-ku Tokyo 113-8656 Japan.

出版信息

ChemistryOpen. 2018 Jul 2;7(7):513-519. doi: 10.1002/open.201800071. eCollection 2018 Jul.

DOI:10.1002/open.201800071
PMID:30003005
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6031860/
Abstract

The origin of the unusually high stability of the sialic acid (SA) and phenylboronic acid (PBA) complex was investigated by a combined nuclear magnetic resonance (NMR) spectroscopy and density functional theory (DFT) study. SA is a glycan-terminating monosaccharide, and its importance as a clinical target has long been recognized. Inspired by the fact that the binding properties of SA-PBA complexation are anomalously high relative to those of typical monosaccharides, great effort has been made to build a clinical platform with the use of PBA as a SA-selective receptor. Although a number of applications have been reported in recent years, the ability of PBA to recognize SA-terminating surface glycans selectively is still unclear, because high-affinity SA-PBA complexation might not occur in a physiological environment. In particular, different forms of SA (α- and β-pyranose) were not considered in detail. To answer this question, the combined NMR spectroscopy/DFT study revealed that the advantageous binding properties of the SA-PBA complex arise from ester bonding involving the α-carboxylate moieties (C and C) of β-SA but not α-SA. Moreover, the facts that the C atom is blocked by a glycoside bond in a physiological environment and that α-SA basically exists on membrane-bound glycans in a physiological environment lead to the conclusion that PBA cannot selectively recognize the SA unit to discriminate specific types of cells. Our results have a significant impact on the field of SA-based cell recognition.

摘要

通过核磁共振(NMR)光谱和密度泛函理论(DFT)相结合的研究,对唾液酸(SA)与苯硼酸(PBA)复合物异常高稳定性的起源进行了探究。SA是一种位于聚糖末端的单糖,其作为临床靶点的重要性早已得到认可。鉴于SA-PBA络合的结合特性相对于典型单糖异常高,人们付出了巨大努力以构建一个以PBA作为SA选择性受体的临床平台。尽管近年来已有许多应用报道,但PBA选择性识别SA末端表面聚糖的能力仍不明确,因为在生理环境中可能不会发生高亲和力的SA-PBA络合。特别是,不同形式的SA(α-和β-吡喃糖)未得到详细考虑。为回答这个问题,NMR光谱/DFT联合研究表明,SA-PBA复合物有利的结合特性源于涉及β-SA而非α-SA的α-羧基部分(C和C)的酯键。此外,在生理环境中C原子被糖苷键阻断以及α-SA在生理环境中基本存在于膜结合聚糖上这些事实,得出PBA无法选择性识别SA单元以区分特定类型细胞的结论。我们的结果对基于SA的细胞识别领域具有重大影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/332e/6031860/af399ff8f760/OPEN-7-513-g006.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/332e/6031860/b381c65ff1d9/OPEN-7-513-g002.jpg
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