In silico design of halogenated carbohydrate mimetics as potential halogen-bonding ligands

Proceedings of MOL2NET 2018, International Conference on Multidisciplinary Sciences, 4th edition Pub Date : 2019-01-06 DOI:10.3390/mol2net-04-06125

Rafael Nunes, N. Xavier, Paulo J. Costa

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Abstract

1749-016 Lisboa, Portugal Abstract The molecular recognition of carbohydrates by proteins is characterized by the presence of classical hydrogen bonds stabilizing binding together with an important contribution from other intermolecular interactions conferring high specificity. [1] The design of glycomimetic ligands as modulators of protein-carbohydrate binding events is a common approach in the context of chemical glycobiology [2] and carbohydrate-based drug discovery. [3] While a diversity of functional groups has been successfully introduced in carbohydrate structures, [2] the use of halogens has been largely neglected, except for fluorine. However, heavier halogens (X = Cl, Br, or I) can establish highly directional, R–X ××× B interactions with Lewis bases (B), known as halogen bonds (HaB). These interactions have been mostly explained by the presence of an electropositive site at the outermost region of X species, named sigma-hole. [4] HaB-mediated molecular recognition phenomena are widespread across biological systems and have been used as tools in medicinal chemistry, [5]

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卤化碳水化合物模拟物作为潜在卤素键配体的计算机设计

摘要蛋白质对碳水化合物的分子识别以经典氢键的存在为特征，氢键的存在稳定了碳水化合物的结合，而其他分子间相互作用也为碳水化合物的识别提供了高度的特异性。[1]设计拟糖配体作为蛋白质-碳水化合物结合事件的调节剂是化学糖生物学[2]和基于碳水化合物的药物发现的一种常见方法。[3]虽然在碳水化合物结构中已经成功地引入了多种官能团[2]，但除氟外，卤素的使用在很大程度上被忽视了。然而，较重的卤素(X = Cl, Br或I)可以与路易斯碱(B)建立高度定向的R-X ××× B相互作用，称为卤素键(HaB)。这些相互作用主要是由X种最外层区域的正电位点(称为sigma-hole)的存在来解释的。[4] hab介导的分子识别现象在生物系统中广泛存在，并已被用作药物化学的工具，[5]

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Proceedings of MOL2NET 2018, International Conference on Multidisciplinary Sciences, 4th edition

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