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基于卤素键、硫族元素键和氮族元素键的阴离子转运体:迈向生物应用

Anion transporters based on halogen, chalcogen, and pnictogen bonds: towards biological applications.

作者信息

Singh Anurag, Torres-Huerta Aaron, Meyer Franck, Valkenier Hennie

机构信息

Université libre de Bruxelles (ULB), Engineering of Molecular NanoSystems Avenue F. Roosevelt 50, CP165/64 1050 Brussels Belgium

Université libre de Bruxelles (ULB), Microbiology, Bioorganic and Macromolecular Chemistry Unit, Faculty of Pharmacy Boulevard du Triomphe 1050 Brussels Belgium.

出版信息

Chem Sci. 2024 Sep 10;15(37):15006-22. doi: 10.1039/d4sc04644g.

DOI:10.1039/d4sc04644g
PMID:39268212
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11385378/
Abstract

Motivated by their potential biological applications, anion receptors are increasingly explored as transmembrane transporters for anions. The vast majority of the reported anion transporters rely on hydrogen bonding to interact with the anions. However, in recent decades, halogen, chalcogen, and pnictogen bonding, collectively referred to as sigma-hole interactions, have received increasing attention. Most research efforts on these interactions have focused on crystal engineering, anion sensing, and organocatalysis. In recent years, however, these sigma-hole interactions have also been explored more widely in synthetic anion transporters. This perspective shows why synthetic transporters are promising candidates for biological applications. We provide a comprehensive review of the compounds used to transport anions across membranes, with a particular focus on how the binding atoms and molecular design affect the anion transport activity and selectivity. Few cell studies have been reported for these transporters based on sigma-hole interactions and we highlight the critical need for further biological studies on the toxicity, stability, and deliverability of these compounds to explore their full potential in biological applications, such as the treatment of cystic fibrosis.

摘要

受其潜在生物学应用的推动,阴离子受体作为阴离子的跨膜转运体正受到越来越多的探索。绝大多数已报道的阴离子转运体依靠氢键与阴离子相互作用。然而,近几十年来,卤键、硫族元素键和氮族元素键,统称为σ-空穴相互作用,受到了越来越多的关注。对这些相互作用的大多数研究工作都集中在晶体工程、阴离子传感和有机催化方面。然而近年来,这些σ-空穴相互作用在合成阴离子转运体中也得到了更广泛的探索。这一观点展示了为什么合成转运体是生物学应用的有前景的候选者。我们对用于跨膜转运阴离子的化合物进行了全面综述,特别关注结合原子和分子设计如何影响阴离子转运活性和选择性。基于σ-空穴相互作用的这些转运体的细胞研究报道很少,我们强调迫切需要对这些化合物的毒性、稳定性和递送能力进行进一步的生物学研究,以探索它们在生物学应用中的全部潜力,如治疗囊性纤维化。

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