A Halogen Bond-mediated Highly Active Artificial Chloride Channel with High Anticancer Activity

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2018 May 22

PMID 29780533

Citations 19

Authors

Changliang Ren

Xin Ding

Arundhati Roy

Jie Shen

Shaoyuan Zhou

Feng Chen

Sam Fong Yau Li

Haisheng Ren

Yi Yan Yang

Huaqiang Zeng

Affiliations

Soon will be listed here.

Abstract

Chloride-selective transmembrane carriers or channels might have possible uses in treating channelopathies or cancers. While chloride carriers have been extensively investigated, the corresponding chloride channels have remained limitedly studied. Moreover, all hitherto reported channel systems lack clearly definable and readily modifiable positions in their structures for the reliable construction and combinatorial optimization of their ion transport properties. As a result, the existing channels are limited by their large molecular weight, weak activity or low anion selectivity. In this report, we describe a readily accessible and robust monopeptide-based scaffold for the reliable construction of halogen bond-mediated artificial anion channels directional assembly of electron-deficient iodine atoms, which create a transmembrane pathway for facilitating anion transport. The high intrinsic modularity of the backbone of the scaffold, which enables the rapid and combinatorial optimization of the transport activity and selectivity of channels, effectively delivers a highly active chloride channel . Such high activity in chloride transport subsequently leads to an excellent IC value of 20 μM toward inhibiting the growth of human breast cancer cells (BT-474), an anticancer activity that is even higher than that of the well-known anticancer agent cisplatin.

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