Research Progress on the Macrocycle-Derived Artificial Transmembrane Ion Channels

doi:10.6023/A21050222

Acta Chimica Sinica ›› 2021, Vol. 79 ›› Issue (8): 999-1007.DOI: 10.6023/A21050222 Previous Articles Next Articles

Special Issue: 分子探针、纳米生物学与生命分析化学

Review

大环分子衍生物在人工跨膜离子通道领域中的研究进展

闫腾飞^a^,^b, 刘盛达^a^,^b, 罗逸尘^b, 邹应萍^a^,^*(), 刘俊秋^b^,^c^,^*()

a 中南大学化学化工学院长沙 410083
b 杭州师范大学材料与化学化工学院杭州 310036
c 吉林大学化学学院超分子结构与材料国家重点实验室长春 130012

投稿日期:2021-05-19 发布日期:2021-06-24
通讯作者: 邹应萍, 刘俊秋

作者简介:

闫腾飞, 博士后, 1990年出生于河北省石家庄, 2014年本科毕业于廊坊师范学院化学与材料科学学院, 2019年博士毕业于吉林大学化学学院高分子化学与物理专业, 导师为刘俊秋教授. 2020年入职中南大学化学化工学院从事博士后研究 (与杭州师范大学联合培养), 导师为邹应萍教授和刘俊秋教授, 研究方向为生物超分子材料的制备与性能研究.

刘盛达, 博士后, 1991年出生于吉林省吉林市, 2015年本科毕业于长春理工大学化学与环境工程学院, 2020年博士毕业于吉林大学化学学院高分子化学与物理专业, 导师为刘俊秋教授. 2020年入职中南大学化学化工学院从事博士后研究 (与杭州师范大学联合培养), 导师为刘又年教授和刘俊秋教授, 研究方向为仿生高分子材料.

罗逸尘, 硕士, 1995年出生于浙江省台州市, 2017年本科毕业于复旦大学高分子科学系, 导师为周平教授. 2020年进入杭州师范大学材料与化学化工学院攻读硕士学位, 导师为刘俊秋教授, 研究方向为新型智能离子通道的设计与开发.

邹应萍, 中南大学化学化工学院教授, 博士生导师. 2008年博士毕业于中国科学院化学研究所. 2008年至今中南大学从事教学科研工作, 2014年2月破格晋升教授. 在加拿大拉瓦尔大学(2008~2010年)和美国斯坦福大学(2012~2014年)从事博士后/访问研究. 在SCI源刊物上发表学术论文200余篇, 引用10000余次, H指数为49. 主要研究方向为有机高分子光电材料与器件.

刘俊秋, 杭州师范大学材料与化学化工学院教授, 1999年于吉林大学化学系高分子专业获理学博士学位. 2002~2003年获洪堡基金资助在德国从事博士后研究. 2003年加入吉林大学超分子结构与材料国家重点实验室, 担任全职教授. 2019年调入杭州师范大学材料与化学化工学院工作, 研究方向包括仿生化学、蛋白质组装与功能化、生物材料等.

基金资助:
国家自然科学基金(21875286); 国家自然科学基金(22001054); 国家自然科学基金(22075065)

Research Progress on the Macrocycle-Derived Artificial Transmembrane Ion Channels

Tengfei Yan^a^,^b, Shengda Liu^a^,^b, Yichen Luo^b, Yingping Zou^a(), Junqiu Liu^b^,^c()

a College of Chemistry and Chemical Engineering, Central South University, Changsha 410083, China
b College of Material, Chemistry and Chemical Engineering, Hangzhou Normal University, Hangzhou 310036, China
c College of Chemistry, State Key Laboratory of Supramolecular Structure and Materials, Jilin University, Changchun 130012, China

Received:2021-05-19 Published:2021-06-24
Contact: Yingping Zou, Junqiu Liu
Supported by:
National Natural Science Foundation of China(21875286); National Natural Science Foundation of China(22001054); National Natural Science Foundation of China(22075065)

Macrocycles such as cyclodextrin and crown ether are applied to construct artificial transmembrane ion transport systems owing to their unique cavity structure and the ability to recognize molecules and ions via host-guest interaction. Compared with natural channel proteins, macrocycles have many advantages, such as the low cost, stabilities, easy structural modification and functionalization, etc., which make them preferable candidates for preparing artificial ion channel. Herein, we reviewed the recent progress of macrocycles-based artificial ion channels, and systematically summarized the preparation methods, structural regulation and potential applications of the artificial ion channels based on different macrocycles. Finally, we have briefly summarized and outlooked the progress of macrocycle-based artificial ion channels. This review is of great significance for developing novel artificial transmembrane ion channels and exploring their potential applications.

Key words: macrocycle, ion recognition, transmembrane channel, structural regulation, biological application

Cite this article

Tengfei Yan, Shengda Liu, Yichen Luo, Yingping Zou, Junqiu Liu. Research Progress on the Macrocycle-Derived Artificial Transmembrane Ion Channels[J]. Acta Chimica Sinica, 2021, 79(8): 999-1007.

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Fig. & Tab. 9

Figure 1. The schematic illustration of artificial transmembrane ion channels based on different kind of macrocycles

Figure 2. Artificial transmembrane ion channels based on (a, b) cyclodextrins and (c~e) crown ethers

Figure 3. (a) Artificial transmembrane ion channels based on calix[4]- arene; electrophysiological signals of the compounds (b) 7 and (c) 6 recorded by planer lipid bilayer

Figure 4. Artificial transmembrane ion channels based on (a) pillar[5]arene and (b) cucurbit[5]/[6]urils

Figure 5. Artificial transmembrane ion channels based on (a, b) cyclic peptide and (c~e) rigid flat aromatic ring

Figure 6. Artificial transmembrane ion channels based on (a, b) G-quartets and (c, d) metal-organic polyhedra

Figure 7. Intelligent artificial transmembrane ion channels with stimuli-responsive abilities

Figure 8. Artificial transmembrane ion channels with controllable transport selectivity

Figure 9. Artificial transmembrane ion channels with antimicrobial activity

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大环分子衍生物在人工跨膜离子通道领域中的研究进展

Research Progress on the Macrocycle-Derived Artificial Transmembrane Ion Channels

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