Salt-Excluding Artificial Water Channels Exhibiting Enhanced Dipolar Water and Proton Translocation

Aquaporins (AQPs) are biological water channels known for fast water transport (∼108–109 molecules/s/channel) with ion exclusion. Few synthetic channels have been designed to mimic this high water permeability, and none reject ions at a significant level. Selective water translocation has previously...

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Published in:Journal of the American Chemical Society 2016-04, Vol.138 (16), p.5403-5409
Main Authors: Licsandru, Erol, Kocsis, Istvan, Shen, Yue-xiao, Murail, Samuel, Legrand, Yves-Marie, van der Lee, Arie, Tsai, Daniel, Baaden, Marc, Kumar, Manish, Barboiu, Mihail
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cited_by cdi_FETCH-LOGICAL-a429t-78a9da7c1e0dfd021de9d0bd773cd2f3410578eb16e4abf1cecd5df850e38bbd3
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container_issue 16
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container_title Journal of the American Chemical Society
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creator Licsandru, Erol
Kocsis, Istvan
Shen, Yue-xiao
Murail, Samuel
Legrand, Yves-Marie
van der Lee, Arie
Tsai, Daniel
Baaden, Marc
Kumar, Manish
Barboiu, Mihail
description Aquaporins (AQPs) are biological water channels known for fast water transport (∼108–109 molecules/s/channel) with ion exclusion. Few synthetic channels have been designed to mimic this high water permeability, and none reject ions at a significant level. Selective water translocation has previously been shown to depend on water-wires spanning the AQP pore that reverse their orientation, combined with correlated channel motions. No quantitative correlation between the dipolar orientation of the water-wires and their effects on water and proton translocation has been reported. Here, we use complementary X-ray structural data, bilayer transport experiments, and molecular dynamics (MD) simulations to gain key insights and quantify transport. We report artificial imidazole-quartet water channels with 2.6 Å pores, similar to AQP channels, that encapsulate oriented dipolar water-wires in a confined chiral conduit. These channels are able to transport ∼106 water molecules/s, which is within 2 orders of magnitude of AQPs’ rates, and reject all ions except protons. The proton conductance is high (∼5 H+/s/channel) and approximately half that of the M2 proton channel at neutral pH. Chirality is a key feature influencing channel efficiency.
doi_str_mv 10.1021/jacs.6b01811
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title Salt-Excluding Artificial Water Channels Exhibiting Enhanced Dipolar Water and Proton Translocation
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