Currently, completely abiotic channel systems that concurrently reproduce the high selectivity and high permeation rate of natural protein channels are rare. Here, we provide one such biomimetic channel system, i.e., a novel family of helically folded hybrid amide foldamers that can serve as powerful artificial proton channels to mimic key transport features of the exceptionally selective Matrix-2 (M2) proton channels. Possessing an angstrom-scale tubular pore 3 Å in diameter, these low water permeability artificial channels transport protons at a rate 1.22 and 11 times as fast as gramicidin A and M2 channels, respectively, with exceptionally high selectivity factors of 167.6, 122.7, and 81.5 over Cl- , Na+ , and K+ ions. Based on the experimental and computational findings, we propose a novel proton transport mechanism where a proton may create a channel-spanning water chain from two or more short water chains to facilitate its own transmembrane flux via the Grotthuss mechanism.
Keywords: Foldamers; Hydrogen Bonds; Organic Nanotubes; Proton Channels; Supramolecular Chemistry.
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