Fan Yang scite author profile

Membrane channels span the cellular lipid bilayers to transport ions and molecules into cells with sophisticated properties including high efficiency and selectivity. It is of particular biological importance in developing biomimetic transmembrane channels with unique functions by means of chemically synthetic strategies. An artificial unimolecular transmembrane channel using pore‐containing helical macromolecules is reported. The self‐folding, shape‐persistent, pore‐containing helical macromolecules are able to span the lipid bilayer, and thus result in extraordinary channel stability and high transporting efficiency for protons and cations. The lifetime of this artificial unimolecular channel in the lipid bilayer membrane is impressively long, rivaling those of natural protein channels. Natural channel mimics designed by helically folded polymeric scaffolds will display robust and versatile transport‐related properties at single‐molecule level.

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Linolenic acid-modified PEG-PCL micelles for curcumin delivery

Song

Zhu

Liu

et al. 2014

International Journal of Pharmaceutics

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Highly Selective Artificial Potassium Ion Channels Constructed from Pore‐Containing Helical Oligomers

et al. 2017

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Potassium ion channels specifically transport K ions over Na ions across a cell membrane. A queue of four binding sites in the K channel pore plays significant roles during highly selective conduction. A kind of aromatic helical oligomer was synthesized that can selectively bind K over Na . By aromatic stacking of helical oligomers, a type of artificial K channels with contiguous K binding sites was constructed. Such artificial channels exhibited exceptionally high K /Na selectivity ratios during transmembrane ion conduction.

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Template-Free Construction of Highly Ordered Monolayered Fluorescent Protein Nanosheets: A Bioinspired Artificial Light-Harvesting System

Qiao

Zhao

et al. 2019

ACS Nano

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Using biological materials for light-harvesting applications has attracted considerable attention in recent years. Such materials provide excellent environmental compatibility and often exhibit superior properties over synthetic materials. Herein, inspired by the outstanding energy transfer performance in coelenterates, we constructed a template-free, highly ordered two-dimensional light-harvesting system by covalent-induced coassembly of EBFP2 (donor) and EGFP (acceptor), in which the fluorescent chromophores were well distributed and adopted a fixed orientation. By introducing approximate square planar binding sites on the side surface of protein, assembly pattern was pin down and self-assembly extended in orthogonal directions to achieve monolayered and tessellated protein nanoarrays. The excellent antiself-quenching property of fluorescent proteins endowed the coassembled system with attractive light-harvesting capability. Even at high local concentrations, a low resonance energy transfer self-quenching was observed and, therefore, energy can be efficiently transferred. More importantly, the distance between adjacent chromophores is continuously adjustable. By making minor changes to the length of the inducing linker, we have achieved significant control over the size of the assembly. A micron-sized light-harvesting system with satisfactory energy transfer efficiency was finally obtained. This work developed a template-free light-harvesting system completely based on fluorescent proteins (FPs), which overcame the restriction of using templates. Not limited to this work, the special core−shell structure of FPs may be expected to direct the optimization of fluorescent dyes by cladding.

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Semithiobambus[6]uril is a transmembrane anion transporter

et al. 2017

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Semithiobambus[6]uril is shown to be an efficient transmembrane anion transporter. Although all bambusuril analogs (having either O, S or N atoms in their portals) are excellent anion binders, only the sulfur analog is also an effective anion transporter capable of polarizing lipid membranes through selective anion uniport. This notable divergence reflects significant differences in the lipophilic character of the bambusuril analogs.

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Fan Yang

Biomimetic Transmembrane Channels with High Stability and Transporting Efficiency from Helically Folded Macromolecules

Linolenic acid-modified PEG-PCL micelles for curcumin delivery

Highly Selective Artificial Potassium Ion Channels Constructed from Pore‐Containing Helical Oligomers

Template-Free Construction of Highly Ordered Monolayered Fluorescent Protein Nanosheets: A Bioinspired Artificial Light-Harvesting System

Semithiobambus[6]uril is a transmembrane anion transporter

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