Issue 8, 2013

Selective and ATP-driven transport of ions across supported membranes into nanoporous carriers using gramicidin A and ATP synthase

Abstract

We report a robust and versatile membrane protein based system for selective uptake and release of ions from nanoporous particles sealed with ion-tight lipid bilayers of various compositions that is driven by the addition of ATP or a chemical potential gradient. We have successfully incorporated both a passive ion channel-type peptide (gramicidin A) and a more complex primary sodium ion transporter (ATP synthase) into the supported lipid bilayers on solid nanoporous silica particles. Protein-mediated controlled release/uptake of sodium ions across the ion-tight lipid bilayer seal from or into the nanoporous silica carrier was imaged in real time using a confocal laser scanning microscope and the intensity changes were quantified. ATP-driven transport of sodium ions across the supported lipid bilayer against a chemical gradient was demonstrated. The possibility of designing durable carriers with tight lipid membranes, containing membrane proteins for selective ion uptake and release, offers new possibilities for functional studies of single or cascading membrane protein systems and could also be used as biomimetic microreactors for controlled synthesis of inorganic multicomponent materials.

Graphical abstract: Selective and ATP-driven transport of ions across supported membranes into nanoporous carriers using gramicidin A and ATP synthase

Supplementary files

Article information

Article type
Paper
Submitted
10 Sep 2012
Accepted
04 Jan 2013
First published
04 Jan 2013
This article is Open Access

Phys. Chem. Chem. Phys., 2013,15, 2733-2740

Selective and ATP-driven transport of ions across supported membranes into nanoporous carriers using gramicidin A and ATP synthase

V. Oliynyk, C. Mille, J. B. S. Ng, C. von Ballmoos, R. W. Corkery and L. Bergström, Phys. Chem. Chem. Phys., 2013, 15, 2733 DOI: 10.1039/C2CP43166A

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