Fast formation of low-defect-density tethered bilayers by fusion of multilamellar vesicles.

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TitleFast formation of low-defect-density tethered bilayers by fusion of multilamellar vesicles.
Publication TypeJournal Article
Year of Publication2017
AuthorsRagaliauskas, T, Mickevicius, M, Rakovska, B, Penkauskas, T, Vanderah, DJ, Heinrich, F, Valincius, G
JournalBiochim Biophys Acta
Date Published2017 Jan 11
ISSN0006-3002
Abstract

A facile and reproducible preparation of surface-supported lipid bilayers is essential for fundamental membrane research and biotechnological applications. We demonstrate that multilamellar vesicles fuse to molecular-anchor-grafted surfaces yielding low-defect-density, tethered bilayer membranes. Continuous bilayers are formed within 10min, while the electrically insulating bilayers with <0.1μm(-2) defect density can be accomplished within 60min. Surface plasmon resonance spectroscopy indicates that an amount of lipid material transferred from vesicles to a surface is inversely proportional to the density of an anchor, while the total amount of lipid that includes tethered and transferred lipid remains constant within 5% standard error. This attests for the formation of intact bilayers independent of the tethering agent density. Neutron reflectometry (NR) revealed the atomic level structural details of the tethered bilayer showing, among other things, that the total thickness of the hydrophobic slab of the construct was 3.2nm and that the molar fraction of cholesterol in lipid content is essentially the same as the molar fraction of cholesterol in the multilamellar liposomes. NR also indicated the formation of an overlayer with an effective thickness of 1.9nm. These overlayers may be easily removed by a single rinse of the tethered construct with 30% ethanol solution. Fast assembly and low residual defect density achievable within an hour of fusion makes our tethered bilayer methodology an attractive platform for biosensing of membrane damaging agents, such as pore forming toxins.

DOI10.1016/j.bbamem.2017.01.015
Alternate JournalBiochim. Biophys. Acta
PubMed ID28088448