Cholesterol-Enriched Domain Formation Induced by Viral-Encoded, Membrane-Active Amphipathic Peptide.

The α-helical (AH) domain of the hepatitis C virus nonstructural protein NS5A, anchored at the cytoplasmic leaflet of the endoplasmic reticulum, plays a role in viral replication. However, the peptides derived from this domain also exhibit remarkably broad-spectrum virocidal activity, raising questions about their modes of membrane association. Here, using giant lipid vesicles, we show that the AH peptide discriminates between membrane compositions. In cholesterol-containing membranes, peptide binding induces microdomain formation. By contrast, cholesterol-depleted membranes undergo global softening at elevated peptide concentrations. Furthermore, in mixed populations, the presence of ∼100 nm vesicles of viral dimensions suppresses these peptide-induced perturbations in giant unilamellar vesicles, suggesting size-dependent membrane association. These synergistic composition- and size-dependent interactions explain, in part, how the AH domain might on the one hand segregate molecules needed for viral assembly and on the other hand furnish peptides that exhibit broad-spectrum virocidal activity.

On-demand self-assembly of supported membranes using sacrificial, anhydrobiotic sugar coats.

Borrowing principles of anhydrobiosis, we have developed a technique for self-assembling proteolipid-supported membranes on demand--simply by adding water. Intact lipid- and proteolipid vesicles dispersed in aqueous solutions of anhydrobiotic trehalose are vitrified on arbitrary substrates, producing glassy coats encapsulating biomolecules. Previous efforts establish that these carbohydrate coats arrest molecular mobilities and preserve native conformations and aggregative states of the embedded biomolecules, thereby enabling long-term storage. Subsequent rehydration, even after an extended period of time (e.g., weeks), devitrifies sugar--releasing the cargo and unmasking the substrate surface--thus triggering substrate-mediated vesicle fusion in real time, producing supported membranes. Using this method, arrays of membranes, including those functionalized with membrane proteins, can be readily produced in situ by spatially addressing vitrification using common patterning tools--useful for multiplexed or stochastic sensing and assaying of target interactions with the fluid and functional membrane surface.