Abstract
Liposomes are widely investigated as vaccine delivery systems, but antigen loading efficiency can be low. Moreover, adsorbed antigen may rapidly desorb under physiological conditions. Encapsulation of antigens overcomes the latter problem but results in significant antigen loss during preparation and purification of the liposomes. Here, we propose an alternative attachment method, based on a complementary heterodimeric coiled coil peptide pair pepK and pepE.PepK was conjugated to cholesterol (yielding CPK) and pepE was covalently linked to model antigen OVA323 (yielding pepE-OVA323). CPK was incorporated in the lipid bilayer of cationic liposomes (180 nm in size). Antigen was associated more efficiently to functionalized liposomes (Kd 166 nM) than to cationic liposomes (Kd not detectable). In vivo co-localization of antigen and liposomes was strongly increased upon CPK-functionalization (35% -> 80%). CPK-functionalized liposomes induced 5-fold stronger CD4+ T-cell proliferation than non-functionalized liposomes in vitro. Both formulations were able to induce strong CD4+ T-cell expansion in mice, but more IFN-y and IL-10 production was observed after immunization with functionalized liposomes. In conclusion, antigen association via coiled coil peptide pair increased co-localization of antigen and liposomes, increased CD4+ T-cell proliferation in vitro and induced a stronger CD4+ T-cell response in vivo.
Highlights
The latest generation of vaccines moves away from whole pathogens and instead uses pathogen-derived proteins or peptides as antigen
We demonstrated a novel antigen association method to liposomes based on a complementary peptide pair that forms a coiled coil (CC) upon interaction
PepK was coupled to cholesterol to yield coupled pepK (CPK), which was encapsulated in the lipid bilayer, whereas peptide E (pepE) was synthesized with two different antigenic epitopes
Summary
The latest generation of vaccines moves away from whole pathogens and instead uses pathogen-derived proteins or peptides (i.e., subunits) as antigen. The lipid composition directs the physicochemical properties of the liposomes, such as size, zeta potential, membrane fluidity and rigidity [1,3]. These properties greatly influence their behavior upon injection and the immune response they may induce [3,5,6,7,8]. Cationic liposomes have been used extensively as vaccine ad juvants They are known to induce strong T-cell expansion and proinflammatory T helper (Th) 1-skewed immune response [9,10,11,12,13,14]
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