Engineered synthetic virus-like particles and their use in vaccine delivery

Engineered nanoparticles have been designed based on the self-assembling properties of synthetic coiled-coil lipopeptide building blocks. The presence of an isoleucine zipper within the lipopeptide together with the aggregating effects of an N-terminal lipid drives formation of 20-25 nm nanoparticles in solution. Biophysical studies support a model in which the lipid is buried in the centre of the nanoparticle, with 20-30 trimeric helical coiled-coil bundles radiating out into solution. A promiscuous T-helper epitope and a synthetic B-cell epitope mimetic derived from the circumsporozoite protein of Plasmodium falciparum have been linked to each lipopeptide chain, with the result that 60-90 copies of each antigen are displayed over the surface of the nanoparticle. These nanoparticles elicit strong humoral immune responses in mice and rabbits, including antibodies able to cross-react with the parasite, thereby, supporting the potential value of this delivery system in synthetic vaccine design. Viral protection: Synthetic virus-like particles (SVLPs) are produced from self-assembling coiled-coil lipopeptide building blocks (see figure). SVLPs allow multivalent display of B-cell epitope mimetics, are highly immunogenic, and can be used to elicit strong epitope- and pathogen-specific humoral immune responses without the use of adjuvants.