Optimization of peptide-based cancer vaccine compositions, by sequential screening, using versatile liposomal platform.

Therapeutic cancer vaccines need thoughtful design to efficiently deliver appropriate antigens and adjuvants to the immune system. In the current study, we took advantage of the versatility of a liposomal platform to conceive and customize vaccines containing three elements needed for the induction of efficient antitumor immunity: i) a CD4 epitope peptide able to activate CD4 T helper cells, ii) a CD8 tumor-specific epitope peptide recognized by CD8 T cytotoxic cells and iii) Pattern Recognition Receptor (PRR) agonists which stand as adjuvants. Each type of component, conjugated to liposomes, was evaluated individually by comparing their vaccine efficacy after immunization of naïve mice.

Liposomal constructs for antitumoral vaccination by the nasal route.

Mucosal surfaces are promising routes for vaccination. Among mucosa, airway mucosa provides the opportunity to develop non-invasive approaches for vaccine delivery. In the current study, nasal route was used to investigate the potency of highly versatile di-epitopic liposomal constructs of different size, structure and composition to exhibit antitumor efficiency after prophylactic vaccination in mice.

Airway administration of a highly versatile peptide-based liposomal construct for local and distant antitumoral vaccination.

With the discovery of tumor-associated antigens such as ErbB2, vaccination is considered as a promising strategy to prevent the development of cancer or treat the existing disease. Among routes of immunization, the respiratory route provides the opportunity to develop non-invasive approach for vaccine delivery. In the current study, this administration route was used in order to investigate the potency of a highly versatile di-epitopic liposomal construct to exhibit local or distant antitumoral efficiency after prophylactic or therapeutic vaccination in mice.