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. These screening steps resulted in the optimization of three liposomal constructs bearing a peptide from HA influenza virus protein as CD4 epitope, a peptide from HPV16 E7 oncoprotein as CD8 epitope and TLR4, TLR2/6 or NOD1 agonists as adjuvant, which displayed antitumor efficiency against a mouse model of disseminated tumors transformed by HPV16. Our results validated the interest of our customizable liposomal platform as delivery system for cancer vaccination. We also demonstrated its interest as tool for vaccine design allowing the strategical selection of components, and the evaluation of epitope-adjuvant association.

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. Well-characterized small unilamellar (SUV), multilamellar (MLV), reverse-phase evaporation (REV) and ultraflexible small unilamellar vesicles (Uf-SUV), containing the ErbB2 T-cytotoxic epitope, the influenza-derived HA T-helper epitope and the lipopeptide adjuvant Pam2CAG, were formulated. These vaccines were administered into the nasal cavity of BALB/c mice, followed by i.v. or s.c. implantation of ErbB2-surexpressing cancer cells. Nasal vaccination with the SUV vaccine resulted in an efficient antitumor activity against lung tumors and a non-significant protection against s.c. tumors. Size, structure and flexibility of liposomes did not impact vaccine immunity and antitumoral efficiency against lung tumors, in contrast to total dose of vaccine or dose of adjuvant. These results showed an undeniable interest of liposomes as lipid-based carriers for antitumor vaccine delivery by the nasal route, opening new perspectives for cancer treatment.

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. Well-characterized liposomes, containing the ErbB2 (p63-71) TCD8(+) and HA (p307-319) TCD4(+) peptide epitopes and the Pam2CAG adjuvant, were formulated and administered into the airway of naïve BALB/c mice. The nanoparticle vaccine candidate induced local and specific systemic immune response, as measured by immune cell infiltration and chemokine and cytokine production in BALF or lung tissue, and by spleen T-cell activation ex vivo, respectively. This potent immune response resulted in an efficient antitumor activity against both lung and solid s.c. tumors. Interestingly, the antitumor efficacy was observed after both prophylactic and therapeutic vaccinations, which are the most judicious ones to fight cancer. Our data showed an undeniable interest of liposomal peptide-based vaccines in antitumor vaccination by the respiratory route, opening new perspectives for cancer treatment.