ABSTRACT
Ionizable lipid nanocarriers have made historical contribution to COVID-19 mRNA vaccines. Here, we report ionizable polymeric nanoparticles that co-deliver bi-adjuvant and neoantigen peptides for cancer immunotherapy in combination with immune checkpoint blockade (ICB). Current cancer ICB benefits only a small subset of patients, largely due to a lack of pre-existing target cells and checkpoint targets for ICB, tumor antigenic heterogeneity, and tumor immunosuppression. Therapeutic vaccines hold the potential to enhance ICB therapeutic efficacy by expanding antitumor cell repertoires, upregulating immune checkpoint levels and hence sensitizing ICB, and reducing tumor immunosuppression. Chemically defined peptide vaccines are attractive, but their current therapeutic efficacy has been limited due to 1) poor vaccine delivery to immunomodulatory lymph nodes (LNs) and antigen (Ag)-presenting cells (APCs), 2) poor immunostimulant adjuvant efficacy with restricted target cell subsets in humans, 3) limited adjuvant/Ag codelivery to enhance Ag immunogenicity, and 4) limited ability to overcome tumor antigenic heterogeneity. Here, we developed nanovaccines (NVs) using pH-responsive polymeric micellular nanoparticles (NPs) for the codelivery of bi-adjuvant [Toll-like receptor (TLR) 7/8 agonist R848 and TLR9 agonist CpG] and peptide neoantigens (neoAgs) to draining LNs for efficient Ag presentation in a broad range of APC subsets. These NVs potentiated the immunogenicity of peptide Ags and elicits robust antitumor T cell responses with memory, and remodeled the tumor immune milium with reduced tumor immunosuppression. As a result, NVs significantly enhanced ICB therapeutic efficacy for murine colorectal tumors and orthotopic glioblastoma multiforme (GBM). These results suggest marked potential of bi-adjuvant/neoAg-codelivering NVs for combination cancer immunotherapy.