ABSTRACT
Synthetic vaccines that induce T cell responses to peptide epitopes are a promising immunotherapy for both communicable and noncommunicable diseases. Stimulating strong and sustained T cell responses requires antigen delivery to appropriately activated antigen presenting cells (APCs). One way this can be accomplished is by chemically conjugating immunogenic peptide epitopes with α-galactosylceramide (α-GalCer), a glycolipid that acts as an immune adjuvant by inducing stimulatory interactions between APCs and type I natural killer T (NKT) cells. Here we investigate whether increasing the ratio of antigen:adjuvant improves antigen-specific T cell responses. A series of conjugate vaccines was prepared in which one, two, four, or eight copies of an immunogenic peptide were covalently attached to a modified form of α-GalCer via the poly(ethoxyethylglycinamide) dendron scaffold. Initial attempts to synthesize these multivalent conjugate vaccines involved attaching the bicyclo[6.1.0]non-4-yne (BCN) group to the adjuvant-dendron structure followed by strain-promoted azide-alkyne cycloaddition of the peptide. Although this approach was successful for preparing vaccines with either one or two peptide copies, the synthesis of vaccines requiring attachment of four or eight BCN groups suffered from low yields due to cyclooctyne degradation. Instead, conjugate vaccines containing up to eight peptide copies were readily achieved through oxime ligation with adjuvant-dendron constructs decorated with the 8-oxo-nonanoyl group. When evaluating T cell responses to vaccination in mice, we confirmed a significant advantage to conjugation over admixes of peptide and α-GalCer, regardless of the peptide to adjuvant ratio, but there was no advantage to increasing the number of peptides attached. However, it was notable that the higher ratio conjugate vaccines required lower levels of NKT cell activation to be effective, which could be a safety advantage for future vaccine candidates.
ABSTRACT
Activated NKT cells can stimulate antigen-presenting cells leading to enhanced peptide antigen-specific immunity. However, administration of potent NKT cell agonists like α-galactosylceramide (α-GalCer) can be associated with release of high levels of cytokines, and in some situations, hepatotoxicity. Here we show that it is possible to provoke sufficient NKT cell activity to stimulate strong antigen-specific T cell responses without these unwanted effects. This was achieved by chemically conjugating antigenic peptides to α-galactosylphytosphingosine (α-GalPhs), an NKT cell agonist with very weak activity based on structural characterisation and biological assays. Conjugation improved delivery to antigen-presenting cells in vivo, while use of a cathepsin-sensitive linker to release the α-GalPhs and peptide within the same cell promoted strong T cell activation and therapeutic anti-tumour responses in mice. The conjugates activated human NKT cells and enhanced human T cell responses to a viral peptide in vitro. Accordingly, we have demonstrated a means to safely exploit the immunostimulatory properties of NKT cells to enhance T cell activation for virus- and tumour-specific immunity.
