Abstract
After more than a century since its initial development, Bacille Calmette-Guérin (BCG) remains the only licensed vaccine against tuberculosis (TB). Subunit boosters are considered a viable strategy to enhance BCG efficacy, which often wanes in adolescence. While many studies on booster subunit vaccines have concentrated on recombinant proteins, here we developed a novel modular peptide-based subunit vaccine platform that is flexible, cold-chain independent and customizable to diverse circumstances and populations. Each individual peptide building block consists of a linear arrangement comprising a 15-leucine self-assembly inducer moiety, a Mycobacterium tuberculosis (Mtb) target epitope and an HLA-E binding moiety, with each moiety separated by a triple lysine spacer. The building blocks, in any combination, were able to form a multiepitope nanoparticle. Six Mtb epitopes were selected to produce the self-assembling and self-adjuvanting peptide-based TB nano-vaccine candidate PNx6. In vivo vaccination-challenge experiments demonstrated that subcutaneous boost of parenteral BCG immunization with PNx6 significantly enhanced its immunogenicity and improved its protective efficacy in a murine model of TB by more than 5-fold. Our study present evidence that purely amphiphilic peptides self-assemble into self-adjuvanting nanoparticles with appropriate size and morphology for TB vaccination with great potential for a multitude of other diseases.
Competing Interest Statement
G.Z., M.S. and I.T. are co-inventors on a patent application entitled: Self-assembling, self-adjuvating system for delivery of vaccines filed by the University of Queensland (application number: WO/2021/138721, PCT/AU2021/050012). The remaining authors declare no competing interests.