Abstract
Tuberculosis (TB) is the leading cause of death due to a pathogen. The live-attenuated BCG vaccine is the only approved vaccine to prevent TB, but it fails to confer long-term protection. We hypothesize that the immunosuppressive cytokine IL-27 may contribute to the inefficacies of the BCG vaccine. IL-27 is elevated in neonates, the population most commonly administered BCG, and levels increase further upon vaccination. IL-27 interferes with the phagolysosomal pathway, suggesting it may limit the diversity of antigens processed and presented to T cells. We hypothesized that in the absence of IL-27 signaling, BCG vaccination induces antigen-specific T cells that recognize a greater number of antigens and provide enhanced protection during M. tuberculosis (Mtb) challenge. CD3(+) T cells isolated from IL-27Rα KO mice vaccinated with BCG as neonates were more responsive to BCG and a Mtb peptide pool than T cells from vaccinated WT mice. Adoptive transfer of IL-27Rα KO T cells provided more consistent protection against Mtb than WT, but this was not observed in TCRα(-/-) mice. A principal component analysis suggested a more consistent multifunctional cytokine response was associated IL-27Rα KO T cells. These findings enhance our understanding of IL-27 during neonatal vaccination and development of protective immunity.