The human pathogen Trypanosoma cruzi is an intracellular parasite and the etiological agent of Chagas disease. Protective immune responses to T. cruzi are highly dependent on T helper 1 and CD8+ T cells which produce interferon-gamma. A deficiency in these responses has severe consequences on the ability to control infection. Our investigation into the role of the Th1 transcription factor, T-bet, during murine T. cruzi infection revealed that T-bet is required for resistance. Contrary to our expectations, T-bet was not required for the development of Th1 immunity during infection, as T-bet-deficient mice still developed interferon-gamma-producing T cells. However, T-bet was required to suppress the differentiation of Th17 cells and for the expansion of T. cruzi-specific CD8+ T cells. We first sought to determine the cause of reduced numbers of T. cruzi-specific CD8+ T cells in infected T-bet-deficient mice. First, we found that impaired migration or survival did not contribute to the low number of T. cruzi-specific CD8+ T cells. Secondly, we determined that reduced numbers of CD8+ T cells was not secondary to a defect in antigen-presenting cell activation or priming of CD8+ T cells. A recapitulation of defective expansion in mice with normal T-bet-expressing antigen-presenting cells demonstrated that T-bet expression in T cells was required. Thus, we determined that T-bet regulates the expansion of antigen-specific CD8+ T cells during T. cruzi infection in a T cell-intrinsic manner. Although it was evident T-bet had an integral role in suppressing the development of Th17 cells in response to infection with T. cruzi, several issues remained unclear. The first was the apparent lack of a negative regulatory effect of IFN-g/IFN-g-signaling on Th17 cells, which contradicted published reports. To clarify the role of IFN-g, we investigated the effect of IFN-g- or Stat-1-deficiency during T. cruzi infection. Surprisingly, IFN-g did not have a major role in up-regulating T-bet or for suppressing the development of Th17 responses, whereas Stat-1 was necessary for both. This was unexpected as Stat-1 is an IFN-g-inducible transcription factor, and its activation leads to T-bet induction. Thus, the T-bet-mediated inhibition of Th17 responses during T. cruzi infection is dependent on Stat-1, but not IFN-g. The final aim of this project was to identify the cytokines that negatively regulate Th17 differentiation in response to T. cruzi. We focused on the IL-12-family cytokines, IL-12 and IL-27, which are known to regulate T cell responses. Indeed, IL-12-deficient mice infected with T. cruzi developed a significant increase in Th17 cells similar to that observed in T-bet-deficient mice. Surprisingly, and in contrast to published results in other models, IL-27-deficient mice did not exhibit an increase in Th17 development. Our results demonstrate that IL-12, but not IL-27, is necessary for optimal T-bet expression and regulation of Th17 responses during T. cruzi infection
