Abstract

Abstract Functionally distinct subsets of pathogen-specific CD4 helper T cells, including T follicular helper (Tfh) and T helper type 1 (Th1) subsets, are critical for orchestrating the induction and maturation of innate and adaptive immune responses. Proper genetic programming of Tfh and Th1 differentiation is required for regulating immune responses to clear primary infections and promote long-lived memory CD4 T cell-mediated protection against pathogen re-exposures. Genetic approaches to study CD4 T cell differentiation have been largely focused on transcriptional programming, but gene regulation is also critically tied to epigenetic modifications, which represents a major knowledge gap in our understanding of CD4 T cell biology. Ten-eleven-translocation (TET) family enzymes facilitate DNA demethylation to influence chromatin accessibility and promote gene expression. Prior work has shown that TET2 activity has been linked to optimal Th1 responses in vitro. TET1 and TET3 proteins mediate Cd4 locus demethylation and are required for stable CD4 expression during thymocyte development. However, the precise role of either TET1 or TET3 activity to mediate CD4 T cell fate and function in vivo has not been directly investigated. Thus, we hypothesized that TET1 and TET3 activity in peripheral, mature CD4 T cells is required for regulating T helper cell differentiation and function. We used conditional genetic and chimeric approaches, coupled with robust systems of infectious disease immunology, to directly test our hypothesis. Our data show substantial CD4 T cell developmental skewing towards Tfh fates in the absence of specific TET family members. This suggests that TET1 and TET3 enzymes play a role in governing Tfh and Th1 CD4 cell fate.

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