Batf stabilizes Th17 cell development via impaired Stat5 recruitment of Ets1-Runx1 complexes.

Although the activator protein-1 (AP-1) factor Batf is required for Th17 cell development, its mechanisms of action to underpin the Th17 program are incompletely understood. Here, we find that Batf ensures Th17 cell identity in part by restricting alternative gene programs through its actions to restrain IL-2 expression and IL-2-induced Stat5 activation. This, in turn, limits Stat5-dependent recruitment of Ets1-Runx1 factors to Th1- and Treg-cell-specific gene loci. Thus, in addition to pioneering regulatory elements in Th17-specific loci, Batf acts indirectly to inhibit the assembly of a Stat5-Ets1-Runx1 complex that enhances the transcription of Th1- and Treg-cell-specific genes. These findings unveil an important role for Stat5-Ets1-Runx1 interactions in transcriptional networks that define alternate T cell fates and indicate that Batf plays an indispensable role in both inducing and maintaining the Th17 program through its actions to regulate the competing actions of Stat5-assembled enhanceosomes that promote Th1- and Treg-cell developmental programs.

Differential IL-2 expression defines developmental fates of follicular versus nonfollicular helper T cells.

In response to infection, naïve CD4+ T cells differentiate into two subpopulations: T follicular helper (TFH) cells, which support B cell antibody production, and non-TFH cells, which enhance innate immune cell functions. Interleukin-2 (IL-2), the major cytokine produced by naïve T cells, plays an important role in the developmental divergence of these populations. However, the relationship between IL-2 production and fate determination remains unclear. Using reporter mice, we found that differential production of IL-2 by naïve CD4+ T cells defined precursors fated for different immune functions. IL-2 producers, which were fated to become TFH cells, delivered IL-2 to nonproducers destined to become non-TFH cells. Because IL-2 production was limited to cells receiving the strongest T cell receptor (TCR) signals, a direct link between TCR-signal strength, IL-2 production, and T cell fate determination has been established.

IL-6 promotes the differentiation of a subset of naive CD8+ T cells into IL-21-producing B helper CD8+ T cells.

IL-6 is known to contribute to the differentiation of CD4+ T cells into different subsets of effector T helper cells. Less is known about the potential of IL-6 in regulating CD8+ T cell effector function. Here, we identify IL-6 as a master regulator of IL-21 in effector CD8+ T cells. IL-6 promotes the differentiation of a subset of naive CD8+ T cells that express IL-6R into a unique population of effector CD8+ T cells characterized by the production of high levels of IL-21 and low levels of IFN-γ. Similar to CD4+ T follicular helper (Tfh) cells, IL-21-producing CD8+ T cells generated in the presence of IL-6 directly provide help to B cells to induce isotype switching. CD8+ T cell-derived IL-21 contributes to the production of protective virus-specific IgG antibodies during influenza virus infection. Thus, this study reveals the presence of a new mechanism by which IL-6 regulates antibody production during viral infection, and a novel function of effector CD8+ T cells in the protection against viruses.

Th22 cells are an important source of IL-22 for host protection against enteropathogenic bacteria.

Interleukin-22 (IL-22) is central to host protection against bacterial infections at barrier sites. Both innate lymphoid cells (ILCs) and T cells produce IL-22. However, the specific contributions of CD4(+) T cells and their developmental origins are unclear. We found that the enteric pathogen Citrobacter rodentium induced sequential waves of IL-22-producing ILCs and CD4(+) T cells that were each critical to host defense during a primary infection. Whereas IL-22 production by ILCs was strictly IL-23 dependent, development of IL-22-producing CD4(+) T cells occurred via an IL-6-dependent mechanism that was augmented by, but not dependent on, IL-23 and was dependent on both transcription factors T-bet and AhR. Transfer of CD4(+) T cells differentiated with IL-6 in the absence of TGF-ß ("Th22" cells) conferred complete protection of infected IL-22-deficient mice whereas transferred Th17 cells did not. These findings establish Th22 cells as an important component of mucosal antimicrobial host defense.