Calcitriol and Retinoic acid antagonize each other to suppress the production of IL-9 by Th9 cells

Distinct T helper cells, including Th9 cells help maintain homeostasis in the immune system. Vitamins play pivotal role in the immune system through many mechanisms, including regulating the differentiation of T helper cells. Calcitriol (1,25-dihydroxyvitamin D3) and retinoic acid possess hormone-like properties and are the bioactive metabolites of vitamin D and A, respectively, that signal through heterodimers containing the common retinoid X receptor. In contrast to individual treatment with the vitamins that significantly attenuates IL-9 production from Th9 cells, Th9 cells treated with both vitamins demonstrated IL-9 production similar to untreated Th9 cells. This is associated with reciprocal expression of PU.1 and Foxp3. While the recruitment of PU.1 was significantly impaired to the Il9 gene in the presence of calcitriol or retinoic acid in Th9 cells, addition of both vitamins together increased the recruitment of PU.1 to the Il9 gene. Calcitriol and retinoic acid together impaired the recruitment of HDAC1 to the Il9 gene without impacting Gcn5 recruitment. Importantly, retinoic acid negated the effect of calcitriol and impaired the binding of VDR on the Il9 gene by dampened VDR-RXR formation. Collectively, our data show that calcitriol and retinoic acid antagonize each other to regulate the differentiation of Th9 cells.     

NFκB attenuates IL-5 production and upregulates T-box transcription factors in Th2-like T cells

IL-5 plays important roles in eosinophil differentiation, expansion, and recruitment. The regulation of IL-5 seems critical for the treatment of eosinophil-mediated allergic reactions. However, the precise mechanisms for IL-5 regulation remain unknown. In this study, we investigated how IL-5 production is regulated. The transduction of GATA-3 into a murine T cell hybridoma resulted in acquiring the ability to produce IL-5 in response to an antigenic stimulus like Th2 cells. This production was dependent on the cAMP-PKA pathway, but not on p38 activation. Transduction of NIK largely impaired IL-5 production. RelA and RelB similarly impaired IL-5 production. RelA decreased not only IL-5 protein amount but mRNA. RelA also inhibited Il5-luciferase reporter activity. The transduction of GATA-3 decreased the expression of Tbx21 and Eomes, but the additional transduction of RelA abrogated the decreased expression of GATA-3-induced Tbx21 and Eomes. Furthermore, the transduction of T-bet or Eomes into the GATA-3-transduced T cell hybridoma impaired IL-5 production. These results suggested that strong enhancement of the NFκB pathway downregulates IL-5 production and upregulates T-box protein expression to shift an immune response from Th2 to inflammatory Th1.     

IL-27 Receptor Signalling Restricts the Formation of Pathogenic,Terminally Differentiated Th1 Cells during Malaria Infection by Repressing IL-12 Dependent Signals

The IL-27R, WSX-1, is required to limit IFN-γ production by effector CD4⁺ T cells in a number of different inflammatory conditions but the molecular basis of WSX-1-mediated regulation of Th1 responses in vivo during infection has not been investigated in detail. In this study we demonstrate that WSX-1 signalling suppresses the development of pathogenic, terminally differentiated (KLRG-1⁺) Th1 cells during malaria infection and establishes a restrictive threshold to constrain the emergent Th1 response. Importantly, we show that WSX-1 regulates cell-intrinsic responsiveness to IL-12 and IL-2, but the fate of the effector CD4⁺ T cell pool during malaria infection is controlled primarily through IL-12 dependent signals. Finally, we show that WSX-1 regulates Th1 cell terminal differentiation during malaria infection through IL-10 and Foxp3 independent mechanisms; the kinetics and magnitude of the Th1 response, and the degree of Th1 cell terminal differentiation, were comparable in WT, IL-10R1^−/− and IL-10^−/− mice and the numbers and phenotype of Foxp3⁺ cells were largely unaltered in WSX-1^−/− mice during infection. As expected, depletion of Foxp3⁺ cells did not enhance Th1 cell polarisation or terminal differentiation during malaria infection. Our results significantly expand our understanding of how IL-27 regulates Th1 responses in vivo during inflammatory conditions and establishes WSX-1 as a critical and non-redundant regulator of the emergent Th1 effector response during malaria infection.     

Development of a unique epigenetic signature during in vivo Th17 differentiation

Activated naive CD4⁺ T cells are highly plastic cells that can differentiate into various T helper (Th) cell fates characterized by the expression of effector cytokines like IFN-γ (Th1), IL-4 (Th2) or IL-17A (Th17). Although previous studies have demonstrated that epigenetic mechanisms including DNA demethylation can stabilize effector cytokine expression, a comprehensive analysis of the changes in the DNA methylation pattern during differentiation of naive T cells into Th cell subsets is lacking. Hence, we here performed a genome-wide methylome analysis of ex vivo isolated naive CD4⁺ T cells, Th1 and Th17 cells. We could demonstrate that naive CD4⁺ T cells share more demethylated regions with Th17 cells when compared to Th1 cells, and that overall Th17 cells display the highest number of demethylated regions, findings which are in line with the previously reported plasticity of Th17 cells. We could identify seven regions located in Il17a, Zfp362, Ccr6, Acsbg1, Dpp4, Rora and Dclk1 showing pronounced demethylation selectively in ex vivo isolated Th17 cells when compared to other ex vivo isolated Th cell subsets and in vitro generated Th17 cells, suggesting that this unique epigenetic signature allows identifying and functionally characterizing in vivo generated Th17 cells.     

Abnormal Th1 cell differentiation and IFN-gamma production in T lymphocytes from motheaten viable mice mutant for Src homology 2 domain-containing protein tyrosine phosphatase-1

Src homology 2 domain-containing protein tyrosine phosphatase-1 (SHP-1) plays an important role in T and B lymphocyte signaling; however, the function of SHP-1 in Th cell differentiation, in particular, the Th1 response, has not been defined. In this study, we provide evidence that SHP-1 phosphatase negatively regulates Th1 cell development and IFN-gamma production. Compared with the wild-type control, anti-CD3-activated mouse T lymphocytes carrying the motheaten viable mutation in the SHP-1 gene produced a significantly increased amount of IFN-gamma in the presence of IL-12. This increase was also seen at the basal level without IL-12 addition. Similarly, Th1 cell differentiation and proliferation of anti-CD3-activated SHP-1 mutant lymph node cells in the presence or absence of IL-12 were markedly enhanced, indicating a negative role for SHP-1 phosphatase in such lymphocyte activities. Interestingly, IL-12-induced activation of Jak2 and STAT4, critical components for IL-12-mediated cellular responses, was shortened or attenuated in mutant T cells. Together these results suggest that SHP-1 negatively regulates Th1 cell development and functions through a mechanism that is not directly related to IL-12 signaling.     

Ikaros Sets the Potential for Th17 Lineage Gene Expression through Effects on Chromatin State in Early T Cell Development

Th17 cells are important effectors of immunity to extracellular pathogens, particularly at mucosal surfaces, but they can also contribute to pathologic tissue inflammation and autoimmunity. Defining the multitude of factors that influence their development is therefore of paramount importance. Our previous studies using Ikaros^−/− CD4+ T cells implicated Ikaros in Th1 versus Th2 lineage decisions. Here we demonstrate that Ikaros also regulates Th17 differentiation through its ability to promote expression of multiple Th17 lineage-determining genes, including Ahr, Runx1, Rorc, Il17a, and Il22. Ikaros exerts its influence on the chromatin remodeling of these loci at two distinct stages in CD4+ T helper cell development. In naive cells, Ikaros is required to limit repressive chromatin modifications at these gene loci, thus maintaining the potential for expression of the Th17 gene program. Subsequently, Ikaros is essential for the acquisition of permissive histone marks in response to Th17 polarizing signals. Additionally, Ikaros represses the expression of genes that limit Th17 development, including Foxp3 and Tbx21. These data define new targets of the action of Ikaros and indicate that Ikaros plays a critical role in CD4+ T cell differentiation by integrating specific cytokine cues and directing epigenetic modifications that facilitate activation or repression of relevant genes that drive T cell lineage choice.     

Stat6 is necessary and sufficient for IL-4's role in Th2 differentiation and cell expansion

IL-4 plays a critical role in the differentiation of TCR-stimulated naive CD4 T cells to the Th2 phenotype. In response to IL-4, the IL-4R activates a set of phosphotyrosine binding domain-containing proteins, including insulin receptor substrate 1/2, Shc, and IL-4R interacting protein, as well as Stat6. Stat6 has been shown to be required for Th2 differentiation. To determine the roles of the phosphotyrosine binding adaptors in Th2 differentiation, we prepared a retrovirus containing a mutant of the human (h)IL-4R alpha-chain, Y497F, which is unable to recruit these adaptors. The mutant hIL-4Ralpha, as well as the wild-type (WT) hIL-4Ralpha, was introduced into naive CD4 T cells. Upon hIL-4 stimulation, Y497F worked as well as the WT hIL-4Ralpha in driving Th2 differentiation, as measured by Gata3 up-regulation and IL-4 production. Furthermore, IL-4-driven cell expansion was also normal in the cells infected with Y497F, although cells infected with Y497F were not capable of phosphorylating insulin receptor substrate 2. These results suggest that the signal pathway mediated by Y497 is dispensable for both IL-4-driven Th2 differentiation and cell expansion. Both WT and Y497F hIL-4Ralpha lose the ability to drive Th2 differentiation and cell expansion in Stat6-knockout CD4 T cells. A constitutively activated form of Stat6 introduced into CD4 T cells resulted in both Th2 differentiation and enhanced cell expansion. Thus, activated Stat6 is necessary and sufficient to mediate both IL-4-driven Th2 differentiation and cell expansion in CD4 T cells.