The human IL-13 locus in neonatal CD4+ T cells is refractory to the acquisition of a repressive chromatin architecture

The Th2 cytokine IL-13 is a major effector molecule in human allergic inflammation. Notably, IL-13 expression at birth correlates with subsequent susceptibility to atopic disease. In order to characterize the chromatin-based mechanisms that regulate IL-13 expression in human neonatal CD4(+) T cells, we analyzed patterns of DNase I hypersensitivity and epigenetic modifications within the IL-13 locus in cord blood CD4(+) T cells, naive or differentiated in vitro under Th1- or Th2-polarizing conditions. In naive CD4(+) T cells, hypersensitivity associated with DNA hypomethylation was limited to the distal promoter. Unexpectedly, during both Th1 and Th2 differentiation, the locus was extensively remodeled, as revealed by the formation of numerous HS sites and decreased DNA methylation. Obvious differences in chromatin architecture were limited to the proximal promoter, where strong hypersensitivity, hypomethylation, and permissive histone modifications were found selectively in Th2 cells. In addition to revealing the locations of putative cis-regulatory elements that may be required to control IL-13 expression in neonatal CD4(+) T cells, our results suggest that differential IL-13 expression may depend on the acquisition of a permissive chromatin architecture at the proximal promoter in Th2 cells rather than the formation of locus-wide repressive chromatin in Th1 cells.     

CpG methylation of the IFNG gene as a mechanism to induce immunosuppression [correction of immunosupression] in tumor-infiltrating lymphocytes

The execution of appropriate gene expression patterns during immune responses is of eminent importance where CpG methylation has emerged as an essential mechanism for gene silencing. We have charted the methylation status of regulatory elements in the human IFNG gene encoding the signature cytokine of the Th1 response. Surprisingly, human naive CD4(+) T lymphocytes displayed hypermethylation at the IFNG promoter region, which is in sharp contrast to the completely demethylated status of this region in mice. Th1 differentiation induced demethylation of the IFNG promoter and the upstream conserved nucleotide sequence 1 enhancer region, whereas Th2-differentiated lymphocytes remained hypermethylated. Furthermore, CD19(+) B lymphocytes displayed hypomethylation at the IFNG promoter region with a similar pattern to Th1 effector cells. When investigating the methylation status among tumor-infiltrating CD4(+) T lymphocytes from patients with colon cancer, we found that tumor-infiltrating lymphocytes cells are inappropriately hypermethylated, and thus not confined to the Th1 lineage. In contrast, CD4(+) T cells from the tumor draining lymph node were significantly more demethylated than tumor-infiltrating lymphocytes. We conclude that there are obvious interspecies differences in the methylation status of the IFNG gene in naive CD4(+) T lymphocytes, where Th1 commitment in human lymphocytes involves demethylation before IFNG expression. Finally, investigations of tumor-infiltrating lymphocytes and CD4(+) cells from tumor draining lymph node demonstrate methylation of regulatory regions within key effector genes as an epigenetic mechanism of tumor-induced immunosuppression.     

Regulation of IL-17 in human CCR6+ effector memory T cells

IL-17-secreting T cells represent a distinct CD4(+) effector T cell lineage (Th17) that appears to be essential in the pathogenesis of numerous inflammatory and autoimmune diseases. Although extensively studied in the murine system, human Th17 cells have not been well characterized. In this study, we identify CD4(+)CD45RO(+)CCR7(-)CCR6(+) effector memory T cells as the principal IL-17-secreting T cells. Human Th17 cells have a unique cytokine profile because the majority coexpress TNF-alpha but not IL-6 and a minor subset express IL-17 with IL-22 or IL-17 and IFN-gamma. We demonstrate that the cytokines that promote the differentiation of human naive T cells into IL-17-secreting cells regulate IL-17 production by memory T cells. IL-1beta alone or in association with IL-23 and IL-6 markedly increase IL-17(+) CCR6(+) memory T cells and induce IL-17 production in CCR6(-) memory T cells. We also show that T cell activation induces Foxp3 expression in T cells and that the balance between the percentage of Foxp3(+) and IL-17(+) T cells is inversely influenced by the cytokine environment. These studies suggest that the cytokine environment may play a critical role in the expansion of memory T cells in chronic autoimmune diseases.     

Either IL-2 or IL-12 is sufficient to direct Th1 differentiation by nonobese diabetic T cells

Th cell differentiation from naive precursors is a tightly controlled process; the most critical differentiation factor is the action of the driving cytokine: IL-12 for Th1 development, IL-4 for Th2 development. We found that CD4(+) T cells from nonobese diabetic mice spontaneously differentiate into IFN-gamma-producing Th1 cells in response to polyclonal TCR stimulation in the absence of IL-12 and IFN-gamma. Instead, IL-2 was necessary and sufficient to direct T cell differentiation to the Th1 lineage by nonobese diabetic CD4(+) T cells. Its ability to direct Th1 differentiation of both naive and memory CD4(+) T cells was clearly uncoupled from its ability to stimulate cell division. Autocrine IL-2-driven Th1 differentiation of nonobese diabetic T cells may represent a genetic liability that favors development of IFN-gamma-producing autoreactive T cells.     

Germinal centers regulate human Th2 development

In the present study we demonstrate that all CD4(+) T cells in human tonsil expressing the Th2-selective receptor chemoattractant receptor-homologous molecule expressed on Th2 cells (CRTH2) also 1) express high levels of CXCR5, and 2) display a transitional CD45RA/RO phenotype and consistently do not produce significant amounts of cytokines when immediately analyzed ex vivo. Hence, they represent precursors of Th2 effector cells, a conclusion confirmed by their robust production of IL-4, IL-5, and IL-13, but not IFN-gamma, after in vitro activation. CD4(+) T cells, which express only intermediate levels of CXCR5, instead develop into IFN-gamma-producing cells under identical culture conditions, thus establishing a correlation between relative levels of CXCR5 expression and the acquired cytokine profile. Because CXCR5 is critically involved in follicular localization, the results suggest that these CRTH2(+) Th2 cells preferentially develop their cytokine-producing phenotype within germinal centers (GCs), whereas extrafollicular differentiation instead promotes Th1 development. In support for this proposal, we show that T cells with an intermediate expression of CXCR5 can be forced to also produce IL-4 and IL-13 if cultured with allogenic GC B cells. Finally, we demonstrate that the previously described CD57(+) GC T cells also express high levels of CXCR5 but instead of comprising a Th2 precursor, they represent anergized T cells. Taken together, these data suggest that GCs and B cells regulate CD4(+) T cell differentiation in a finely tuned fashion, either by promoting differentiation of Th2 cells, which apparently leave the lymphoid tissue before evolving a cytokine-producing phenotype, or by furnishing T cell unresponsiveness.     

Essential role of GATA3 for the maintenance of type 2 helper T (Th2) cytokine production and chromatin remodeling at the Th2 cytokine gene loci

GATA3 expression is essential for type-2 helper T (Th2) cell differentiation. GATA3-mediated chromatin remodeling at the Th2 cytokine gene loci, including Th2-specific long range histone hyperacetylation of the interleukin (IL)-13/IL-4 gene loci, occurs in developing Th2 cells. However, little is known about the role of GATA3, if any, in the maintenance of established remodeled chromatin at the Th2 cytokine gene loci. Here, we established a Cre/LoxP-based site-specific recombination system in cultured CD4 T cells using a unique adenovirus-mediated gene transfer technique. This system allowed us to investigate the effect of loss of GATA3 expression in in vitro differentiated Th2 cells. After ablation of GATA3, we detected reduced production of all Th2 cytokines, increased DNA methylation at the IL-4 gene locus, and decreased histone hyperacetylation at the IL-5 gene locus but not significantly so at the IL-13/IL-4 gene loci. Thus, GATA3 plays important roles in the maintenance of the Th2 phenotype and continuous chromatin remodeling of the specific Th2 cytokine gene locus through cell division.     

Chronic morphine treatment promotes specific Th2 cytokine production by murine T cells in vitro via a Fas/Fas ligand-dependent mechanism

Improper homeostasis of Th1 and Th2 cell differentiation can promote pathological immune responses such as autoimmunity and asthma. A number of factors govern the development of these cells including TCR ligation, costimulation, death effector expression, and activation-induced cell death (AICD). Although chronic morphine administration has been shown to selectively promote Th2 development in unpurified T cell populations, the direct effects of chronic morphine on Th cell skewing and cytokine production by CD4(+) T cells have not been elucidated. We previously showed that morphine enhances Fas death receptor expression in a T cell hybridoma and human PBL. In addition, we have demonstrated a role for Fas, Fas ligand (FasL), and TRAIL in promoting Th2 development via killing of Th1 cells. Therefore, we analyzed whether the ability of morphine to affect Th2 cytokine production was mediated by regulation of Fas, FasL, and TRAIL expression and AICD directly in purified Th cells. We found that morphine significantly promoted IL-4 and IL-13 production but did not alter IL-5 or IFN-gamma. Furthermore, morphine enhanced the mRNA expression of Fas, FasL and TRAIL and promoted Fas-mediated AICD of CD4(+) T cells. Additionally, blockade of Fas/FasL interaction by anti-FasL inhibited the morphine-induced production of IL-4 and IL-13 and AICD of CD4(+) T cells. These results suggest that morphine preferentially enhances Th2 cell differentiation via killing of Th1 cells in a Fas/FasL-dependent manner.