IL-10 Locus Research Articles

Calcitriol Impairs the Secretion of IL-4 and IL-13 in Th2 Cells via Modulating the VDR-Gata3-Gfi1 Axis.

Calcitriol, the bioactive form of vitamin D, exerts its biological functions by binding to its cognate receptor, the vitamin D receptor (VDR). The indicators of the severity of allergies and asthma have been linked to low vitamin D levels. However, the role of calcitriol in regulating IL-4 and IL-13, two cytokines pivotal to allergic inflammation, remained unclear. Our study observed diminished IL-4 and IL-13 secretion in murine and human Th2 cells treated with calcitriol. In murine Th2 cells, Gata3 expression was attenuated by calcitriol. However, the expression of the transcriptional repressor Gfi1, too, was attenuated in the presence of calcitriol. Ectopic expression of either Gfi1 or VDR impaired the secretion of IL-13 in Th2 cells. In murine Th2 cells, VDR interacted with Gata3 but not Gfi1. Gfi1 significantly impaired Il13 promoter activation, which calcitriol failed to restore. Conversely, calcitriol augmented Gfi1 recruitment to the Il13 promoter. Ecr, a conserved region between these two genes, which enhanced the transactivation of Il4 and Il13 promoters, is essential for calcitriol-mediated suppression of both the genes. Calcitriol augmented the recruitment of VDR to the Il13 promoter and Ecr regions. Gata3 recruitment was significantly impaired at the Il13 and Ecr loci in the presence of calcitriol but increased at the Il4 promoter. Furthermore, the recruitment of the histone deacetylase HDAC1 was universally increased at the promoters of Il4, Il13, and Ecr when calcitriol was present. Together, our data clearly elucidate that calcitriol modulates VDR, Gata3, and Gfi1 to suppress IL-4 and IL-13 production in Th2 cells.

TL1A priming induces a multi-cytokine Th9 cell phenotype that promotes robust allergic inflammation in murine models of asthma

The Th9 subset of T lymphocytes secretes the pleiotropic cytokine IL-9 which has functions in allergic airway disease, helminth infections, and tumor immunity. We and others have shown presence of Th cells that secrete IL-9 and type 2 cytokines in mouse and human allergic inflammation. However, the cytokines that promote a multi-cytokine secreting phenotype have not been defined. TNF superfamily members promote IL-9 production, and the TNF superfamily member TL1A signals through its receptor DR3 to potently increase IL-9. Here we demonstrate that TL1A increases expression of IL-9 and IL-13 as well as the frequency of IL-9 and IL-13 co-expressing cells in murine Th9 cell cultures, inducing a robust multi-cytokine phenotype. Mechanistically, this is linked to histone modifications allowing for increased accessibility at the Il9 and Il13 loci. We further show that TL1A alters the transcription factor network underlying expression of IL-9 and IL-13 in Th9 cells and increases binding of transcription factors to Il9 and Il13 loci. TL1A-priming enhances the pathogenicity of Th9 cells in murine models of allergic airway disease (AAD) through the increased expression of IL-9 and IL-13. Lastly, in both chronic and memory recall models of AAD, blockade of TL1A signaling decreases the multi-cytokine Th9 cell population and attenuates the allergic phenotype. Taken together, these data demonstrate that TL1A promotes the development of multi-cytokine Th9 cells that drive allergic airway diseases and that targeting pathogenic T helper cell-promoting cytokines could be an effective approach for modifying disease.

STAT6 tunes maximum T cell IL-4 production from stochastically regulated Il4 alleles.

T helper 2 (Th2) cells stochastically express from the Il4 locus but it has not been determined whether allelic expression is linked or independent. Here, we provide evidence that alleles are independently activated and inactivated. We compared Il4 locus expression in T cells from hemizygous IL-4 reporter mice in culture and in vivo following exposure to type 2 immunogens. In culture, Il4 alleles had independent, heritable expression probabilities. Modeling showed that in co-expressors, dual allele transcription occurs for only short periods, limiting per-cell mRNA variation in individual cells within a population of Th2 cells. In vivo profiles suggested that early in the immune response, IL-4 output was derived predominantly from single alleles, but co-expression became more frequent over time and were tuned by STAT6, supporting the probabilistic regulation of Il4 alleles in vivo among committed IL-4 producers. We suggest an imprinted probability of expression from individual alleles with a short transcriptional shutoff time controls the magnitude of T cell IL-4 output, but the amount produced per allele is amplified by STAT6 signaling. This form of regulation may be a relevant general mechanism governing cytokine expression.

Identification of a transcription factor network regulating anti-TNF mediated IL10 expression in human CD4+ T cells.

CD4+ T cells are key players in immune-mediated inflammatory diseases (IMIDs) through the production of inflammatory mediators including tumour necrosis factor (TNF). Anti-TNF therapy has revolutionized the treatment of several IMIDs and we previously demonstrated that in vitro treatment of human CD4+ T cells with anti-TNF promotes anti-inflammatory IL-10 expression in multiple subpopulations of CD4+ T cells. Here we investigated the transcriptional mechanisms underlying the IL-10 induction by TNF-blockade in CD4+ T cells, isolated from PBMCs of healthy volunteers, stimulated in vitro for 3 days with anti-CD3/CD28 mAb in the absence or presence of anti-TNF. After culture, CD45RA+ cells were depleted before performing gene expression profiling and chromatin accessibility analysis. Gene expression analysis of CD45RA-CD4+ T cells showed a distinct anti-TNF specific gene signature of 183 genes (q-value < 0.05). Pathway enrichment analysis of differentially expressed genes revealed multiple pathways related to cytokine signalling and regulation of cytokine production; in particular, IL10 was the most upregulated gene by anti-TNF, while the proinflammatory cytokines and chemokines IFNG, IL9, IL22, and CXCL10 were significantly downregulated (q-value < 0.05). Transcription factor motif analysis at the differentially open chromatin regions, after anti-TNF treatment, revealed 58 transcription factor motifs enriched at the IL10 locus. We identified seven transcription factor candidates for the anti-TNF mediated regulation of IL-10, which were either differentially expressed or whose locus was differentially accessible upon anti-TNF treatment. Correlation analysis between the expression of these transcription factors and IL10 suggests a role for MAF, PRDM1, and/or EOMES in regulating IL10 expression in CD4+ T cells upon anti-TNF treatment.

Variants of IL6, IL10, FCN2, RNASE3, IL12B and IL17B loci are associated with Schistosoma mansoni worm burden in the Albert Nile region of Uganda.

Individuals genetically susceptible to high schistosomiasis worm burden may contribute disproportionately to transmission and could be prioritized for control. Identifying genes involved may guide development of therapy. A cohort of 606 children aged 10-15 years were recruited in the Albert Nile region of Uganda and assessed for Schistosoma mansoni worm burden using the Up-Converting Particle Lateral Flow (UCP-LF) test detecting circulating anodic antigen (CAA), point-of-care Circulating Cathodic Antigen (POC-CCA) and Kato-Katz tests. Whole genome genotyping was conducted on 326 children comprising the top and bottom 25% of worm burden. Linear models were fitted to identify variants associated with worm burden in preselected candidate genes. Expression quantitative trait locus (eQTL) analysis was conducted for candidate genes with UCP-LF worm burden included as a covariate. Single Nucleotide Polymorphism loci associated with UCP-LF CAA included IL6 rs2066992 (OR = 0.43, p = 0.0006) and rs7793163 (OR = 2.0, p = 0.0007); IL21 SNP kgp513476 (OR 1.79, p = 0.0025) and IL17B SNP kgp708159 (OR = 0.35, p = 0.0028). A haplotype in the IL10 locus was associated with lower worm burden (OR = 0.53, p = 0.015) and overlapped SNPs rs1800896, rs1800871 and rs1800872. Significant haplotypes (p<0.05, overlapping significant SNP) associated with worm burden were observed in IL6 and the Th17 pathway IL12B and IL17B genes. There were significant eQTL in the IL6, IL5, IL21, IL25 and IFNG regions. Variants associated with S. mansoni worm burden were in IL6, FCN2, RNASE3, IL10, IL12B and IL17B gene loci. However only eQTL associations remained significant after Bonferroni correction. In summary, immune balance, pathogen recognition and Th17 pathways may play a role in modulating Schistosoma worm burden. Individuals carrying risk variants may be targeted first in allocation of control efforts to reduce the burden of schistosomiasis in the community.

17-β Estradiol (E2) distinctly regulates the expression of IL-4 and IL-13 in Th2 cells via modulating the interplay between GATA3 and PU.1

17-β Estradiol (E2) has long standing known functions in regulating human physiology as well as immune system. E2 is known to elicit a protective role against experimental autoimmune encephalomyelitis (EAE) and has been used as a drug for treatment against multiple sclerosis. Moreover, E2 regulates the adaptive immune system by directly affecting the T helper cell subsets differentiation and antibody secretion mediated by B cells. Reports have shown that E2 promotes Th1 and Treg cell differentiation; whereas it attenuated the Th17 and Tfh cell differentiation. Albeit multiple and contrasting studies, the mechanisms of behind E2 action on Th2 cells remained understudied. Hence, we sought to dissect the impact of E2 in Th2 cell differentiation. In this study, we elucidated the molecular mechanisms behind E2-mediated regulation of the differentiation of Th2 cells. We observed that E2 significantly attenuated the IL-4-secreting Th2 population in an ERα-dependent manner. We validated these findings using ICI 182, 780, an antagonist to ERα, not ERβ and ectopically overexpressing ERα in Th2 cells. We further determined that ERα alters the recruitment of GATA3 and PU.1 to Il4 gene by directly interacting with them. This altered recruitment was observed to be stronger at Il4 than Il13 locus. Interestingly, we detected a distinct recruitment of GATA3 and PU.1 at Il13 gene; however, there was no E2-mediated broad alteration in the recruitment of histone-modifiers at Il13 locus. These findings suggest that E2 regulates Il4 in a distinctly separate mechanism as opposed to Il13 locus in Th2 cells.

Association between polymorphisms of anti-inflammatory gene alleles and periodontitis risk in a Chinese Han population.

Cytokines that mediate the immune responses are important in the pathogenesis of periodontitis. The genetic polymorphisms of IL-10, TNFAIP3 (A20), and NF-κB1 (p105/p50) and their association with the risk of periodontitis were investigated. Venous blood from 102 clinical periodontal healthy participants and 100 patients with periodontitis was collected to genotype the IL-10 (rs1800872), A20 (rs2230926, rs5029937, rs6927127), and NF-κB1 (rs28362491) SNP loci by Sanger technology. Univariable and multivariable logic regression and path analysis model was used to analyze the genotypes and alleles. Single-gene mutations in the A20 (rs2230926, rs5029937, rs6927127) and IL-10 (rs1800872) genes were not associated with the risk of periodontitis. NF-κΒ1 (rs28362491) gene influenced periodontitis susceptibility by affecting CAL. The combined effect of A20 and IL-10 was related to the risk of periodontitis (ORa = 0.123-0.151). One site mutated in the A20 (rs2230926, rs5029937, rs6927127) gene or IL-10 (rs1800872) gene reduced the risk of periodontitis. Single gene polymorphisms in A20 and IL-10 genes were not associated with the risk of periodontitis. NF-κB1 gene polymorphism indirectly affects susceptibility to periodontitis. The combined effect of anti-inflammatory gene polymorphisms (A20 and IL-10) correlated with the decreased risk of periodontitis. This study helps to explore the potential mechanisms underlying the role of anti-inflammatory genes in the progression of periodontal disease and provides a basis for the selection and development of appropriate periodontal treatment strategies based on the genetic profile of the patient.

T cell intrinsic STAT1 signaling prevents aberrant Th1 responses during acute toxoplasmosis.

Infection-induced T cell responses must be properly tempered and terminated to prevent immuno-pathology. Using transgenic mice, we demonstrate that T cell intrinsic STAT1 signaling is required to curb inflammation during acute infection with Toxoplasma gondii. Specifically, we report that mice lacking STAT1 selectively in T cells expel parasites but ultimately succumb to lethal immuno-pathology characterized by aberrant Th1-type responses with reduced IL-10 and increased IL-13 production. We also find that, unlike STAT1, STAT3 is not required for induction of IL-10 or suppression of IL-13 during acute toxoplasmosis. Each of these findings was confirmed in vitro and ChIP-seq data mining showed that STAT1 and STAT3 co-localize at the Il10 locus, as well as loci encoding other transcription factors that regulate IL-10 production, most notably Maf and Irf4. These data advance basic understanding of how infection-induced T cell responses are managed to prevent immuno-pathology and provide specific insights on the anti-inflammatory properties of STAT1, highlighting its role in shaping the character of Th1-type responses.

IL-1β promotes IL-9-producing Th cell differentiation in IL-2-limiting conditions through the inhibition of BCL6.

IL-9-producing CD4+ T helper cells, termed Th9 cells, differentiate from naïve precursor cells in response to a combination of cytokine and cell surface receptor signals that are elevated in inflamed tissues. After differentiation, Th9 cells accumulate in these tissues where they exacerbate allergic and intestinal disease or enhance anti-parasite and anti-tumor immunity. Previous work indicates that the differentiation of Th9 cells requires the inflammatory cytokines IL-4 and TGF-β and is also dependent of the T cell growth factor IL-2. While the roles of IL-4 and TGF-β-mediated signaling are relatively well understood, how IL-2 signaling contributes to Th9 cell differentiation outside of directly inducing the Il9 locus remains less clear. We show here that murine Th9 cells that differentiate in IL-2-limiting conditions exhibit reduced IL-9 production, diminished NF-kB activation and a reduced NF-kB-associated transcriptional signature, suggesting that IL-2 signaling is required for optimal NF-kB activation in Th9 cells. Interestingly, both IL-9 production and the NF-kB transcriptional signature could be rescued by addition of the NF-kB-activating cytokine IL-1β to IL-2-limiting cultures. IL-1β was unique among NF-kB-activating factors in its ability to rescue Th9 differentiation as IL-2 deprived Th9 cells selectively induced IL-1R expression and IL-1β/IL-1R1 signaling enhanced the sensitivity of Th9 cells to limiting amounts of IL-2 by suppressing expression of the Th9 inhibitory factor BCL6. These data shed new light on the intertwined nature of IL-2 and NF-kB signaling pathways in differentiating Th cells and elucidate the potential mechanisms that promote Th9 inflammatory function in IL-2-limiting conditions.

Gene-gene and gene-environment interactions of the inflammatory gene variants in the development of chronic obstructive pulmonary disease

Chronic obstructive pulmonary disease (COPD) is a complex chronic inflammatory disease that is characterized by partly reversible airflow limitation, chronic inflammation, fibrosis of small airways, and destruction of lung parenchyma. We aimed to assess the association of the inflammatory gene loci singly and in combinations with COPD in smokers and non-smokers in ethnic Tatar from Russia to evaluate the gene-gene and gene-environment interactions in COPD development. Eleven loci of inflammatory genes, including IL19, IL20, IL24, PPBP, IL4, IL4RA, С5, FAS, FASLG, and TGFb1, were genotyped in 484 smoking COPD patients, 517 healthy smokers, 117 non-smoking COPD patients, and 100 healthy non-smokers. Significant associations with COPD in smokers were identified for IL19 (rs2243193), IL4 (rs2243250), IL4 (rs2070874), and PPBP (rs352010). In non-smokers, associations were established for IL24 (rs291107), IL4 (rs2070874), and PPBP (rs352010). Associations of inflammatory genes loci IL19 (rs2243193), IL4 (rs2070874), TGFb1 (rs1800469), PPBP (rs352010), and FASLG (rs763110) and smoking index were determined. Associations of FAS (rs1800682), FASLG (rs763110), IL4 (rs2243250), IL4RA (rs1805010), and PPBP (rs352010) loci with pulmonary function variables were observed. The results of gene-gene interactions analysis showed distinctive patterns of association of inflammatory gene loci with COPD in groups stratified by smoking status. The combination of A allele of IL19 (rs2243193), C allele of IL4 (rs2243250), and T allele of PPBP (rs352010) was the main component of the majority of protective gene-gene combination associated with COPD in smokers. The highest risk of COPD was conferred by TT genotype of PPBP (rs352010) in combination with A allele of FAS (rs1800682). While in non-smokers, the most commonly featured was IL24 (rs291107) C allele in protective patterns and IL24 (rs291107) T allele in predisposing combinations. The highest risk of COPD in non-smokers was detected in a gene-gene combination consisting of A allele of IL12RB2 (rs3762317) together with G allele of IL12A (rs2243115), C allele of IL4 (rs2070874), and A allele of IL4RA (rs1805010).

Role of CNSs Conserved Distal Cis-Regulatory Elements in CD4 + T Cell Development and Differentiation.

Naïve CD4+ T cells differentiate into diverse subsets of effector cells and perform various homeostatic and immune functions. The differentiation and maintenance of these different subsets are controlled through the upregulation and silencing of master genes. Mechanistic studies of the regulation of these master genes identified conserved and distal intronic regulatory elements, which are accessible subsets of conserved non-coding sequences (CNSs), acting as cis-regulatory elements in a lineage-specific manner that controls the function of CD4+ T cells. Abnormal CNS activity is associated with incorrect expression of master genes and development of autoimmune diseases or immune suppression. Here, we describe the function of several conserved, distal cis-regulatory elements at the Foxp3, Rorc, Il-4, Il-10 and Il-17 gene locus were shown to play important roles in CD4+ T cells differentiation. Together, this review briefly outlines currently known CNSs, with a focus on their regulations and functions in complexes modulating the differentiation and maintenance of various CD4+ T cells subsets, in health and disease contexts, as well as during the conversion of T regulatory cells to T helper 17 cells. This article will provide a comprehensive view of CNSs conserved distal cis-regulatory elements at a few loci that control aspects of CD4+ T cells function.

TL1A promotes a multi-cytokine Th9 cell phenotype

Abstract The TNF superfamily member TL1A is a costimulatory molecule that signals through its receptor DR3 on T lymphocytes. The Th9 subset of T lymphocytes secretes the pleiotropic cytokine IL-9 which has functions in allergic airway disease, helminth infections, and tumor immunity. TL1A signaling has been shown to increase IL-9 production by Th9 cells. However, its role in regulating other functions of Th9 cells is unknown. Here we demonstrate that TL1A increases expression of IL-9 and IL-13 as well as the frequency of IL-9 and IL-13 co-expressing cells in Th9 cell cultures through flow cytometric analyses. We also show that the Il9 and Il13 promoter and enhancer regions are differentially accessible in response to TL1A over a five-day culture period through chromatin accessibility assays. At the Il9 locus, TL1A enhances binding of IRF4, BATF, and PPARg. Mechanistically, this is linked to decreased H3K9 tri-methylation and increased H3K4 tri-methylation at Il9 enhancer region CNS2. At the Il13 locus, TL1A enhances binding of BATF at the Il13 promoter alongside decreased H3K9 tri-methylation and increased H3K4 tri-methylation. Ongoing experiments define the function of TL1A-induced multi-cytokine producing cells. Together, these data indicate that TL1A contributes to heterogeneity of IL-9-secreting T cell populations. Supported by NIH Combined Adult and Pediatrics Pulmonary Research Training Program T32

The role of cytokine gene single nucleotide polymorphism in the development of recurrent acute otitis media

The study aimed at examining the role of single nucleotide polymorphism (SNP) of cytokine genes in the development of recurrent acute otitis media (AOM) among children. Single nucleotide polymorphism of IFN-, IL-6, IL-10, TNF-α, and TGF-β1, were analyzed by the polymerase chain reaction with sequence-specific primers (PCR-SSP) in 82 children with recurrent AOM and compared with a similar control group. There was a significant higher incidence of IL-10 polymorphisms (loci -592, -819 and -1082) in children with recurrent AOM (P=0.0137, 0.0137 and 0.0072, respectively). However, there was no significant difference in the distribution of other cytokine genotypes between the two study groups. Among the 5 studied cytokine genes, only IL-10 loci showed significant correlation to the development of recurrent AOM.

PRDM1 Is Sufficient for Inducing Human Primary T Cell Hyporesponsiveness and Implicates Low Gvhd Occurrence after Allo-HSCT

T cell hyporesponsiveness is crucial for functional immune system and prevent the damage induced by alloreactive T cells in autoimmune pathology and transplantation. As one of the most important regulators during B cell development, PRDM1 (also known as BLIMP-1) has been demonstrated its essential role for maintaining T cell hyporesponsiveness and homeostasis, evidenced by Prdm1 deficient mice accumulating activated T cells and developing multiorgan inflammatory disease. However, the mechanism of PRDM1 regulating T cell hyporesponsiveness is still ambiguous.In this study, we took advantage of multiomics technologies and systemic report the central role of PRDM1 in inducing human primary T cell hyporesponsiveness. Firstly, we overexpressed PRDM1 in human primary T cells and found increased ratio of CD4 +CD25 +FOXP3 + Treg cell subsets and increased IL-4 secretion. In parallel, inhibited PRDM1 expression level in human T cells decreased ratio of Treg cells and secretion of IL-4. Meanwhile, transcriptome analyses revealed that overexpressed PRDM1 enriched negative regulation of cell proliferation signaling pathway and resulted in a global reduction in IL-2 and inflammatory response signaling pathways. Furthermore, overexpressed PRDM1 in primary T cells upregulated several negative regulators of T cell function like EOMES, KLF2, LILRB1, KLRB1 and CD244, indicating a pioneer role of PRDM1 in inducing T cell hyporesponsive. To further investigate the regulation role of T cell hyporesponsiveness of PRDM1, we performed CUT&Tag and ATAC-seq in PRDM1 overexpressed primary T cells. CUT&Tag analysis showed PRDM1 could directly upregulated T cell hyporesponsiveness related gene such as KLF2, CD244 and KLRD1. Importantly, we observed consistent changes of IL-2, central regulator of T cell activation, in PRDM1 overexpressed T cell from ATAC-seq, CUT&Tag and RNA-seq data. We found PRDM1 could binding to IL-2 locus and decreased the chromatin accessibility of IL-2, consequently downregulated the expression level of IL-2 in human primary T cells. Moreover, altered open chromatin regions (OCRs) in PRDM1 overexpressed T cells enriched the similar transcription factors (TFs) with PRDM1 binding sites, indicating PRDM1 might be a pioneer TF in T cell hyporesponsiveness. These results demonstrated PRDM1 is sufficient for inducing T cell hyporesponsiveness in human primary T cells.To further validate the coexpression relationship between PRDM1 and Treg cell central TF FOXP3, we upregulated PRDM1 expression level on Jurkat T cells lines. The results also showed that elevated FOXP3 both in mRNA and protein level accompanied with upregulated PRDM1 expression level. To analyze the mechanism of PRDM1 regulating FOXP3 expression level, CUT&Tag data analyses showed that PRDM1 might upregulated FOXP3 by directly binding to the enhancer region of upstream of FOXP3 locus. Meanwhile, PRDM1 indirectly upregulated FOXP3 by upregulated KLF2, evidenced by inhibiting KLF2 in PRDM1 overexpressed primary T cells downregulated FOXP3 expression level. To further investigate the clinical implication of PRDM1 inducing T cell hyporesponsiveness, we detected the relationship of PRDM1 expression level and acute graft-versus-host disease(aGVHD) occurrence after allogeneic hematopoietic stem cell transplantation (allo-HSCT). Our results showed that patients with aGVHD (n=7) exhibited lower PRDM1 expression level than those without aGVHD in the same period after HSCT (n=7). Furthermore, we detected the expression level of PRDM1 in CD4 + T cell and CD8 + T cells from bone marrow allografts (BM) or peripheral blood allografts (PB) and followed up the occurrence of GVHD after HSCT for 2 years (n=18). There are low expression levels of PRDM1 in CD4 + T cells both from BM or PB grafts corelated with aGVHD occurrence in patients after allo-HSCT compared with those without aGVHD occurrence. In conclusion, our study provides the global regulatory model of PRDM1 in human primary T cell. We introduced PRDM1 as a sufficient regulator in T cell hyporesponsiveness induction, which is altering the chromatin accessibility and directly upregulated T cell inhibitory signals and downregulated T cell activated signals. The negative relationship between PRDM1 expression level with GVHD occurrence indicated it might be a potential biomarker for indicating HSCT prognosis. DisclosuresNo relevant conflicts of interest to declare.

STAT5 Represses a STAT3-Independent Th17-like Program during Th9 Cell Differentiation.

IL-9-producing Th cells, termed Th9 cells, contribute to immunity against parasites and cancers but have detrimental roles in allergic disease and colitis. Th9 cells differentiate in response to IL-4 and TGF-β, but these signals are insufficient to drive Th9 differentiation in the absence of IL-2. IL-2-induced STAT5 activation is required for chromatin accessibility within Il9 enhancer and promoter regions and directly transactivates the Il9 locus. STAT5 also suppresses gene expression during Th9 cell development, but these roles are less well defined. In this study, we demonstrate that human allergy-associated Th9 cells exhibited a signature of STAT5-mediated gene repression that is associated with the silencing of a Th17-like transcriptional signature. In murine Th9 cell differentiation, blockade of IL-2/STAT5 signaling induced the expression of IL-17 and the Th17-associated transcription factor Rorγt. However, IL-2-deprived Th9 cells did not exhibit a significant Th17- or STAT3-associated transcriptional signature. Consistent with these observations, differentiation of IL-17-producing cells under these conditions was STAT3-independent but did require Rorγt and BATF. Furthermore, ectopic expression of Rorγt and BATF partially rescued IL-17 production in STAT3-deficient Th17 cells, highlighting the importance of these factors in this process. Although STAT3 was not required for the differentiation of IL-17-producing cells under IL-2-deprived Th9 conditions, their prolonged survival was STAT3-dependent, potentially explaining why STAT3-independent IL-17 production is not commonly observed in vivo. Together, our data suggest that IL-2/STAT5 signaling plays an important role in controlling the balance of a Th9 versus a Th17-like differentiation program in vitro and in allergic disease.

Roles of TET and TDG in DNA demethylation in proliferating and non-proliferating immune cells

BackgroundTET enzymes mediate DNA demethylation by oxidizing 5-methylcytosine (5mC) in DNA to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC), and 5-carboxylcytosine (5caC). Since these oxidized methylcytosines (oxi-mCs) are not recognized by the maintenance methyltransferase DNMT1, DNA demethylation can occur through “passive,” replication-dependent dilution when cells divide. A distinct, replication-independent (“active”) mechanism of DNA demethylation involves excision of 5fC and 5caC by the DNA repair enzyme thymine DNA glycosylase (TDG), followed by base excision repair.ResultsHere by analyzing inducible gene-disrupted mice, we show that DNA demethylation during primary T cell differentiation occurs mainly through passive replication-dependent dilution of all three oxi-mCs, with only a negligible contribution from TDG. In addition, by pyridine borane sequencing (PB-seq), a simple recently developed method that directly maps 5fC/5caC at single-base resolution, we detect the accumulation of 5fC/5caC in TDG-deleted T cells. We also quantify the occurrence of concordant demethylation within and near enhancer regions in the Il4 locus. In an independent system that does not involve cell division, macrophages treated with liposaccharide accumulate 5hmC at enhancers and show altered gene expression without DNA demethylation; loss of TET enzymes disrupts gene expression, but loss of TDG has no effect. We also observe that mice with long-term (1 year) deletion of Tdg are healthy and show normal survival and hematopoiesis.ConclusionsWe have quantified the relative contributions of TET and TDG to cell differentiation and DNA demethylation at representative loci in proliferating T cells. We find that TET enzymes regulate T cell differentiation and DNA demethylation primarily through passive dilution of oxi-mCs. In contrast, while we observe a low level of active, replication-independent DNA demethylation mediated by TDG, this process does not appear to be essential for immune cell activation or differentiation.

STAT5 promotes accessibility and is required for BATF-mediated plasticity at the Il9 locus

T helper cell differentiation requires lineage-defining transcription factors and factors that have shared expression among multiple subsets. BATF is required for development of multiple Th subsets but functions in a lineage-specific manner. BATF is required for IL-9 production in Th9 cells but in contrast to its function as a pioneer factor in Th17 cells, BATF is neither sufficient nor required for accessibility at the Il9 locus. Here we show that STAT5 is the earliest factor binding and remodeling the Il9 locus to allow BATF binding in both mouse and human Th9 cultures. The ability of STAT5 to mediate accessibility for BATF is observed in other Th lineages and allows acquisition of the IL-9-secreting phenotype. STAT5 and BATF convert Th17 cells into cells that mediate IL-9-dependent effects in allergic airway inflammation and anti-tumor immunity. Thus, BATF requires the STAT5 signal to mediate plasticity at the Il9 locus.

IL-17+ CD8+ T cell suppression by dimethyl fumarate associates with clinical response in multiple sclerosis

IL-17-producing CD8+ (Tc17) cells are enriched in active lesions of patients with multiple sclerosis (MS), suggesting a role in the pathogenesis of autoimmunity. Here we show that amelioration of MS by dimethyl fumarate (DMF), a mechanistically elusive drug, associates with suppression of Tc17 cells. DMF treatment results in reduced frequency of Tc17, contrary to Th17 cells, and in a decreased ratio of the regulators RORC-to-TBX21, along with a shift towards cytotoxic T lymphocyte gene expression signature in CD8+ T cells from MS patients. Mechanistically, DMF potentiates the PI3K-AKT-FOXO1-T-BET pathway, thereby limiting IL-17 and RORγt expression as well as STAT5-signaling in a glutathione-dependent manner. This results in chromatin remodeling at the Il17 locus. Consequently, T-BET-deficiency in mice or inhibition of PI3K-AKT, STAT5 or reactive oxygen species prevents DMF-mediated Tc17 suppression. Overall, our data disclose a DMF-AKT-T-BET driven immune modulation and suggest putative therapy targets in MS and beyond.

Treg expression of CIS suppresses allergic airway inflammation through antagonizing an autonomous TH2 program.

Maintenance of regulatory T (Treg) cells is crucial for the regulatory function of Treg cells in immune homeostasis and self-tolerance; however, the detailed underlying mechanisms remain elusive. In the current study, we found that the cytokine suppressor CIS is required for maintenance of Treg cell identity. Mice with Treg specific Cis-deficiency displayed aggravated experimental allergic asthma and in adulthood, developed splenomegaly, lymphadenopathy and spontaneous eosinophilic airway inflammation, accompanied by accumulation of effector memory helper T (TH) cells. Cis-deficiency led to loss of Foxp3 expression and decrease in suppressive function of Treg cells. Cis-deficient Treg cells expressed TH2 cell signature genes, Gata3, Irf4 and Il4, and excessive IL-4-STAT6 signals resulted in repressive chromatin modification in the Foxp3 locus and permissive modification in the Il4 loci. In vitro, blockade of IL-4 restored the expression of Foxp3 and the suppressive function of iTreg cells. Thus, we identified a novel feedback loop in stabilization of Treg cells and suppression of TH2 type inflammation in a Treg-intrinsic manner.

BATF3 is sufficient for the induction of Il9 expression and can compensate for BATF during Th9 cell differentiation

Th9 cells preferentially produce IL-9 and participate in allergic responses and asthma. Differentiation of Th9 cells is induced by IL-4 and TGF-β, and then the cells are amplified by OX40 signals. The transcription factors PU.1, IRF4, and BATF are required for Th9 differentiation. BATF3 is an AP-1 family transcription factor that is highly homologous to BATF; however, its role in Th9 cells is poorly defined. Here, we show that OX40 signaling induced the expression of Batf3 and that its overexpression in the presence or absence of OX40 signaling increased the expression of IL-9 in Th9 cells. BATF3 physically interacted with IRF4 and was bound to the Il9 locus. A transient reporter assay revealed that the BATF3–IRF4 complex induced Il9 promoter activity. BATF3 rescued Il9 expression and restored the capacity to induce the airway inflammation in Batf KO Th9 cells. Thus, BATF3 itself is sufficient for the induction of Th9 cell differentiation and can substitute for BATF during Th9 cell differentiation.