Project description:ICOS is a T cell costimulatory receptor critical for Tfh cell generation and function. However, the role of ICOS in Tfr cell differentiation remains unclear. Using Foxp3-Cre-mediated ICOS knockout (ICOS FC) mice, we show that ICOS deficiency in Treg-lineage cells drastically reduces the number of Tfr cells during GC reactions but has a minimal impact on conventional Treg cells. Single-cell transcriptome analysis of Foxp3+ cells at an early stage of the GC reaction suggests that ICOS normally inhibits Klf2 expression to promote follicular features including Bcl6 upregulation. Further, ICOS costimulation promotes nuclear localization of NFAT2, a known driver of CXCR5 expression. Notably, ICOS FC mice had an unaltered overall GC B cell output but showed signs of expanded autoreactive B cells along with elevated autoantibody titers. Thus, our study demonstrates that ICOS costimulation is critical for Tfr cell differentiation and highlights the importance of Tfr cells in maintaining humoral immune tolerance during GC reactions.

Project description:CD4+Foxp3+ Treg cells are essential for maintaining self-tolerance and preventing excessive immune responses. In the context of Th1 immune responses, co-expression of the Th1 transcription factor T-bet with Foxp3 is essential for Treg cells to control Th1 responses. T-bet-dependent expression of CXCR3 directs Tregs to the site of inflammation, however, the suppressive mediators enabling effective control of Th1 responses at this site are unknown. In this study, we determined the signature of CXCR3+ Treg cells arising in Th1 settings and defined universal features of Treg cells in this context using multiple Th1-dominated models. Our analysis defined a set of Th1-specific co-inhibitory receptors that are specifically expressed in Treg cells during Th1 immune responses. Among these, we identified the novel co-inhibitory receptor CD85k as a functional mediator of the enhanced suppression of Th1 effector cells by CXCR3+ Treg cells.

Project description:Here, we report on experiments in double-transgenic mice, in which RFP is expressed in all Foxp3+ Treg cells, whereas Foxp3-dependent GFP expression is exclusively confined to intrathymically induced Foxp3+ Treg cells. This novel molecular genetic tool enabled us to faithfully track and characterize naturally induced Treg cells of intrathymic (RFP+GFP+) and extrathymic (RFP+GFPM-bM-^HM-^R) origin in otherwise unmanipulated mice. These experiments directly demonstrate that extrathymically induced Treg cells substantially contribute to the overall pool of mature Foxp3+ Treg cells residing in peripheral lymphoid tissues of steady-state mice. Furthermore, we provide evidence that intra- and extrathymically induced Foxp3+ Treg cells represent distinct phenotypic and functional sublineages. CD4+CD25+ RFP+GFP- and CD4+CD25+ RFP+GFP+ T cells from pooled lymph nodes and pooled spleens of 20 mice were FACS sorted for RNA extraction and hybridization on Affymetrix microarrays in duplicates.

Project description:The interplay between effector and regulatory T (Treg) cells is crucial for adaptive immunity, but how Treg control effector cell flexibility is elusive. We found that the phosphatase PTEN links Treg stability to the repression of TH1 and TFH (follicular helper) responses. Depletion of PTEN in Treg resulted in excessive TFH and germinal center responses and spontaneous inflammatory disease. These defects are considerably blocked by deletion of Interferon-γ, indicating coordinated control of TH1 and TFH responses. Mechanistically, PTEN maintains Treg stability and proper metabolic balance between glycolysis and mitochondrial fitness. Moreover, PTEN deficiency markedly upregulates mTORC2-Akt activity, and loss of this activity restores PTEN-deficient Treg function. Our studies establish a PTEN-mTORC2 axis that actively maintains Treg stability and coordinates Treg-mediated control of effector cell flexibility. We used microarrays to explore the gene expression profiles differentially expressed in CD4+CD25+Foxp3-YFP+ Treg cells from wild-type (WT; C57BL/6 crossed with Foxp3-Cre) and Ptenfl/flFoxp3-Cre (Ptenfl/fl mice crossed with Foxp3-Cre) mice

Project description:Here, we report on experiments in double-transgenic mice, in which RFP is expressed in all Foxp3+ Treg cells, whereas Foxp3-dependent GFP expression is exclusively confined to intrathymically induced Foxp3+ Treg cells. This novel molecular genetic tool enabled us to faithfully track and characterize naturally induced Treg cells of intrathymic (RFP+GFP+) and extrathymic (RFP+GFP−) origin in otherwise unmanipulated mice. These experiments directly demonstrate that extrathymically induced Treg cells substantially contribute to the overall pool of mature Foxp3+ Treg cells residing in peripheral lymphoid tissues of steady-state mice. Furthermore, we provide evidence that intra- and extrathymically induced Foxp3+ Treg cells represent distinct phenotypic and functional sublineages.

Project description:Regulatory T (Treg) cells harbor immune suppressive capacity and are crucial for the maintenance of peripheral tolerance. Treg cells are considered to be heterogenic, where compromised FOXP3 expression results in the generation of exTreg cells. Here we report that the E3 deubiquitinase USP21 prevents the depletion of FOXP3 protein and restricts tissue-resident exTreg cell generation. Mice lacking USP21 in Treg cells display immune disorders characterized by spontaneous T cell activation and excessive T helper type 1 (Th1) skewing. USP21 stabilizes FOXP3 protein by mediating its deubiquitination and therefore helps to maintain the expression of Treg signature genes. Moreover, at inflamed loci, tissue-resident USP21-deficient Treg cells display a Th1-like effector phenotype. Therefore, we demonstrate how USP21 controls the identity of tissue-resident Treg cells by preventing FOXP3 loss.

Project description:In this study, we determined the signature of CD4+Foxp3- effector T cells and CD4+Foxp3+ Treg cells in naive animals and following LCMV WE infection. In addition, transcriptional signatures were determined in CXCR3+ CD4+Foxp3+ Treg cells arising in Th1 settings following LCMV infection.

Project description:A variety of CD4+Foxp3+ Treg cell types have been described previously, indicating molecular heterogeneity within the Foxp3+ pool of CD4+ T cells. However, the factors that shape the transcriptomic identities of different Foxp3+ Treg cells are poorly understood. To identify the molecular pathways involved, we isolated CD4+Foxp3gfp+ cells from Th1-rich or Th2-rich environments following chronic Leishmania major or Schistosoma mansoni infection, respectively. Whole genome expression profiling and next generation small RNA sequencing revealed significantly different mRNA and miRNA profiles. In-silico analyses identified miR-10a and miR-182 as ‘regulatory miRNA hubs’ in CD4+Foxp3+ cells in Th1 and Th2-environments, respectively. Using in vitro and in vivo systems we identified that IL-12/IFNg down-regulated miR-10a and its putative transcription factor, Creb. Importantly, we demonstrated that miR-10a controls a suite of genes that regulate IFNg production in Th1-Treg cells. Also, Treg cells treated with IL-4 increased miR-182 and its putative transcription factor, cMaf. Up-regulation of miR-182 mitigated IL-2 secretion, in part through repression of IL2-promoting genes, including Bach2 and Cd2ap. This study indicates that CD4+Foxp3+ cells are influenced by their environment, and that Th1 or Th2 environments promote distinct miRNA pathways, preserving Treg stability and suppressor function. mouse infection vs. naïve

Project description:Regulatory T (Treg) cells are involved in self tolerance, immune homeostasis, prevention of autoimmunity, and suppression of immunity to pathogens or tumours. The forkhead transcription factor FOXP3 is essential for Treg cell development and function as mutations in FOXP3 cause severe autoimmunity in mice and humans. However, the FOXP3-dependent molecular mechanisms leading to this severe phenotype are not well understood. Here we introduce the chromatin remodelling enzyme SATB1 (special AT-rich sequence-binding protein-1) as an important target gene of FOXP3. So far, SATB1 has been associated with normal thymic T-cell development, peripheral T-cell homeostasis, TH1/TH2 polarization, and reprogramming of gene expression. In natural and induced murine and human FOXP3+ Treg cells SATB1 expression is significantly reduced. While there is no differential epigenetic regulation of the SATB1 locus between Treg and Teffector cells, FOXP3 reduces SATB1 expression directly as a transcriptional repressor at the SATB1 locus and indirectly via miR-155 induction, which specifically binds to the 3’UTR of the SATB1 mRNA. Reduced SATB1 expression in FOXP3+ cells achieved either by overexpression or induction of FOXP3 is linked to significant reduction in TH1 and TH2 cytokines, while loss of FOXP3 function either by knock down or genetic mutation leads to significant upregulation of SATB1 and subsequent cytokine production. Alltogether, these findings demonstrate that reduced SATB1 expression in Treg cells is necessary for maintenance of a Treg-cell phenotype in vitro and in vivo and places SATB1-mediated T cell-specific modulation of global chromatin remodelling central during the decision process between effector and regulatory T-cell function. Gene expression profiling of freshly isolated CD4+ T cells, separated into CD25 negative and positive subpopulations, from three different donors. FOXP3 is stably and constitutively expressed at a high level in CD4+CD25+ regulatory T cells and at a low level in CD4+CD25- cells.

Project description:The role of ICOS in anti-tumor T cell responses and overall tumor progression has been controversial. Here, we compared tumor progression in mice lacking ICOS only in Treg cells or in all T cells. We found that Treg-specific ICOS knockout reduces the overall tumor burden compared to Cre control mice with increased T effector/Treg ratios in the tumor. In contrast, there was no difference in the tumor burden in mice lacking ICOS in all the T cell compartments. This suggests a dual role of ICOS costimulation in promoting pro- and anti-tumor T cell responses. Consistent with reduced tumor burden, we found that Treg-specific deletion of ICOS leads to an increase of CD8+ CTLs that express high levels of granzyme B and perforin. Moreover, single-cell transcriptome analysis revealed an increase of Ly108hiEomeshi CD8+ T cell subset at the cost of Ly108hiT-bethi subset in Treg-specific knockout mice. These results suggest that ICOS-expressing Treg cells suppress CTL maturation process at the level of Eomes upregulation, a critical step known to drive perforin expression and cytotoxicity. Collectively, our data imply that cancer immunotherapies using ICOS agonist antibodies would work better in Treg-low tumors or when they are combined with regimens that deplete tumor-infiltrating Treg cells.