Project description:Polymorphisms in MHC class II molecules, in particular around ?-chain position-57 (?57), afford susceptibility/resistance to multiple autoimmune diseases, including type 1 diabetes, through obscure mechanisms. Here, we show that the antidiabetogenic MHC class II molecule I-A(b) affords diabetes resistance by promoting the differentiation of MHC-promiscuous autoreactive CD4(+) T cells into disease-suppressing natural regulatory T cells, in a ?56-67-regulated manner. We compared the tolerogenic and antidiabetogenic properties of CD11c promoter-driven transgenes encoding I-A(b) or a form of I-A(b) carrying residues 56-67 of I-A?(g7) (I-A(b-g7)) in wild-type nonobese diabetic (NOD) mice, as well as NOD mice coexpressing a diabetogenic and I-A(g7)-restricted, but MHC-promiscuous T-cell receptor (4.1). Both I-A transgenes protected NOD and 4.1-NOD mice from diabetes. However, whereas I-A(b) induced 4.1-CD4(+) thymocyte deletion and 4.1-CD4(+)Foxp3(+) regulatory T-cell development, I-A(b-g7) promoted 4.1-CD4(+)Foxp3(+) Treg development without inducing clonal deletion. Furthermore, non-T-cell receptor transgenic NOD.CD11cP-I-A(b) and NOD.CD11cP-IA(b-g7) mice both exported regulatory T cells with superior antidiabetogenic properties than wild-type NOD mice. We propose that I-A(b), and possibly other protective MHC class II molecules, afford disease resistance by engaging a naturally occurring constellation of MHC-promiscuous autoreactive T-cell clonotypes, promoting their deviation into autoregulatory T cells.

Project description:The presence of post-translational regulation of MHC class II (MHC II) under physiological conditions has been demonstrated recently in dendritic cells (DCs) that potently function as antigen-presenting cells (APCs). Here, we report that MARCH-I, an E3 ubiquitin ligase, plays a pivotal role in the post-translational regulation of MHC II in B cells. MARCH-I expression was particularly high in B cells, and the forced expression of MARCH-I induced the ubiquitination of MHC II. In B cells from MARCH-I-deficient mice (MARCH-I KO), the half-life of surface MHC II was prolonged and the ubiquitinated form of MHC II completely disappeared. In addition, MARCH-I-deficient B cells highly expressed exogenous antigen-loaded MHC II on their surface and showed high ability to present exogenous antigens. These results suggest that the function of MHC II in B cells is regulated through ubiquitination by MARCH-I.

Project description:Foxp3+ T-regulatory (Treg) cells are capable of suppressing immune responses. Lysine acetylation is a key mechanism of post-translational control of various transcription factors, and when acetylated, Foxp3 is stabilized and transcriptionally active. Therefore, understanding the roles of various histone/protein deacetylases (HDAC) are key to promoting Treg-based immunotherapy. Several of the 11 classical HDAC enzymes are necessary for optimal Treg function while others are dispensable. We investigated the effect of HDAC10 in murine Tregs. HDAC10 deletion had no adverse effect on the health of mice, which retained normal CD4+ and CD8+ T cell function. However, HDAC10-/- Treg exhibited increased suppressive function in vitro and in vivo. C57BL/6 Rag1-/- mice adoptively transferred with HDAC10-/- but not wild Treg, were protected from developing colitis. HDAC10-/- but not wild-type mice receiving fully MHC-mismatched cardiac transplants became tolerant and showed long-term allograft survival (>100 d). We conclude that targeting of HDAC10 may be of therapeutic value for inflammatory disorders including colitis and also for transplantation.

Project description:Use of Foxp3-positive (Foxp3(+)) T-regulatory (Treg) cells as potential cellular therapy in patients with autoimmunity, or post-stem cell or -organ transplantation, requires a sound understanding of the transcriptional regulation of Foxp3. Conserved CpG dinucleotides in the Treg-specific demethylation region (TSDR) upstream of Foxp3 are demethylated only in stable, thymus-derived Foxp3(+) Treg cells. Since methyl-binding domain (Mbd) proteins recruit histone-modifying and chromatin-remodeling complexes to methylated sites, we tested whether targeting of Mbd2 might promote demethylation of Foxp3 and thereby promote Treg numbers or function. Surprisingly, while chromatin immunoprecipitation (ChIP) analysis showed Mbd2 binding to the Foxp3-associated TSDR site in Treg cells, Mbd2 targeting by homologous recombination, or small interfering RNA (siRNA), decreased Treg numbers and impaired Treg-suppressive function in vitro and in vivo. Moreover, we found complete TSDR demethylation in wild-type (WT) Treg cells but >75% methylation in Mbd2(-/-) Treg cells, whereas reintroduction of Mbd2 into Mbd2-null Treg cells restored TSDR demethylation, Foxp3 gene expression, and Treg-suppressive function. Lastly, thymic Treg cells from Mbd2(-/-) mice had normal TSDR demethylation, but compared to WT Treg cells, peripheral Mbd2(-/-) Treg cells had a marked impairment of binding of Tet2, the DNA demethylase enzyme, at the TSDR site. These data show that Mbd2 has a key role in promoting TSDR demethylation, Foxp3 expression, and Treg-suppressive function.

Project description:Naturally occurring regulatory T (Treg) cells, which specifically express the transcription factor forkhead box P3 (Foxp3), are engaged in the maintenance of immunological self-tolerance and homeostasis. By transcriptional start site cluster analysis, we assessed here how genome-wide patterns of DNA methylation or Foxp3 binding sites were associated with Treg-specific gene expression. We found that Treg-specific DNA hypomethylated regions were closely associated with Treg up-regulated transcriptional start site clusters, whereas Foxp3 binding regions had no significant correlation with either up- or down-regulated clusters in nonactivated Treg cells. However, in activated Treg cells, Foxp3 binding regions showed a strong correlation with down-regulated clusters. In accordance with these findings, the above two features of activation-dependent gene regulation in Treg cells tend to occur at different locations in the genome. The results collectively indicate that Treg-specific DNA hypomethylation is instrumental in gene up-regulation in steady state Treg cells, whereas Foxp3 down-regulates the expression of its target genes in activated Treg cells. Thus, the two events seem to play distinct but complementary roles in Treg-specific gene expression.

Project description:MHC class I molecules are normally expressed at very low levels in the brain and their up-regulation in response to cytokines and viral infections has been associated with a number of neurological disorders. Here we demonstrate that the down-regulation of surface class I molecules in differentiated primary rat oligodendrocytes was accompanied by reduced steady-state levels of class I heavy-chain mRNA. Transient expression assays were performed in oligodendrocytes and fibroblasts, using a mouse H-2Kb class I promoter chloramphenicol acetyltransferase plasmid termed pH2KCAT (which contained 5'-flanking sequences from -2033 to +5 bp of the H-2Kb gene relative to the transcriptional start site at +1 bp). These assays showed that H-2Kb promoter activity was reduced in oligodendrocytes but not in class I-expressing fibroblasts. H-2Kb promoter activity was up-regulated in oligodendrocytes co-transfected with a plasmid expression vector encoding the transcriptional activator tax of human T-cell leukaemia virus type I, showing that down-regulation of promoter activity was reversible. Deletion mutant analysis of the H-2Kb promoter revealed the presence of negative regulatory elements that were functional in oligodendrocytes at -1.61 to -1.07 kb and -242 to -190 bp. Deletion of sequences in pH2KCAT encompassing the downstream element totally abolished promoter activity in both oligodendrocytes and fibroblasts, whereas a deletion within the upstream negative regulatory element increased promoter activity specifically in oligodendrocytes. The upstream negative regulatory element also down-regulated a linked heterologous herpes simplex virus thymidine kinase promoter in oligodendrocytes, but not in fibroblasts. Gel retardation assays using overlapping DNA probes that spanned the entire -1.61 to -1.07 kb region revealed the presence of a number of DNA-binding activities that were present in oligodendrocyte, but not in fibroblast nuclear extracts.

Project description:Foxp3, a winged-helix family transcription factor, serves as the master switch for CD4(+) regulatory T cells (Treg). We identified a unique and evolutionarily conserved CpG-rich island of the Foxp3 nonintronic upstream enhancer and discovered that a specific site within it was unmethylated in natural Treg (nTreg) but heavily methylated in naive CD4(+) T cells, activated CD4(+) T cells, and peripheral TGFbeta-induced Treg in which it was bound by DNMT1, DNMT3b, MeCP2, and MBD2. Demethylation of this CpG site using the DNA methyltransferase inhibitor 5-aza-2'-deoxycytidine (Aza) induced acetylation of histone 3, interaction with TIEG1 and Sp1, and resulted in strong and stable induction of Foxp3. Conversely, IL-6 resulted in methylation of this site and repression of Foxp3 expression. Aza plus TGFbeta-induced Treg resembled nTreg, expressing similar receptors, cytokines, and stable suppressive activity. Strong Foxp3 expression and suppressor activity could be induced in a variety of T cells, including human CD4(+)CD25(-) T cells. Epigenetic regulation of Foxp3 can be predictably controlled with DNMT inhibitors to generate functional, stable, and specific Treg.

Project description:Suppressor of cytokine signaling (SOCS) proteins are key regulators of CD4(+) T cell differentiation, and in particular, we have recently shown that SOCS2 inhibits the development of Th2 cells and allergic immune responses. Interestingly, transcriptome analyses have identified SOCS2 as being preferentially expressed in both natural regulatory T cells (Tregs) and inducible Tregs (iTregs); however, the role of SOCS2 in Foxp3(+) Treg function or development has not been fully elucidated. In this study, we show that despite having no effect on natural Treg development or function, SOCS2 is highly expressed in iTregs and required for the stable expression of Foxp3 in iTregs in vitro and in vivo. Indeed, SOCS2-deficient CD4(+) T cells upregulated Foxp3 following in vitro TGF-β stimulation, but failed to maintain stable expression of Foxp3. Moreover, in vivo generation of iTregs following OVA feeding was impaired in the absence of SOCS2 and could be rescued in the presence of IL-4 neutralizing Ab. Following IL-4 stimulation, SOCS2-deficient Foxp3(+) iTregs secreted elevated IFN-γ and IL-13 levels and displayed enhanced STAT6 phosphorylation. Therefore, we propose that SOCS2 regulates iTreg stability by downregulating IL-4 signaling. Moreover, SOCS2 is essential to maintain the anti-inflammatory phenotype of iTregs by preventing the secretion of proinflammatory cytokines. Collectively, these results suggest that SOCS2 may prevent IL-4-induced Foxp3(+) iTreg instability. Foxp3(+) iTregs are key regulators of immune responses at mucosal surfaces; therefore, this dual role of SOCS2 in both Th2 and Foxp3(+) iTregs reinforces SOCS2 as a potential therapeutic target for Th2-biased diseases.

Project description:Forkhead box P3 (FOXP3)-positive Treg cells are crucial for maintaining immune homeostasis. FOXP3 cooperates with its binding partners to elicit Treg cells' signature and function, but the molecular mechanisms underlying the modulation of the FOXP3 complex remain unclear. Here we report that Deleted in breast cancer 1 (DBC1) is a key subunit of the FOXP3 complex. We found that DBC1 interacts physically with FOXP3, and depletion of DBC1 attenuates FOXP3 degradation in inflammatory conditions. Treg cells from Dbc1-deficient mice were more resistant to inflammation-mediated abrogation of Foxp3 expression and function and delayed the onset and severity of experimental autoimmune encephalomyelitis and colitis in mice. These findings establish a previously unidentified mechanism regulating FOXP3 stability during inflammation and reveal a pathway for potential therapeutic modulation and intervention in inflammatory diseases.

Project description:Forkhead winged-helix transcription factor Foxp3 serves as the dedicated mediator of the genetic program governing CD25+CD4+ regulatory T cell (T(R)) development and function in mice. In humans, its role in mediating T(R) development has been controversial. Furthermore, the fate of T(R) precursors in FOXP3 deficiency has yet to be described. Making use of flow cytometric detection of human FOXP3, we have addressed the relationship between FOXP3 expression and human T(R) development. Unlike murine Foxp3- T cells, a small subset of human CD4+ and CD8+ T cells transiently up-regulated FOXP3 upon in vitro stimulation. Induced FOXP3, however, did not alter cell-surface phenotype or suppress T helper 1 cytokine expression. Furthermore, only ex vivo FOXP3+ T(R) cells persisted after prolonged culture, suggesting that induced FOXP3 did not activate a T(r) developmental program in a significant number of cells. FOXP3 flow cytometry was also used to further characterize several patients exhibiting symptoms of immune dysregulation, polyendocrinopathy, enteropathy, X-linked syndrome (IPEX) with or without FOXP3 mutations. Most patients lacked FOXP3-expressing cells, further solidifying the association between FOXP3 deficiency and immune dysregulation, polyendocrinopathy, enteropathy, X-linked syndrome. Interestingly, one patient bearing a FOXP3 mutation enabling expression of stable FOXP3(mut) protein exhibited FOXP3(mut)-expressing cells among a subset of highly activated CD4+ T cells. This observation raises the possibility that the severe autoimmunity in FOXP3 deficiency can be attributed, in part, to aggressive T helper cells that have developed from T(R) precursors.