Project description:Immune homeostasis in peripheral tissues is achieved by maintaining a balance between pathogenic effector T cells (Teffs) and protective Foxp3(+) regulatory T cells (Tregs). Using a mouse model of an inducible tissue Ag, we demonstrate that Ag persistence is a major determinant of the relative frequencies of Teffs and Tregs. Encounter of transferred naive CD4(+) T cells with transiently expressed tissue Ag leads to generation of cytokine-producing Teffs and peripheral Tregs. Persistent expression of Ag, a mimic of self-antigen, leads to functional inactivation and loss of the Teffs with preservation of Tregs in the target tissue. The inactivation of Teffs by persistent Ag is associated with reduced ERK phosphorylation, whereas Tregs show less reduction in ERK phosphorylation and are relatively resistant to ERK inhibition. Our studies reveal a crucial role for Ag in maintaining appropriate ratios of Ag-specific Teffs to Tregs in tissues.

Project description:Foxp3-expressing regulatory T cells (Tregs) reside in tissues where they control inflammation and mediate tissue-specific functions. The skin of mice and humans contain a large number of Tregs; however, the mechanisms of how these cells function in skin remain largely unknown. In this article, we show that Tregs facilitate cutaneous wound healing. Highly activated Tregs accumulated in skin early after wounding, and specific ablation of these cells resulted in delayed wound re-epithelialization and kinetics of wound closure. Tregs in wounded skin attenuated IFN-? production and proinflammatory macrophage accumulation. Upon wounding, Tregs induce expression of the epidermal growth factor receptor (EGFR). Lineage-specific deletion of EGFR in Tregs resulted in reduced Treg accumulation and activation in wounded skin, delayed wound closure, and increased proinflammatory macrophage accumulation. Taken together, our results reveal a novel role for Tregs in facilitating skin wound repair and suggest that they use the EGFR pathway to mediate these effects.

Project description:Thymic Foxp3-expressing regulatory T cells are activated by peripheral self-antigen to increase their suppressive function, and a fraction of these cells survive as memory regulatory T cells (mTregs). mTregs persist in nonlymphoid tissue after cessation of Ag expression and have enhanced capacity to suppress tissue-specific autoimmunity. In this study, we show that murine mTregs express specific effector memory T cell markers and localize preferentially to hair follicles in skin. Memory Tregs express high levels of both IL-2Rα and IL-7Rα. Using a genetic-deletion approach, we show that IL-2 is required to generate mTregs from naive CD4(+) T cell precursors in vivo. However, IL-2 is not required to maintain these cells in the skin and skin-draining lymph nodes. Conversely, IL-7 is essential for maintaining mTregs in skin in the steady state. These results elucidate the fundamental biology of mTregs and show that IL-7 plays an important role in their survival in skin.

Project description:Recognition of self-peptide-MHC complexes by high-affinity TCRs and CD28 signaling are critical for the development of forkhead-winged helix box transcription factor 3(+) regulatory T cells (Tregs) in thymus. However, the type of APCs that are responsible for selecting Tregs has remained unclear. To dissect the role of hematopoietic-derived APCs (HCs) and thymic epithelial cells (TECs) in Treg selection, we constructed bone marrow chimeras with disrupted CD28/B7 signaling in the HC or TEC compartment and analyzed the generation of Tregs in the thymus. We found that both HCs and TECs were independently able to fully reconstitute the Treg population in the thymus of bone marrow chimeras. In addition, Treg selection requires the TCR signal and CD28 costimulation presented in cis on the same APC type in vivo. This study demonstrates a new role, to our knowledge, for HCs in the development of Tregs in thymus.

Project description:Despite accounting for 10-30% of the T cell population in mice and humans, the role of dual TCR-expressing T cells in immunity remains poorly understood. It has been hypothesized that dual TCR T cells pose an autoimmune hazard by allowing self-reactive TCRs to escape thymic selection. We revisited this hypothesis using the NOD murine model of type 1 diabetes. We bred NOD mice hemizygous at both TCR? and ? (TCR?+/- ?+/-) loci, rendering them incapable of producing dual TCR T cells. We found that the lack of dual TCR? expression skewed the insulin-specific thymocyte population toward greater regulatory T (Treg) cell commitment, resulting in a more tolerogenic Treg to conventional T cell ratio and protection from diabetes. These data support a novel hypothesis by which dual TCR expression can promote autoimmunity by limiting agonist selection of self-reactive thymocytes into the Treg cell lineage.

Project description:The neutralization of ?4 integrin is currently used as treatment in several autoimmune diseases and is thought to prevent the entry of most immune cells in target tissues. In this study, we showed that selective deletion of ?4 integrin in T cells did not prevent but delayed the development of experimental autoimmune encephalomyelitis. Whereas both Th1 and Th17 cells infiltrate the CNS of wild-type mice, T cells present in the CNS of mice lacking ?4 integrin were mainly enriched in Th17 cells, suggesting that this T cell subset uses other integrins to access the CNS. In contrast, ?4 integrin expression is important for Th1 cells to enter the CNS and for the stability of their Th1-associated genetic program. Therefore, our data suggest that anti-?4 integrin Ab treatment may be more efficient in the treatment of Th1- rather than Th17-mediated disease.

Project description:Various innate-like T cell subsets preferentially reside in specific epithelial tissues as the first line of defense. However, mechanisms regulating their tissue-specific development are poorly understood. Using the prototypical skin intraepithelial γδT cells (sIELs) as a model, we show in this study that a TCR-mediated selection plays an important role in promoting acquisition of a specific skin-homing property by fetal thymic sIEL precursors for their epidermal location, and the skin-homing potential is intrinsically programmed even before the selection. In addition, once localized in the skin, the sIEL precursors develop into sIELs without the requirement of further TCR-ligand interaction. These studies reveal that development of the tissue-specific lymphocytes is a hard-wired process that targets them to specific tissues for proper functions.

Project description:Follicular CD4(+) Th (Tfh) cells provide B cell help in germinal center reactions that support class switching, somatic hypermutation, and the generation of high-affinity Abs. In this article, we show that deficiency in NFAT1 and NFAT2 in CD4(+) T cells leads to impaired germinal center reactions upon viral infection because of reduced Tfh cell differentiation and defective expression of proteins involved in T/B interactions and B cell help, including ICOS, PD-1, and SLAM family receptors. Genome-wide chromatin immunoprecipitation data suggest that NFAT proteins likely directly participate in regulation of genes important for Tfh cell differentiation and function. NFAT proteins are important TCR and Ca(2+)-dependent regulators of T cell biology, and in this article we demonstrate a major positive role of NFAT family members in Tfh differentiation.

Project description:Naive CD4 T cells can differentiate into a number of functional subsets in response to Ag, including Foxp3(+) induced regulatory T cells (iTregs). The in vivo development and function of iTregs has been primarily demonstrated in systems involving Ag encountered systemically or delivered via the intestinal mucosa. In this study, we demonstrate that de novo Foxp3 expression in naive CD4 T cells is a critical mechanism for establishing tolerance for a tissue-restricted neo-self Ag. Naive CD4 T cells lacking a functional Foxp3 gene cannot achieve tolerance, but can be suppressed in vivo in the presence of wild type naive CD4 T cells. Exposure to nonspecific inflammation during priming undermines tolerance through impaired Foxp3 induction, suggesting that the microenvironment also has a role. These data show that de novo Foxp3 expression is an integral component of establishing and maintaining tolerance among naive peripheral CD4 T cells.

Project description:Fasting is beneficial in the prevention and amelioration of the clinical manifestations of autoimmune diseases including systemic lupus erythematosus. The mechanisms responsible for these effects are not well understood. During fasting, there is a dramatic reduction of the levels of circulating leptin, an adipokine with proinflammatory effects. Leptin also inhibits CD4(+)CD25(+)Foxp3(+) regulatory T cells, which are known to contribute significantly to the mechanisms of peripheral immune tolerance. In this study, we show that fasting-induced hypoleptinemia in (NZB × NZW)F(1) lupus-prone mice induced an expansion of functional regulatory T cells that was reversed by leptin replacement. The specificity of the findings was indicated by the lack of these effects in leptin-deficient ob/ob mice and leptin receptor-deficient db/db mice. These observations help to explain the beneficial effects of fasting in autoimmunity and could be exploited for leptin-based immune intervention in systemic lupus erythematosus.