Mouse and human CD8(+) CD28(low) regulatory T lymphocytes differentiate in the thymus.

Regulatory T (Treg) lymphocytes play a central role in the control of immune responses and so maintain immune tolerance and homeostasis. In mice, expression of the CD8 co-receptor and low levels of the co-stimulatory molecule CD28 characterizes a Treg cell population that exerts potent suppressive function in vitro and efficiently controls experimental immunopathology in vivo. It has remained unclear if CD8(+) CD28(low) Treg cells develop in the thymus or represent a population of chronically activated conventional T cells differentiating into Treg cells in the periphery, as suggested by their CD28(low) phenotype. We demonstrate that functional CD8(+) CD28(low) Treg cells are present in the thymus and that these cells develop locally and are not recirculating from the periphery. Differentiation of CD8(+) CD28(low) Treg cells requires MHC class I expression on radioresistant but not on haematopoietic thymic stromal cells. In contrast to other Treg cells, CD8(+) CD28(low) Treg cells develop simultaneously with CD8(+) CD28(high) conventional T cells. We also identified a novel homologous naive CD8(+) CD28(low) T-cell population with immunosuppressive properties in human blood and thymus. Combined, our data demonstrate that CD8(+) CD28(low) cells can develop in the thymus of mice and suggest that the same is true in humans.

Increased thymic development of regulatory T cells in NOD mice is functionally dissociated from type I diabetes susceptibility.

Regulatory T (Treg) lymphocytes play a central role in the control of autoimmune pathology. Any alteration in Treg-cell biology in mouse strains used for the study of these disorders therefore raises the question of its direct link with disease susceptibility. Paradoxically, in non-obese diabetic (NOD) mice increased numbers of Treg cells develop in the thymus. In this report we identify a locus of <7 Mbp that quantitatively controls Treg-cell development in the thymus of the NOD mouse. This 'Trd1' region is located centromeric to the H2 complex on chromosome 17 and does not include genes encoding classical MHC molecules. The genomic region identified here contains the Idd16 diabetes susceptibility locus and the use of congenic mouse strains allowed us to investigate the potential link between quantitatively altered thymic Treg cells and diabetes susceptibility. Hybrid mice present similar levels of thymic Treg cells as B6 animals but they developed diabetes with the same kinetics as NOD mice. Therefore, the increased Treg-cell development in NOD mice controlled by Trd1 is functionally dissociated from the susceptibility of NOD to diabetes.

The thymic niche does not limit development of the naturally diverse population of mouse regulatory T lymphocytes.

Thymus-derived CD4(+)Foxp3(+) regulatory T lymphocytes (Tregs) play a central role in the suppression of immune responses to self-antigens and thus avoid autoimmune disorders. It remains unclear if the specialized thymic niche controls the number of differentiating Tregs. We investigated development of murine Tregs from precursors expressing the naturally very large repertoire of TCRs. By analyzing their developmental kinetics, we observed that differentiating Tregs dwell in the thymus ∼1 d longer than their conventional T cell counterparts. By generating hematopoietic chimeras with very low proportions of trackable precursors, we could follow individual waves of developing T cells in the thymus. We observed strongly increased proportions of Tregs at the end of the waves, confirming that these cells are the last to leave the thymus. To assess whether the thymic niche limits Treg development, we generated hematopoietic chimeras in which very few T cell precursors could develop. The substantial increase in the proportion of Tregs we found in these mice suggested a limiting role of the thymic niche; however, this increase was accounted for entirely by the prolonged thymic dwell time of Tregs. We conclude that, when precursors express a naturally diverse TCR repertoire, the thymic niche does not limit differentiation of Tregs.

Autoimmune regulator (AIRE)-deficient CD8+CD28low regulatory T lymphocytes fail to control experimental colitis.

Mutations in the gene encoding the transcription factor autoimmune regulator (AIRE) are responsible for autoimmune polyendocrinopathy candidiasis ectodermal dystrophy syndrome. AIRE directs expression of tissue-restricted antigens in the thymic medulla and in lymph node stromal cells and thereby substantially contributes to induction of immunological tolerance to self-antigens. Data from experimental mouse models showed that AIRE deficiency leads to impaired deletion of autospecific T-cell precursors. However, a potential role for AIRE in the function of regulatory T-cell populations, which are known to play a central role in prevention of immunopathology, has remained elusive. Regulatory T cells of CD8(+)CD28(low) phenotype efficiently control immune responses in experimental autoimmune and colitis models in mice. Here we show that CD8(+)CD28(low) regulatory T lymphocytes from AIRE-deficient mice are transcriptionally and phenotypically normal and exert efficient suppression of in vitro immune responses, but completely fail to prevent experimental colitis in vivo. Our data therefore demonstrate that AIRE plays an important role in the in vivo function of a naturally occurring regulatory T-cell population.

Shaping of the autoreactive regulatory T cell repertoire by thymic cortical positive selection.

The main function of regulatory T lymphocytes is to keep autoimmune responses at bay. Accordingly, it has been firmly established that the repertoire of CD4(+)CD25(+)Foxp3(+) regulatory T cells (Tregs) is enriched in autospecific cells. Differences in thymic-positive and/or -negative selection may account for selection of the qualitatively distinct regulatory and conventional T cell (Tconv) repertoires. It has previously been shown that precursors for Tregs are less sensitive to negative selection than Tconv precursors. Studies with TCR/ligand doubly transgenic mice suggested that an agonist ligand might induce positive selection of Treg (but not Tconv) cells. However, massive deletion of Tconv (but not Treg) cell precursors observed in these mice renders interpretation of such data problematic and a potential role for positive selection in generation of the autospecific Treg repertoire has remained therefore incompletely understood. To study this important unresolved issue and circumvent use of TCR/ligand-transgenic mice, we have developed transgenic mice expressing a single MHC class II/peptide ligand on positively selecting thymic cortical epithelial cells. We found that functional Treg (but not Tconv) cells specific for the single ligand were preferentially selected from the naturally diverse repertoire of immature precursors. Our data therefore demonstrate that thymic cortical positive selection of regulatory and Tconv precursors is governed by distinct rules and that it plays an important role in shaping the autoreactive Treg repertoire.