IL-2 −/− mice develop autoimmunity despite having relatively normal numbers of regulatory T cells (Tregs). In contrast, we demonstrate that IL-2−/− × IL-15−/− and IL-2Rβ−/− mice have a significant decrease in Treg numbers. Ectopic expression of foxp3 in a subset of CD4+ T cells rescued Treg development and prevented autoimmunity in IL-2Rβ−/− mice, suggesting that IL-2Rβ-dependent signals regulate foxp3 expression in Tregs. Subsequent analysis of IL-2Rβ-dependent signal transduction pathways established that the transcription factor STAT5 is necessary and sufficient for Treg development. Specifically, T cell-specific deletion of STAT5 prevented Treg development; conversely, reconstitution of IL-2Rβ−/− mice with bone marrow cells expressing an IL-2Rβ mutant that exclusively activates STAT5 restored Treg development. Finally, STAT5 binds to the promoter of the foxp3 gene suggesting that IL-2Rβ-dependent STAT5 activation promotes Treg differentiation by regulating expression of foxp3.
The last ten years have seen an explosive growth in our understanding of IFN gamma. The cloning of the cDNAs for IFN gamma and its receptor have made available large amounts of highly purified recombinant IFN gamma and soluble IFN gamma receptor. In addition, highly specific neutralizing monoclonal antibodies have been generated to both of these proteins. Using these reagents, IFN gamma and the IFN gamma receptor have been characterized on a molecular basis. Structure-function studies carried out on these proteins have identified key molecular regions that are required for biologic activity. Moreover, a great deal is now known concerning the physiologic role that IFN gamma plays in vivo. In this review we focus on the new developments in the areas of IFN gamma biochemistry and biology and pay particular attention to the IFN gamma receptor and three aspects of IFN gamma biology that are of special interest to immunologists: host defense, inflammation, and autoimmunity.
Inflammatory CD4+ T cell responses to self or commensal bacteria underlie the pathogenesis of autoimmunity and inflammatory bowel disease (IBD), respectively. While selection of self-specific T cells in the thymus limits responses to tissue antigens, the mechanisms that control selection of commensal bacteria-specific T cells remain poorly understood. Here we demonstrate that group 3 innate lymphoid cell (ILC3)-intrinsic expression of major histocompatibility complex class II (MHCII) is regulated similarly to thymic epithelial cells, and that MHCII+ ILC3s directly induce cell death of activated commensal bacteria-specific T cells. Further, MHCII on human colonic ILC3s was reduced in pediatric IBD patients. Collectively, these results define a selection pathway for commensal bacteria-specific CD4+ T cells in the intestine, and suggest that this process is dysregulated in human IBD.
Appropriate development of regulatory T (Treg) cells is necessary to prevent autoimmunity. Neonatal mice, unlike adults, lack factors required for Treg cell development. It is unclear what these missing factors are. However, signals emanating from the T cell receptor (TCR), the costimulatory receptor CD28, and the family of gammac-dependent cytokine receptors are required for Treg cell development. Herein we demonstrate that expression of a constitutively active Stat5b transgene (Stat5b-CA) allowed for Treg cell development in neonatal mice and restored Treg cell numbers in Cd28(-/-) mice. Sequence analysis of TCR genes in Stat5b-CA Treg cells indicated that ectopic STAT5 activation resulted in a TCR repertoire that more closely resembled that of naive T cells. Using MHCII tetramers to identify antigen-specific T cells, we showed that STAT5 signals diverted thymocytes normally destined to become naive T cells into the Treg cell lineage. Our data support a two-step model of Treg cell differentiation in which TCR and CD28 signals induce cytokine responsiveness and STAT5-inducing cytokines then complete the program of Treg cell differentiation.
Herein we report that interferon‐gamma (IFN gamma) induces the rapid and reversible tyrosine phosphorylation of the IFN gamma receptor. Using a panel of receptor intracellular domain mutants, we show that a membrane‐proximal LPKS sequence (residues 266‐269) is required for ligand‐induced tyrosine kinase activation and/or kinase‐receptor association and biological responsiveness, and a functionally critical membrane‐distal tyrosine residue (Y440) is a target of the activated enzyme. The biological significance of Y440 phosphorylation was demonstrated by showing that a receptor‐derived nonapeptide corresponding to receptor residues 436‐444 and containing phosphorylated Y440 bound specifically to p91, blocked p91 phosphorylation and inhibited the generation of an active p91‐containing transcription factor complex. In contrast, nonphosphorylated wild‐type, phosphorylated mutant, or phosphorylated irrelevant peptides did not. Moreover, the phosphorylated Y440‐containing peptide did not interact with a related but distinct latent transcription factor (p113) which is activatible by IFN alpha but not IFN gamma. These results thus document the specific and inducible association of p91 with the phosphorylated IFN gamma receptor and thereby elucidate the mechanism by which ligand couples the IFN gamma receptor to its signal transduction system.
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