Inflammation is typically induced in response to a microbial infection. The release of proinflammatory cytokines enhances the stimulatory capacity of antigen-presenting cells, as well as recruits adaptive and innate immune effectors to the site of infection. Once the microbe is cleared, inflammation is resolved by various mechanisms to avoid unnecessary tissue damage. Autoimmunity arises when aberrant immune responses target self-tissues causing inflammation. In type 1 diabetes (T1D), T cells attack the insulin producing β cells in the pancreatic islets. Genetic and environmental factors increase T1D risk by in part altering central and peripheral tolerance inducing events. This results in the development and expansion of β cell-specific effector T cells (Teff) which mediate islet inflammation. Unlike protective immunity where inflammation is terminated, autoimmunity is sustained by chronic inflammation. In this review, we will highlight the key events which initiate and sustain T cell-driven pancreatic islet inflammation in nonobese diabetic mice and in human T1D. Specifically, we will discuss: (i) dysregulation of thymic selection events, (ii) the role of intrinsic and extrinsic factors that enhance the expansion and pathogenicity of Teff, (iii) defects which impair homeostasis and suppressor activity of FoxP3-expressing regulatory T cells, and (iv) properties of β cells which contribute to islet inflammation.
The property of functional avidity is recognized to be of critical importance in determining pathogen clearance. An unresolved question with regard to this property is whether distinct naive subsets exist that display inherent differences in their peptide sensitivity requirements for activation, i.e., functional avidity, or whether differences in peptide sensitivity are induced following peptide encounter. In this study, we demonstrate that naive populations that can give rise to both high- and low-avidity cells do not contain subsets that exhibit differences in the amount of peptide required for activation. Furthermore, we show that an individual T cell clone can generate both high- and low-avidity effectors. The work presented here provides the first formal demonstration that an individual cell can give rise to both high- and low-avidity progeny, suggesting that avidity modulation at the level of an individual cell may play an important role in the CD8+ T cell response generated in vivo.
Summary The generation of an optimal CD8+ cytotoxic T lymphocyte (CTL) response is critical for the clearance of many intracellular pathogens. Previous studies suggest that one contributor to an optimal immune response is the presence of CD8+ cells exhibiting high functional avidity. In this regard, CD8 expression has been shown to contribute to peptide sensitivity. Here, we investigated the ability of naive splenocytes to modulate CD8 expression according to the concentration of stimulatory peptide antigen. Our results showed that the level of CD8 expressed was inversely correlated with the amount of peptide used for the primary stimulation, with higher concentrations of antigen resulting in lower expression of both CD8α and CD8β. Importantly the ensuing CD8low and CD8high CTL populations were not the result of the selective outgrowth of naive CD8+ T‐cell subpopulations expressing distinct levels of CD8. Subsequent encounter with peptide antigen resulted in continued modulation of both the absolute level and the isoform of CD8 expressed and in the functional avidity of the responding cells. We propose that CD8 cell surface expression is not a static property, but can be modulated to ‘fine tune’ the sensitivity of responding CTL to a defined concentration of antigen.
Inefficient thymic negative selection of self-specific T cells is associated with several autoimmune diseases, including type 1 diabetes (T1D). The factors that influence the efficacy of thymic negative selection, and the kinetics of thymic output of autoreactive T cells remain ill-defined. We investigated thymic production of β cell-specific T cells using a thymus transplantation model. Thymi from different aged NOD mice representing distinct stages of T1D, were implanted into NOD.scid recipients and the diabetogenicity of the resulting T cell pool examined. Strikingly, the development of diabetes-inducing β cell-specific CD4+ and CD8+ T cells was regulated in an age-dependent manner. NOD.scid recipients of newborn NOD thymi developed diabetes. However, recipients of thymi from 7 and 10 d-old NOD donor mice remained diabetes-free, and exhibited a progressive decline in islet infiltration and β cell-specific CD4+ and CD8+ T cells. A similar temporal decrease in autoimmune infiltration was detected in some but not all tissues of recipient mice implanted with thymi from NOD mice lacking expression of the autoimmune regulator transcription factor, which develop multi-organ T cell-mediated autoimmunity. In contrast, recipients of 10 d or older thymi lacked diabetogenic T cells but developed severe colitis marked by increased effector T cells reactive to intestinal microbiota. These results demonstrate that thymic development of autoreactive T cells is limited to a narrow time-window, and occurs in a reciprocal manner compared to colonic microbiota-responsive T cells in NOD mice.
T cell-mediated autoimmune diseases such as type 1 diabetes (T1D) are believed to be the result in part of inefficient negative selection of self-specific thymocytes. However, the events regulating thymic negative selection are not fully understood. In the current study, we demonstrate that nonobese diabetic (NOD) mice lacking expression of the Mer tyrosine kinase (MerTK) have reduced inflammation of the pancreatic islets and fail to develop diabetes. Furthermore, NOD mice deficient in MerTK expression (Mer ؊/؊ ) exhibit a reduced frequency of  cell-specific T cells independent of immunoregulatory effectors. The establishment of bone marrow chimeric mice demonstrated that the block in  cell autoimmunity required hematopoietic-derived cells lacking MerTK expression. Notably, fetal thymic organ cultures and self-peptide administration showed increased thymic negative selection in Mer ؊/؊ mice. Finally, thymic dendritic cells (DC) prepared from Mer ؊/؊ mice exhibited an increased capacity to induce thymocyte apoptosis in a peptide-specific manner in vitro. These findings provide evidence for a unique mechanism involving MerTK-mediated regulation of thymocyte negative selection and thymic DC, and suggest a role for MerTK in contributing to  cell autoimmunity. can result in the development of T cell mediated autoimmune diseases such as type 1 diabetes (T1D), multiple sclerosis, and rheumatoid arthritis (8-11). The failure in T cell tolerance is generally influenced by a number of genes, most of which have yet to be identified (12). In the nonobese diabetic (NOD) mouse, a spontaneous model for T1D, both inefficient negative selection and dysregulation of peripheral tolerance mechanisms contribute to the development and activation, respectively, of pathogenic T cells that target the insulin producing  cells found in the islets of Langerhans (13). Inefficient negative selection in NOD mice is partly the result of the peptide binding properties of the MHC class II molecule IA g7 , and the relative insensitivity of NOD CD4 ϩ CD8 ϩ double-positive (DP) thymocytes to apoptosis-inducing events (9,14,15). One intriguing possibility is that the efficiency of negative selection is also regulated by the activation and/or functional state of medullary thymic epithelial cells (mTEC) and resident dendritic cells (DC). For instance events that regulate the avidity between DP thymocytes and mTEC and/or thymic DC may influence the efficiency of negative selection. This is likely similar to mechanisms in the periphery.The activation and maturation status of peripheral DC is critical for determining the outcome of a T cell response (16). Immature DC found under homeostatic conditions are characterized by low levels of MHC and T cell costimulatory molecules such as CD40, CD80, and CD86, and typically mediate clonal anergy/deletion of naïve T cells (17). However, upon activation and subsequent maturation, DC upregulate MHC and costimulatory molecules and secrete proinflammatory cytokines to promote robust expansion and effector T cell...
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