Abstract
During the progression of the clinical onset of Type 1 Diabetes (T1D), high-risk individuals exhibit multiple islet autoantibodies and high-avidity T cells which progressively destroy beta cells causing overt T1D. In particular, novel autoantibodies, such as those against IA-2 epitopes (aa1-577), had a predictive rate of 100% in a 10-year follow up (rapid progressors), unlike conventional autoantibodies that required 15 years of follow up for a 74% predictive rate (slow progressors). The discrepancy between these two groups is thought to be associated with T-cell avidity, including CD8 and/or CD4 T cells. For this purpose, we build a series of mathematical models incorporating first one clone then multiple clones of islet-specific and pathogenic CD8 and/or CD4 T cells, together with B lymphocytes, to investigate the interaction of T-cell avidity with autoantibodies in predicting disease onset. These models are instrumental in examining several experimental observations associated with T-cell avidity, including the phenomenon of avidity maturation (increased average T-cell avidity over time), based on intra- and cross-clonal competition between T cells in high-risk human subjects. The model shows that the level and persistence of autoantibodies depends not only on the avidity of T cells, but also on the killing efficacy of these cells. Quantification and modeling of autoreactive T-cell avidities can thus determine the level of risk associated with each type of autoantibodies and the timing of T1D disease onset in individuals that have been tested positive for these autoantibodies. Such studies may lead to early diagnosis of the disease in high-risk individuals and thus potentially serve as a means of staging patients for clinical trials of preventive or interventional therapies far before disease onset.
Highlights
Type 1 Diabetes (T1D) is an autoimmune disorder in which the body’s own immune cells target the insulin-secreting beta cells in the Islets of Langerhans of the pancreas
We have modeled autoantigen processing and peptide-MHC complex (p-MHC) formation in beta cells and antigen presenting cells (APCs) [36], but here we assume for simplicity that such processes are fast and reach steady state rapidly compared to the long time scales studied here
We find as expected that the scaled version of the reduced model (2a)–(2b) exhibits bistable behaviour in which one steady state, S1~(0,0), is stable and corresponds to healthy individuals, while the other steady state, S2, possessing an elevated level of autoreactive T cells, is stable but corresponds to type 1 diabetic patients. [In the case of the full one-clone model, S2 becomes a transient steady state, see below.] By considering the points of intersection of the tc- and pc-nullclines, we demonstrate in Supplementary Material S1 that these two states coexist whenever 0ƒkƒ1, where k~
Summary
Type 1 Diabetes (T1D) is an autoimmune disorder in which the body’s own immune cells (cytotoxic T lymphocytes, CTLs) target the insulin-secreting beta cells in the Islets of Langerhans of the pancreas. These CTLs (including CD8z and CD4z T cells) recognize beta cells and kill them. T cells can directly kill beta cells via cell-to-cell contact, through a cytotoxic process, but they can influence their destruction through other factors, including the release of proinflammatory cytokines, granzyme B, or perforin, and possibly signaling through pathways of programmed cell death [7,8,9]. Autoreactive T cells with potential preferential usage of TCRs responsive to diabetesrelated autoantigens may serve as both a potential marker for disease progression and a target for immune manipulation in autoimmune diabetes
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