The identification of over 80 autoimmune diseases in humans has led to the realization that a breakdown in self-tolerance accounts for many of the most devastating chronic diseases affecting human health worldwide. Over the past 10 years, it has become apparent that this breakdown in self-tolerance is in large part due to a loss of immune regulation, most prominently a consequence of defective regulatory T cells (Treg) and their inability to control pathogenic immunity. This conclusion has been reached based on numerous studies in animal models of autoimmunity, direct evidence in humans and genetic studies highlight the critical role of this T cell subset. These master regulators of immunity arise both in the thymus (called natural Tregs, nTregs) and in the peripheral immune system (called adaptive Tregs, aTregs) as a consequence of exposure to self-antigens. A loss of Tregs results in a fatal autoimmune disease (termed IPEX in humans), and small changes in Treg numbers or function accompany the onset of autoimmune diseases. In fact, recent data suggest that these regulatory T cells may be altered during disease progression and, in some cases, become so unstable such that they may themselves participate in destructive autoimmunity. Data from patients with a variety of autoimmune diseases has increasingly suggested that Tregs are defective. Several of the susceptibility genes identified in genome studies have shown that several genes that increase the risk for autoimmunity encode variant proteins that control Treg develop and function. However, the basis for these Treg defects and the relative contributions of nTregs versus aTregs in autoimmunity remain controversial. We hypothesize that nTregs are intimately involved in overall immune homeostasis, while aTregs that develop as a consequence of inflammation are critical for controlling local immunity and as such are most susceptible for destabilization. Recent studies in our group using gene expression arrays has identified a unique signature that distinguishes nTregs from aTregs, thus enabling, perhaps for the first time, an ability to distinguish and study these subsets. The goal of this application is to test this hypothesis in mouse models of experimental autoimmune encephalomyelitis, to define the relative importance and functional stability of Tregs in different phases of disease and to determine the relative effectiveness of nTreg versus aTregs in controlling disease activity. To test this hypothesis, we propose the following specific aims: 1. To characterize specific attributes and contributions of nTregs and aTregs in protection from autoimmune disease;and 2. To examine the stability of Tregs during autoimmune disease pathogenesis. We anticipate that the results of these studies will enable a more robust understanding of Treg function in humans with autoimmunity, provide new tools for tracking Treg function during disease progression and facilitate our ability to exploit Tregs for therapeutic usage.

Public Health Relevance

The identification of 80+ autoimmune diseases in humans has led to the realization that a breakdown in self-tolerance accounts for many of the most devastating chronic diseases affecting human health. This breakdown is in large part do to a loss of immune regulation as a consequence of defective regulatory T cells (Tregs) and their inability to control pathogenic immunity. This project will pursue efforts to define the properties of adaptive versus natural Tregs, their stabilty and ability to control autoimmunity.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI046643-15
Application #
8659331
Study Section
Transplantation, Tolerance, and Tumor Immunology Study Section (TTT)
Program Officer
Esch, Thomas R
Project Start
2000-03-01
Project End
2016-05-31
Budget Start
2014-06-01
Budget End
2015-05-31
Support Year
15
Fiscal Year
2014
Total Cost
Indirect Cost
Name
University of California San Francisco
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
City
San Francisco
State
CA
Country
United States
Zip Code
94143
Wang, David; Quiros, Jason; Mahuron, Kelly et al. (2018) Targeting EZH2 Reprograms Intratumoral Regulatory T Cells to Enhance Cancer Immunity. Cell Rep 23:3262-3274
Bluestone, Jeffrey A (2017) FOXP3, the Transcription Factor at the Heart of the Rebirth of Immune Tolerance. J Immunol 198:979-980
Morita, Shuhei; Villalta, S Armando; Feldman, Hannah C et al. (2017) Targeting ABL-IRE1? Signaling Spares ER-Stressed Pancreatic ? Cells to Reverse Autoimmune Diabetes. Cell Metab 25:883-897.e8
June, Carl H; Warshauer, Jeremy T; Bluestone, Jeffrey A (2017) Is autoimmunity the Achilles' heel of cancer immunotherapy? Nat Med 23:540-547
Roan, Florence; Stoklasek, Thomas A; Whalen, Elizabeth et al. (2016) Correction: CD4+ Group 1 Innate Lymphoid Cells (ILC) Form a Functionally Distinct ILC Subset That Is Increased in Systemic Sclerosis. J Immunol 196:3966
Kishnani, Priya S; Dickson, Patricia I; Muldowney, Laurie et al. (2016) Immune response to enzyme replacement therapies in lysosomal storage diseases and the role of immune tolerance induction. Mol Genet Metab 117:66-83
DuPage, Michel; Bluestone, Jeffrey A (2016) Harnessing the plasticity of CD4(+) T cells to treat immune-mediated disease. Nat Rev Immunol 16:149-63
Gitelman, Stephen E; Bluestone, Jeffrey A (2016) Regulatory T cell therapy for type 1 diabetes: May the force be with you. J Autoimmun 71:78-87
Bluestone, Jeffrey A; Tang, Qizhi (2015) Immunotherapy: making the case for precision medicine. Sci Transl Med 7:280ed3
Bluestone, Jeffrey A; Buckner, Jane H; Fitch, Mark et al. (2015) Type 1 diabetes immunotherapy using polyclonal regulatory T cells. Sci Transl Med 7:315ra189

Showing the most recent 10 out of 37 publications