We and others have recently investigated patients with type 1 diabetes for the frequency and function of a population of regulatory T cells (Treg), characterized by the simultaneous expression of CD4 and CD25. Our studies did not support the notion that altered CD4+CD25+ T cell frequencies are associated with type 1 diabetes, but rather identified type 1 diabetes related alterations in the functional activities of these cells in terms of suppressing effector T (Teff) cell responses in vitro. The need to bring resolution to the aforementioned published discrepancies in frequency and function of Treg in type 1 diabetes, as well as investigate the potential for Teff cell defects, would be afforded with expanded studies that include the parameters of age, metabolic control, and disease duration, as well as to define (in association with Projects 1 and 2) the cellular and molecular mechanism(s) underlying this defect. Therefore, the overall objective of Project 3 is to improve our understanding the mechanisms of immune regulation afforded by CD4+CD25+ T cells, identify their contribution to the pathogenesis of type 1 diabetes, and evaluate the potential of these cells to serve as a marker for autoimmune disease activity.
Our specific aims are designed to test the hypothesis that Treg cells are functionally defective in type 1 diabetes, as a result of dysregulated interactions with APC, Teff, and NKT cells, and that the cellular &molecular basis for this defect resides in pathways controlling the phenotypic signature of Treg including surface CD25, FOXP3, as well as TGFfS. This hypothesis has been formed based on our observations of deficient functional activities of Treg in human type 1 diabetes, recent data suggesting the surface expression/stability of CD25 is crucial to maintaining regulatory homeostasis between Treg and Teff, literature indicating the immunological synapse with other immune system cells (e.g., DC, NKT cells) may influence the functional activities of Treg, as well as information suggesting key roles for a limited number of cytokines (e.g., IL-2, IL-10, TGFp) and matrix metalloproteinases are associated with these regulatory processes. The Project has two specific aims: 1) Identify the influence of age, type 1 diabetes, and metabolic control on the frequency and function of regulatory T cells defined by co-expression of CD4 and CD25, as well as on the cellular expression of the fork-head transcription factor FoxPS. 2) Define the molecular mechanisms underlying deficiencies in CD4+CD25+ T cell function in subjects with type 1 diabetes. The successful completion of these studies could provide key information to fill an existing knowledge void regarding the mechanistic interactions between specific cell populations that underlie the failure of immune regulation which results in type 1 diabetes.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Program Projects (P01)
Project #
5P01AI042288-13
Application #
8131063
Study Section
Special Emphasis Panel (ZAI1)
Project Start
Project End
Budget Start
2010-09-01
Budget End
2011-08-31
Support Year
13
Fiscal Year
2010
Total Cost
$261,570
Indirect Cost
Name
University of Florida
Department
Type
DUNS #
969663814
City
Gainesville
State
FL
Country
United States
Zip Code
32611
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Chen, Yi-Guang; Mathews, Clayton E; Driver, John P (2018) The Role of NOD Mice in Type 1 Diabetes Research: Lessons from the Past and Recommendations for the Future. Front Endocrinol (Lausanne) 9:51
Kusmartseva, Irina; Beery, Maria; Philips, Tiffany et al. (2018) Hospital time prior to death and pancreas histopathology: implications for future studies. Diabetologia 61:954-958
Hu, Ronghua; Xia, Chang-Qing; Butfiloski, Edward et al. (2018) Effect of high glucose on cytokine production by human peripheral blood immune cells and type I interferon signaling in monocytes: Implications for the role of hyperglycemia in the diabetes inflammatory process and host defense against infection. Clin Immunol 195:139-148
Smith, Mia J; Rihanek, Marynette; Wasserfall, Clive et al. (2018) Loss of B-Cell Anergy in Type 1 Diabetes Is Associated With High-Risk HLA and Non-HLA Disease Susceptibility Alleles. Diabetes 67:697-703
Posgai, Amanda L; Wasserfall, Clive H; Kwon, Kwang-Chul et al. (2017) Plant-based vaccines for oral delivery of type 1 diabetes-related autoantigens: Evaluating oral tolerance mechanisms and disease prevention in NOD mice. Sci Rep 7:42372
Sebastiani, Guido; Ventriglia, Giuliana; Stabilini, Angela et al. (2017) Regulatory T-cells from pancreatic lymphnodes of patients with type-1 diabetes express increased levels of microRNA miR-125a-5p that limits CCR2 expression. Sci Rep 7:6897
O'Kell, Allison L; Wasserfall, Clive; Catchpole, Brian et al. (2017) Comparative Pathogenesis of Autoimmune Diabetes in Humans, NOD Mice, and Canines: Has a Valuable Animal Model of Type 1 Diabetes Been Overlooked? Diabetes 66:1443-1452
Newby, Brittney N; Brusko, Todd M; Zou, Baiming et al. (2017) Type 1 Interferons Potentiate Human CD8+ T-Cell Cytotoxicity Through a STAT4- and Granzyme B-Dependent Pathway. Diabetes 66:3061-3071
Whitener, Robert L; Gallo Knight, Lisa; Li, Jianwei et al. (2017) The Type 1 Diabetes-Resistance Locus Idd22 Controls Trafficking of Autoreactive CTLs into the Pancreatic Islets of NOD Mice. J Immunol 199:3991-4000

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