Tregs with an MHC class II peptide–specific chimeric antigen receptor prevent autoimmune diabetes in mice
Justin A. Spanier, … , Brian T. Fife, Megan K. Levings
Justin A. Spanier, … , Brian T. Fife, Megan K. Levings
Published August 10, 2023
Citation Information: J Clin Invest. 2023;133(18):e168601. https://doi.org/10.1172/JCI168601.
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Research Article Autoimmunity Immunology

Tregs with an MHC class II peptide–specific chimeric antigen receptor prevent autoimmune diabetes in mice

Abstract

Adoptive immunotherapy with Tregs is a promising approach for preventing or treating type 1 diabetes. Islet antigen–specific Tregs have more potent therapeutic effects than polyclonal cells, but their low frequency is a barrier for clinical application. To generate Tregs that recognize islet antigens, we engineered a chimeric antigen receptor (CAR) derived from a monoclonal antibody with specificity for the insulin B chain 10–23 peptide presented in the context of the IAg7 MHC class II allele present in NOD mice. Peptide specificity of the resulting InsB-g7 CAR was confirmed by tetramer staining and T cell proliferation in response to recombinant or islet-derived peptide. The InsB-g7 CAR redirected NOD Treg specificity such that insulin B 10–23–peptide stimulation enhanced suppressive function, measured via reduction of proliferation and IL-2 production by BDC2.5 T cells and CD80 and CD86 expression on dendritic cells. Cotransfer of InsB-g7 CAR Tregs prevented adoptive transfer diabetes by BDC2.5 T cells in immunodeficient NOD mice. In WT NOD mice, InsB-g7 CAR Tregs prevented spontaneous diabetes. These results show that engineering Treg specificity for islet antigens using a T cell receptor–like CAR is a promising therapeutic approach for the prevention of autoimmune diabetes.

Authors

Justin A. Spanier, Vivian Fung, Christine M. Wardell, Mohannad H. Alkhatib, Yixin Chen, Linnea A. Swanson, Alexander J. Dwyer, Matthew E. Weno, Nubia Silva, Jason S. Mitchell, Paul C. Orban, Majid Mojibian, C. Bruce Verchere, Brian T. Fife, Megan K. Levings

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Figure 5

InsB-g7 CAR Tregs suppress BDC 2.5 T cell–induced autoimmune diabetes.

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InsB-g7 CAR Tregs suppress BDC 2.5 T cell–induced autoimmune diabetes. (...
(A) Experimental design indicating that 450 × 103 (9:1) or 150 × 103 (3:1) untransduced control Tregs or InsB-g7CAR Tregs were cotransferred with 50 × 103 naive BDC2.5 CD4+ T cells into 6- to 10-week-old NOD.Rag1–/– recipient mice. (B) Diabetes-free survival of mice described in A with pooled 9:1 and 3:1 Treg/BDC T cell treatment groups. Data are from 2–3 independent experiments. No Tregs, n = 14; 150 × 103 control Tregs, n = 4; 450 × 103 control Tregs, n = 9; 150 × 103 1B2 Tregs, n = 4; 450 × 103 1B2 Tregs, n = 9. Log-rank test with Bonferroni’s correction. *P < 0.05; ***P < 0.001. (C) Quantification of CD4+CD45.2+FOXP3+ Tregs isolated from spleen and pLNs from mice treated at 9:1 (filled circles) or 3:1 (open circles) Treg/Tconv, as indicated in pooled groups shown in B. Circles containing crosshairs depict diabetic mice, with all mice analyzed either 2 days after becoming diabetic or at day 30 after transfer. Two-way ANOVA with multiple comparisons. *P < 0.05; ***P < 0.001. (D) Representative flow cytometry plot illustrating gating strategy for identification of CD4+CD45.2+ InsBP8E tetramer+ and tetramerneg FOXP3+ Tregs from InsB-g7 CAR Treg–treated mice shown in B. (E) The frequency of Ki67+ and gMFI of surface PD-1 and intracellular CTLA4 of tetramerneg and tetramer+ InsBg7 CAR Tregs. Data are pooled from mice treated at 9:1 and 3:1 InsB-g7 CAR Tregs/BDC2.5 T cells and are from 2–3 independent experiments. n = 5–10 mice/group. Only mice with more than 10 CD4+CD45.2+ T cells (limit of detection) were included in the analysis. Student’s t test, 2-tailed. *P < 0.05; ***P < 0.001.