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The XCL1/XCR1 axis is upregulated in type 1 diabetes and aggravates its pathogenesis
Camilla Tondello, Christine Bender, Gregory J. Golden, Deborah Puppe, Elisa Blickberndt, Monika Bayer, Giulia K. Buchmann, Josef Pfeilschifter, Malte Bachmann, Edith Hintermann, Ralf P. Brandes, Michael R. Betts, Richard A. Kroczek, Urs Christen
Camilla Tondello, Christine Bender, Gregory J. Golden, Deborah Puppe, Elisa Blickberndt, Monika Bayer, Giulia K. Buchmann, Josef Pfeilschifter, Malte Bachmann, Edith Hintermann, Ralf P. Brandes, Michael R. Betts, Richard A. Kroczek, Urs Christen
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Research Article Immunology

The XCL1/XCR1 axis is upregulated in type 1 diabetes and aggravates its pathogenesis

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Abstract

Type 1 diabetes (T1D) is precipitated by the autoimmune destruction of the insulin-producing β cells in the pancreatic islets of Langerhans. Chemokines have been identified as major conductors of islet infiltration by autoaggressive leukocytes, including antigen-presenting cells and islet autoantigen–specific T cells. We have previously generated a road map of gene expression in the islet microenvironment during T1D in a mouse model and found that most of the chemokine axes are chronically upregulated during T1D. The XCL1/XCR1 chemokine axis is of particular interest, since XCR1 is exclusively expressed on conventional DCs type 1 (cDC1) that excel by their high capacity for T cell activation. Here, we demonstrate that cDC1-expressing XCR1 are present in and around the islets of patients with T1D and of individuals with islet autoantibody positivity. Furthermore, we show that XCL1 plays an important role in the attraction of highly potent DCs expressing XCR1 to the islets in an inducible mouse model for T1D. XCL1-deficient mice display a diminished infiltration of XCR1+ cDC1 and, subsequently, a reduced magnitude and activity of islet autoantigen–specific T cells, resulting in a profound decrease in T1D incidence. Interference with the XCL1/XCR1 chemokine axis might constitute a novel therapy for T1D.

Authors

Camilla Tondello, Christine Bender, Gregory J. Golden, Deborah Puppe, Elisa Blickberndt, Monika Bayer, Giulia K. Buchmann, Josef Pfeilschifter, Malte Bachmann, Edith Hintermann, Ralf P. Brandes, Michael R. Betts, Richard A. Kroczek, Urs Christen

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Figure 5

Switch to a Treg milieu in the islets of XCL1-deficient mice.

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Switch to a Treg milieu in the islets of XCL1-deficient mice.
(A) Freque...
(A) Frequencies of CD8 T cells expressing perforin (Perf), granzyme B (GrB), PD-1, or KLRG1 of total CD8 T cells or LCMV-GP33–specific CD8 T cells. Data were obtained via flow cytometric analysis of islet-infiltrating cells of RIP-GP mice and RIP-GP × XCL1–/– mice at day 7 and day 28 after infection. Results are shown as mean ± SEM, and P values (Mann-Whitney t test) are indicated when significant (n = 7–9). (B) In vivo cytotoxicity assay, comparing RIP-GP uninfected mice (d0) to RIP-GP and RIP-GP × XCL1–/– mice at day 28 after infection. Differently labeled GP33-loaded and unloaded target splenocytes were injected i.v. at a 1:1 ratio. At 10 minutes and 1, 4, 24, and 48 hours after injection, blood was taken, and the ratio of GP33-loaded and unloaded target cells was determined by flow cytometry. The obtained data were normalized against uninfected mice (baseline). (C) Calculated half-life of GP33-loaded target cell turnover (left) and different visualization of the GP33+/GP33– ratio at 48 hours after the i.v. injection for the infected RIP-GP and RIP-GP × XCL1–/– at day 28 after infection. Values are shown as mean ± SEM. Number of mice used are displayed in brackets. (D) Frequencies of FoxP3+ cells among CD8+ cells (left) and CD4+ cells (right) obtained via flow cytometric analysis of islet-infiltrating cells of RIP-GP and RIP-GP × XCL1–/– mice at day 7 and day 28 after infection. Results are displayed as mean ± SEM. (E) Ratio of total FoxP3+ cells and total autoaggressive (IFN-γ+) CD8 T cells. Results are displayed as mean ± SEM. Number of mice and significant P values (Mann-Whitney t test) are indicated.

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