Expression of αvβ8 integrin on dendritic cells regulates Th17 cell development and experimental autoimmune encephalomyelitis in mice
Andrew C. Melton, Samantha L. Bailey-Bucktrout, Mark A. Travis, Brian T. Fife, Jeffrey A. Bluestone, Dean Sheppard
Andrew C. Melton, Samantha L. Bailey-Bucktrout, Mark A. Travis, Brian T. Fife, Jeffrey A. Bluestone, Dean Sheppard
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Research Article

Expression of αvβ8 integrin on dendritic cells regulates Th17 cell development and experimental autoimmune encephalomyelitis in mice

Abstract

Th17 cells promote a variety of autoimmune diseases, including psoriasis, multiple sclerosis, rheumatoid arthritis, and inflammatory bowel disease. TGF-β is required for conversion of naive T cells to Th17 cells, but the mechanisms regulating this process are unknown. Integrin αvβ8 on DCs can activate TGF-β, and this process contributes to the development of induced Tregs. Here, we have now shown that integrin αvβ8 expression on DCs plays a critical role in the differentiation of Th17 cells. Th17 cells were nearly absent in the colons of mice lacking αvβ8 expression on DCs. In addition, these mice and the DCs harvested from them had an impaired ability to convert naive T cells into Th17 cells in vivo and in vitro, respectively. Importantly, mice lacking αvβ8 on DCs showed near-complete protection from experimental autoimmune encephalomyelitis. Our results therefore suggest that the integrin αvβ8 pathway is biologically important and that αvβ8 expression on DCs could be a therapeutic target for the treatment of Th17-driven autoimmune disease.

Authors

Andrew C. Melton, Samantha L. Bailey-Bucktrout, Mark A. Travis, Brian T. Fife, Jeffrey A. Bluestone, Dean Sheppard

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Figure 4

Characterization of draining lymph node DCs in β8fl/fl × CD11c-cre mice.

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Characterization of draining lymph node DCs in β8fl/fl × CD11c-cre mice....
(A) Flow cytometry plots of MHCII+CD11c+ DCs isolated from the draining lymph nodes of control or β8fl/fl × CD11c-cre mice 7 days after in vivo stimulation with CFA. DCs within plots are gated on CD8+ (lymphoid) and CD8 (myeloid) DCs (top) or B220+mPDCA-1+ (plasmacytoid; bottom). Numbers next to the gates indicate the percentage of CD8+ or CD8 MHCII+CD11c+ cells (top) or B220+mPDCA-1+MHCII+CD11c+ cells (bottom). (B) Percentage of lymphoid (Lym), myeloid (Mye), and plasmacytoid (Plas) DCs isolated from control β8fl/fl × CD11c-cre mice. (C) Flow cytometry plots of CD4+ T cells isolated from control or β8fl/fl × CD11c-cre mice 7 days after immunization with MOG plus CFA and stained with MHCII tetramers loaded with MOG or OVA peptide. Numbers above the gates indicate the percentage of cells labeled with tetramer after enrichment for tetramer-positive cells. (D) Percentage of CD4+ T cells labeled with MOG tetramer after enrichment for tetramer-positive cells isolated from control or β8fl/fl × CD11c-cre mice. (E) Flow cytometry histograms of CFSE-stained Thy1.1+2D2+ TCR transgenic T cells isolated from control or β8fl/fl × CD11c-cre mice 7 days after immunization with MOG plus CFA. Numbers above gates indicate the percentage of divided (left gate) and undivided (right gate) cells. (F) Percentage of undivided and divided 2D2+ Thy1.1+ cells isolated from control or β8fl/fl × CD11c-cre mice.