Reduced expression of phosphatase PTPN2 promotes pathogenic conversion of Tregs in autoimmunity
Mattias N.D. Svensson, … , Pandurangan Vijayanand, Nunzio Bottini
Mattias N.D. Svensson, … , Pandurangan Vijayanand, Nunzio Bottini
Published January 8, 2019
Citation Information: J Clin Invest. 2019;129(3):1193-1210. https://doi.org/10.1172/JCI123267.
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Research Article Autoimmunity Immunology

Reduced expression of phosphatase PTPN2 promotes pathogenic conversion of Tregs in autoimmunity

Abstract

Genetic variants at the PTPN2 locus, which encodes the tyrosine phosphatase PTPN2, cause reduced gene expression and are linked to rheumatoid arthritis (RA) and other autoimmune diseases. PTPN2 inhibits signaling through the T cell and cytokine receptors, and loss of PTPN2 promotes T cell expansion and CD4- and CD8-driven autoimmunity. However, it remains unknown whether loss of PTPN2 in FoxP3+ regulatory T cells (Tregs) plays a role in autoimmunity. Here we aimed to model human autoimmune-predisposing PTPN2 variants, the presence of which results in a partial loss of PTPN2 expression, in mouse models of RA. We identified that reduced expression of Ptpn2 enhanced the severity of autoimmune arthritis in the T cell–dependent SKG mouse model and demonstrated that this phenotype was mediated through a Treg-intrinsic mechanism. Mechanistically, we found that through dephosphorylation of STAT3, PTPN2 inhibits IL-6–driven pathogenic loss of FoxP3 after Tregs have acquired RORγt expression, at a stage when chromatin accessibility for STAT3-targeted IL-17–associated transcription factors is maximized. We conclude that PTPN2 promotes FoxP3 stability in mouse RORγt+ Tregs and that loss of function of PTPN2 in Tregs contributes to the association between PTPN2 and autoimmunity.

Authors

Mattias N.D. Svensson, Karen M. Doody, Benjamin J. Schmiedel, Sourya Bhattacharyya, Bharat Panwar, Florian Wiede, Shen Yang, Eugenio Santelli, Dennis J. Wu, Cristiano Sacchetti, Ravindra Gujar, Gregory Seumois, William B. Kiosses, Isabelle Aubry, Gisen Kim, Piotr Mydel, Shimon Sakaguchi, Mitchell Kronenberg, Tony Tiganis, Michel L. Tremblay, Ferhat Ay, Pandurangan Vijayanand, Nunzio Bottini

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Figure 10

exTregs display a unique chromatin landscape.

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exTregs display a unique chromatin landscape. (A–J) ATAC-Seq for chromat...
(AJ) ATAC-Seq for chromatin accessibility in SKG Tregs and SKG Th17 cells, as well as SKG Tregs during in vitro conversion and SKG exTregs. (A) Experimental design for evaluation of chromatin profile in SKG Tregs during in vitro conversion in the presence of IL-6 (50 ng/ml) and anti-CD3/CD28–coated beads. Tregs were isolated after 24, 48, and 72 hours of culture, whereas exTregs were isolated after 72 hours. (BD) Scatterplots of ATAC-Seq counts per peak comparing indicated samples. (EG) Boxplots of ATAC-Seq counts per peak from indicated samples at common or differentially accessible regions from the comparison labeled above. Boxes indicate interquartile range with whiskers ± 1.5 times this range and outlier points. (HJ) Normalized ATAC-Seq coverage at the Foxp3 (H), Rorc (I), and Il17a and Il17f (J) loci in Tregs, Th17 cells, Tregs during in vitro conversion, and exTregs. Scale: 0–1200 for Foxp3 and Rorc, 0–800 for Il17a and Il17f. Black rectangles represent visually evident changes in ATAC signal. ATAC-Seq from 2 independent replicates.