SUMO-defective c-Maf preferentially transactivates Il21 to exacerbate autoimmune diabetes
Chao-Yuan Hsu, … , Deh-Ming Chang, Huey-Kang Sytwu
Chao-Yuan Hsu, … , Deh-Ming Chang, Huey-Kang Sytwu
Published July 30, 2018
Citation Information: J Clin Invest. 2018;128(9):3779-3793. https://doi.org/10.1172/JCI98786.
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Research Article Autoimmunity Immunology

SUMO-defective c-Maf preferentially transactivates Il21 to exacerbate autoimmune diabetes

Abstract

SUMOylation is involved in the development of several inflammatory diseases, but the physiological significance of SUMO-modulated c-Maf in autoimmune diabetes is not completely understood. Here, we report that an age-dependent attenuation of c-Maf SUMOylation in CD4+ T cells is positively correlated with the IL-21–mediated diabetogenesis in NOD mice. Using 2 strains of T cell–specific transgenic NOD mice overexpressing wild-type c-Maf (Tg-WTc) or SUMOylation site–mutated c-Maf (Tg-KRc), we demonstrated that Tg-KRc mice developed diabetes more rapidly than Tg-WTc mice in a CD4+ T cell–autonomous manner. Moreover, SUMO-defective c-Maf preferentially transactivated Il21 to promote the development of CD4+ T cells with an extrafollicular helper T cell phenotype and expand the numbers of granzyme B–producing effector/memory CD8+ T cells. Furthermore, SUMO-defective c-Maf selectively inhibited recruitment of Daxx/HDAC2 to the Il21 promoter and enhanced histone acetylation mediated by CREB-binding protein (CBP) and p300. Using pharmacological interference with CBP/p300, we illustrated that CBP30 treatment ameliorated c-Maf–mediated/IL-21–based diabetogenesis. Taken together, our results show that the SUMOylation status of c-Maf has a stronger regulatory effect on IL-21 than the level of c-Maf expression, through an epigenetic mechanism. These findings provide new insights into how SUMOylation modulates the pathogenesis of autoimmune diabetes in a T cell–restricted manner and on the basis of a single transcription factor.

Authors

Chao-Yuan Hsu, Li-Tzu Yeh, Shin-Huei Fu, Ming-Wei Chien, Yu-Wen Liu, Shi-Chuen Miaw, Deh-Ming Chang, Huey-Kang Sytwu

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Figure 4

SUMO-defective c-Maf promotes the differentiation of CD4+ T cells with an extrafollicular helper T cell phenotype.

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SUMO-defective c-Maf promotes the differentiation of CD4+ T cells with a...
(A) Flow cytometry analysis of the expression of ICOS, PD-1, and CXCR5 in splenic CD4+ T cells from 12- to 14-week-old control, Tg-WTc, and Tg-KRc NOD mice. Summary of the frequencies of ICOShiCD4+, PD-1hiCD4+, and CXCR5+CD4+ T cells. (B) Flow cytometry analysis of the expression of ICOS and PD-1 in splenic CD4+ T cells as described in A. Numbers adjacent to outlined areas indicate the percentages of ICOShiPD-1hi cells (left panel). Right panel: Summary of the frequencies of ICOShiPD-1hiCD4+ T cells. (C) Flow cytometry analysis of ICOS or PD-1 expression in ICOSloPD-1loCD4+ and ICOShiPD-1hiCD4+ T cells from 12- to 14-week-old control, Tg-WTc, and Tg-KRc NOD mice. Summary of the geometric mean fluorescence intensity (gMFI) of ICOS or PD-1 in ICOSloPD-1loCD4+ or ICOShiPD-1hiCD4+ T cells. (D) Flow cytometry analysis of the expression of ICOS, PD-1, and CXCR5 in splenic CD4+ T cells as described in A. Summary of the frequencies of CXCR5ICOShiPD-1hiCD4+ and CXCR5+ICOShiPD-1hiCD4+ T cells. (E and F) Expression of Il21 mRNA in CXCR5ICOSloPD-1loCD4+, CXCR5ICOShiPD-1hiCD4+, and CXCR5+ICOShiPD-1hiCD4+ T cells from control, Tg-WTc, and Tg-KRc NOD mice. Data represent the mean ± SEM; n = 6 mice (AD) or n = 3 mice (E and F) per group; 3–4 independent experiments. *P < 0.05; **P < 0.01; 1-way ANOVA with Tukey’s post-test.