Tregs epigenetically reprogrammed from autoreactive effector T cells mitigate established autoimmunity
Tyler R. Colson, James J. Cameron, Hayley I. Muendlein, Mei-An Nolan, Jamie L. Leiriao, James H. Kim, Alexander N. Poltorak, Xudong Li
Tyler R. Colson, James J. Cameron, Hayley I. Muendlein, Mei-An Nolan, Jamie L. Leiriao, James H. Kim, Alexander N. Poltorak, Xudong Li
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Research Article Immunology Inflammation

Tregs epigenetically reprogrammed from autoreactive effector T cells mitigate established autoimmunity

Abstract

Reprogramming autoreactive CD4+ effector T (Teff) cells into immunosuppressive Tregs represents a promising strategy for treating established autoimmune diseases. However, the stability and function of such reprogrammed Tregs under inflammatory conditions remain unclear. Here, we show that demethylation of core Treg identity genes in Teff cells yields lineage-stable effector T cell reprogrammed Tregs (ER-Tregs). A single adoptive transfer of ER-Tregs not only prevents autoimmune neuroinflammation in mice when given before disease onset but also arrests its progression when administered after onset. Compared with Foxp3-overexpressing Teff cells, induced Tregs from naive precursors, and endogenous Tregs, ER-Tregs provide superior protection against autoimmune neuroinflammation. This enhanced efficacy stems from their inherited autoantigen specificity and selectively preserved effector cell transcriptional programs, which together bolster their fitness in inflammatory environments and enhance their suppressive capacity. Our results establish epigenetic reprogramming of autoreactive Teff cells as an effective approach to generate potent, stable Tregs for the treatment of refractory autoimmune conditions.

Authors

Tyler R. Colson, James J. Cameron, Hayley I. Muendlein, Mei-An Nolan, Jamie L. Leiriao, James H. Kim, Alexander N. Poltorak, Xudong Li

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Figure 4

Inheritance of autoantigen specificity contributes to superior suppressive function of ER-Tregs as compared with induced Tregs.

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Inheritance of autoantigen specificity contributes to superior suppressi...
(A) Flow cytometry of Foxp3 expression in CTVloCD4+ Tconv and nTregs 8 days after they were isolated from CD45.2+Foxp3Thy1.1 mice, labeled with CTV, and adoptively transferred into CD45.1+Foxp3Thy1.1 mice, which were subsequently immunized with MOG/CFA 1 day after adoptive transfer. (BD) EAE was induced in Rag1–/– mice via MOG/CFA immunization 1 day after adoptive transfer of MOG/CFA-primed CD4+ Tconv cells with or without cotransfer of congenically distinct ER-Tregs reprogrammed from MOG/CFA- or OVA/CFA-primed CD4+ Teff cells, or cotransfer of induced Tregs (iTregs) generated with in vitro differentiation of Tn cells isolated from MOG/CFA-primed mice. Flow cytometry analyses were conducted at 17 dpi. n = 6 per group. (B) EAE disease curve. (C) EAE scores at 17 dpi. (D) Flow cytometry analysis of the frequencies of adoptively transferred ER-Tregs or iTregs (CD45.1CD45.2+) in the spinal cord and draining LNs. Data are shown as mean ± SEM. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001, unpaired 2-tailed t test in B, 1-way ANOVA and Holm-Šídák test in C and D.