Endogenous antigens shape the transcriptome and TCR repertoire in an autoimmune arthritis model
Elizabeth E. McCarthy, … , Arthur Weiss, Judith F. Ashouri
Elizabeth E. McCarthy, … , Arthur Weiss, Judith F. Ashouri
Published November 26, 2024
Citation Information: J Clin Invest. 2025;135(2):e174647. https://doi.org/10.1172/JCI174647.
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Research Article Autoimmunity Immunology

Endogenous antigens shape the transcriptome and TCR repertoire in an autoimmune arthritis model

Abstract

The development of pathogenic autoreactive CD4+ T cells, particularly in the context of impaired signaling, remains poorly understood. Unraveling how defective signaling pathways contribute to their activation and persistence is crucial for identifying new therapeutic targets. We performed bulk and single-cell RNA-Seq (scRNA-Seq) and single-cell T cell receptor sequencing (scTCR-Seq) to profile a highly arthritogenic subset of naive CD4+ T cells from BALB/c-Zap70*W163C (SKG) mice, which develop CD4+ T cell–mediated autoimmune arthritis driven by a hypomorphic mutation in Zap70 — a key TCR signaling kinase. Despite impaired signaling, these cells exhibited heightened expression of T cell activation and cytokine signaling genes but diminished expression of a subset of tolerogenic markers (Izumo1r, Tnfrsf9, Cd5, S100a11) compared with WT cells. The arthritogenic cells showed an enrichment for TCR variable β (Vβ) chains targeting superantigens (Sags) from the endogenous mouse mammary tumor virus (MMTV) but exhibited diminished induction of tolerogenic markers following peripheral antigen encounter, contrasting with the robust induction of the negative regulators seen in WT cells. In arthritic joints, cells expressing Sag-reactive Vβs expanded alongside detectable MMTV proviruses. Antiretroviral treatment and Sag-reactive T cell depletion curtailed SKG arthritis, suggesting that endogenous retroviruses disrupted peripheral tolerance and promoted the activation and differentiation of autoreactive CD4+ T cells into pathogenic effector cells.

Authors

Elizabeth E. McCarthy, Steven Yu, Noah Perlmutter, Yuka Nakao, Ryota Naito, Charles Lin, Vivienne Riekher, Joe DeRisi, Chun Jimmie Ye, Arthur Weiss, Judith F. Ashouri

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Figure 4

Trajectory analysis of T.4NNr4a1 cells orthogonally uncovers acute versus chronically antigen-activated T cell states with a distinct distribution in the SKGNur GFPhi subset.

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Trajectory analysis of T.4NNr4a1 cells orthogonally uncovers acute versu...
(A) UMAP of cells from the T.4NNr4a1 cluster colored according to latent time. (B and C) Smoothed gene expression analysis of cells in the T.4NNr4a1 cluster of selected genes with the highest expression earlier (B) or later (C) along the latent time axis. (D) Probability densities of latent time distribution of cells from the T.4NNr4a1 cluster assigned to 4 distinct clusters (labeled stages 1–4) by a Gaussian mixture model. (E) Predicted transitions from the partition-based graph abstraction (PAGA) algorithm between cells from the stages indicated in D. (F) Heatmap of single-cell, standard scale–normalized expression of genes ordered top to bottom by peak expression at earlier to later latent times. Chosen genes are the top 300 highest-confidence genes used in the modeling of latent time. Column annotation bar indicates stage assignment of the cell in each column. (G and H) Probability densities of latent time distribution for GFPhi (G) and GFPlo (H) cells from WTNur and SKGNur mice, with P values determined by Kolmogorov-Smirnov test.