An oral lichen planus–like mouse model driven by IFN-γ signaling and cytotoxic CD8+ T cells
Zhenlai Zhu, Tinglan Yang, Peng Peng, Kang Li, Wen Qin, Chen Zhang, Shuyan Wang, Yuanyuan Wang, Minghui Wei, Erle Dang, Meng Fu, Hao Guo, Wen Yin, Shuai Shao, Qing Liu
Zhenlai Zhu, Tinglan Yang, Peng Peng, Kang Li, Wen Qin, Chen Zhang, Shuyan Wang, Yuanyuan Wang, Minghui Wei, Erle Dang, Meng Fu, Hao Guo, Wen Yin, Shuai Shao, Qing Liu
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Research Article Dermatology Immunology Inflammation

An oral lichen planus–like mouse model driven by IFN-γ signaling and cytotoxic CD8+ T cells

Abstract

Oral lichen planus (OLP) is a recalcitrant inflammatory disease with potential for malignant transformation, involving a cytotoxic CD8+ T cell–mediated basal keratinocyte apoptosis. However, it lacks an appropriate mouse model for study. Here we developed an OLP-like mouse model using topical oxazolone to induce a delayed-type hypersensitivity-mediated oral lichenoid reaction. Histological and ultrastructural analysis confirmed hallmark pathological features of OLP, including band-like CD8+ T cell infiltration and basal cell damage as well as the presence of Civatte bodies. Comparative transcriptomic analysis revealed significant similarity between RNA-Seq profiles of the mouse model and human OLP lesions, highlighting shared upregulated genes and enriched pathways, particularly those related to IFN-γ signaling and cytotoxic T cell activity. Functional studies demonstrated that the OLP phenotype depended on IFN-γ, with local priming by IFN-γ intensifying the disease through upregulation of major histocompatibility complex class I. Additionally, the absence of Langerhans cells exacerbated disease severity in vivo. Therapeutic evaluation showed that the JAK inhibitors baricitinib and ruxolitinib effectively reduced disease burden and provided mechanistic insights. In conclusion, this OLP-like mouse model recapitulates key immunopathological and transcriptomic features of human OLP, offering a robust platform for dissecting disease mechanisms and evaluating novel therapeutic strategies.

Authors

Zhenlai Zhu, Tinglan Yang, Peng Peng, Kang Li, Wen Qin, Chen Zhang, Shuyan Wang, Yuanyuan Wang, Minghui Wei, Erle Dang, Meng Fu, Hao Guo, Wen Yin, Shuai Shao, Qing Liu

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Figure 2

Comparative transcriptome analysis reveals similarities between mouse OLP-like lesions and human OLP lesions.

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Comparative transcriptome analysis reveals similarities between mouse OL...
(A) Volcano plots comparing gene expression in ethanol-treated control mice and OXA-induced OLP-like lesions (n = 6 for vehicle control group, n = 5 for OXA group per group). Representative significantly upregulated and downregulated genes are labeled. Dashed lines indicate thresholds for log2 fold change and adjusted P value. Genes not meeting these criteria are marked as “none.” (B) GO enrichment analysis of upregulated genes, highlighting IFN responses and immune-related pathways. Bubble size reflects the number of genes associated with each GO category, while bubble color represents the –log10(P value). (C) KEGG pathway enrichment analysis of upregulated genes, showing involvement in JAK/STAT signaling and immune pathways. The rich factor is represented by horizontal bars, while the –log10(P value) is depicted as connected points. (D) Overlap analysis of differentially expressed genes between mouse and human OLP datasets. Fisher’s exact test indicates significant concordance in both upregulated and downregulated genes; odds ratios (OR), 95% CI, and P values are shown. (E) Gene Set Enrichment Analysis (GSEA) demonstrating enrichment of “cell killing” and “type II interferon-mediated signaling pathway” in both human OLP lesions and OLP-like mouse lesions (left), compared with the control group (right). (F) Venn diagram showing overlapping upregulated genes between human and mouse datasets, with corresponding expression levels of representative genes displayed in a bar plot.