Inhibiting LSD1 unlocks retinoid AP-1 programming to activate epithelial immunity and skin tumor suppression
Nina Kuprasertkul, Alyssa F. Moore, Carina A. D’souza, Julia Chini, Eun-Kyung Ko, Sijia Huang, Shuo Zhang, Ashley S. Anderson, Shaun Egolf, Laura V. Pinheiro, Alison Jaccard, Claudia T. Magahis, Lydia Bao, Yann Aubert, Cyria Olingou, Stephen M. Prouty, Donna Brennan-Crispi, David A. Hill, John T. Seykora, Kathryn E. Wellen, Brian C. Capell
Nina Kuprasertkul, Alyssa F. Moore, Carina A. D’souza, Julia Chini, Eun-Kyung Ko, Sijia Huang, Shuo Zhang, Ashley S. Anderson, Shaun Egolf, Laura V. Pinheiro, Alison Jaccard, Claudia T. Magahis, Lydia Bao, Yann Aubert, Cyria Olingou, Stephen M. Prouty, Donna Brennan-Crispi, David A. Hill, John T. Seykora, Kathryn E. Wellen, Brian C. Capell
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Research Article Dermatology Oncology

Inhibiting LSD1 unlocks retinoid AP-1 programming to activate epithelial immunity and skin tumor suppression

Abstract

Lysine-specific demethylase 1 (LSD1; KDM1A) orchestrates context-dependent chromatin programs, yet its role in epithelial immunity remains largely unknown. Here, we identify LSD1 as a central brake on retinoid-driven and activator protein-1–driven (AP-1–driven) enhancer activation in epidermis and demonstrate that its inhibition induces antitumor immunity. Whereas epidermal LSD1 is required during development, acute loss or topical inhibition in adult skin was tolerated and triggered coordinated expression of retinoic acid signaling, lipid remodeling, and chemokine induction pathways. CUT&RUN profiling revealed that LSD1 occupies enhancer regions enriched for AP-1 motifs at retinoid metabolism, lipid homeostasis, and immune genes. LSD1 loss increased H3K4me1/2 and gene activation at these sites, licensing a poised AP-1–retinoid program. Single-cell spatial analyses showed that discrete keratinocyte subsets initiate retinoid signaling to recruit dendritic cells and activate CD4+ T cell responses. Topical LSD1 inhibition suppressed cutaneous squamous cell carcinoma in 2 models while amplifying keratinocyte–immune cell crosstalk. Functional perturbations revealed that retinoid signaling partially contributes to, whereas CD4+ T cells are essential for, tumor control. These findings define LSD1 as a master repressor of epithelial immune competence and nominate LSD1 inhibition as a therapeutic strategy to activate retinoid–AP-1 enhancer circuits and drive CD4-dependent tumor immunity in skin cancer.

Authors

Nina Kuprasertkul, Alyssa F. Moore, Carina A. D’souza, Julia Chini, Eun-Kyung Ko, Sijia Huang, Shuo Zhang, Ashley S. Anderson, Shaun Egolf, Laura V. Pinheiro, Alison Jaccard, Claudia T. Magahis, Lydia Bao, Yann Aubert, Cyria Olingou, Stephen M. Prouty, Donna Brennan-Crispi, David A. Hill, John T. Seykora, Kathryn E. Wellen, Brian C. Capell

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Figure 5

LSD1 inhibition modulates retinoid-immune pathways and restrains tumor growth.

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LSD1 inhibition modulates retinoid-immune pathways and restrains tumor g...
(A) Schematic for cSCC induction by chemical methods (DMBA-TPA, left) or genetic methods (Fyn mice, right). (B) Tumor area growth in DMBA-TPA (left) or Fyn model (right); multiple unpaired t tests (P value = t test on last day). (C) UMAP from Xenium data in topical LSD1i- or DMSO-treated Fyn tumors. (D) Dot plot with RA genes from Xenium in LSD1i- or DMSO-treated Fyn tumors. (E) Xenium H&E sections from topical LSD1i- or DMSO-treated tumors, Aldh1a3 (green) labeled. Dotted line indicates approximation of dermal-epidermal junction or tumor area. Scale bar: 500 μm. (F) Dot plot with immune genes from Xenium in LSD1i- or DMSO-treated Fyn tumors. (G) GO analysis of genes upregulated in CD3+ T cells in LSD1i- vs. DMSO-treated Fyn tumors. GO terms include leukocyte activation (GO: 0045321) and glucose catabolism (GO: 0006007). (H) IF for CD3 (green) in Fyn tumor cohort. KRT14 (red) and DAPI (blue). Quantification on right; 1-way ANOVA. (I) IHC for PD-1 in Fyn tumor cohort. Quantification on right; 1-way ANOVA. Scale bars: 100 μm unless indicated. Data represented as mean ± SD. Each dot represents an individual mouse for bar graphs: for B, n = 4–5 mice per condition in DMBA-TPA model and n = 3–4 mice per condition in Fyn model; for CG, n = 3 mice per condition; for H, n = 6 tumors across 3–4 mice per condition, n = 3 mice for normal skin for staining; for I, n = 3 mice per condition for staining. **P < 0.005.