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A human ex vivo model of radiation-induced skin injury recapitulates p53-driven profibrotic response to radiotherapy
Caroline Dodson, Sophie M. Bilik, Gabrielle DiBartolomeo, Hannah Pachalis, Lindsey G. Siegfried, Jordan A.K. Johnson, Seth R. Thaller, Irena Pastar, Marjana Tomic-Canic, Anthony J. Griswold, Rivka C. Stone
Caroline Dodson, Sophie M. Bilik, Gabrielle DiBartolomeo, Hannah Pachalis, Lindsey G. Siegfried, Jordan A.K. Johnson, Seth R. Thaller, Irena Pastar, Marjana Tomic-Canic, Anthony J. Griswold, Rivka C. Stone
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Research Article Dermatology Genetics Inflammation

A human ex vivo model of radiation-induced skin injury recapitulates p53-driven profibrotic response to radiotherapy

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Abstract

Cutaneous radiation injury is an unintended consequence of radiotherapy for many common cancers and can progress to debilitating radiation-induced skin fibrosis (RISF). Existing radiation injury models do not fully capture the skin toxicities observed in patients, contributing to the lack of efficacious therapies to mitigate RISF. To address this, we developed an ex vivo human skin model that recapitulates the temporal radiation injury and RISF response. Human skin explants (n = 12) subjected to ionizing radiation demonstrated DNA double-stranded breaks and robust p53-driven transcriptional programming of cell cycle arrest, apoptosis, and senescence compared with nonirradiated controls. Irradiated skin also exhibited induction of pro-inflammatory cytokines, epithelial-mesenchymal transition, profibrotic TGF-β1–mediated signaling, and thickened collagen over time. P53 regulators murine double minute 2 (MDM2) and miR-34a were induced after irradiation and may be leveraged to modulate injury response. Notably, RNA-sequencing of postradiotherapy breast skin from patients who had undergone mastectomy showed similar p53, inflammatory, and TGF-β1 signatures as the ex vivo model, supporting its translational relevance. Together, this model provides a platform for identifying biomarkers and testing therapies to prevent or mitigate cutaneous radiation toxicities. Targeting the dynamic p53-driven profibrotic radiation response represents a potentially new therapeutic avenue to improve quality of life for patients after radiotherapy.

Authors

Caroline Dodson, Sophie M. Bilik, Gabrielle DiBartolomeo, Hannah Pachalis, Lindsey G. Siegfried, Jordan A.K. Johnson, Seth R. Thaller, Irena Pastar, Marjana Tomic-Canic, Anthony J. Griswold, Rivka C. Stone

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Figure 1

Establishment of a human ex vivo skin model and validation of early DNA damage responses to study radiation-induced injury.

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Establishment of a human ex vivo skin model and validation of early DNA ...
(A) Workflow schematic of the human ex vivo model used in this study. (B) Donor demographics (ID, age, and sex) and irradiation dose. Donors A–F, marked with an asterisk, were used for bulk RNA-seq. (C) Representative immunofluorescence images at 1 hour after irradiation showing phosphorylated H2AX (red) as a marker of dsDNA breaks, DAPI (blue) nuclear counterstain, and merged images from irradiated (3.5 Gy) and control (nonirradiated) samples. Scale bar: 20 μm. (D) Quantification of H2AX foci staining from C, based on counts from 3 independent blinded observers. Data represents n = 3 donors; symbols correspond to individual donors; mean ± SD. Statistical significance was assessed using a 1-tailed paired t test. (E) IPA of gene expression data in skin immediately after irradiation, highlighting cell survival–related genes and pathways. Differential expression was performed using edgeR on bulk RNA-seq data filtered for protein-coding genes. IPA Core Analysis was filtered to genes with P ≤ 0.05 and log2 fold-change ≥ ±0.5. Gene color reflects z score; numerical values indicate Benjamini-Hochberg–corrected –log10 (P value). Asterisks indicate statistical significance (*P < 0.05, **P < 0.01).

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