Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors

Xiaowei Bian; Minna Piipponen; Zhuang Liu; Lihua Luo; Jennifer Geara; Yongjian Chen; Traimate Sangsuwan; Monica Maselli; Candice Diaz; Connor A. Bain; Evelien Eenjes; Maria Genander; Michael Crichton; Jenna L. Cash; Louis Archambault; Siamak Haghdoost; Julie Fradette; Pehr Sommar; Martin Halle; Ning Xu Landén

doi:10.1038/s41467-024-53295-1

Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors

Xiaowei Bian
, Minna Piipponen
, Zhuang Liu
, Lihua Luo
, Jennifer Geara
, Yongjian Chen
, Traimate Sangsuwan
, Monica Maselli
, Candice Diaz
, Connor A. Bain
, Evelien Eenjes
, Maria Genander
, Michael Crichton
, Jenna L. Cash
, Louis Archambault
, Siamak Haghdoost
, Julie Fradette
, Pehr Sommar
, Martin Halle^*
, Ning Xu Landén^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

58 Downloads (Pure)

Abstract

Radiotherapy (RT), a common cancer treatment, unintentionally harms surrounding tissues, including the skin, and hinders wound healing years after treatment. This study aims to understand the mechanisms behind these late-onset adverse effects. We compare skin biopsies from previously irradiated (RT+) and non-irradiated (RT−) sites in breast cancer survivors who underwent RT years ago. Here we show that the RT+ skin has compromised healing capacity and fibroblast functions. Using ATAC-seq, we discover altered chromatin landscapes in RT+ fibroblasts, with THBS1 identified as a crucial epigenetically primed wound repair-related gene. This is further confirmed by single-cell RNA-sequencing and spatial transcriptomic analysis of human wounds. Notably, fibroblasts in both murine and human post-radiation wound models show heightened and sustained THBS1 expression, impairing fibroblast motility and contractility. Treatment with anti-THBS1 antibodies promotes ex vivo wound closure in RT+ skin from breast cancer survivors. Our findings suggest that fibroblasts retain a long-term radiation memory in the form of epigenetic changes. Targeting this maladaptive epigenetic memory could mitigate RT’s late-onset adverse effects, improving the quality of life for cancer survivors.

Original language	English
Article number	9286
Journal	Nature Communications
Volume	15
DOIs	https://doi.org/10.1038/s41467-024-53295-1
Publication status	Published - 28 Oct 2024

Keywords

Animals
Breast Neoplasms - radiotherapy - genetics - pathology
Cancer Survivors
Epigenesis, Genetic - radiation effects
Epigenetic Memory
Female
Fibroblasts - radiation effects - metabolism
Humans
Mice
Middle Aged
Radiotherapy - adverse effects
Skin - radiation effects - metabolism - pathology
Wound Healing - radiation effects - genetics

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Bian, X., Piipponen, M., Liu, Z., Luo, L., Geara, J., Chen, Y., Sangsuwan, T., Maselli, M., Diaz, C., Bain, C. A., Eenjes, E., Genander, M., Crichton, M., Cash, J. L., Archambault, L., Haghdoost, S., Fradette, J., Sommar, P., Halle, M., & Xu Landén, N. (2024). Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors. Nature Communications, 15, Article 9286. https://doi.org/10.1038/s41467-024-53295-1

@article{fa63b393059a45dc8108328e415c85bb,

title = "Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors",

abstract = "Radiotherapy (RT), a common cancer treatment, unintentionally harms surrounding tissues, including the skin, and hinders wound healing years after treatment. This study aims to understand the mechanisms behind these late-onset adverse effects. We compare skin biopsies from previously irradiated (RT+) and non-irradiated (RT−) sites in breast cancer survivors who underwent RT years ago. Here we show that the RT+ skin has compromised healing capacity and fibroblast functions. Using ATAC-seq, we discover altered chromatin landscapes in RT+ fibroblasts, with THBS1 identified as a crucial epigenetically primed wound repair-related gene. This is further confirmed by single-cell RNA-sequencing and spatial transcriptomic analysis of human wounds. Notably, fibroblasts in both murine and human post-radiation wound models show heightened and sustained THBS1 expression, impairing fibroblast motility and contractility. Treatment with anti-THBS1 antibodies promotes ex vivo wound closure in RT+ skin from breast cancer survivors. Our findings suggest that fibroblasts retain a long-term radiation memory in the form of epigenetic changes. Targeting this maladaptive epigenetic memory could mitigate RT{\textquoteright}s late-onset adverse effects, improving the quality of life for cancer survivors.",

keywords = "Animals, Breast Neoplasms - radiotherapy - genetics - pathology, Cancer Survivors, Epigenesis, Genetic - radiation effects, Epigenetic Memory, Female, Fibroblasts - radiation effects - metabolism, Humans, Mice, Middle Aged, Radiotherapy - adverse effects, Skin - radiation effects - metabolism - pathology, Wound Healing - radiation effects - genetics",

author = "Xiaowei Bian and Minna Piipponen and Zhuang Liu and Lihua Luo and Jennifer Geara and Yongjian Chen and Traimate Sangsuwan and Monica Maselli and Candice Diaz and Bain, \{Connor A.\} and Evelien Eenjes and Maria Genander and Michael Crichton and Cash, \{Jenna L.\} and Louis Archambault and Siamak Haghdoost and Julie Fradette and Pehr Sommar and Martin Halle and \{Xu Land{\'e}n\}, Ning",

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doi = "10.1038/s41467-024-53295-1",

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Bian, X, Piipponen, M, Liu, Z, Luo, L, Geara, J, Chen, Y, Sangsuwan, T, Maselli, M, Diaz, C, Bain, CA, Eenjes, E, Genander, M, Crichton, M, Cash, JL, Archambault, L, Haghdoost, S, Fradette, J, Sommar, P, Halle, M & Xu Landén, N 2024, 'Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors', Nature Communications, vol. 15, 9286. https://doi.org/10.1038/s41467-024-53295-1

TY - JOUR

T1 - Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors

AU - Bian, Xiaowei

AU - Piipponen, Minna

AU - Liu, Zhuang

AU - Luo, Lihua

AU - Geara, Jennifer

AU - Chen, Yongjian

AU - Sangsuwan, Traimate

AU - Maselli, Monica

AU - Diaz, Candice

AU - Bain, Connor A.

AU - Eenjes, Evelien

AU - Genander, Maria

AU - Crichton, Michael

AU - Cash, Jenna L.

AU - Archambault, Louis

AU - Haghdoost, Siamak

AU - Fradette, Julie

AU - Sommar, Pehr

AU - Halle, Martin

AU - Xu Landén, Ning

PY - 2024/10/28

Y1 - 2024/10/28

N2 - Radiotherapy (RT), a common cancer treatment, unintentionally harms surrounding tissues, including the skin, and hinders wound healing years after treatment. This study aims to understand the mechanisms behind these late-onset adverse effects. We compare skin biopsies from previously irradiated (RT+) and non-irradiated (RT−) sites in breast cancer survivors who underwent RT years ago. Here we show that the RT+ skin has compromised healing capacity and fibroblast functions. Using ATAC-seq, we discover altered chromatin landscapes in RT+ fibroblasts, with THBS1 identified as a crucial epigenetically primed wound repair-related gene. This is further confirmed by single-cell RNA-sequencing and spatial transcriptomic analysis of human wounds. Notably, fibroblasts in both murine and human post-radiation wound models show heightened and sustained THBS1 expression, impairing fibroblast motility and contractility. Treatment with anti-THBS1 antibodies promotes ex vivo wound closure in RT+ skin from breast cancer survivors. Our findings suggest that fibroblasts retain a long-term radiation memory in the form of epigenetic changes. Targeting this maladaptive epigenetic memory could mitigate RT’s late-onset adverse effects, improving the quality of life for cancer survivors.

AB - Radiotherapy (RT), a common cancer treatment, unintentionally harms surrounding tissues, including the skin, and hinders wound healing years after treatment. This study aims to understand the mechanisms behind these late-onset adverse effects. We compare skin biopsies from previously irradiated (RT+) and non-irradiated (RT−) sites in breast cancer survivors who underwent RT years ago. Here we show that the RT+ skin has compromised healing capacity and fibroblast functions. Using ATAC-seq, we discover altered chromatin landscapes in RT+ fibroblasts, with THBS1 identified as a crucial epigenetically primed wound repair-related gene. This is further confirmed by single-cell RNA-sequencing and spatial transcriptomic analysis of human wounds. Notably, fibroblasts in both murine and human post-radiation wound models show heightened and sustained THBS1 expression, impairing fibroblast motility and contractility. Treatment with anti-THBS1 antibodies promotes ex vivo wound closure in RT+ skin from breast cancer survivors. Our findings suggest that fibroblasts retain a long-term radiation memory in the form of epigenetic changes. Targeting this maladaptive epigenetic memory could mitigate RT’s late-onset adverse effects, improving the quality of life for cancer survivors.

KW - Animals

KW - Breast Neoplasms - radiotherapy - genetics - pathology

KW - Cancer Survivors

KW - Epigenesis, Genetic - radiation effects

KW - Epigenetic Memory

KW - Female

KW - Fibroblasts - radiation effects - metabolism

KW - Humans

KW - Mice

KW - Middle Aged

KW - Radiotherapy - adverse effects

KW - Skin - radiation effects - metabolism - pathology

KW - Wound Healing - radiation effects - genetics

UR - https://www.scopus.com/pages/publications/85208081764

U2 - 10.1038/s41467-024-53295-1

DO - 10.1038/s41467-024-53295-1

M3 - Article

C2 - 39468077

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

M1 - 9286

ER -

Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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