DNA损伤
纤维化
炎症
癌变
癌症研究
间质细胞
乳腺癌
癌症
DNA
巨噬细胞
化学
细胞生物学
脂质过氧化
活性氧
癌细胞
病理
医学
基质
淋巴系统
生物
氧化应激
作者
Mary-Kate Hayward,Jason J. Northey,Valentina Opazo-Mellado,Connor Stashko,Ori Maller,Alastair Ironside,Xuchu Que,Jonathon N. Lakins,E Shelley Hwang,Joseph L. Witztum,Hugo González,Valerie M Weaver
出处
期刊:Cancer Cell
[Cell Press]
日期:2026-04-30
卷期号:44 (6): 1255-1269.e9
标识
DOI:10.1016/j.ccell.2026.03.022
摘要
Inflammation can induce mutagenic DNA damage to enhance cancer risk and progression. Inflammation also increases fibrosis and stromal stiffening that promotes malignancy, and tissues with higher cancer risk are often stiffer. Despite this connection, how stromal stiffness contributes to inflammatory-mediated DNA damage in tumorigenesis remains unclear. Here, we show that tissue tension engages macrophages to generate lipid peroxidation-induced DNA damage, contributing to mutational burden that may promote malignant progression. We identify that fibrotic breast tumors display higher mutational burdens. Mechanistically, tissue tension increases epithelial STAT3 to drive chemokine-mediated macrophage recruitment. Stiffness promotes reactive oxygen species-induced lipid peroxidation in recruited macrophages, generating aldehydes that damage DNA and enhance progression. Notably, high mammographically dense breast tissues-associated with increased cancer risk-are stiffer and inflamed and display elevated lipid aldehydes and DNA damage. This work links fibrosis and inflammation to tension-mediated cancer initiation and progression.
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