Therapeutic pressure drives the evolution of a protective ecotype characterized by AR-loss-induced senescence in prostate cancer
Limin He, Jun Jiang, Shaojie Liu, Hongtao Song, Tong Lu, Zhihao Hu, Yu Li, Hai Zhu, Yike Zhou, Zhengxuan Li, Fa Yang, Keying Zhang, Rui Zhang, Tao Wu, Kai Gan, Bin Zhao, Jingliang Zhang, Dailing Si,
Journal:Theranostics
IF:14.9
DOI:10.7150/thno.134940
PMID:42244988
Published:2026-05-11
research field:肿瘤学肿瘤微环境分子生物学转化医学癌症生物学衰老研究系统生物学细胞信号转导
Abstract
Rationale Prostate cancer treatment relies heavily on androgen deprivation therapy, yet the progression to a lethal treatment-resistant state presents a nearly universal clinical challenge. While tumor-intrinsic changes are well documented, the manner in which the broader tumor microenvironment dynamically reorganizes into distinct macroscopic ecological states under therapeutic pressure remains elusive. This underscores that dismantling specific therapy-induced TME niches may represent a promising strategy for CRPC treatment. Methods We constructed a comprehensive single-cell atlas comprising 399,276 cells from 133 clinical samples to systematically investigate sample-level microenvironmental heterogeneity. Integrative bioinformatics and a meta-analysis of 1,259 patients were utilized to validate the clinical relevance. The upstream regulatory role of the androgen receptor on the NF-κB2/p52 pathway in cancer-associated fibroblasts was elucidated and validated using CRISPR-Cas9, ChIP-qPCR, and dual-luciferase reporter assays. Functional studies and therapeutic strategies targeting this axis were conducted using gain- and loss-of-function assays, and evaluated through in vitro organoid co-cultures and in vivo transgenic and xenograft mouse models. Results We demonstrated that hormonal therapy drives a convergent systemic evolution toward a specific treatment-refractory ecological state termed Ecotype 4. Rather than isolated cellular events, this highly malignant ecosystem is characterized by a TGF-β-driven rigid vascular-stromal barrier enforcing immune exclusion and the prominent accumulation of an androgen receptor-negative senescent fibroblast population. Mechanistically, we identified that the loss of the androgen receptor releases a physiological brake on the non-canonical NF-κB pathway, forcing these fibroblasts into a pro-tumorigenic senescence phenotype. Importantly, pharmacologically blocking this NF-κB2/p52 pathway with the inhibitor SN52 reverses t
本文使用的Yeasen产品


