Low tristetraprolin expression activates phenotypic plasticity and primes transition to lethal prostate cancer in mice
Katherine L. Morel, … , Christopher J. Sweeney, Leigh Ellis
Katherine L. Morel, … , Christopher J. Sweeney, Leigh Ellis
Published November 19, 2024
Citation Information: J Clin Invest. 2025;135(2):e175680. https://doi.org/10.1172/JCI175680.
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Research Article Cell biology Oncology

Low tristetraprolin expression activates phenotypic plasticity and primes transition to lethal prostate cancer in mice

Abstract

Phenotypic plasticity is a hallmark of cancer and is increasingly realized as a mechanism of resistance to androgen receptor–targeted (AR-targeted) therapy. Now that many prostate cancer (PCa) patients are treated upfront with AR-targeted agents, it is critical to identify actionable mechanisms that drive phenotypic plasticity, to prevent the emergence of resistance. We showed that loss of tristetraprolin (TTP; gene ZFP36) increased NF-κB activation, and was associated with higher rates of aggressive disease and early recurrence in primary PCa. We also examined the clinical and biological impact of ZFP36 loss with co-loss of PTEN, a known driver of PCa. Analysis of multiple independent primary PCa cohorts demonstrated that PTEN and ZFP36 co-loss was associated with increased recurrence risk. Engineering prostate-specific Zfp36 deletion in vivo induced prostatic intraepithelial neoplasia, and, with Pten codeletion, resulted in rapid progression to castration-resistant adenocarcinoma. Zfp36 loss altered the cell state driven by Pten loss, as demonstrated by enrichment of epithelial–mesenchymal transition (EMT), inflammation, TNF-α/NF-κB, and IL-6–JAK/STAT3 gene sets. Additionally, our work revealed that ZFP36 loss also induced enrichment of multiple gene sets involved in mononuclear cell migration, chemotaxis, and proliferation. Use of the NF-κB inhibitor dimethylaminoparthenolide (DMAPT) induced marked therapeutic responses in tumors with PTEN and ZFP36 co-loss and reversed castration resistance.

Authors

Katherine L. Morel, Beatriz Germán, Anis A. Hamid, Jagpreet S. Nanda, Simon Linder, Andries M. Bergman, Henk van der Poel, Ingrid Hofland, Elise M. Bekers, Shana Y. Trostel, Deborah L. Burkhart, Scott Wilkinson, Anson T. Ku, Minhyung Kim, Jina Kim, Duanduan Ma, Jasmine T. Plummer, Sungyong You, Xiaofeng A. Su, Wilbert Zwart, Adam G. Sowalsky, Christopher J. Sweeney, Leigh Ellis

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Figure 1

ZFP36/TTP and clinical outcomes.

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ZFP36/TTP and clinical outcomes. (A) RNA- and IHC-based forest plots de...
(A) RNA- and IHC-based forest plots depicting ZFP36/TTP expression related to clinical outcomes (biochemical recurrence and disease-free survival) and risk of lethal PCa (case-control cohorts). TCGA PRAD, The Cancer Genome Atlas Prostate Adenocarcinoma data set; DFCI FIHC, Dana-Farber Cancer Institute Fluorescent IHC; HPHS-PHS, Health Professionals Follow-up Study and Physicians’ Health Study. (B) Upregulated and downregulated genes were identified by differential expression analysis of TCGA PRAD cases divided by lower-quartile expression of ZFP36. (C) Representative images of immunofluorescent (IF) staining for pan-cytokeratin (yellow) and basal (red) markers, as well as TTP (green) in human PCa used for expression analysis. Benign glands (arrowheads) costain for pan-cytokeratin and basal cocktails; tumor cells (arrows) demonstrate absent basal expression. Far right images display diffuse prostate tumor with absent TTP expression. (D) Kaplan-Meier survival analysis demonstrating that TTP deficiency, measured by protein expression (DFCI, refs. 40, 69) and ZFP36 mRNA expression (TCGA PRAD, ref. 35; Taylor et al., ref. 34), results in shorter disease-free-survival, and even shorter disease-free survival in combination with PTEN deficiency.