High matrix stiffness triggers the YAP-OPA1-TET1/3 loop to drive chemoresistance via enhanced nuclear-mitochondrial communication

Summary Chemoresistance remains a major obstacle in prostate cancer therapy. This study demonstrates that high extracellular matrix stiffness promotes chemoresistance by disrupting mitochondrial-nuclear communication. Culturing prostate cancer cells on polyacrylamide hydrogels of varying stiffness revealed that a high-stiffness environment promotes mitochondrial fusion and enhances function. Mechanistic investigations revealed that high matrix stiffness activates YAP, leading to dysregulation of the Hippo signaling pathway, which subsequently upregulates the expression of OPA1 and induces mitochondrial fusion. This fusion triggers a reprogramming of glutamine metabolism. The resulting metabolite, α-ketoglutarate, activated DNA demethylases TET1 and TET3, causing epigenetic modifications of YAP target genes and further exacerbating Hippo pathway dysregulation. Together, this establishes a YAP-OPA1-TET1/3-mediated positive feedback loop between the nucleus and mitochondria that drives drug resistance. Crucially, targeting OPA1 disrupted this loop and reversed stiffness-induced chemoresistance. These findings reveal a novel mitochondrial-nuclear communication, offering new insights for overcoming chemoresistance in prostate cancer.

• Publication year

  2025

• Venue

  iScience

• Publication date

  2025-11-01

• Fields of study

  Biology, Medicine

• Identifiers
  DOI 10.1016/j.isci.2025.113996PMID 41362610PMCID 12682049
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• The mitochondrial unfolded protein response inhibits pluripotency acquisition and mesenchymal-to-epithelial transition in somatic cell reprogramming

  2025cited by this paper
• The Warburg effect: the hacked mitochondrial-nuclear communication in cancer.

  2025cited by this paper
• Revealing the landscape of targeting mitochondrial functions and behaviors to overcome cancer chemoresistance

  2025cited by this paper
• Cellular ATP demand creates metabolically distinct subpopulations of mitochondria

  2024cited by this paper
• OPA1 promotes ferroptosis by augmenting mitochondrial ROS and suppressing an integrated stress response.

  2024cited by this paper
• Chronic stress dysregulates the Hippo/YAP/14-3-3η pathway and induces mitochondrial damage in basolateral amygdala in a mouse model of depression

  2024cited by this paper
• Extracellular matrix stiffness as an energy metabolism regulator drives osteogenic differentiation in mesenchymal stem cells

  2024cited by this paper
• TET2-mediated tumor cGAS triggers endothelial STING activation to regulate vasculature remodeling and anti-tumor immunity in liver cancer

  2024cited by this paper
• TET Enzymes in the Immune System: From DNA Demethylation to Immunotherapy, Inflammation, and Cancer.

  2024cited by this paper
• The Hippo pathway: Organ size control and beyond.

  2024cited by this paper
• YAP1 preserves tubular mitochondrial quality control to mitigate diabetic kidney disease

  2024cited by this paper
• The Extracellular Matrix: Its Composition, Function, Remodeling, and Role in Tumorigenesis

  2023cited by this paper
• A defect in mitochondrial protein translation influences mitonuclear communication in the heart

  2023cited by this paper
• Targeting Hippo signaling in cancer: novel perspectives and therapeutic potential

  2023cited by this paper
• Matrix Stiffness Triggers Lipid Metabolic Cross-talk between Tumor and Stromal Cells to Mediate Bevacizumab Resistance in Colorectal Cancer Liver Metastases

  2023cited by this paper
• YAP governs cellular adaptation to perturbation of glutamine metabolism by regulating ATF4-mediated stress response

  2023cited by this paper
• Endoplasmic reticulum-mitochondrial calcium transport contributes to soft extracellular matrix-triggered mitochondrial dynamics and mitophagy in breast carcinoma cells.

  2023cited by this paper
• MFN2 suppresses clear cell renal cell carcinoma progression by modulating mitochondria‐dependent dephosphorylation of EGFR

  2023cited by this paper
• 2022 Update on Prostate Cancer Epidemiology and Risk Factors-A Systematic Review.

  2023cited by this paper
• Novel tumor therapy strategies targeting endoplasmic reticulum-mitochondria signal pathways.

  2023cited by this paper
• Determinants and outcomes of mitochondrial dynamics.

  2023cited by this paper
• Mitochondrial-to-nuclear communication in aging: an epigenetic perspective.

  2022cited by this paper
• Mitochondrial fission links ECM mechanotransduction to metabolic redox homeostasis and metastatic chemotherapy resistance

  2022cited by this paper
• Inhibition of the mitochondrial protein Opa1 curtails breast cancer growth

  2022cited by this paper
• Targeting extracellular matrix stiffness and mechanotransducers to improve cancer therapy

  2022cited by this paper
• FUNDC2 promotes liver tumorigenesis by inhibiting MFN1-mediated mitochondrial fusion

  2022cited by this paper
• Mitochondrial adaptation in cancer drug resistance: prevalence, mechanisms, and management

  2022cited by this paper
• Reprogramming of glutamine metabolism and its impact on immune response in the tumor microenvironment

  2022cited by this paper
• Roles of focal adhesion proteins in skeleton and diseases

  2022cited by this paper
• Taxanes in cancer treatment: Activity, chemoresistance and its overcoming.

  2021cited by this paper
• Activation of Hippo signaling pathway mediates mitochondria dysfunction and dilated cardiomyopathy in mice

  2021cited by this paper
• PGRMC1-dependent lipophagy promotes ferroptosis in paclitaxel-tolerant persister cancer cells

  2021cited by this paper
• The matrix in cancer

  2021cited by this paper
• Global Cancer Statistics 2020: GLOBOCAN Estimates of Incidence and Mortality Worldwide for 36 Cancers in 185 Countries

  2021cited by this paper
• Effects of extracellular matrix viscoelasticity on cellular behaviour

  2020cited by this paper
• Mitochondrial Fusion: The Machineries In and Out.

  2020cited by this paper
• Developmental and Tumor Angiogenesis Requires the Mitochondria-Shaping Protein Opa1.

  2020cited by this paper
• AIM2 promotes the development of non-small cell lung cancer by modulating mitochondrial dynamics

  2020cited by this paper
• Neutrophil Extracellular Traps Drive Mitochondrial Homeostasis in Tumors to Augment Growth.

  2019cited by this paper
• The role of YAP/TAZ activity in cancer metabolic reprogramming

  2018cited by this paper
• Hippo–YAP/TAZ signalling in organ regeneration and regenerative medicine

  2018cited by this paper
• Glutamine Metabolism in Cancer: Understanding the Heterogeneity.

  2017cited by this paper
• TET-Mediated Sequestration of miR-26 Drives EZH2 Expression and Gastric Carcinogenesis.

  2017cited by this paper
• Mitochondrial Dynamics and Metabolic Regulation.

  2016cited by this paper
• Mito-Morphosis: Mitochondrial Fusion, Fission, and Cristae Remodeling as Key Mediators of Cellular Function.

  2016cited by this paper
• Immunosuppressive plasma cells impede T cell-dependent immunogenic chemotherapy

  2015cited by this paper
• Hypoxia-inducible factor 1α (HIF-1α) and reactive oxygen species (ROS) mediates radiation-induced invasiveness through the SDF-1α/CXCR4 pathway in non-small cell lung carcinoma cells

  2015cited by this paper
• Mutations causing mitochondrial disease: What is new and what challenges remain?

  2015cited by this paper
• Influence of tumour micro-environment heterogeneity on therapeutic response

  2013cited by this paper
• Inactivation of the Hippo tumour suppressor pathway by integrin-linked kinase

  2013cited by this paper
• Androgen receptors in hormone-dependent and castration-resistant prostate cancer.

  2013cited by this paper
• Role of YAP/TAZ in mechanotransduction

  2011cited by this paper
• Deletion of Tet2 in mice leads to dysregulated hematopoietic stem cells and subsequent development of myeloid malignancies.

  2011cited by this paper
• Insulin-like growth factor-I-dependent up-regulation of ZEB1 drives epithelial-to-mesenchymal transition in human prostate cancer cells.

  2008cited by this paper

• Mechanical forces orchestrate the epigenetic landscape of oral mesenchymal stem/progenitor cell fate in dental and periodontal tissues

  2026cites this paper