PO.MCB09.01 · 分子与细胞生物学

MEX3A sustains mitochondrial integrity and metabolic resilience to drive ovarian clear cell carcinoma progression and liver colonization

编号 2032 展板 25 时间 4/20 09:00–12:00 区域 Section 24 主讲 Priyanka Vinothkumar, B Eng;MS
分会场 Metabolic Regulation in Breast and Gynecologic Cancers
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作者与单位

Priyanka Vinothkumar1, Pei-Yi Lin2, Li-Tzu Cheng3, Chen-Hsin Albert Yu4, Pang-Hung Hsu5, Yu-Chi Chou6, Wendy W. Hwang-Verslues7

1Molecular and Cell Biology, Taiwan International Graduate Program, Academia Sinica; Graduate Institute of Life Sciences, National Defense Medical University, Genomics Research Center, Academia Sinica, Taipei, Taiwan,2Genomics Research Center, Genomics Research Center, Academia Sinica, Taipei, Taiwan,3Graduate Institute of Life Sciences, National Defense Medical University, Taipei, Taiwan,4Institute of Molecular Biology, Taipei, Taiwan,5Department of Bioscience and Biotechnology, Department of Bioscience and Biotechnology, National Taiwan Ocean University Keelung City, Keelung, Taiwan,6Biomedical Translation Research Center, Academia Sinica, Taipei, Taiwan,7Genomics Research Center, Academia Sinica, Taipei, Taiwan

摘要 Abstract

Background and Aim: Ovarian clear cell carcinomaOCCC is a metabolically distinct and chemo-resistant subtype of ovarian cancer characterized by poor prognosis and high recurrence rates. OCCC exhibits unique metabolic adaptations that enables survival under nutrient deprivation and oxidative stresses. Mitochondrial integrity is central to this adaptive capacity, yet the molecular mechanisms that preserve mitochondrial homeostasis in OCCC remain poorly defined. Recent evidence has identified the RNA-binding protein MEX3A as an oncogenic regulator in several cancers, including OCCC, where it promotes tumor progression. However, its role in regulating mitochondrial metabolism and stress adaptation is largely unexplored. This study aims to elucidate whether and how MEX3A sustains mitochondrial homeostasis to drive OCCC progression, focusing on its impact on tumor growth, mitochondrial structure and transcriptional responses to metabolic and mitochondrial stress. Methods: Endogenous MEX3A protein levels were evaluated across an OCCC cell panel by western blotting. Stable MEX3A knockdown and control cells were generated using a lentivirus shRNA system. Functional studies were performed using OCCC cell lines TOV21G,JHOC5 and in vivo orthotopic intrabursa and intrasplenic xenograft models to assess tumor growth and liver colonization. Mitochondrial function was analyzed by Seahorse metabolic flux assays, ATP quantification and NAD + /NADH measurements. Morphological and ultrastructural alterations were examined by confocal and transmission electron microscopy. Mitochondrial biogenesis genes and mitophagy markers were assessed by qPCR and immunoblotting. Results: MEX3A expression was significantly elevated in OCCC tissues and correlated with poor overall survival. Knockdown of MEX3A in OCCC cells markedly reduced primary tumor growth and significantly reduced the number of liver metastatic nodules in mouse models, demonstrating its functional importance for metastatic colonization. At the cellular level, MEX3A depletion led to loss of mitochondrial cristae integrity, fragmented morphology, reduced oxygen consumption and decreased ATP generation, indicating a dysfunctional in oxidative phosphorylation. Under mitochondrial stress induced by FCCP or liver-extract, control cells activated transcriptional programs for mitochondrial biogenesis, upregulating PGC1A, NRF2 and TFAM. In contrast, MEX3A-deficient cells failed to induce this adaptive response, leading to TOM20 degradation and defective mitochondrial recovery. Conclusion: Our study reveals MEX3A as a crucial RNA-binding protein that preserves mitochondrial integrity and enables metabolic adaptation in OCCC. By sustaining mitochondrial biogenesis and recovery following stress, MEX3A enhances OCCC fitness, tumor growth and liver colorization
利益披露 Disclosure
P. Vinothkumar, None.. P. Lin, None.. L. Cheng, None.. C. Albert Yu, None.. P. Hsu, None.. Y. Chou, None.. W. W. Hwang-Verslues, None.

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