PubMed İndeksli Yayınlar Koleksiyonu / PubMed Indexed Publications Collection
Permanent URI for this collectionhttps://hdl.handle.net/11147/7645
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Article Subtype-Specific Divergent Roles of Calpain-1 and Calpain-2 in Basal a Triple-Negative Breast Cancer(BMC, 2025) Uner, Goklem; Oztarhan, Gokhan; Kirmizibayrak, Petek BallarBackgroundCAPN-1 and CAPN-2, two ubiquitously expressed calpains, have been implicated in cancer progression, but their distinct roles in breast cancer remain poorly defined. This study aims to define the opposing roles of CAPN-1 and CAPN-2 in breast cancer progression, with a focus on their regulatory impact on cell proliferation. Since these calpains may have different functions in the mammary gland, we aimed to investigate the possible antagonistic roles of CAPN-1 and CAPN-2 in breast cancer progression, focusing on their expression patterns and functional impact on cell proliferation.Methods and resultsWe analyzed breast cancer cell lines using immunoblotting and real-time cellular assays, showing that HCC1937 cells exhibit an opposite expression pattern of CAPN-1 and CAPN-2 compared to non-cancerous breast cells. CAPN-1 promoted cancer cell survival and negatively regulated CAPN-2 at both the protein and mRNA levels, whereas CAPN-2 suppressed proliferation. Additionally, the calpain activator AG-08 triggered cell death through CAPN-2 but not CAPN-1. In silico analysis confirmed higher CAPN-1 and lower CAPN-2 expression levels in breast cancer samples compared to normal tissue.ConclusionsThese findings indicate that CAPN-1 and CAPN-2 may exert antagonistic roles in breast cancer, but importantly, this effect was restricted to HCC1937 cells, representing a basal A TNBC subtype. Validation in additional basal A models and patient-derived samples will be essential to confirm these results. Our study, therefore, provides preliminary, model-specific insights into calpain regulation in TNBC and suggests that future therapeutic strategies should carefully account for subtype heterogeneity.Article Disruption of Glutamine Transport Uncouples the NUPR1 Stress-Adaptation Program and Induces Prostate Cancer Radiosensitivity(BMC, 2025) Kahya, Ugur; Lukiyanchuk, Vasyl; Gorodetska, Ielizaveta; Weigel, Matthias M.; Koeseer, Ayse Sedef; Alkan, Berke; Dubrovska, AnnaBackgroundMetabolic and stress response adaptations in prostate cancer (PCa) mediate tumor resistance to radiation therapy (RT). Our study investigated the roles of glutamine (Gln) transporters SLC1A5, SLC7A5, and SLC38A1 in regulating NUPR1-mediated stress response, PCa cell survival, metabolic reprogramming, and response to RT.MethodsThe radiosensitizing potential of GLS inhibition with CB-839 was analyzed in prostate cancer xenograft models. The level of gene expression was analyzed by RNA sequencing and RT-qPCR in the established cell lines or patient-derived tumor and adjacent non-cancerous tissues. Phosphoproteomic analysis was employed to identify the underlying signaling pathways. The publicly available PCa patient datasets, and a dataset for the patients treated with RT were analyzed by SUMO software. The key parameters of mitochondrial functions were measured by Seahorse analysis. Analysis of the general oxidative stress level and mitochondrial superoxide detection were conducted using flow cytometry. gamma H2A.X foci analysis was used to assess the DNA double strand break. Relative cell sensitivity to RT was evaluated by radiobiological clonogenic assays. Aldefluor assay and sphere-forming analysis were used to determine cancer stem cell (CSC) phenotype.ResultsA siRNA-mediated knockdown of Gln transporters SLC1A5, SLC7A5, and SLC38A1 resulted in significant radiosensitization of PCa cells. Consistently, the first-in-clinic glutaminase (GLS) inhibitor CB-839, combined with RT, demonstrated a synergistic effect with radiotherapy in vivo, significantly delaying tumor growth. Inhibition of Gln metabolism or knockdown of Gln transporters SLC1A5, SLC7A5, or SLC38A1 induces expression of NUPR1, a stress response transcriptional regulator, but simultaneously uncouples the NUPR1-driven metabolic stress-adaptation program. Similarly to the effect from NUPR1 knockdown, depletion of these Gln transporters led to reduced cell viability, accumulation of mitochondrial ROS, and increased PCa radiosensitivity. This effect is more pronounced in PCa cells with high dependency on OXPHOS for energy production.ConclusionsOur work underscores the role of Gln transporters and the NUPR1-mediated stress response in PCa cell survival, oxidative stress, mitochondrial functions, and radioresistance. Our findings provide a potential therapeutic in vivo strategy to enhance the efficacy of RT and suggest a potential synergism between the depletion of Gln transporters or NUPR1 and OXPHOS inhibition.Article Citation - WoS: 1Citation - Scopus: 1Differential Susceptibility and Role for Senescence in Cart Cells Based on Costimulatory Domains(BMC, 2025) Can, Ismail; Siegler, Elizabeth L.; Sirpilla, Olivia L.; Manriquez-Roman, Claudia; Yun, Kun; Stewart, Carli M.; Kenderian, Saad S.Despite the success of chimeric antigen receptor T (CART) cell therapy in hematological malignancies, durable remissions remain low. Here, we report CART senescence as a potential resistance mechanism in 41BB-costimulated CART cell therapy. To mimic cancer relapse, we utilized an in vitro model with repeated CART cell activation cycles followed by rest periods. Using CD19-targeted CART cells with costimulation via 4-1BB-CD3 zeta (BB zeta) or CD28-CD3 zeta (28 zeta), we showed that CART cells undergo functional, phenotypical, and transcriptomic changes of senescence, which is more prominent in BB zeta. We then utilized two additional independent strategies to induce senescence through MYC activation and irradiation. Induction of senescence impaired BB zeta activity but improved 28 zeta activity in preclinical studies. These findings were supported by analyses of independent patient data sets; senescence signatures in CART cell products were associated with non-response to BB zeta but with improved clinical outcomes in 28 zeta treatment. In summary, our study identifies senescence as a potential mechanism of failure predominantly in 41BB-costimulated CART cells.