Scopus İndeksli Yayınlar Koleksiyonu / Scopus Indexed Publications Collection

Permanent URI for this collectionhttps://hdl.handle.net/11147/7148

Browse

Filters

2007 - 200912010 - 201912020 - 20251

Settings

Subject: search.filters.subject.MitochondriaWoS Q: search.filters.wosQuartile.Q1

Search Results

Now showing 1 - 3 of 3
  • 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, Anna
    BackgroundMetabolic 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: 12
    Citation - Scopus: 12
    Identification of Respiratory Chain Gene Mutations That Shorten Replicative Life Span in Yeast
    (Elsevier Ltd., 2012) Hacıoğlu, Elise; Demir, Ayşe Banu; Koç, Ahmet
    Aging is the progressive accumulation of alterations in cells that elevates the risk of death. The mitochondrial theory of aging postulates that free radicals produced by the mitochondrial respiratory system contribute to the aging process. However, the roles of individual electron transfer chain (ETC) components in cellular aging have not been elucidated. In this study, we analyzed the replicative life span of 73 yeast deletion mutants lacking the genes of the mitochondrial electron transfer chain system, and found that nine of these mutants (δ nde1, δ tcm62, δ rip1, δ cyt1, δ qrc8, δ pet117, δ cox11, δ atp11, δ fmc1) had significantly shorter life spans. These mutants had lower rates of respiration and were slightly sensitive to exogenous administration of hydrogen peroxide. However, only two of them, δ nde1 and δ fmc1, produced higher amounts of intrinsic superoxide radicals in the presence of glucose compared to that of wild type cells. Interestingly, there were no significant alterations in the mitochondrial membrane potentials of these mutants. We speculate that the shorter life spans of ETC mutants result from multiple mechanisms including the low respiration rate and low energy production rather than just a ROS-dependent path. © 2011 Elsevier Inc.
  • Article
    Citation - WoS: 59
    Citation - Scopus: 60
    Effects of Deleting Mitochondrial Antioxidant Genes on Life Span
    (John Wiley and Sons Inc., 2007) Ünlü, Ercan Selçuk; Koç, Ahmet
    Reactive oxygen species (ROS) damage biomolecules, accelerate aging, and shorten life span, whereas antioxidant enzymes mitigate these effects. Because mitochondria are a primary site of ROS generation and also a primary target of ROS attack, they have become a major focus area of aging studies. Here, we employed yeast genetics to identify mitochondrial antioxidant genes that are important for replicative life span. In our studies, it was found that among the known mitochondrial antioxidant genes (TTR1, CCD1, SOD1, GLO4, TRR2, TRX3, CCS1, SOD2, GRX5, PRX1), deletion of only three genes, SOD1 (Cu, Zn superoxide dismutase), SOD2 (Manganese-containing superoxide dismutase), and CCS1 (Copper chaperone), shortened the life span enormously. The life span decreased 40% for Δsod1 mutant, 72% for Δsod2 mutant, and 50% for Δccs1 mutant. Deletion of the other genes had little or no effect on life span.