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2. Amylopectinosis of the fatal epilepsy Lafora disease resists autophagic glycogen catabolism

Author

Jun Wu, Or Kakhlon, Miguel Weil, Alexander Lossos, and Berge A Minassian

Subjects
Medicine (General), R5-920, Genetics, QH426-470
Abstract

In this Correspondence, B. Minassian and colleagues report that GHF201, an autophagy activator shown to diminish abnormal glycogen aggregates in a mouse model of Adult Polyglucosan Body Disease, fails to reduce such accumulations in a mouse model of Lafora disease.

Published
2024
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3. Mitochondrial Dysfunction in Glycogen Storage Disorders (GSDs)

Author

Kumudesh Mishra and Or Kakhlon

Subjects
mitochondrial dysfunction, glycogen storage disorders, reactive oxygen species, oxidative stress, autophagy and mitophagy, myopathy, Microbiology, QR1-502
Abstract

Glycogen storage disorders (GSDs) are a group of inherited metabolic disorders characterized by defects in enzymes involved in glycogen metabolism. Deficiencies in enzymes responsible for glycogen breakdown and synthesis can impair mitochondrial function. For instance, in GSD type II (Pompe disease), acid alpha-glucosidase deficiency leads to lysosomal glycogen accumulation, which secondarily impacts mitochondrial function through dysfunctional mitophagy, which disrupts mitochondrial quality control, generating oxidative stress. In GSD type III (Cori disease), the lack of the debranching enzyme causes glycogen accumulation and affects mitochondrial dynamics and biogenesis by disrupting the integrity of muscle fibers. Malfunctional glycogen metabolism can disrupt various cascades, thus causing mitochondrial and cell metabolic dysfunction through various mechanisms. These dysfunctions include altered mitochondrial morphology, impaired oxidative phosphorylation, increased production of reactive oxygen species (ROS), and defective mitophagy. The oxidative burden typical of GSDs compromises mitochondrial integrity and exacerbates the metabolic derangements observed in GSDs. The intertwining of mitochondrial dysfunction and GSDs underscores the complexity of these disorders and has significant clinical implications. GSD patients often present with multisystem manifestations, including hepatomegaly, hypoglycemia, and muscle weakness, which can be exacerbated by mitochondrial impairment. Moreover, mitochondrial dysfunction may contribute to the progression of GSD-related complications, such as cardiomyopathy and neurocognitive deficits. Targeting mitochondrial dysfunction thus represents a promising therapeutic avenue in GSDs. Potential strategies include antioxidants to mitigate oxidative stress, compounds that enhance mitochondrial biogenesis, and gene therapy to correct the underlying mitochondrial enzyme deficiencies. Mitochondrial dysfunction plays a critical role in the pathophysiology of GSDs. Recognizing and addressing this aspect can lead to more comprehensive and effective treatments, improving the quality of life of GSD patients. This review aims to elaborate on the intricate relationship between mitochondrial dysfunction and various types of GSDs. The review presents challenges and treatment options for several GSDs.

Published
2024
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6. The Autophagic Activator GHF-201 Can Alleviate Pathology in a Mouse Model and in Patient Fibroblasts of Type III Glycogenosis

Author

Kumudesh Mishra, Sahar Sweetat, Saja Baraghithy, Uri Sprecher, Monzer Marisat, Sultan Bastu, Hava Glickstein, Joseph Tam, Hanna Rosenmann, Miguel Weil, Edoardo Malfatti, and Or Kakhlon

Subjects
glycogen, glycogen storage disease type III, pharmacotherapy, Microbiology, QR1-502
Abstract

Glycogen storage disease type III (GSDIII) is a hereditary glycogenosis caused by deficiency of the glycogen debranching enzyme (GDE), an enzyme, encoded by Agl, enabling glycogen degradation by catalyzing alpha-1,4-oligosaccharide side chain transfer and alpha-1,6-glucose cleavage. GDE deficiency causes accumulation of phosphorylase-limited dextrin, leading to liver disorder followed by fatal myopathy. Here, we tested the capacity of the new autophagosomal activator GHF-201 to alleviate disease burden by clearing pathogenic glycogen surcharge in the GSDIII mouse model Agl−/−. We used open field, grip strength, and rotarod tests for evaluating GHF-201’s effects on locomotion, a biochemistry panel to quantify hematological biomarkers, indirect calorimetry to quantify in vivo metabolism, transmission electron microscopy to quantify glycogen in muscle, and fibroblast image analysis to determine cellular features affected by GHF-201. GHF-201 was able to improve all locomotion parameters and partially reversed hypoglycemia, hyperlipidemia and liver and muscle malfunction in Agl−/− mice. Treated mice burnt carbohydrates more efficiently and showed significant improvement of aberrant ultrastructural muscle features. In GSDIII patient fibroblasts, GHF-201 restored mitochondrial membrane polarization and corrected lysosomal swelling. In conclusion, GHF-201 is a viable candidate for treating GSDIII as it recovered a wide range of its pathologies in vivo, in vitro, and ex vivo.

Published
2024
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7. A New Tailored Nanodroplet Carrier of Astaxanthin Can Improve Its Pharmacokinetic Profile and Antioxidant and Anti-Inflammatory Efficacies

Author

Kumudesh Mishra, Nadin Khatib, Dinorah Barasch, Pradeep Kumar, Sharon Garti, Nissim Garti, and Or Kakhlon

Subjects
astaxanthin, nanodroplet formulations, oxidative damage, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

Astaxanthin (ATX) is a carotenoid nutraceutical with poor bioavailability due to its high lipophilicity. We tested a new tailored nanodroplet capable of solubilizing ATX in an oil-in-water micro-environment (LDS-ATX) for its capacity to improve the ATX pharmacokinetic profile and therapeutic efficacy. We used liquid chromatography tandem mass spectrometry (LC-MS/MS) to profile the pharmacokinetics of ATX and LDS-ATX, superoxide mutase (SOD) activity to determine their antioxidant capacity, protein carbonylation and lipid peroxidation to compare their basal and lipopolysaccharide (LPS)-induced oxidative damage, and ELISA-based detection of IL-2 and IFN-γ to determine their anti-inflammatory capacity. ATX and LDS-ATX corrected only LPS-induced SOD inhibition and oxidative damage. SOD activity was restored only by LDS-ATX in the liver and brain and by both ATX and LDS-ATX in muscle. While in the liver and muscle, LDS-ATX attenuated oxidative damage to proteins and lipids better than ATX; only oxidative damage to lipids was preferably corrected by LDS-ATX in the brain. IL-2 and IFN-γ pro-inflammatory response was corrected by LDS-ATX and not ATX in the liver and brain, but in muscle, the IL-2 response was not corrected and the IFN-γ response was mitigated by both. These results strongly suggest an organ-dependent improvement of ATX bioavailability and efficacy by the LDS-ATX nanoformulation.

Published
2024
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9. The Autophagic Activator GHF-201 can Alleviate Pathology in a Mouse Model and in Patient Fibroblasts of Type III Glycogenosis

Author

Mishra, Kumudesh, primary, Sweetat, Sahar, additional, Baraghithy, Saja, additional, Sprecher, Uri, additional, Marisat, Monzer, additional, Bastu, Sultan, additional, Glickstein, Hava, additional, Tam, Joseph, additional, Rosenmann, Hanna, additional, Weil, Miguel, additional, Malfatti, Edoardo, additional, and Kakhlon, Or, additional

Published
2024
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10. Mitochondrial Dysfunction in Glycogen Storage Disorders (GSDs).

Author

Mishra, Kumudesh and Kakhlon, Or

Subjects
*PULLULANASE, *MITOCHONDRIAL dynamics, *GLYCOGEN storage disease type II, *ENZYME deficiency, *REACTIVE oxygen species
Abstract

Glycogen storage disorders (GSDs) are a group of inherited metabolic disorders characterized by defects in enzymes involved in glycogen metabolism. Deficiencies in enzymes responsible for glycogen breakdown and synthesis can impair mitochondrial function. For instance, in GSD type II (Pompe disease), acid alpha-glucosidase deficiency leads to lysosomal glycogen accumulation, which secondarily impacts mitochondrial function through dysfunctional mitophagy, which disrupts mitochondrial quality control, generating oxidative stress. In GSD type III (Cori disease), the lack of the debranching enzyme causes glycogen accumulation and affects mitochondrial dynamics and biogenesis by disrupting the integrity of muscle fibers. Malfunctional glycogen metabolism can disrupt various cascades, thus causing mitochondrial and cell metabolic dysfunction through various mechanisms. These dysfunctions include altered mitochondrial morphology, impaired oxidative phosphorylation, increased production of reactive oxygen species (ROS), and defective mitophagy. The oxidative burden typical of GSDs compromises mitochondrial integrity and exacerbates the metabolic derangements observed in GSDs. The intertwining of mitochondrial dysfunction and GSDs underscores the complexity of these disorders and has significant clinical implications. GSD patients often present with multisystem manifestations, including hepatomegaly, hypoglycemia, and muscle weakness, which can be exacerbated by mitochondrial impairment. Moreover, mitochondrial dysfunction may contribute to the progression of GSD-related complications, such as cardiomyopathy and neurocognitive deficits. Targeting mitochondrial dysfunction thus represents a promising therapeutic avenue in GSDs. Potential strategies include antioxidants to mitigate oxidative stress, compounds that enhance mitochondrial biogenesis, and gene therapy to correct the underlying mitochondrial enzyme deficiencies. Mitochondrial dysfunction plays a critical role in the pathophysiology of GSDs. Recognizing and addressing this aspect can lead to more comprehensive and effective treatments, improving the quality of life of GSD patients. This review aims to elaborate on the intricate relationship between mitochondrial dysfunction and various types of GSDs. The review presents challenges and treatment options for several GSDs. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Metabolomic profiling of triple negative breast cancer cells suggests that valproic acid can enhance the anticancer effect of cisplatin

Author

Avital Granit, Kumudesh Mishra, Dinorah Barasch, Tamar Peretz-Yablonsky, Sara Eyal, and Or Kakhlon

Subjects
valproic acid, metabolomics, metabolism, cisplalin, triple negative breast cancer, Biology (General), QH301-705.5
Abstract

Cisplatin is an effective chemotherapeutic agent for treating triple negative breast cancer (TNBC). Nevertheless, cisplatin-resistance might develop during the course of treatment, allegedly by metabolic reprograming, which might influence epigenetic regulation. We hypothesized that the histone deacetylase inhibitor (HDACi) valproic acid (VPA) can counter the cisplatin-induced metabolic changes leading to its resistance. We performed targeted metabolomic and real time PCR analyses on MDA-MB-231 TNBC cells treated with cisplatin, VPA or their combination. 22 (88%) out of the 25 metabolites most significantly modified by the treatments, were acylcarnitines (AC) and three (12%) were phosphatidylcholines (PCs). The most discernible effects were up-modulation of AC by cisplatin and, contrarily, their down-modulation by VPA, which was partial in the VPA-cisplatin combination. Furthermore, the VPA-cisplatin combination increased PCs, sphingomyelins (SM) and hexose levels, as compared to the other treatments. These changes predicted modulation of different metabolic pathways, notably fatty acid degradation, by VPA. Lastly, we also show that the VPA-cisplatin combination increased mRNA levels of the fatty acid oxidation (FAO) promoting enzymes acyl-CoA synthetase long chain family member 1 (ACSL1) and decreased mRNA levels of fatty acid synthase (FASN), which is the rate limiting enzyme of long-chain fatty acid synthesis. In conclusion, VPA supplementation altered lipid metabolism, especially fatty acid oxidation and lipid synthesis, in cisplatin-treated MDA-MB-231 TNBC cells. This metabolic reprogramming might reduce cisplatin resistance. This finding may lead to the discovery of new therapeutic targets, which might reduce side effects and counter drug tolerance in TNBC patients.

Published
2022
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15. Alleviation of a polyglucosan storage disorder by enhancement of autophagic glycogen catabolism

Author

Or Kakhlon, Hilla Vaknin, Kumudesh Mishra, Jeevitha D’Souza, Monzer Marisat, Uri Sprecher, Shane Wald‐Altman, Anna Dukhovny, Yuval Raviv, Benny Da’adoosh, Hamutal Engel, Sandrine Benhamron, Keren Nitzan, Sahar Sweetat, Anna Permyakova, Anat Mordechai, Hasan Orhan Akman, Hanna Rosenmann, Alexander Lossos, Joseph Tam, Berge A. Minassian, and Miguel Weil

Subjects
adult polyglucosan body disease, autophagy, glycogen, lysosomes, polyglucosan, Medicine (General), R5-920, Genetics, QH426-470
Abstract

Abstract This work employs adult polyglucosan body disease (APBD) models to explore the efficacy and mechanism of action of the polyglucosan‐reducing compound 144DG11. APBD is a glycogen storage disorder (GSD) caused by glycogen branching enzyme (GBE) deficiency causing accumulation of poorly branched glycogen inclusions called polyglucosans. 144DG11 improved survival and motor parameters in a GBE knockin (Gbeys/ys) APBD mouse model. 144DG11 reduced polyglucosan and glycogen in brain, liver, heart, and peripheral nerve. Indirect calorimetry experiments revealed that 144DG11 increases carbohydrate burn at the expense of fat burn, suggesting metabolic mobilization of pathogenic polyglucosan. At the cellular level, 144DG11 increased glycolytic, mitochondrial, and total ATP production. The molecular target of 144DG11 is the lysosomal membrane protein LAMP1, whose interaction with the compound, similar to LAMP1 knockdown, enhanced autolysosomal degradation of glycogen and lysosomal acidification. 144DG11 also enhanced mitochondrial activity and modulated lysosomal features as revealed by bioenergetic, image‐based phenotyping and proteomics analyses. As an effective lysosomal targeting therapy in a GSD model, 144DG11 could be developed into a safe and efficacious glycogen and lysosomal storage disease therapy.

Published
2021
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16. The Beneficial Effect of Mitochondrial Transfer Therapy in 5XFAD Mice via Liver–Serum–Brain Response

Author

Sahar Sweetat, Keren Nitzan, Nir Suissa, Yael Haimovich, Michal Lichtenstein, Samar Zabit, Sandrine Benhamron, Karameh Akarieh, Kumudesh Mishra, Dinorah Barasch, Ann Saada, Tamar Ziv, Or Kakhlon, Haya Lorberboum-Galski, and Hanna Rosenmann

Subjects
mitochondria, Alzheimer’s disease, mitochondrial transfer, 5XFAD, amyloid, cognition, Cytology, QH573-671
Abstract

We recently reported the benefit of the IV transferring of active exogenous mitochondria in a short-term pharmacological AD (Alzheimer’s disease) model. We have now explored the efficacy of mitochondrial transfer in 5XFAD transgenic mice, aiming to explore the underlying mechanism by which the IV-injected mitochondria affect the diseased brain. Mitochondrial transfer in 5XFAD ameliorated cognitive impairment, amyloid burden, and mitochondrial dysfunction. Exogenously injected mitochondria were detected in the liver but not in the brain. We detected alterations in brain proteome, implicating synapse-related processes, ubiquitination/proteasome-related processes, phagocytosis, and mitochondria-related factors, which may lead to the amelioration of disease. These changes were accompanied by proteome/metabolome alterations in the liver, including pathways of glucose, glutathione, amino acids, biogenic amines, and sphingolipids. Altered liver metabolites were also detected in the serum of the treated mice, particularly metabolites that are known to affect neurodegenerative processes, such as carnosine, putrescine, C24:1-OH sphingomyelin, and amino acids, which serve as neurotransmitters or their precursors. Our results suggest that the beneficial effect of mitochondrial transfer in the 5XFAD mice is mediated by metabolic signaling from the liver via the serum to the brain, where it induces protective effects. The high efficacy of the mitochondrial transfer may offer a novel AD therapy.

Published
2023
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17. The Autophagic Activator GHF-201 Can Alleviate Pathology in a Mouse Model and in Patient Fibroblasts of Type III Glycogenosis.

Author

Mishra, Kumudesh, Sweetat, Sahar, Baraghithy, Saja, Sprecher, Uri, Marisat, Monzer, Bastu, Sultan, Glickstein, Hava, Tam, Joseph, Rosenmann, Hanna, Weil, Miguel, Malfatti, Edoardo, and Kakhlon, Or

Subjects
GLYCOGEN storage disease, PULLULANASE, TRANSMISSION electron microscopy, GRIP strength, MITOCHONDRIAL membranes
Abstract

Glycogen storage disease type III (GSDIII) is a hereditary glycogenosis caused by deficiency of the glycogen debranching enzyme (GDE), an enzyme, encoded by Agl, enabling glycogen degradation by catalyzing alpha-1,4-oligosaccharide side chain transfer and alpha-1,6-glucose cleavage. GDE deficiency causes accumulation of phosphorylase-limited dextrin, leading to liver disorder followed by fatal myopathy. Here, we tested the capacity of the new autophagosomal activator GHF-201 to alleviate disease burden by clearing pathogenic glycogen surcharge in the GSDIII mouse model Agl−/−. We used open field, grip strength, and rotarod tests for evaluating GHF-201's effects on locomotion, a biochemistry panel to quantify hematological biomarkers, indirect calorimetry to quantify in vivo metabolism, transmission electron microscopy to quantify glycogen in muscle, and fibroblast image analysis to determine cellular features affected by GHF-201. GHF-201 was able to improve all locomotion parameters and partially reversed hypoglycemia, hyperlipidemia and liver and muscle malfunction in Agl−/− mice. Treated mice burnt carbohydrates more efficiently and showed significant improvement of aberrant ultrastructural muscle features. In GSDIII patient fibroblasts, GHF-201 restored mitochondrial membrane polarization and corrected lysosomal swelling. In conclusion, GHF-201 is a viable candidate for treating GSDIII as it recovered a wide range of its pathologies in vivo, in vitro, and ex vivo. [ABSTRACT FROM AUTHOR]

Published
2024
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18. A New Tailored Nanodroplet Carrier of Astaxanthin Can Improve Its Pharmacokinetic Profile and Antioxidant and Anti-Inflammatory Efficacies.

Author

Mishra, Kumudesh, Khatib, Nadin, Barasch, Dinorah, Kumar, Pradeep, Garti, Sharon, Garti, Nissim, and Kakhlon, Or

Subjects
ASTAXANTHIN, LIQUID chromatography-mass spectrometry, PHARMACOKINETICS
Abstract

Astaxanthin (ATX) is a carotenoid nutraceutical with poor bioavailability due to its high lipophilicity. We tested a new tailored nanodroplet capable of solubilizing ATX in an oil-in-water micro-environment (LDS-ATX) for its capacity to improve the ATX pharmacokinetic profile and therapeutic efficacy. We used liquid chromatography tandem mass spectrometry (LC-MS/MS) to profile the pharmacokinetics of ATX and LDS-ATX, superoxide mutase (SOD) activity to determine their antioxidant capacity, protein carbonylation and lipid peroxidation to compare their basal and lipopolysaccharide (LPS)-induced oxidative damage, and ELISA-based detection of IL-2 and IFN-γ to determine their anti-inflammatory capacity. ATX and LDS-ATX corrected only LPS-induced SOD inhibition and oxidative damage. SOD activity was restored only by LDS-ATX in the liver and brain and by both ATX and LDS-ATX in muscle. While in the liver and muscle, LDS-ATX attenuated oxidative damage to proteins and lipids better than ATX; only oxidative damage to lipids was preferably corrected by LDS-ATX in the brain. IL-2 and IFN-γ pro-inflammatory response was corrected by LDS-ATX and not ATX in the liver and brain, but in muscle, the IL-2 response was not corrected and the IFN-γ response was mitigated by both. These results strongly suggest an organ-dependent improvement of ATX bioavailability and efficacy by the LDS-ATX nanoformulation. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Alleviation of a polyglucosan storage disorder by enhancement of autophagic glycogen catabolism

Author

Kakhlon, Or, Vaknin, Hilla, Mishra, Kumudesh, D’Souza, Jeevitha, Marisat, Monzer, Sprecher, Uri, Wald‐Altman, Shane, Dukhovny, Anna, Raviv, Yuval, Da’adoosh, Benny, Engel, Hamutal, Benhamron, Sandrine, Nitzan, Keren, Sweetat, Sahar, Permyakova, Anna, Mordechai, Anat, Akman, Hasan Orhan, Rosenmann, Hanna, Lossos, Alexander, Tam, Joseph, Minassian, Berge A., and Weil, Miguel

Published
2021
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22. Multifaceted Analyses of Isolated Mitochondria Establish the Anticancer Drug 2-Hydroxyoleic Acid as an Inhibitor of Substrate Oxidation and an Activator of Complex IV-Dependent State 3 Respiration

Author

Kumudesh Mishra, Mária Péter, Anna Maria Nardiello, Guy Keller, Victoria Llado, Paula Fernandez-Garcia, Ulf D. Kahlert, Dinorah Barasch, Ann Saada, Zsolt Török, Gábor Balogh, Pablo V. Escriba, Stefano Piotto, and Or Kakhlon

Subjects
2-hydroxyoleic acid, mitochondria, molecular dynamics, respiration, glycolysis, shotgun lipidomics, Cytology, QH573-671
Abstract

The synthetic fatty acid 2-hydroxyoleic acid (2OHOA) has been extensively investigated as a cancer therapy mainly based on its regulation of membrane lipid composition and structure, activating various cell fate pathways. We discovered, additionally, that 2OHOA can uncouple oxidative phosphorylation, but this has never been demonstrated mechanistically. Here, we explored the effect of 2OHOA on mitochondria isolated by ultracentrifugation from U118MG glioblastoma cells. Mitochondria were analyzed by shotgun lipidomics, molecular dynamic simulations, spectrophotometric assays for determining respiratory complex activity, mass spectrometry for assessing beta oxidation and Seahorse technology for bioenergetic profiling. We showed that the main impact of 2OHOA on mitochondrial lipids is their hydroxylation, demonstrated by simulations to decrease co-enzyme Q diffusion in the liquid disordered membranes embedding respiratory complexes. This decreased co-enzyme Q diffusion can explain the inhibition of disjointly measured complexes I–III activity. However, it doesn’t explain how 2OHOA increases complex IV and state 3 respiration in intact mitochondria. This increased respiration probably allows mitochondrial oxidative phosphorylation to maintain ATP production against the 2OHOA-mediated inhibition of glycolytic ATP production. This work correlates 2OHOA function with its modulation of mitochondrial lipid composition, reflecting both 2OHOA anticancer activity and adaptation to it by enhancement of state 3 respiration.

Published
2022
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23. Canonical WNT pathway inhibition reduces ATP synthesis rates in glioblastoma stem cells

Author

Dymphna Margriet Ouwens, Michael Hewera, Guanzhang Li, Wang Di, Sajjad Muhammad, Daniel Hänggi, Hans-Jakob Steiger, Claudia A. Dumitru, Erol Sandalcioglu, Roland S Croner, Wei Zhang, Or Kakhlon, and Ulf D. Kahlert

Subjects
tumor stem cells, wnt, metabolism, bioenergetics, single cell rna sequencing, Biochemistry, QD415-436, Biology (General), QH301-705.5
Abstract

Background: The conserved stem cell signaling network canonical Wingless (WNT) plays important roles in development and disease. Aberrant activation of this pathway has been linked to tumor progression and resistance to therapy. Industry and academia have substantially invested in developing substances, which can efficiently and specifically block the WNT signaling pathway. However, a clear clinical proof of the efficacy of this approach is still missing. Studies on the metabolomics dysregulation of cancer cells have led to innovations in oncological diagnostics. In addition, modulation of cancer cell metabolome is at the base of promising clinical oncology trials currently underway. While onco-protein activation can have profound metabolic outcomes, the involvement of stem cell signals, such as the WNT pathway, in tumor cell metabolomics is yet insufficiently characterized. Material and methods: We determined live cell metabolism and bioenergetics in pathophysiological relevant, WNT-dependent glioblastoma stem cell (GSC) models. We quantified those parameters in cells with canonical WNT activity and in isogenic cells where WNT activity had been inhibited by short hairpin RNA against β-catenin. Furthermore, we applied computational analysis of RNA sequencing to verify our functional findings in independent GSCs cohorts. Results: The investigated collection of disease models allows the separation in tumors with low, moderate and high base line metabolic activity. Suppression of canonical WNT signaling led to significant reduction of total, mitochondrial, and glycolytic ATP production rates. Elevated canonical WNT transcription signature in GSCs positively correlated with transcription levels of mitochondrial ATP synthesis, whereas non-canonical WNT gene expression signature did not. Conclusion: The applied disease modeling technology allows the recapitulation of inter-tumoral heterogeneous metabolic properties of glioblastoma. Our data show for the first time that inhibition of canonical WNT signaling in alive GSCs functionally correlates with energy inhibition and glucose homeostasis. As this correlation occurs in GSCs from different transcriptional or epigenetic transcriptional subtypes, our results suggest that developing therapies directed against glycolysis/ATP-synthesis may be a promising strategy to overcome therapy resistance due to inter-tumoral heterogeneity and offers starting point to impair downstream signal WNT.

Published
2022
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24. Triacylglycerol mimetics regulate membrane interactions of glycogen branching enzyme: implications for therapy

Author

Rafael Alvarez, Jesús Casas, David J. López, Maitane Ibarguren, Ariadna Suari-Rivera, Silvia Terés, Francisca Guardiola-Serrano, Alexander Lossos, Xavier Busquets, Or Kakhlon, and Pablo V. Escribá

Subjects
triglycerides, metabolic disease, diseases, drug therapy, protein-membrane interactions, membrane lipid therapy, Biochemistry, QD415-436
Abstract

Adult polyglucosan body disease (APBD) is a neurological disorder characterized by adult-onset neurogenic bladder, spasticity, weakness, and sensory loss. The disease is caused by aberrant glycogen branching enzyme (GBE) (GBE1Y329S) yielding less branched, globular, and soluble glycogen, which tends to aggregate. We explore here whether, despite being a soluble enzyme, GBE1 activity is regulated by protein-membrane interactions. Because soluble proteins can contact a wide variety of cell membranes, we investigated the interactions of purified WT and GBE1Y329S proteins with different types of model membranes (liposomes). Interestingly, both triheptanoin and some triacylglycerol mimetics (TGMs) we have designed (TGM0 and TGM5) markedly enhance GBE1Y329S activity, possibly enough for reversing APBD symptoms. We show that the GBE1Y329S mutation exposes a hydrophobic amino acid stretch, which can either stabilize and enhance or alternatively, reduce the enzyme activity via alteration of protein-membrane interactions. Additionally, we found that WT, but not Y329S, GBE1 activity is modulated by Ca2+ and phosphatidylserine, probably associated with GBE1-mediated regulation of energy consumption and storage. The thermal stabilization and increase in GBE1Y329S activity induced by TGM5 and its omega-3 oil structure suggest that this molecule has a considerable therapeutic potential for treating APBD.

Published
2017
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25. A differential autophagy-dependent response to DNA double-strand breaks in bone marrow mesenchymal stem cells from sporadic ALS patients

Author

Shane Wald-Altman, Edward Pichinuk, Or Kakhlon, and Miguel Weil

Subjects
ALS, DNA damage response, Autophagy, Human mesenchymal stem cell, Medicine, Pathology, RB1-214
Abstract

Amyotrophic lateral sclerosis (ALS) is an incurable motor neurodegenerative disease caused by a diversity of genetic and environmental factors that leads to neuromuscular degeneration and has pathophysiological implications in non-neural systems. Our previous work showed abnormal levels of mRNA expression for biomarker genes in non-neuronal cell samples from ALS patients. The same genes proved to be differentially expressed in the brain, spinal cord and muscle of the SOD1G93A ALS mouse model. These observations support the idea that there is a pathophysiological relevance for the ALS biomarkers discovered in human mesenchymal stem cells (hMSCs) isolated from bone marrow samples of ALS patients (ALS-hMSCs). Here, we demonstrate that ALS-hMSCs are also a useful patient-based model to study intrinsic cell molecular mechanisms of the disease. We investigated the ALS-hMSC response to oxidative DNA damage exerted by neocarzinostatin (NCS)-induced DNA double-strand breaks (DSBs). We found that the ALS-hMSCs responded to this stress differently from cells taken from healthy controls (HC-hMSCs). Interestingly, we found that ALS-hMSC death in response to induction of DSBs was dependent on autophagy, which was initialized by an increase of phosphorylated (p)AMPK, and blocked by the class III phosphoinositide 3-kinase (PI3K) and autophagy inhibitor 3-methyladenine (3MeA). ALS-hMSC death in response to DSBs was not apoptotic as it was caspase independent. This unique ALS-hMSC-specific response to DNA damage emphasizes the possibility that an intrinsic abnormal regulatory mechanism controlling autophagy initiation exists in ALS-patient-derived hMSCs. This mechanism may also be relevant to the most-affected tissues in ALS. Hence, our approach might open avenues for new personalized therapies for ALS.

Published
2017
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26. The Beneficial Effect of Mitochondrial Transfer Therapy in 5XFAD Mice via Liver–Serum–Brain Response

Author

Sweetat, Sahar, primary, Nitzan, Keren, additional, Suissa, Nir, additional, Haimovich, Yael, additional, Lichtenstein, Michal, additional, Zabit, Samar, additional, Benhamron, Sandrine, additional, Akarieh, Karameh, additional, Mishra, Kumudesh, additional, Barasch, Dinorah, additional, Saada, Ann, additional, Ziv, Tamar, additional, Kakhlon, Or, additional, Lorberboum-Galski, Haya, additional, and Rosenmann, Hanna, additional

Published
2023
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27. Imprinted cell memory in glycogen storage disorder 1a

Author

Sprecher, U, primary, D’Souza, J, additional, Mishra, K, additional, Canella Miliano, A, additional, Mithieux, G, additional, Rajas, F, additional, Avraham, S, additional, Anikster, Y, additional, Kakhlon, O, additional, and Weil, M, additional

Published
2023
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29. Imprinted cell memory in glycogen storage disorder 1a

Author

U Sprecher, J D’Souza, K Mishra, A Canella Miliano, G Mithieux, F Rajas, S Avraham, Y Anikster, O Kakhlon, and M Weil

Abstract

SummaryGlycogen storage disorder type 1a (GSD1a) is caused by loss-of-function mutations in the catalytic subunit of glucose-6-phosphatase enzyme (G6PC1) in the liver, kidney and intestine exclusively. Here we show the surprising results that while not expressingG6PC1, primary skin fibroblasts isolated from GSD1a patients’ skin biopsies preserve a distinctive disease phenotype irrespective of the different culture conditions under which they grow. This discovery was initially made by phenotypic image-based high content analysis (HCA). Deeper analysis into this disease phenotype, revealed impaired lysosomal and mitochondrial functions in GSD1a cells, which were driven by a transcriptional dysregulation of the NAD+/NADH-Sirt1-TFEB regulatory axis. This dysregulation impacts the normal balance between mitochondrial biogenesis and mitophagy in the patients’ cells. The distinctive GSD1a fibroblasts phenotype involves elevated H3 K27 histone acetylation and global DNA hypomethylation suggesting that in some way the disease imprinted a distinctive cell phenotype in these cells. Remarkably, GHF201, an established glycogen reducing molecule, which ameliorated GSD1a pathology in a liver-targeted inducibleL.G6pc-/-knockout mouse model, also reversed impaired cellular functions in GSD1a patients’ fibroblasts. Altogether, this experimental evidence strongly suggests that these cells express a strong and reversible disease phenotype without expressing the causalG6PC1gene.

Published
2023

30. The Implications for Cells of the Lipid Switches Driven by Protein–Membrane Interactions and the Development of Membrane Lipid Therapy

Author

Manuel Torres, Catalina Ana Rosselló, Paula Fernández-García, Victoria Lladó, Or Kakhlon, and Pablo Vicente Escribá

Subjects
protein–membrane interactions, melitherapy, lipid bilayer, membrane lipid switch, peripheral amphitropic non-permanently bound membrane proteins, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

The cell membrane contains a variety of receptors that interact with signaling molecules. However, agonist–receptor interactions not always activate a signaling cascade. Amphitropic membrane proteins are required for signal propagation upon ligand-induced receptor activation. These proteins localize to the plasma membrane or internal compartments; however, they are only activated by ligand-receptor complexes when both come into physical contact in membranes. These interactions enable signal propagation. Thus, signals may not propagate into the cell if peripheral proteins do not co-localize with receptors even in the presence of messengers. As the translocation of an amphitropic protein greatly depends on the membrane’s lipid composition, regulation of the lipid bilayer emerges as a novel therapeutic strategy. Some of the signals controlled by proteins non-permanently bound to membranes produce dramatic changes in the cell’s physiology. Indeed, changes in membrane lipids induce translocation of dozens of peripheral signaling proteins from or to the plasma membrane, which controls how cells behave. We called these changes “lipid switches”, as they alter the cell’s status (e.g., proliferation, differentiation, death, etc.) in response to the modulation of membrane lipids. Indeed, this discovery enables therapeutic interventions that modify the bilayer’s lipids, an approach known as membrane-lipid therapy (MLT) or melitherapy.

Published
2020
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32. Casting iron into the cell fate mold

Author

Or Kakhlon

Subjects
Iron-Sulfur Proteins, Saccharomyces cerevisiae Proteins, Iron, Saccharomyces cerevisiae, Cell, Cell fate determination, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, medicine, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, Activator (genetics), Chemistry, Autophagy, Cell Biology, Metabolism, biology.organism_classification, Amino acid, medicine.anatomical_structure, Fermentation, 030217 neurology & neurosurgery, Transcription Factors
Abstract

This commentary discusses general concepts introduced in the article ‘Bulk autophagy induction and life extension is achieved when iron is the only limited nutrient in Saccharomyces cerevisiae’ by Montella-Manuel et al. (Biochem J (2021) 478: 811–837). Montella-Manuel et al. show that like central carbon metabolism, iron metabolism is also closely implicated in autophagy-mediated life extension via the TORC2 activator Ypk1p and the iron regulator Aft1p. While not being an iron-sulfur cluster protein, Aft1p interacts with such proteins and thus senses the redox status of the cell, which, similar to amino acids and AMP, reports its energetic status. Furthermore, glucose and iron deficiencies are interrelated as the diauxic shift in glucose depleted cells requires iron uptake for activating respiration in the absence of fermentation.

Published
2021

34. Frequent misdiagnosis of adult polyglucosan body disease

Author

Hellmann, Mark A., Kakhlon, Or, Landau, Ezekiel H., Sadeh, Menachem, Giladi, Nir, Schlesinger, Ilana, Kidron, Daphne, Abramsky, Oded, Reches, Avinoam, Argov, Zohar, Rabey, Jose M., Chapman, Joab, Rosenmann, Hanna, Gal, Aya, Moshe Gomori, J., Meiner, Vardiella, and Lossos, Alexander

Published
2015
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35. Multifaceted Analyses of Isolated Mitochondria Establish the Anticancer Drug 2-Hydroxyoleic Acid as an Inhibitor of Substrate Oxidation and an Activator of Complex IV-Dependent State 3 Respiration

Author

Mishra, Kumudesh, primary, Péter, Mária, additional, Nardiello, Anna Maria, additional, Keller, Guy, additional, Llado, Victoria, additional, Fernandez-Garcia, Paula, additional, Kahlert, Ulf D., additional, Barasch, Dinorah, additional, Saada, Ann, additional, Török, Zsolt, additional, Balogh, Gábor, additional, Escriba, Pablo V., additional, Piotto, Stefano, additional, and Kakhlon, Or, additional

Published
2022
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39. A new drug candidates for glycogen storage disorders enhances glycogen catabolism: Lessons from Adult Polyglucosan Body Disease models

Author

Keren Nitzan, Hamutal Engel, Hanna Rosenmann, Miguel Weil, Shane Wald-Altman, Berge A. Minassian, Anna Dukhovny, Benny Da'adoosh, Or Kakhlon, Hilla Vaknin, Marisat M, Yuval Raviv, Alexander Lossos, Sprecher U, D'Souza J, Joseph Tam, Anna Permyakova, Kumudesh Mishra, and Sandrine Benhamron

Subjects
LAMP1, Glycogen, biology, Catabolism, Leukodystrophy, Adult polyglucosan body disease, medicine.disease, Cell biology, chemistry.chemical_compound, chemistry, In vivo, Glycogen branching enzyme, biology.protein, medicine, Glycolysis
Abstract

This work employs Adult Polyglucosan Body Disease (APBD) models to explore the efficacy and mechanism of action of 144DG11, a new polyglucosan-reducing lead compound discovered by a high-throughput screen (HTS). APBD is an adult onset glycogen storage disorder (GSD) manifesting as a debilitating progressive axonopathic leukodystrophy. APBD is caused by glycogen branching enzyme (GBE) deficiency leading to poorly branched and insoluble glycogen inclusions, which precipitate as neuropathogenic polyglucosans (PG). 144DG11 led to prolonged survival and improved motor parameters in a GBE knockin (Gbeys/ys) APBD mouse model. Histopathologically, 144DG11 reduced PG and glycogen levels in brain, liver, heart, and peripheral nerve. Indirect calorimetry experiments revealed that 144DG11 increases carbohydrate burn at the expense of fat burn, suggesting metabolic mobilization of pathogenic PG. These results were also reflected at the cellular level by increased glycolytic, mitochondrial and total ATP production. Mechanistically, we show that the molecular target of 144DG11 is the lysosomal membrane protein LAMP1, whose interaction with the compound, similar to LAMP1 knockdown, enhanced autolysosomal degradation of glycogen and lysosomal acidification. Enhanced mitochondrial activity and lysosomal modifications were also the most pronounced effects of 144DG11 in APBD patient fibroblasts as discovered by image-based multiparametric phenotyping analysis and corroborated by proteomics. In summary, this work presents a broad mechanistic and target-based characterization of 144DG11 in in vivo and cell models of the prototypical GSD APBD. This investigation warrants development of 144DG11 into a safe and efficacious GSD therapy.One Sentence SummaryA new compound, demonstrated to ameliorate APBD in vivo and ex vivo by autophagic catabolism of glycogen, may potentially become a universal drug for glycogen storage disorders.

Published
2021

41. 251st ENMC international workshop: Polyglucosan storage myopathies 13–15 December 2019, Hoofddorp, the Netherlands

Author

Pascal Laforêt, Anders Oldfors, Edoardo Malfatti, John Vissing, Marie-Anne Colle, Jordi Duran, Matthew Gentry, Joan Guinovart, Thomas Hurley, Or Kakhlon, Thomas Krag, Hal Landy, Camilla B. Lilleør, Berge Minassian, Federico Mingozzi, Elaine Murphy, Richard Piercy, Monique Piraud, Vyas Ramanan, Mads Stemmerik, Christer Thomsen, Miguel Weil, Université de Versailles Saint-Quentin-en-Yvelines - UFR Sciences de la santé Simone Veil (UVSQ Santé), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ), European Neuromuscular Centre, ENMC, This workshop was made possible by the financial support of the European Neuromuscular center (ENMC) and ENMC main sponsors, and The organizers are grateful for the valuable support by the ENMC staff especially Managing Director Alexandra Breukel and Operational Manager Annelies Zittersteijn

Subjects
0303 health sciences, Pediatrics, medicine.medical_specialty, business.industry, MEDLINE, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Article, 03 medical and health sciences, 0302 clinical medicine, Neurology, Pediatrics, Perinatology and Child Health, Medicine, Neurology (clinical), business, 030217 neurology & neurosurgery, Genetics (clinical), ComputingMilieux_MISCELLANEOUS, 030304 developmental biology
Abstract

International audience

Published
2021

42. 251st ENMC international workshop:Polyglucosan storage myopathies 13–15 December 2019, Hoofddorp, the Netherlands

Author

Laforêt, Pascal, Oldfors, Anders, Malfatti, Edoardo, Vissing, John, Colle, Marie Anne, Duran, Jordi, Gentry, Matthew, Guinovart, Joan, Hurley, Thomas, Kakhlon, Or, Krag, Thomas, Landy, Hal, Lilleør, Camilla B., Minassian, Berge, Mingozzi, Federico, Murphy, Elaine, Piercy, Richard, Piraud, Monique, Ramanan, Vyas, Stemmerik, Mads, Thomsen, Christer, Weil, Miguel, Laforêt, Pascal, Oldfors, Anders, Malfatti, Edoardo, Vissing, John, Colle, Marie Anne, Duran, Jordi, Gentry, Matthew, Guinovart, Joan, Hurley, Thomas, Kakhlon, Or, Krag, Thomas, Landy, Hal, Lilleør, Camilla B., Minassian, Berge, Mingozzi, Federico, Murphy, Elaine, Piercy, Richard, Piraud, Monique, Ramanan, Vyas, Stemmerik, Mads, Thomsen, Christer, and Weil, Miguel

Published
2021

44. Iron redistribution as a therapeutic strategy for treating diseases of localized iron accumulation

Author

Kakhlon, Or, Breuer, William, Munnich, Arnold, and Cabantchik, Z. Ioav

Subjects
Gene mutations -- Health aspects -- Research -- Genetic aspects, Friedreich's ataxia -- Risk factors -- Research -- Complications and side effects -- Care and treatment -- Genetic aspects, Iron metabolism disorders -- Care and treatment -- Complications and side effects -- Genetic aspects -- Research -- Risk factors, Biological sciences
Abstract

Defective iron utilization leading to either systemic or regional misdistribution of the metal has been identified as a critical feature of several different disorders. Iron concentrations can rise to toxic levels in mitochondria of excitable cells, often leaving the cytosol iron-depleted, in some forms of neurodegeneration with brain accumulation (NBIA) or following mutations in genes associated with mitochondrial functions, such as ABCB7 in X-linked sideroblastic anemia with ataxia (XLSA/A) or the genes encoding frataxin in Friedreich's ataxia (FRDA). In anemia of chronic disease (ACD), iron is withheld by macrophages, while iron levels in extracellular fluids (e.g., plasma) are drastically reduced. One possible therapeutic approach to these diseases is iron chelation, which is known to effectively reduce multiorgan iron deposition in iron-overloaded patients. However, iron chelation is probably inappropriate for disorders associated with misdistribution of iron within selected tissues or cells. One chelator in clinical use for treating iron overload, deferiprone (DFP), has been identified as a reversed siderophore, that is, an agent with iron-relocating abilities in settings of regional iron accumulation. DFP was applied to a cell model of FRDA, a paradigm of a disorder etiologically associated with cellular iron misdistribution. The treatment reduced the mitochondrial levels of labile iron pools (LIP) that were increased by frataxin deficiency. DFP also conferred upon cells protection against oxidative damage and concomitantly mediated the restoration of various metabolic parameters, including aconitase activity. Administration of DFP to FRDA patients for 6 months resulted in selective and significant reduction in foci of brain iron accumulation (assessed by T2* MRI) and initial functional improvements, with only minor changes in net body iron stores. The prospects of drug-mediated iron relocation versus those of chelation are discussed in relation to other disorders involving iron misdistribution, such as ACD and XLSA/A. Key words: iron, oxidative damage, anemia, mitochondria, Friedreich's ataxia, neurodegeneration. Une utilisation defectueuse du fer entrainant une mauvaise distribution systemique ou regionale du metal est une caracteristique importante de differents types de desordres. Le fer augmente a des taux toxiques dans les mitochondries des cellules excitables dans certaines formes de neurodeegenerescence avec accumulation cerebrale de fer (NBIA), ou apres des mutations dans les genes associees aux fonctions mitochondriales, tels que le gene ABCB7 dans l'anemie sideroblastique lieee a l'X avec ataxie (XLSA/A) et la frataxine dans l'ataxie de Friedreich (FRDA), laissant souvent le cytosol appauvri en fer. Dans l'anemie des maladies chroniques (AMC), le fer est retenu dans les macrophages, alors que sa teneur est considerablement reduite dans les liquides extracellulaires (p. ex. le plasma). La chelation du fer est une approche therapeutique possible a ces maladies, car elle reduit efficacement le depot multivisceeral de metal chez les patients ayant une surcharge en fer. Toutefois, cette approche est probablement inapproprieee pour les desordres associeesa une mauvaise distribution du fer dans des tissus/cellules determines. Un chelateur utilise; en clinique pour traiter la surcharge en fer, la deferiprone (DFP), a ete identifie comme un sideerophore inverse, c.-a-d. un agent ayant la capacites de redistribuer l'accumulation regionale de fer. On a applique la DFP a un modele cellulaire de FRDA, un modele de desordre associe etiologiquement a une mauvaise distribution de fer dans les cellules. Le traitement a reduit les taux des pools de fer labile (LIP) dans les mitochondries, qui avaient ete augmentes par la deficience en frataxine, protege les cellules contre un dommage oxydatif, et retabli divers parametres meetaboliques, y compris l'activite de l'aconitase. L'administration de DFP pendant 6 mois a des patients FRDA a entrainee une reduction selective et significative de l'accumulation de fer (evalueee par IRM T2*) dans certains foyers du cerveau, et quelques ameliorations fonctionnelles, avec seulement des modifications mineures dans les reserves de fer corporel. On discute des perspectives de redistribution vs. chelation du fer par un medicament en relation avec d'autres desordres impliquant une mauvaise distribution du fer, tels que l'ACD et la XLSA/A. Mots-cles: fer, dommage oxydatif, anemie, mitochondries, ataxie de Friedreich, neurodegeenerescence. [Traduit par la Redaction], Introduction The realization that some pathologies are caused by inappropriate iron distribution is relatively recent and is distinct from classic paradigms of toxicity caused by systemic iron overload. In iron-overload [...]

Published
2010
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46. A new drug candidates for glycogen storage disorders enhances glycogen catabolism: Lessons from Adult Polyglucosan Body Disease models

Author

Vaknin, Hilla, primary, Mishra, Kumudesh, additional, D’Souza, Jeevitha, additional, Marisat, Monzer, additional, Sprecher, Uri, additional, Wald-Altman, Shane, additional, Dukhovny, Anna, additional, Raviv, Yuval, additional, Da’adoosh, Benny, additional, Engel, Hamutal, additional, Benhamron, Sandrine, additional, Nitzan, Keren, additional, Permyakova, Anna, additional, Rosenmann, Hanna, additional, Lossos, Alexander, additional, Tam, Joseph, additional, Minassian, Berge A., additional, Kakhlon, Or, additional, and Weil, Miguel, additional

Published
2021
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48. Editorial: Using Small Molecules to Treat Macromolecule Storage Disorders

Author

Pablo V. Escribá, Miguel Weil, Or Kakhlon, and Hasan O. Akman

Subjects
storage disorders, Chemistry, Cell injury, Cell Biology, Small molecule, small molecules, lcsh:Biology (General), Biophysics, aggregates, lcsh:QH301-705.5, Developmental Biology, Macromolecule, aggregate clearance, cell injury
Published
2020

49. Canonical WNT pathway inhibition reduces ATP synthesis rates in glioblastoma stem cells

Author

Ulf D. Kahlert, Or Kakhlon, Wei Zhang, Roland S Croner, Erol Sandalcioglu, Claudia A. Dumitru, Hans-Jakob Steiger, Daniel Hänggi, Sajjad Muhammad, Wang Di, Guanzhang Li, Michael Hewera, and Dymphna Margriet Ouwens

Subjects
Adenosine Triphosphate, General Immunology and Microbiology, Cell Line, Tumor, Neoplastic Stem Cells, Humans, Glioblastoma, Glycolysis, Wnt Signaling Pathway, beta Catenin, General Biochemistry, Genetics and Molecular Biology
Abstract

The conserved stem cell signaling network canonical Wingless (WNT) plays important roles in development and disease. Aberrant activation of this pathway has been linked to tumor progression and resistance to therapy. Industry and academia have substantially invested in developing substances, which can efficiently and specifically block the WNT signaling pathway. However, a clear clinical proof of the efficacy of this approach is still missing. Studies on the metabolomics dysregulation of cancer cells have led to innovations in oncological diagnostics. In addition, modulation of cancer cell metabolome is at the base of promising clinical oncology trials currently underway. While onco-protein activation can have profound metabolic outcomes, the involvement of stem cell signals, such as the WNT pathway, in tumor cell metabolomics is yet insufficiently characterized.We determined live cell metabolism and bioenergetics in pathophysiological relevant, WNT-dependent glioblastoma stem cell (GSC) models. We quantified those parameters in cells with canonical WNT activity and in isogenic cells where WNT activity had been inhibited by short hairpin RNA against β-catenin. Furthermore, we applied computational analysis of RNA sequencing to verify our functional findings in independent GSCs cohorts.The investigated collection of disease models allows the separation in tumors with low, moderate and high base line metabolic activity. Suppression of canonical WNT signaling led to significant reduction of total, mitochondrial, and glycolytic ATP production rates. Elevated canonical WNT transcription signature in GSCs positively correlated with transcription levels of mitochondrial ATP synthesis, whereas non-canonical WNT gene expression signature did not.The applied disease modeling technology allows the recapitulation of inter-tumoral heterogeneous metabolic properties of glioblastoma. Our data show for the first time that inhibition of canonical WNT signaling in alive GSCs functionally correlates with energy inhibition and glucose homeostasis. As this correlation occurs in GSCs from different transcriptional or epigenetic transcriptional subtypes, our results suggest that developing therapies directed against glycolysis/ATP-synthesis may be a promising strategy to overcome therapy resistance due to inter-tumoral heterogeneity and offers starting point to impair downstream signal WNT.

Published
2022

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