Your search keyword '"Nadia Bendridi"' showing total 8 results

1. Warburg-associated acidification represses lactic fermentation independently of lactate, contribution from real-time NMR on cell-free systems

Author

Zoé Daverio, Maxime Kolkman, Johan Perrier, Lexane Brunet, Nadia Bendridi, Corinne Sanglar, Marie-Agnès Berger, Baptiste Panthu, and Gilles J. P. Rautureau

Subjects

Medicine, Science

Abstract

Abstract Lactate accumulation and acidification in tumours are a cancer hallmark associated with the Warburg effect. Lactic acidosis correlates with cancer malignancy, and the benefit it offers to tumours has been the subject of numerous hypotheses. Strikingly, lactic acidosis enhances cancer cell survival to environmental glucose depletion by repressing high-rate glycolysis and lactic fermentation, and promoting an oxidative metabolism involving reactivated respiration. We used real-time NMR to evaluate how cytosolic lactate accumulation up to 40 mM and acidification up to pH 6.5 individually impact glucose consumption, lactate production and pyruvate evolution in isolated cytosols. We used a reductive cell-free system (CFS) to specifically study cytosolic metabolism independently of other Warburg-regulatory mechanisms found in the cell. We assessed the impact of lactate and acidification on the Warburg metabolism of cancer cytosols, and whether this effect extended to different cytosolic phenotypes of lactic fermentation and cancer. We observed that moderate acidification, independently of lactate concentration, drastically reduces the glucose consumption rate and halts lactate production in different lactic fermentation phenotypes. In parallel, for Warburg-type CFS lactate supplementation induces pyruvate accumulation at control pH, and can maintain a higher cytosolic pyruvate pool at low pH. Altogether, we demonstrate that intracellular acidification accounts for the direct repression of lactic fermentation by the Warburg-associated lactic acidosis.

Published

2023

2. Hepatitis C virus replication requires integrity of mitochondria-associated ER membranes

Author

Sarah Duponchel, Lea Monnier, Jennifer Molle, Nadia Bendridi, Muhammad Rizwan Alam, Ahmed Gaballah, Boyan Grigorov, Alexander Ivanov, Marcel Schmiel, Margarete Odenthal, Michel Ovize, Jennifer Rieusset, Fabien Zoulim, and Birke Bartosch

Subjects

hepatitis C virus, mitochondria-associated ER membranes, voltage-dependent anion channel 1, fibrosis, Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Background & Aims: Chronic HCV infection causes cellular stress, fibrosis and predisposes to hepatocarcinogenesis. Mitochondria play key roles in orchestrating stress responses by regulating bioenergetics, inflammation and apoptosis. To better understand the role of mitochondria in the viral life cycle and disease progression of chronic hepatitis C, we studied morphological and functional mitochondrial alterations induced by HCV using productively infected hepatoma cells and patient livers. Methods: Biochemical and imaging assays were used to assess localization of cellular and viral proteins and mitochondrial functions in cell cultures and liver biopsies. Cyclophilin D (CypD) knockout was performed using CRISPR/Cas9 technology. Viral replication was quantified by quantitative reverse-transcription PCR and western blotting. Results: Several HCV proteins were found to associate with mitochondria-associated endoplasmic reticulum (ER) membranes (MAMs), the points of contact between the ER and mitochondria. Downregulation of CypD, which is known to disrupt MAM integrity, reduced viral replication, suggesting that MAMs play an important role in the viral life cycle. This process was rescued by ectopic CypD expression. Furthermore, HCV proteins were found to associate with voltage dependent anion channel 1 (VDAC1) at MAMs and to reduce VDAC1 protein levels at MAMs in vitro and in patient biopsies. This association did not affect MAM-associated functions in glucose homeostasis and Ca2+ signaling. Conclusions: HCV proteins associate specifically with MAMs and MAMs play an important role in viral replication. The association between viral proteins and MAMs did not impact Ca2+ signaling between the ER and mitochondria or glucose homeostasis. Whether additional functions of MAMs and/or VDAC are impacted by HCV and contribute to the associated pathology remains to be assessed. Impact and implications: Hepatitis C virus infects the liver, where it causes inflammation, cell damage and increases the long-term risk of liver cancer. We show that several HCV proteins interact with mitochondria in liver cells and alter the composition of mitochondrial subdomains. Importantly, HCV requires the architecture of these mitochondrial subdomains to remain intact for efficient viral replication.

Published

2023

3. Calcium channel ITPR2 and mitochondria–ER contacts promote cellular senescence and aging

Author

Dorian V. Ziegler, David Vindrieux, Delphine Goehrig, Sara Jaber, Guillaume Collin, Audrey Griveau, Clotilde Wiel, Nadia Bendridi, Sophia Djebali, Valerio Farfariello, Natacha Prevarskaya, Léa Payen, Jacqueline Marvel, Sébastien Aubert, Jean-Michel Flaman, Jennifer Rieusset, Nadine Martin, and David Bernard

Subjects

Science

Abstract

Contacts between mitochondria and endoplasmatic reticulum (ER), and the transfer of calcium between them, have an important role in the regulation of cellular phenotypes, including senescence. Here the authors show that ITPR2 deficient mice display improved aging, associated with a decreased number of contacts between the mitochondria and the ER.

Published

2021

4. Impaired aerobic capacity and premature fatigue preceding muscle weakness in the skeletal muscle Tfam-knockout mouse model

Author

Benjamin Chatel, Sylvie Ducreux, Zeina Harhous, Nadia Bendridi, Isabelle Varlet, Augustin C. Ogier, Monique Bernard, Julien Gondin, Jennifer Rieusset, Håkan Westerblad, David Bendahan, and Charlotte Gineste

Subjects

mitochondrial myopathy, energy metabolism, muscle fatigue, exercise intolerance, muscle weakness, Medicine, Pathology, RB1-214

Abstract

Mitochondrial diseases are genetic disorders that lead to impaired mitochondrial function, resulting in exercise intolerance and muscle weakness. In patients, muscle fatigue due to defects in mitochondrial oxidative capacities commonly precedes muscle weakness. In mice, deletion of the fast-twitch skeletal muscle-specific Tfam gene (Tfam KO) leads to a deficit in respiratory chain activity, severe muscle weakness and early death. Here, we performed a time-course study of mitochondrial and muscular dysfunctions in 11- and 14-week-old Tfam KO mice, i.e. before and when mice are about to enter the terminal stage, respectively. Although force in the unfatigued state was reduced in Tfam KO mice compared to control littermates (wild type) only at 14 weeks, during repeated submaximal contractions fatigue was faster at both ages. During fatiguing stimulation, total phosphocreatine breakdown was larger in Tfam KO muscle than in wild-type muscle at both ages, whereas phosphocreatine consumption was faster only at 14 weeks. In conclusion, the Tfam KO mouse model represents a reliable model of lethal mitochondrial myopathy in which impaired mitochondrial energy production and premature fatigue occur before muscle weakness and early death.

Published

2021

5. Ketone Bodies as Metabolites and Signalling Molecules at the Crossroad between Inflammation and Epigenetic Control of Cardiometabolic Disorders

Author

Nadia Bendridi, Anna Selmi, Aneta Balcerczyk, and Luciano Pirola

Subjects

ketone bodies, histone PTMs, histone β-hydroxybutyrylation, cardiovascular diseases, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

For many years, it has been clear that a Western diet rich in saturated fats and sugars promotes an inflammatory environment predisposing a person to chronic cardiometabolic diseases. In parallel, the emergence of ketogenic diets, deprived of carbohydrates and promoting the synthesis of ketone bodies imitating the metabolic effects of fasting, has been shown to provide a possible nutritional solution to alleviating diseases triggered by an inflammatory environment. The main ketone body, β-hydroxybutyrate (BHB), acts as an alternative fuel, and also as a substrate for a novel histone post-translational modification, β-hydroxybutyrylation. β-hydroxybutyrylation influences the state of chromatin architecture and promotes the transcription of multiple genes. BHB has also been shown to modulate inflammation in chronic diseases. In this review, we discuss, in the pathological context of cardiovascular risks, the current understanding of how ketone bodies, or a ketogenic diet, are able to modulate, trigger, or inhibit inflammation and how the epigenome and chromatin remodeling may be a key contributor.

Published

2022

6. Effect of Metformin on T2D-Induced MAM Ca2+ Uncoupling and Contractile Dysfunction in an Early Mouse Model of Diabetic HFpEF

Author

Maya Dia, Christelle Leon, Stephanie Chanon, Nadia Bendridi, Ludovic Gomez, Jennifer Rieusset, Helene Thibault, and Melanie Paillard

Subjects

diabetic cardiomyopathy, heart failure, type 2 diabetes, reticulum-mitochondria interactions, Ca2+ signaling, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Diabetic cardiomyopathy (DCM) is a leading complication in type 2 diabetes patients. Recently, we have shown that the reticulum-mitochondria Ca2+ uncoupling is an early and reversible trigger of the cardiac dysfunction in a diet-induced mouse model of DCM. Metformin is a first-line antidiabetic drug with recognized cardioprotective effect in myocardial infarction. Whether metformin could prevent the progression of DCM remains not well understood. We therefore investigated the effect of a chronic 6-week metformin treatment on the reticulum-mitochondria Ca2+ coupling and the cardiac function in our high-fat high-sucrose diet (HFHSD) mouse model of DCM. Although metformin rescued the glycemic regulation in the HFHSD mice, it did not preserve the reticulum-mitochondria Ca2+ coupling either structurally or functionally. Metformin also did not prevent the progression towards cardiac dysfunction, i.e., cardiac hypertrophy and strain dysfunction. In summary, despite its cardioprotective role, metformin is not sufficient to delay the progression to early DCM.

Published

2022

7. Glucocorticoid-dependent REDD1 expression reduces muscle metabolism to enable adaptation under energetic stress

Author

Florian A. Britto, Fabienne Cortade, Yassine Belloum, Marine Blaquière, Yann S. Gallot, Aurélie Docquier, Allan F. Pagano, Elodie Jublanc, Nadia Bendridi, Christelle Koechlin-Ramonatxo, Béatrice Chabi, Marc Francaux, François Casas, Damien Freyssenet, Jennifer Rieusset, Sophie Giorgetti-Peraldi, Gilles Carnac, Vincent Ollendorff, and François B. Favier

Subjects

Skeletal muscle, Metabolism, Hypoxia, Fasting, Exercise, Mitochondria, Biology (General), QH301-705.5

Abstract

Abstract Background Skeletal muscle atrophy is a common feature of numerous chronic pathologies and is correlated with patient mortality. The REDD1 protein is currently recognized as a negative regulator of muscle mass through inhibition of the Akt/mTORC1 signaling pathway. REDD1 expression is notably induced following glucocorticoid secretion, which is a component of energy stress responses. Results Unexpectedly, we show here that REDD1 instead limits muscle loss during energetic stresses such as hypoxia and fasting by reducing glycogen depletion and AMPK activation. Indeed, we demonstrate that REDD1 is required to decrease O2 and ATP consumption in skeletal muscle via reduction of the extent of mitochondrial-associated endoplasmic reticulum membranes (MAMs), a central hub connecting energy production by mitochondria and anabolic processes. In fact, REDD1 inhibits ATP-demanding processes such as glycogen storage and protein synthesis through disruption of the Akt/Hexokinase II and PRAS40/mTORC1 signaling pathways in MAMs. Our results uncover a new REDD1-dependent mechanism coupling mitochondrial respiration and anabolic processes during hypoxia, fasting, and exercise. Conclusions Therefore, REDD1 is a crucial negative regulator of energy expenditure that is necessary for muscle adaptation during energetic stresses. This present study could shed new light on the role of REDD1 in several pathologies associated with energetic metabolism alteration, such as cancer, diabetes, and Parkinson’s disease.

Published

2018

8. Regulation of Mitochondria-Associated Membranes (MAMs) by NO/sGC/PKG Participates in the Control of Hepatic Insulin Response

Author

Arthur Bassot, Marie-Agnès Chauvin, Nadia Bendridi, Jingwei Ji-Cao, Guillaume Vial, Léa Monnier, Birke Bartosch, Anaïs Alves, Cécile Cottet-Rousselle, Yves Gouriou, Jennifer Rieusset, and Béatrice Morio

Subjects

mitochondria-associated endoplasmic reticulum membranes, nitric oxide, cyclic guanosine monophosphate (cgmp)-dependent protein kinase, hepatic glucose metabolism, metabolic flexibility, Cytology, QH573-671

Abstract

Under physiological conditions, nitric oxide (NO) produced by the endothelial NO synthase (eNOS) upregulates hepatic insulin sensitivity. Recently, contact sites between the endoplasmic reticulum and mitochondria named mitochondria-associated membranes (MAMs) emerged as a crucial hub for insulin signaling in the liver. As mitochondria are targets of NO, we explored whether NO regulates hepatic insulin sensitivity by targeting MAMs. In Huh7 cells, primary rat hepatocytes and mouse livers, enhancing NO concentration increased MAMs, whereas inhibiting eNOS decreased them. In vitro, those effects were prevented by inhibiting protein kinase G (PKG) and mimicked by activating soluble guanylate cyclase (sGC) and PKG. In agreement with the regulation of MAMs, increasing NO concentration improved insulin signaling, both in vitro and in vivo, while eNOS inhibition disrupted this response. Finally, inhibition of insulin signaling by wortmannin did not affect the impact of NO on MAMs, while experimental MAM disruption, using either targeted silencing of cyclophilin D or the overexpression of the organelle spacer fetal and adult testis-expressed 1 (FATE-1), significantly blunted the effects of NO on both MAMs and insulin response. Therefore, under physiological conditions, NO participates to the regulation of MAM integrity through the sGC/PKG pathway and concomitantly improves hepatic insulin sensitivity. Altogether, our data suggest that the induction of MAMs participate in the impact of NO on hepatocyte insulin response.

Published

2019