TNF-α- and tumor-induced skeletal muscle atrophy involves sphingolipid metabolism

Additional filesInternational audienceUNLABELLED: ABSTRACT: BACKGROUND: Muscle atrophy associated with various pathophysiological conditions represents a major health problem, because of its contribution to the deterioration of patient status and its effect on mortality. Although the involvement of pro-inflammatory cytokines in this process is well recognized, the role of sphingolipid metabolism alterations induced by the cytokines has received little attention. RESULTS: We addressed this question both in vitro using differentiated myotubes treated with TNF-α, and in vivo in a murine model of tumor-induced cachexia. Myotube atrophy induced by TNF-α was accompanied by a substantial increase in cell ceramide levels, and could be mimicked by the addition of exogenous ceramides. It could be prevented by the addition of ceramide-synthesis inhibitors that targeted either the de novo pathway (myriocin), or the sphingomyelinases (GW4869 and 3-O-methylsphingomyelin). In the presence of TNF-α, ceramide-synthesis inhibitors significantly increased protein synthesis and decreased proteolysis. In parallel, they lowered the expression of both the Atrogin-1 and LC3b genes, involved in muscle protein degradation by proteasome and in autophagic proteolysis, respectively, and increased the proportion of inactive, phosphorylated Foxo3 transcription factor. Furthermore, these inhibitors increased the expression and/or phosphorylation levels of key factors regulating protein metabolism, including phospholipase D, an activator of mammalian target of rapamycin (mTOR), and the mTOR substrates S6K1 and Akt. In vivo, C26 carcinoma implantation induced a substantial increase in muscle ceramide, together with drastic muscle atrophy. Treatment of the animals with myriocin reduced the expression of the atrogenes Foxo3 and Atrogin-1, and partially protected muscle tissue from atrophy. CONCLUSIONS: Ceramide accumulation induced by TNF-α or tumor development participates in the mechanism of muscle-cell atrophy, and sphingolipid metabolism is a logical target for pharmacological or nutritional interventions aiming at preserving muscle mass in pathological situations

Molecular mechanisms of skeletal muscle atrophy in a mouse model of cerebral ischemia : potential role of myostatin inhibition

Les accidents vasculaires cérébraux (AVC) sont considérés comme la pathologie neurologique la plus sévère en termes de mortalité et d’infirmité. Ils touchent plus de 140 000 personnes chaque année. L’AVC ischémique, qui représente 80% des AVC, est causé par l’occlusion localisée d’un vaisseau conduisant à un arrêt de l’apport en oxygène et en glucose au cerveau. Il est ainsi responsable de déficits moteurs, sensitifs et cognitifs qui peuvent gravement compromettre l’autonomie et la qualité de vie des patients. Les patients qui ont subi un AVC ischémique développent notamment une atrophie musculaire qui se produit principalement dans le membre parétique, mais aussi dans une moindre mesure dans le membre non parétique. Toutefois, les mécanismes moléculaires à l’origine de cette atrophie musculaire sont méconnus. Dans une première étude, l’objectif a été d’identifier les déterminants moléculaires mis en jeu dans l’atrophie musculaire induite par une ischémie cérébrale. Pour répondre à cet objectif, les travaux ont été menés sur un modèle d'ischémie cérébrale chez la souris qui consiste en l’occlusion de l'artère cérébrale moyenne par un monofilament en nylon. Nous avons montré que l’ischémie cérébrale entraînait, 3 jours après son induction, une atrophie musculaire des muscles quadriceps, soleus et tibialis anterior du côté parétique. Cette atrophie musculaire était associée à des déficits moteurs touchant l’équilibre, la coordination, la force musculaire, la posture ou la marche. Au niveau moléculaire, nous avons reporté un déséquilibre de la balance entre la synthèse et la dégradation des protéines musculaires en faveur d’une augmentation de la dégradation dans les muscles parétique et non parétique des souris ischémiées. Nous avons notamment montré que l’expression de la myostatine, un régulateur négatif majeur de la masse musculaire, était significativement augmentée. Dans une seconde étude, l’objectif a été d’identifier une cible d’intervention thérapeutique pour préserver la masse musculaire suite à une ischémie cérébrale. Au vu des résultats obtenus dans la première étude, nous avons ciblé la myostatine. Nous avons montré que l’inhibition de la myostatine entraînait, une meilleure récupération du poids de corps et du poids de divers muscles, 15 jours après une ischémie cérébrale. De plus, l’inhibition de la myostatine tendait à améliorer le comportement moteur des souris ischémiées (équilibre, coordination, force musculaire). En revanche, nous n’avons reporté aucune variation majeure des niveaux en ARNm ou protéines d’acteurs impliqués dans les voies de signalisation Akt/mTOR, Smad2/3, ubiquitine-protéasome et autophagie-lysosome, 15 jours après une ischémie cérébrale. Ces données préliminaires suggèrent que l’inhibition pharmacologique de la myostatine pourrait représenter une stratégie thérapeutique efficace pour limiter la perte de masse musculaire suite à une ischémie cérébraleStrokes are considered as the most severe neurological disease in terms of mortality and disability. The incidence of stroke in France is estimated at 140 000. Ischemic stroke, which represents about 80% of strokes occur as a result of an obstruction of a blood vessel supplying blood to the brain. Motor, cognitive and sensory deficits are common impacts of stroke and can seriously compromise the autonomy and patient quality of life. Ischemic stroke leads to muscle atrophy, wich occurs primarily in the paretic limb, but also to a lesser extent in the nonparetic limb. However, the molecular mechanisms of muscle atrophy is unknown. In a first study, the purpose was to identify the molecular determinants involved in skeletal muscle atrophy following cerebral ischemia. To meet this objective, the work was carried out on a mouse model of cerebral ischemia, which involves the occlusion of the middle cerebral artery (MCAO) with a nylon monofilament. We have shown that cerebral ischemia leads to skeletal muscle atrophy of quadriceps, soleus and tibialis anterior muscles of the paretic side, 3 days after MCAO. This muscular atrophy was associated with motor deficits in the balance, coordination, muscle strength, posture and walking. From a molecular point of view, we reported an imbalance between the rates of synthesis and degradation of muscle protein, in favour of protein degradation in both paretic and nonparetic muscles. In particular, we showed that the expression of myostatin, a master negative regulator of skeletal muscle mass was significantly increased. In a second study, the purpose was to identify a target for therapeutic intervention in order to maintain muscle mass following cerebral ischemia. In view of the results obtained in the first study, we targeted the myostatin. Our results show that myostatin inhibition increases body weight and muscle mass recovery, 15 days after cerebral ischemia. In addition, myostatin inhibition tends to improve motor behavior (balance, coordination, strength). From a molecular point of view, we reported no major change in mRNA or protein level of actors involved in Akt/mTOR, Smad2/3, autophagy-lysosome and ubiquitin-proteasome pathways, involved in the control of muscle mass, 15 days after cerebral ischemia. These preliminary results strongly suggest that pharmacological inhibitors of myostatin may provide significant therapeutic benefit for muscle atrophy following cerebral ischemi

Autophagy-lysosomal pathway in response to fasting/refeeding in C2C12 myotubes

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Post-transcriptional regulation of autophagy in C2C12 myotubes following starvation and nutrient restoration

Times Cited: 0International audienceIn skeletal muscle, autophagy is activated in multiple physiological and pathological conditions, notably through the transcriptional regulation of autophagy-related genes by FoxO3. However, recent evidence suggests that autophagy could also be regulated by post-transcriptional mechanisms. The purpose of the study was therefore to determine the temporal regulation of transcriptional and post-transcriptional events involved in the control of autophagy during starvation (4 h) and nutrient restoration (4 h) in C2C12 myotubes. Starvation was associated with an activation of autophagy (decrease in mTOR activity, increase in AMPK activity and Ulk1 phosphorylation on Ser467), an increase in autophagy flux (increased LC3B-II/LC3B-I ratio, LC3B-II level and LC3B-positive punctate), and an increase in the content of autophagy-related proteins (Ulk1, Atg13, Vps34, and Atg5-Atg12 conjugate). Our data also indicated that the content of autophagy-related proteins was essentially maintained when nutrient sufficiency was restored. By contrast, mRNA level of Ulk1, Atg5, Bnip3, LC3B and Gabarapl1 did not increase in response to starvation. Accordingly, binding of FoxO3 transcription factor on LC3B promoter was only increased at the end of the starvation period, whereas mRNA levels of Atrogin1/MAFbx and MuRF1, two transcriptional targets of FoxO involved in ubiquitin-proteasome pathway, were markedly increased at this time. Together, these data provide evidence that target genes of FoxO3 are differentially regulated during starvation and that starvation of C2C12 myotubes is associated with a post-transcriptional regulation of autophagy

Molecular mechanisms of skeletal muscle atrophy in a mouse model of cerebral ischemia

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Macrophagic AMPKα1 orchestrates regenerative inflammation induced by glucocorticoids

International audienceAbstract Macrophages are key cells after tissue damage since they mediate both acute inflammatory phase and regenerative inflammation by shifting from pro‐inflammatory to restorative cells. Glucocorticoids (GCs) are the most potent anti‐inflammatory hormone in clinical use, still their actions on macrophages are not fully understood. We show that the metabolic sensor AMP‐activated protein kinase (AMPK) is required for GCs to induce restorative macrophages. GC Dexamethasone activates AMPK in macrophages and GC receptor (GR) phosphorylation is decreased in AMPK‐deficient macrophages. Loss of AMPK in macrophages abrogates the GC‐induced acquisition of their repair phenotype and impairs GC‐induced resolution of inflammation in vivo during post‐injury muscle regeneration and acute lung injury. Mechanistically, two categories of genes are impacted by GC treatment in macrophages. Firstly, canonical cytokine regulation by GCs is not affected by AMPK loss. Secondly, AMPK‐dependent GC‐induced genes required for the phenotypic transition of macrophages are co‐regulated by the transcription factor FOXO3, an AMPK substrate. Thus, beyond cytokine regulation, GR requires AMPK‐FOXO3 for immunomodulatory actions in macrophages, linking their metabolic status to transcriptional control in regenerative inflammation

Macrophagic AMPKα1 orchestrates regenerative inflammation induced by glucocorticoids

Macrophages are key cells after tissue damage since they mediate both acute inflammatory phase and regenerative inflammation by shifting from pro-inflammatory to restorative cells. Glucocorticoids (GCs) are the most potent anti-inflammatory hormone in clinical use, still their actions on macrophages are not fully understood. We show that the metabolic sensor AMP-activated protein kinase (AMPK) is required for GCs to induce restorative macrophages. GC Dexamethasone activates AMPK in macrophages and GC receptor (GR) phosphorylation is decreased in AMPK-deficient macrophages. Loss of AMPK in macrophages abrogates the GC-induced acquisition of their repair phenotype and impairs GC-induced resolution of inflammation in vivo during post-injury muscle regeneration and acute lung injury. Mechanistically, two categories of genes are impacted by GC treatment in macrophages. Firstly, canonical cytokine regulation by GCs is not affected by AMPK loss. Secondly, AMPK-dependent GC-induced genes required for the phenotypic transition of macrophages are co-regulated by the transcription factor FOXO3, an AMPK substrate. Thus, beyond cytokine regulation, GR requires AMPK-FOXO3 for immunomodulatory actions in macrophages, linking their metabolic status to transcriptional control in regenerative inflammation

Pharmacological inhibition of myostatin improves skeletal muscle mass and function in a mouse model of stroke

Abstract In stroke patients, loss of skeletal muscle mass leads to prolonged weakness and less efficient rehabilitation. We previously showed that expression of myostatin, a master negative regulator of skeletal muscle mass, was strongly increased in skeletal muscle in a mouse model of stroke. We therefore tested the hypothesis that myostatin inhibition would improve recovery of skeletal muscle mass and function after cerebral ischemia. Cerebral ischemia (45 minutes) was induced by intraluminal right middle cerebral artery occlusion (MCAO). Swiss male mice were randomly assigned to Sham-operated mice (n = 10), MCAO mice receiving the vehicle (n = 15) and MCAO mice receiving an anti-myostatin PINTA745 (n = 12; subcutaneous injection of 7.5 mg.kg−1 PINTA745 immediately after surgery, 3, 7 and 10 days after MCAO). PINTA745 reduced body weight loss and improved body weight recovery after cerebral ischemia, as well as muscle strength and motor function. PINTA745 also increased muscle weight recovery 15 days after cerebral ischemia. Mechanistically, the better recovery of skeletal muscle mass in PINTA745-MCAO mice involved an increased expression of genes encoding myofibrillar proteins. Therefore, an anti-myostatin strategy can improve skeletal muscle recovery after cerebral ischemia and may thus represent an interesting strategy to combat skeletal muscle loss and weakness in stroke patients