Xavier Bigard

Down-regulation of Akt/mammalian target of rapamycin signaling pathway in response to myostatin overexpression in skeletal muscle.

Myostatin, a member of the TGF-beta family, has been identified as a master regulator of embryonic myogenesis and early postnatal skeletal muscle growth. However, cumulative evidence also suggests that alterations in skeletal muscle mass are associated with dysregulation in myostatin expression and that myostatin may contribute to muscle mass loss in adulthood. Two major branches of the Akt pathway are relevant for the regulation of skeletal muscle mass, the Akt/mammalian target of rapamycin (mTOR) pathway, which controls protein synthesis, and the Akt/forkhead box O (FOXO) pathway, which controls protein degradation. Here, we provide further insights into the mechanisms by which myostatin regulates skeletal muscle mass by showing that myostatin negatively regulates Akt/mTOR signaling pathway. Electrotransfer of a myostatin expression vector into the tibialis anterior muscle of Sprague Dawley male rats increased myostatin protein level and decreased skeletal muscle mass 7 d after gene electrotransfer. Using RT-PCR and immunoblot analyses, we showed that myostatin overexpression was ineffective to alter the ubiquitin-proteasome pathway. By contrast, myostatin acted as a negative regulator of Akt/mTOR pathway. This was supported by data showing that the phosphorylation of Akt on Thr308, tuberous sclerosis complex 2 on Thr1462, ribosomal protein S6 on Ser235/236, and 4E-BP1 on Thr37/46 was attenuated 7 d after myostatin gene electrotransfer. The data support the conclusion that Akt/mTOR signaling is a key target that accounts for myostatin function during muscle atrophy, uncovering a novel role for myostatin in protein metabolism and more specifically in the regulation of translation in skeletal muscle.

Subcellular Creatine Kinase Alterations Implications in Heart Failure

We have tested the hypothesis that decreased functioning of creatine kinase (CK) at sites of energy production and utilization may contribute to alterations in energy fluxes and calcium homeostasis in congestive heart failure (CHF). Heart failure was induced by aortic banding in 3-week-old rats. Myofilaments, sarcoplasmic reticulum (SR), mitochondrial functions, and CK compartmentation were studied in situ using selective membrane permeabilization of left ventricular fibers with detergents (saponin for mitochondria and SR and Triton X-100 for myofibrils). Seven months after surgery, animals were in CHF. A decrease in total CK activity could be accounted for by a 4-fold decrease in activity and content (Western blots) of mitochondrial CK and a 30% decrease in M isoform of CK (MM-CK) activity. In myofibrils, maximal force, crossbridge kinetics, and alpha-myosin heavy-chain expression decreased, whereas calcium sensitivity of tension development remained unaltered. Myofibrillar CK efficacy was unchanged. Calcium uptake capacities of SR were estimated from the surface of caffeine-induced tension transient (SCa) after loading with different substrates. In CHF, SCa decreased by 23%, and phosphocreatine was 2 times less efficient in enhancing calcium uptake. Oxidative capacities of the failing myocardium measured as oxygen consumption per gram of fiber dry weight decreased by 28%. Moreover, the control of respiration by creatine, ADP, and AMP was severely impaired. Our observations provide evidence that alterations in CK compartmentation may contribute to alterations of energy fluxes and calcium homeostasis in CHF.

Physical activity changes the regulation of mitochondrial respiration in human skeletal muscle

This study explores the importance of creatine kinase (CK) in the regulation of muscle mitochondrial respiration in human subjects depending on their level of physical activity. Volunteers were classified as sedentary, active or athletic according to the total activity index as determined by the Baecke questionnaire in combination with maximal oxygen uptake values (peak V̇O2, expressed in ml min−1 kg−1). All volunteers underwent a cyclo‐ergometric incremental exercise test to estimate their peak V̇O2 and V̇O2 at the ventilatory threshold (VT). Muscle biopsy samples were taken from the vastus lateralis and mitochondrial respiration was evaluated in an oxygraph cell on saponin permeabilised muscle fibres in the absence (V̇0) or in the presence (V̇max) of saturating [ADP]. While V̇0 was similar, V̇max differed among groups (sedentary, 3.7 ± 0.3, active, 5.9 ± 0.9 and athletic, 7.9 ± 0.5 μmol O2 min−1 (g dry weight)−1). V̇max was correlated with peak V̇O2 (P < 0.01, r= 0.63) and with V̇T (P < 0.01, r= 0.57). There was a significantly greater degree of coupling between oxidation and phosphorylation (V̇max/V̇0) in the athletic individuals. The mitochondrial Km for ADP was significantly higher in athletic subjects (P < 0.01). Mitochondrial CK (mi‐CK) activation by addition of creatine induced a marked decrease in Km in athletic individuals only, indicative of an efficient coupling of mi‐CK to ADP rephosphorylation in the athletic subjects only. It is suggested that increasing aerobic performance requires an enhancement of both muscle oxidative capacity and mechanisms of respiratory control, attesting to the importance of temporal co‐ordination of energy fluxes by CK for higher efficacy.

Heart Failure Affects Mitochondrial but Not Myofibrillar Intrinsic Properties of Skeletal Muscle

BackgroundCongestive heart failure (CHF) induces abnormalities in skeletal muscle that are thought to in part explain exercise intolerance. The aim of the present study was to determine whether these changes actually result in contractile or metabolic functional alterations and whether they are muscle type specific. Methods and ResultsWith a rat model of CHF (induced by aortic banding), we studied mitochondrial function, mechanical properties, and creatine kinase (CK) compartmentation in situ in permeabilized fibers from soleus (SOL), an oxidative slow-twitch muscle, and white gastrocnemius (GAS), a glycolytic fast-twitch muscle. Animals were studied 7 months after surgery, and CHF was documented on the basis of anatomic data. Alterations in skeletal muscle phenotype were documented with an increased proportion of fast-type fiber and fast myosin heavy chain, decreased capillary-to-fiber ratio, and decreased citrate synthase activity. Despite a slow-to-fast phenotype transition in SOL, no change was observed in contractile capacity or calcium sensitivity. However, muscles from CHF rats exhibited a dramatic decrease in oxidative capacities (oxygen consumption per gram of fiber dry weight) of 35% for SOL and 45% for GAS (P <0.001). Moreover, the regulation of respiration with ADP and mitochondrial CK and adenylate kinase was impaired in CHF SOL. Mitochondrial CK activity and content (Western blots) were dramatically decreased in both muscles. ConclusionsCHF results in alterations in both mitochondrial function and phosphotransfer systems but unchanged myofibrillar function in skeletal muscles, which suggests a myopathy of metabolic origin in CHF.

Oxidative capacity of skeletal muscle in heart failure patients versus sedentary or active control subjects.

OBJECTIVES We investigated the in situ properties of muscle mitochondria using the skinned fiber technique in patients with chronic heart failure (CHF) and sedentary (SED) and more active (ACT) controls to determine: 1) whether respiration of muscle tissue in the SED and ACT groups correlates with peak oxygen consumption (pVO(2)), 2) whether it is altered in CHF, and 3) whether this results from deconditioning or CHF-specific myopathy. BACKGROUND Skeletal muscle oxidative capacity is thought to partly determine the exercise capacity in humans and its decrease to participate in exercise limitation in CHF. METHODS M. Vastus lateralis biopsies were obtained from 11 SED group members, 10 ACT group members and 15 patients with CHF at the time of transplantation, saponine-skinned and placed in an oxygraphic chamber to measure basal and maximal adenosine diphosphate (ADP)-stimulated (V(max)) respiration rates and to assess mitochondrial regulation by ADP. All patients received angiotensin-converting enzyme (ACE) inhibitors. RESULTS The pVO(2) differed in the order CHF < SED < ACT. Compared with SED, muscle alterations in CHF appeared as decreased citrate synthase, creatine kinase and lactate dehydrogenase, whereas the myosin heavy chain profile remained unchanged. However, muscle oxidative capacity (V(max), CHF: 3.53 +/- 0.38; SED: 3.17 +/- 0.48; ACT: 7.47 +/- 0.73, micromol O(2).min(-1).g(-1)dw, p < 0.001 vs. CHF and SED) and regulation were identical in patients in the CHF and SED groups, differing in the ACT group only. In patients with CHF, the correlation between pVO(2) and muscle oxidative capacity observed in controls was displaced toward lower pVO(2) values. CONCLUSIONS In these patients, the disease-specific muscle metabolic impairments derive mostly from extramitochondrial mechanisms that disrupt the normal symmorphosis relations. The possible roles of ACE inhibitors and level of activity are discussed.

Exercise‐Induced Expression of Vascular Endothelial Growth Factor mRNA in Rat Skeletal Muscle is Dependent on Fibre Type

In this study, we quantified the expression of the vascular endothelial growth factor (VEGF) gene in individual muscle fibres at the end of a single 90 min run of 20−25 m min−1, at 10 % incline. In addition, we evaluated the co‐ordinated expression of several hypoxia‐sensitive genes, including the ORP‐150 gene. Individual fibres were taken from rat plantaris muscle, either at the end of a single bout of exercise or at rest, and classified as Type I, IIa, IIx or IIb, according to the expression of myosin heavy chain (MHC) isoforms. VEGF mRNA levels increased by 90 % in exercising whole plantaris in comparison with those in control muscle (P < 0.001), while the VEGF protein content increased by 72 % (P < 0.05). Using real‐time PCR analysis, an accurate and reproducible method for quantification of mRNA levels, a marked rise in VEGF transcript levels was observed at the end of exercise in individual myofibres (P < 0.05), providing the first direct evidence that VEGF transcripts increase in muscle cells after a single bout of exercise. This exercise‐induced increase in VEGF transcript levels was specifically observed in type IIb myofibres, which are predominantly glycolytic and more susceptible to local hypoxia than oxidative myofibres such as type I or IIa fibres (110 %, P < 0.05). Moreover, treadmill exercise increased the expression of two hypoxia‐sensitive genes. The levels of mRNA for Flt‐1, a VEGF‐specific receptor, and those for ORP‐150, a chaperone essential for the secretion of mature VEGF, increased in whole plantaris muscles (108 and 92 %, respectively, P < 0.05). Taken together, these findings are consistent with the suggestion that hypoxia could be one of the mechanisms involved in exercise‐induced capillary growth.

Impaired voluntary running capacity of creatine kinase-deficient mice

The creatine kinase system (CK) is important for energy delivery in skeletal and cardiac muscles. The two main isoforms of this enzyme, cytosolic MM‐CK and mitochondrial mi‐CK, are expressed in a developmental and muscle‐type specific manner. Mice deficient in one or both of these isoforms are viable and fertile but exhibit profound functional, metabolic and structural muscle remodelling that primarily affects fast skeletal muscles, which show an increased contribution of oxidative metabolism to contractile function. However, the consequences of these alterations in terms of physical capabilities have not yet been characterized. Consequently, we compared the voluntary exercise capacity of 9‐month‐old male wild‐type (WT), M‐CK knockout (M‐CK−/−), and M‐CK and mi‐CK double knockout (CK−/−) mice, using cages equipped with running wheels. Exercise performance, calculated by total distance covered and by work done during the training period, was more than 10‐fold lower in CK−/− mice than controls, with M‐CK−/− mice exhibiting intermediate performance. Similarly, the mean distance run per activation was lower in M‐CK−/− and even lower in CK−/− mice. However, the maximal running speed (Vmax) was lower only for CK−/− mice. This was accompanied by severe skeletal muscle mass decrease in CK−/− mice, with signs of histological damage that included enlarged interstitial areas, aggregations of mononuclear cells in the interstitium, heterogeneity of myofibre size and the presence of very small fibres. No overt sign of cardiac dysfunction was observed by magnetic resonance imaging during dobutamine stimulation. These results show that metabolic failure induced by CK deficiency profoundly affects the ability of mice to engage in chronic bouts of endurance running exercise and that this decrease in performance is also associated with muscle wasting.

Fibre-type specificity of interleukin-6 gene transcription during muscle contraction in rat : association with calcineurin activity

In this study, we quantified the transcription of the interleukin‐6 (IL‐6) gene in individual fibres and the associated changes in calcineurin activity assessed at the cellular level during prolonged muscle contraction. Individual myofibres were isolated from plantaris and soleus muscles of rats at the end of an exhaustive running exercise test (n= 10), categorized according to their myosin heavy chain isoform content, and compared to those of resting rats (n= 10). Using real‐time PCR analysis in individual fibres, a marked rise in IL‐6 transcript levels occurred in type I and IIa fibres at the end of exercise (P < 0.05). Transcription of the gene encoding for the modulatory calcineurin‐interacting protein‐1 (MCIP‐1), a sensitive indicator of calcineurin activity, also mainly increased in type I and IIa fibres (P < 0.05). Moreover, a slight increase in MCIP‐1 mRNA levels was observed in type IIx (P < 0.05). Fibre types determined by immunohistochemistry were qualitatively examined for glycogen content using periodic acid–Shiff staining, and no direct relationship was found, at the cellular level, between glycogen content, fibre‐type and IL‐6 transcription. Our data clearly suggest that IL‐6 gene transcription was mainly observed in early recruited myofibres and that contraction‐induced IL‐6 transcription could be associated with enhanced calcineurin activity.

Endothelial nitric oxide synthase (NOS) deficiency affects energy metabolism pattern in murine oxidative skeletal muscle.

Oxidative capacity of muscles correlates with capillary density and with microcirculation, which in turn depend on various regulatory factors, including NO generated by endothelial nitric oxide synthase (eNOS). To determine the role of eNOS in patterns of regulation of energy metabolism in various muscles, we studied mitochondrial respiration in situ in saponin-permeabilized fibres as well as the energy metabolism enzyme profile in the cardiac, soleus (oxidative) and gastrocnemius (glycolytic) muscles isolated from mice lacking eNOS (eNOS(-/-)). In soleus muscle, the absence of eNOS induced a marked decrease in both basal mitochondrial respiration without ADP (-32%; P <0.05) and maximal respiration in the presence of ADP (-29%; P <0.05). Furthermore, the eNOS(-/-) soleus muscle showed a decrease in total creatine kinase (-29%; P <0.05), citrate synthase (-31%; P <0.01), adenylate kinase (-27%; P <0.05), glyceraldehyde-3-phosphate dehydrogenase (-43%; P <0.01) and pyruvate kinase (-26%; P <0.05) activities. The percentage of myosin heavy chains I (slow isoform) was significantly increased from 24.3+/-1.5% in control to 30.1+/-1.1% in eNOS(-/-) soleus muscle ( P <0.05) at the expense of a slight non-significant decrease in the three other (fast) isoforms. Besides, eNOS(-/-) soleus showed a 28% loss of weight. Interestingly, we did not find differences in any parameters in cardiac and gastrocnemius muscles compared with respective controls. These results show that eNOS knockout has an important effect on muscle oxidative capacity as well on the activities of energy metabolism enzymes in oxidative (soleus) muscle. The absence of such effects in cardiac and glycolytic (gastrocnemius) muscle suggests a specific role for eNOS-produced NO in oxidative skeletal muscle.

Cardiac and skeletal muscle energy metabolism in heart failure: beneficial effects of voluntary activity

OBJECTIVE Mitochondrial function and metabolic profile of slow and fast skeletal muscles and cardiac muscle are altered in chronic heart failure (CHF), suggesting a generalized metabolic myopathy in this disease. The aim of this study was to investigate the potential beneficial effects of voluntary activity on cardiac and skeletal muscle energetics in heart failure. METHODS Heart failure was induced in rats by aortic stenosis. Four months after surgery, part of sham and CHF animals were randomly assigned to activity cages equipped with running wheels for 8 weeks or kept sedentary. Mitochondrial capacity and regulation were measured using saponin skinned fibers in left ventricle, slow and fast skeletal muscles, and metabolic and myosin profiles were established. RESULTS Despite four times lower performances of CHF rats, alterations in metabolic and myosin parameters (oxidative capacity, mitochondrial enzymes, cytosolic and mitochondrial creatine kinase, myosin heavy chains) observed in all muscles of CHF animals were almost fully restored in soleus muscle though unchanged in heart and fast skeletal muscles. CONCLUSIONS These results show the powerful beneficial effect of physical activity specifically on active slow oxidative skeletal muscle in CHF, without the worsening of cardiac muscle metabolism.