Implication potentielle des protéines de fusion mitochondriale dans l'ontogenèse des processus bioénergétiques musculaires chez l'oiseau

Cold-exposed young birds maintain their homeothermy by stimulating mitochondrial oxidations in skeletal muscle. Prolonged cold exposure enhances muscle thermogenic capacities through mitochondrial bioenergetics plasticity which control still remains hypothetical. In mammals, fusion proteins (mitofusins (Mfns) and OPA1 (Optic Atrophy 1)) contribute to the permanent and dynamic changes in mitochondrial networks in multiple cell types. The aim of our work was to characterize the expression of avian homologues of mammalian fusion proteins and to study the variations of their expression during the establishment of bioenergetics processes in growing birds, during an acute or a prolonged cold exposure and finally during nutritional or endocrine challenges. Methodologically, an integrative approach has been used from whole animal (indirect calorimetry) to protein (western-blot) or gene (RT-PCR) expression through measurements of the bioenergetics functionality of permeabilized muscle fibers and isolated mitochondria. Two animal models were used, a species naturally adapted to Antarctica harsh conditions, the Adélie penguin (Pygoscelis adeliae), and a laboratory model, the Muscovy duck (Cairina moschata).Our results allowed us to characterize, in birds, the expression of immunoreactive fusion proteins (Mfn2, OPA1) which were homologous to those of mammals. The sequencing of a part of the coding sequence of Mfns genes showed a great similitude between avian and mammalian species. In penguins, the relative abundance of these proteins in muscle mitochondria was modified by growth in the cold and was positively correlated with muscle bioenergetics capacities. In ducks, the respiratory activity and the relative abundance of these proteins were also correlated after a 60h fasting period or,though a lesser extent, after a pharmacological alteration of thyroid status. Our results show, for the first time in birds, the expression of proteins homologous to mammalian fusion proteins. The association between the changes in expression of these proteins and the bioenergetics modifications in skeletal muscle indicates that these proteins could contribute to thebioenergetics plasticity observed in growing chicks. These results suggest that potential modifications of the muscle mitochondrial network organization could play a role in the adaptive responses of organisms to the environmental constraints.Les jeunes oiseaux exposés au froid assurent leur homéothermie en stimulant les oxydations mitochondriales dans les muscles squelettiques. L’exposition prolongée au froid accroit les capacités de thermogenèse musculaire grâce à une plasticité bioénergétique mitochondriale dont le contrôle reste hypothétique. Chez les mammifères, des protéines de fusion (les mitofusines (Mfns) et OPA1(OPtic Atrophy 1)) participent au remaniement des réseaux dynamiques mitochondriaux dans de multiples types cellulaires. Le but de ce travail de thèse était de caractériser l’expression d’homologues aviaires des protéines de fusion mammaliennes et d’étudier leurs variations d’expression lors de la mise en place des processus bioénergétiques chez l’oiseau en croissance, lors d’une exposition aiguë ou prolongée au froid ou lors de challenges nutritionnels ou endocrines.Sur le plan méthodologique, une approche intégrative a été utilisée de l’animal entier (calorimétrie indirecte) à l’expression protéique (western blot) ou transcriptionnelle (RT-PCR) en passant par des mesures de la fonctionnalité bioénergétique sur des fibres musculaires perméabilisées et mitochondries isolées. Deux modèles animaux ont été utilisés, une espèce naturellement adaptée aux conditions extrêmes de l’Antarctique, le manchot Adélie (Pygoscelisadeliae), et un modèle de laboratoire, le canard de Barbarie (Cairina moschata). Nos résultats ont permis de caractériser chez l’oiseau l’expression de protéines de fusion (Mfn2, OPA1) immunoréactives homologues à celles des mammifères. Le séquençage d’une partie de la séquence codante des gènes codant les Mfns a montré une bonne similitude entre les espècesd’oiseaux et les mammifères. Chez le manchot, l’abondance relative de ces protéines dans lesmitochondries musculaires variait avec la croissance et l’exposition thermique en corrélation positiveavec les capacités bioénergétiques musculaires. Chez le canard, l’activité respiratoire et l’abondance relative de ces protéines étaient également corrélées suite à un jeûne de 60h ou, bien que dans une moindre mesure, après altération pharmacologique du statut thyroïdien.Ces résultats montrent pour la première fois chez l’oiseau l’expression de protéines homologues aux protéines de fusion des mammifères. L’association entre les variations d’expression de ces protéines et les modifications bioénergétiques du muscle squelettique indiquent qu’elles pourraient contribuer à la plasticité bioénergétique observée chez l’oiseau en croissance. Ces résultats suggèrent que des modifications potentielles de l’organisation des réseaux mitochondriaux musculaires pourraient contribuer aux réponses adaptatives des organismes face aux contraintes environnementales

Nuclear defects in skeletal muscle from a Dynamin 2-linked centronuclear myopathy mouse model

Abstract Dynamin 2 (DNM2) is a key protein of the endocytosis and intracellular membrane trafficking machinery. Mutations in the DNM2 gene cause autosomal dominant centronuclear myopathy (CNM) and a knock-in mouse model expressing the most frequent human DNM2 mutation in CNM (Knock In-Dnm2 R465W/+) develops a myopathy sharing similarities with human disease. Using isolated muscle fibres from Knock In-Dnm2 R465W/+ mice, we investigated number, spatial distribution and morphology of myonuclei. We showed a reduction of nuclear number from 20 weeks of age in Tibialis anterior muscle from heterozygous mice. This reduction is associated with a decrease in the satellite cell content in heterozygous muscles. The concomitant reduction of myonuclei number and cross-section area in the heterozygous fibres contributes to largely maintain myonuclear density and volume of myonuclear domain. Moreover, we identified signs of impaired spatial nuclear distribution including alteration of distance from myonuclei to their nearest neighbours and change in orientation of the nuclei. This study highlights reduction of number of myonuclei, a key regulator of the myofiber size, as a new pathomechanism underlying muscle atrophy in the dominant centronuclear myopathy. In addition, this study opens a new line of investigation which could prove particularly important on satellite cells in dominant centronuclear myopathy

Thyroid status affects membranes susceptibility to free radicals and oxidative balance in skeletal muscle of Muscovy ducklings (Cairina moschata)

International audienceThyroid hormones (TH) are major contributor to oxidative stress in mammals because they (1) stimulate reactive oxygen species generation (ROS), (2) impair antioxidant defenses, and (3) increase the susceptibility to free radicals of most tissues. Unlike mammals, THs seem to diminish mitochondrial ROS while they have limited effect on the antioxidant machinery in birds. However, how THs modify the susceptibility to ROS has never been explored in an avian model, and very little is known about their effect on oxidative balance in birds. Therefore, the objective of our study was to examine the effect of chronic pharmacological hypo␣ and hyperthyroidism on (i) the susceptibility of mitochondrial membranes to ROS; and (ii) the level of oxidative stress assessed by measuring oxidative damage to lipids, nucleic acids and proteins in the gastrocnemius muscle of ducklings. We show that hypothyroidism had no effect on the susceptibility of mitochondrial membranes to free radicals. Hypothyroid ducklings had lower oxidized lipids (-31%) and DNA (+25%) but a similar level of protein carbonylation relative to controls. Conversely, mitochondrial membranes of hyperthyroid ducklings exhibited higher unsaturation (þ12%) and peroxidation (þ31%) indexes than in controls indicating a greater susceptibility to free radicals. However, hyperthyroid ducklings exhibited more oxidative damages on proteins (+67%) only, whereas lipid damages remained unchanged, and there was a slight reduction (-15%) in damages to DNA compared to euthyroid controls. Our results indicate that birds and mammals present fundamental differences in their oxidative stress response to thyroid status

Skeletal muscle phenotype affects fasting-induced mitochondrial oxidative phosphorylation flexibility in cold-acclimated ducklings

International audienceStarvation is particularly challenging for endotherms that remain active in cold environments or during winter. The aim of this study was to determine whether fasting-induced mitochondrial coupling flexibility depends upon the phenotype of skeletal muscles. The rates of oxidative phosphorylation and mitochondrial efficiency were measured in pectoralis (glycolytic) and gastrocnemius (oxidative) muscles from cold-acclimated ducklings (Cairina moschata). Pyruvate and palmitoyl-L-carnitine were used in the presence of malate as respiratory substrates. Plasma metabolites, skeletal muscle concentrations of triglycerides, glycogen and total protein and mitochondrial levels of oxidative phosphorylation complexes were also quantified. Results from ad libitum fed ducklings were compared with those from ducklings that were fasted for 4 days. During the 4 days of nutritional treatment, birds remained in the cold, at 4°C. The 4 days of starvation preferentially affected the pectoralis muscles, inducing an up-regulation of mitochondrial efficiency, which was associated with a reduction of both total muscle and mitochondrial oxidative phosphorylation protein, and with an increase of intramuscular lipid concentration. By contrast, fasting decreased the activity of oxidative phosphorylation but did not alter the coupling efficiency and protein expression of mitochondria isolated from the gastrocnemius muscles. Hence, the adjustment of mitochondrial efficiency to fasting depends upon the muscle phenotype of cold-acclimated birds. Furthermore, these results suggest that the reduced cost of mitochondrial ATP production in pectoralis muscles may trigger lipid storage within this tissue and help to sustain an important metabolic homeostatic function of skeletal muscles, which is to maintain levels of amino acids in the circulation during the fast