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1	The Metabolic and Structural Response of Human Skeletal Muscle to Acute Exercise and Nutritional Manipulation Cermak, Naomi M. 09 1900 (has links) <p> The work in this thesis describes the metabolic and structural response of human skeletal muscle to acute exercise and nutritional manipulation. Over a series of three studies, healthy young men performed acute bouts of either endurance or resistance exercise, and a range of invasive and non-invasive techniques were applied to examine the muscle adaptive response during exercise and recovery. Study 1 investigated the hypothesis that co-ingestion of protein with carbohydrate during exercise would improve oxidative energy metabolism and attenuate ultrastructural disruption during prolonged 90 min of cycling at ~70% VO2peak. While protein ingestion increased blood amino acids, there was no difference between treatments in glycogen degradation or the content of TCA cycle intermediates during exercise, or the blood concentration of plasma creatine kinase (CK) after 24 h of recovery. Given the limitations associated with traditional indirect markers of muscle injury, study 2 examined the potential for a non-invasive imaging technique, diffusion tensor magnetic resonance imaging (DT-MRI), to detect exercise-induced changes in skeletal muscle structure. Subjects performed 300 eccentric actions of the leg extensors, a protocol previously shown to induce histological evidence of muscle disruption. DT-MRI revealed changes consistent with muscle disorganization 24 h post-exercise compared to baseline, including decreased fractional anisotropy (FA) and increased tensor eigenvalue λ3. The exercise protocol also induced changes in traditional direct and indirect markers of muscle injury, including Z-band streaming, increased blood CK and a decrease in force-generating capacity. Study 3 examined the potential for DT-MRI to detect structural changes in response to an acute bout of work, previously shown to induce muscle damage that more closely simulated normal endurance exercise. Subjects performed 45 min of downhill running (-10° grade) and DT-MRI revealed increased ADC and tensor eigenvalue λ3 24 h post-exercise compared to baseline, in addition to increased plasma CK and decreased force-generating capacity. The main finding from the thesis is the application of DT-MRI to non-invasively detect exercise-induced changes in skeletal muscle structure as verified using well understood direct and indirect measures of muscle damage.</p> / Thesis / Doctor of Philosophy (PhD)
2	The Role of Heat Shock Protein 70 in Protecting Muscle Mechanical Function & SERCA Function in Human Skeletal Muscle Stewart, Riley David 16 March 2009 (has links) Two studies were conducted to determine if Hsp70 is able to protect human skeletal muscle from muscle mechanical damage and alterations in SERCA activity associated with prolonged concentric exercise. In the first study, one-legged isometric knee extension exercise at 40% MVC and a duty cycle of 50% (5 sec contraction followed by 5 sec of relaxation) was used to induce a heat shock response in one leg only. Participants were followed over six recovery days to determine the time course of Hsp70 induction and decay. Results showed fiber type specific increases in Hsp70 that persisted in one leg only throughout six days of recovery. These increases in Hsp70 occurred with only transient changes in Ca2+ uptake and muscular force. With the exception of minor decreases in low frequency force, there were no apparent reductions in muscular force or SERCA activity by the third recovery day. Therefore an exercise protocol was established which was able to induce a heat shock response with only minor alterations in muscle mechanical function and SERCA activity. In the second study, the same isometric exercise was employed, however, on the day corresponding to recovery day 3 in the first study, participants were asked to complete a one hour cycling protocol at 70% VO2 max. The goal was to cause similar one-legged increases in Hsp70 as the first study and to then challenge SERCA activity and muscular force in the presence of elevated Hsp70 by using cycling exercise. Results showed cycling induced reductions in maximal Ca2+ ATPase activity, muscular force, rates of muscle relaxation, and rates of muscle force development were attenuated by the preconditioning (isometric) exercise. These studies confirm the idea that preconditioning exercise is able to attenuate subsequent exercise induced insults to SERCA activity and muscular force, likely through an Hsp70 mediated mechanism. Human Skeletal Muscle Hsp70 SERCA Muscle Fatigue Kinesiology
3	The Role of Heat Shock Protein 70 in Protecting Muscle Mechanical Function & SERCA Function in Human Skeletal Muscle Stewart, Riley David 16 March 2009 (has links) Two studies were conducted to determine if Hsp70 is able to protect human skeletal muscle from muscle mechanical damage and alterations in SERCA activity associated with prolonged concentric exercise. In the first study, one-legged isometric knee extension exercise at 40% MVC and a duty cycle of 50% (5 sec contraction followed by 5 sec of relaxation) was used to induce a heat shock response in one leg only. Participants were followed over six recovery days to determine the time course of Hsp70 induction and decay. Results showed fiber type specific increases in Hsp70 that persisted in one leg only throughout six days of recovery. These increases in Hsp70 occurred with only transient changes in Ca2+ uptake and muscular force. With the exception of minor decreases in low frequency force, there were no apparent reductions in muscular force or SERCA activity by the third recovery day. Therefore an exercise protocol was established which was able to induce a heat shock response with only minor alterations in muscle mechanical function and SERCA activity. In the second study, the same isometric exercise was employed, however, on the day corresponding to recovery day 3 in the first study, participants were asked to complete a one hour cycling protocol at 70% VO2 max. The goal was to cause similar one-legged increases in Hsp70 as the first study and to then challenge SERCA activity and muscular force in the presence of elevated Hsp70 by using cycling exercise. Results showed cycling induced reductions in maximal Ca2+ ATPase activity, muscular force, rates of muscle relaxation, and rates of muscle force development were attenuated by the preconditioning (isometric) exercise. These studies confirm the idea that preconditioning exercise is able to attenuate subsequent exercise induced insults to SERCA activity and muscular force, likely through an Hsp70 mediated mechanism. Human Skeletal Muscle Hsp70 SERCA Muscle Fatigue Kinesiology
4	Methods and models for 2D and 3D image analysis in microscopy, in particular for the study of muscle cells / Metoder och modeller för två- och tredimensionell bildanalys inom mikroskopi, speciellt med inrikting mot muskelceller Karlsson Edlund, Patrick January 2008 (has links) <p>Many research questions in biological research lead to numerous microscope images that need to be evaluated. Here digital image cytometry, i.e., quantitative, automated or semi-automated analysis of the images is an important rapidly growing discipline. This thesis presents contributions to that field. The work has been carried out in close cooperation with biomedical research partners, successfully solving real world problems.</p><p>The world is 3D and modern imaging methods such as confocal microscopy provide 3D images. Hence, a large part of the work has dealt with the development of new and improved methods for quantitative analysis of 3D images, in particular fluorescently labeled skeletal muscle cells.</p><p>A geometrical model for robust segmentation of skeletal muscle fibers was developed. Images of the multinucleated muscle cells were pre-processed using a novel spatially modulated transform, producing images with reduced complexity and facilitating easy nuclei segmentation. Fibers from several mammalian species were modeled and features were computed based on cell nuclei positions. Features such as myonuclear domain size and nearest neighbor distance, were shown to correlate with body mass, and femur length. Human muscle fibers from young and old males, and females, were related to fiber type and extracted features, where myonuclear domain size variations were shown to increase with age irrespectively of fiber type and gender.</p><p>A segmentation method for severely clustered point-like signals was developed and applied to images of fluorescent probes, quantifying the amount and location of mitochondrial DNA within cells. A synthetic cell model was developed, to provide a controllable golden standard for performance evaluation of both expert manual and fully automated segmentations. The proposed method matches the correctness achieved by manual quantification. </p><p>An interactive segmentation procedure was successfully applied to treated testicle sections of boar, showing how a common industrial plastic softener significantly affects testosterone concentrations.</p> medical image analysis image segmentation fluorescence microscopy cytometry human skeletal muscle
5	Methods and models for 2D and 3D image analysis in microscopy, in particular for the study of muscle cells / Metoder och modeller för två- och tredimensionell bildanalys inom mikroskopi, speciellt med inrikting mot muskelceller Karlsson Edlund, Patrick January 2008 (has links) Many research questions in biological research lead to numerous microscope images that need to be evaluated. Here digital image cytometry, i.e., quantitative, automated or semi-automated analysis of the images is an important rapidly growing discipline. This thesis presents contributions to that field. The work has been carried out in close cooperation with biomedical research partners, successfully solving real world problems. The world is 3D and modern imaging methods such as confocal microscopy provide 3D images. Hence, a large part of the work has dealt with the development of new and improved methods for quantitative analysis of 3D images, in particular fluorescently labeled skeletal muscle cells. A geometrical model for robust segmentation of skeletal muscle fibers was developed. Images of the multinucleated muscle cells were pre-processed using a novel spatially modulated transform, producing images with reduced complexity and facilitating easy nuclei segmentation. Fibers from several mammalian species were modeled and features were computed based on cell nuclei positions. Features such as myonuclear domain size and nearest neighbor distance, were shown to correlate with body mass, and femur length. Human muscle fibers from young and old males, and females, were related to fiber type and extracted features, where myonuclear domain size variations were shown to increase with age irrespectively of fiber type and gender. A segmentation method for severely clustered point-like signals was developed and applied to images of fluorescent probes, quantifying the amount and location of mitochondrial DNA within cells. A synthetic cell model was developed, to provide a controllable golden standard for performance evaluation of both expert manual and fully automated segmentations. The proposed method matches the correctness achieved by manual quantification. An interactive segmentation procedure was successfully applied to treated testicle sections of boar, showing how a common industrial plastic softener significantly affects testosterone concentrations. medical image analysis image segmentation fluorescence microscopy cytometry human skeletal muscle
6	Deep-Tissue Heating as a Therapeutic Intervention to Prevent Skeletal Muscle Atrophy in Humans Hafen, Paul S 01 July 2018 (has links) Skeletal muscle is a highly adaptable tissue that comprises approximately 40% of total body weight while accounting for up to 90% of whole-body oxygen consumption and energy expenditure during exercise. The loss of skeletal muscle protein and subsequent decrease in muscle mass (atrophy) that accompanies disuse results primarily from a decrease in intracellular protein synthesis combined with an increase in proteolytic activity. Interestingly, these processes of skeletal muscle atrophy are amplified by changes in mitochondrial capacity, with evidence suggesting that the maintenance of mitochondria during periods of disuse protects skeletal muscle against atrophy. Remarkably, rodents with denervated muscle are protected against muscle atrophy following whole-body heat stress. The mechanism of protection appears to be tied to the observed increases in heat shock protein (HSP) and PGC-1α, which accompany the heat stress. Without any published observations as to whether such heat-induced protection against muscle atrophy would translate to human muscle, the aim of this project was to determine the extent to which deep tissue heating (via pulsed shortwave diathermy) might provide protection against skeletal muscle atrophy. muscle atrophy human skeletal muscle immobilization heat stress heat shock mitochondrial respiration Life Sciences
7	Altérations du muscle squelettique humain lors du vieillissement associé ou non au syndrome métabolique et identification de nouveaux marqueurs Gueugneau, Marine 13 February 2014 (has links) Le vieillissement musculaire (sarcopénie) conduit inéluctablement à une perte d'autonomie, et à une moindre capacité à lutter contre les agressions métaboliques. Or, les mécanismes mis en jeu sont complexes et restent mal connus. Ainsi, au cours de cette thèse, une étude protéomique comparative a été développée afin d'identifier de nouveaux biomarqueurs potentiels de la sarcopénie chez la femme âgée post-ménopausée, et 73 protéines exprimées différentiellement dans le muscle âga ont été identifiées. En plus des altérations du muscle squelettique, l'âge est connu comme étant un facteur favorisant l'apparition du syndrome métabolique (SM), facteur de risque pour les maladies cardiovasculaires et le diabète de type II. Cependant, les effets du SM sur le muscle squelettique des personnes âgées sont peu décrits dans la littérature. Des marquages immunohistologiques ont été réalisés à partir de biopsies du muscle vastus lateralis provenant de personnes jeunes (25 ans) et âgées avec ou sans SM (75 ans), afin de décrire les altérations structurales et fonctionnelles du muscle squelettique liées à l'âge et au MS. Les résultats montrent une atrophie des fibres de type II ayant une déformation accrue lors du vieillissement. Chez les personnes âgées atteintes de SM, l'aire des fibres est augmentée par rapport aux personnes âgées contrôles, et une forte diminution de l'activité cytochrome c oxydase a été observée. De plus, le vieillissement et plus particulièrement le SM sont associés à une forte accumulation de lipides intramusculaires. Enfin, alors que peu de différences ont été observées chez les personnes âgées contrôles, le contenu en capillaire est fortement altéré chez les individus atteints de SM. Par la suite, une étude protéomique comparative a permis d'identifier 42 biomarqueurs potentiellement impliqués dans le vieillissement musculaire et/ou dans le syndrome métabolique. L'ensemble des résultats obtenus au cours de cette thèse devrait permettre d'améliorer notre compréhension des facteurs impliqués dans le développement de la sarcopénie, et pourrait permettre d'identifier à la fois de nouvelles voies de régulation et suggérer des cibles thérapeutiques potentielles. / Muscle aging (sarcopenia) contributes to both loss of autonomy and decreased capacity to prevent metabolic aggressions, but the mechanisms involved are complex and remain unclear. Therefore in this thesis, we have undertaken a top-down differential proteomic approach to reveal novel potential biomarkers of sarcopenia, and 73 differentially expressed proteins were identified. In addition to alterations of skeletal muscle, aging favors metabolic syndrome (MS), a risk factor for cardiovascular disease and type II diabetes. However, the effects of MS on skeletal muscle in old individuals have poorly been investigated. Immunohistochemical studies were performed with vastus lateralis muscle biopsies from young (25 years) and old (75 years) men with and without MS, to reveal the importance of age-dependent and MS-associated modifications on fiber-type characteristics. An atrophy of type-II fibers and altered fiber shape characterized muscle aging in lean healthy men. In contrast, increased cross sectional area of fibers, and reduced cytochrome c oxidase activity in all fiber types characterized MS, even in active elderly men. Moreover, aging and particularly MS were associated with accumulation of intramyocellular lipid droplets. Finally, while few differences were observed in lean healthy men, the capillary supply was strongly altered in old men with MS. Thereafter, a differential proteomic approach identified 42 potential biomarkers implicated in muscle aging and/or in metabolic syndrome. Overall the results obtained in this thesis may improve our understanding of the factors influencing sarcopenia, and may both identify new regulatory pathways and provide potential therapeutical targets. Vieillissement Muscle squelettique humain Types de fibres musculaires Syndrome métabolique Biomarqueurs Aging Human skeletal muscle Fiber types Metabolic syndrome Biomarkers
8	Diffusion Tensor Imaging of the Human Skeletal Muscle : Contributions and Applications / IRM du tenseur de diffusion du muscle squelettique humain : contributions et applications Neji, Radhouène 09 March 2010 (has links) Cette thèse propose des techniques pour le traitement d'images IRM de diffusion. Les méthodes proposées concernent l'estimation et la régularisation, le groupement et la segmentation ainsi que le recalage. Le cadre variationnel proposé dans cette thèse pour l'estimation d'un champ de tenseurs de diffusion à partir d'observations bruitées exploite le fait que les données de diffusion représentent des populations de fibres et que chaque tenseur peut être reconstruit à partir d'une combinaison pondérée de tenseurs dans son voisinage. La méthode de segmentation traite aussi bien les voxels que les fibres. Elle est basée sur l'utilisation de noyaux défini-positifs sur des probabilités gaussiennes de diffusion afin de modéliser la similarité entre tenseurs et les interactions spatiales. Ceci permet de définir des métriques entre fibres qui combinent les informations de localisation spatiale et de tenseurs de diffusion. Plusieurs approches de groupement peuvent être appliquées par la suite pour segmenter des champs de tenseurs et des trajectoires de fibres. Un cadre de groupement supervisé est proposé pour étendre cette technique. L'algorithme de recalage utilise les noyaux sur probabilités pour recaler une image source et une image cible. La régularité de la déformation est évaluée en utilisant la distortion induite sur les distances entre probabilités spatialement voisines. La minimisation de la fonctionnelle de recalage est faite dans un cadre discret. La validation expérimentale est faite sur des images du muscle du mollet pour des sujets sains et pour des patients atteints de myopathies. Les résultats des techniques développées dans cette thèse sont encourageants. / In this thesis, we present several techniques for the processing of diffusion tensor images. They span a wide range of tasks such as estimation and regularization, clustering and segmentation, as well as registration. The variational framework proposed for recovering a tensor field from noisy diffusion weighted images exploits the fact that diffusion data represent populations of fibers and therefore each tensor can be reconstructed using a weighted combination of tensors lying in its neighborhood. The segmentation approach operates both at the voxel and the fiber tract levels. It is based on the use of Mercer kernels over Gaussian diffusion probabilities to model tensor similarity and spatial interactions, allowing the definition of fiber metrics that combine information from spatial localization and diffusion tensors. Several clustering techniques can be subsequently used to segment tensor fields and fiber tractographies. Moreover, we show how to develop supervised extensions of these algorithms. The registration algorithm uses probability kernels in order to match moving and target images. The deformation consistency is assessed using the distortion induced in the distances between neighboring probabilities. Discrete optimization is used to seek an optimum of the defined objective function. The experimental validation is done over a dataset of manually segmented diffusion images of the lower leg muscle for healthy and diseased subjects. The results of the techniques developed throughout this thesis are promising. IRM de diffusion Tenseur de diffusion Fibre Noyaux Groupement Recalage Débruitage Muscle squelettique Myopathies Diffusion Tensor DTI Human Skeletal Muscle
9	ROLE OF SECOND MESSENGER SIGNALING PATHWAYS IN THE REGULATION OF SARCOPLASMIC RETICULUM CALCIUM-HANDLING PROPERTIES IN THE LEFT VENTRICLE AND SKELETAL MUSCLES OF DIFFERENT FIBRE TYPE COMPOSITION Duhamel, Todd A D January 2007 (has links) The overall objective of this thesis was to examine mechanisms involved in the acute regulation of sarcoplasmic reticulum (SR) Ca2+-handling properties by second messenger signaling pathways in skeletal and cardiac muscle. The aim of the first study (Chapter Two) was to characterize changes in the kinetic properties of sarco(endo)-plasmic reticulum Ca2+-ATPase (SERCA) proteins in cardiac and skeletal muscles in response to b-adrenergic, Ca2+-dependent calmodulin kinase II (CaMKII) and protein kinase C (PKC) signaling. The aim of the second study (Chapter Three) was to determine if insulin signaling could acutely regulate SERCA kinetic properties in cardiac and skeletal muscle. The aim of the final study (Chapter Four) was to determine if alterations in plasma glucose, epinephrine and insulin concentrations during exercise are able to influence SR Ca2+-handling properties in contracting human skeletal muscle. Data collected in Chapter Two and Chapter Three were obtained using tissue prepared from a group of 28 male Sprague-Dawley rats (9 weeks of age; mass = 280 ?? 4 g: X ?? S.E). Crude muscle homogenates (11:1 dilution) were prepared from selected hind limb muscles (soleus, SOL; extensor digitorum longus, EDL; the red portion of gastrocnemius, RG; and the white portion of gastrocnemius, WG) and the left ventricle (LV). Enriched SR membrane fractions, prepared from WG and LV, were also analyzed. A spectrophotometric assay was used to measure kinetic properties of SERCA, namely, maximal SERCA activity (Vmax), and Ca2+-sensitivity was characterized by both the Ca50, which is defined as the free Ca2+-concentration needed to elicit 50% Vmax, and the Hill coefficient (nH), which is defined as the relationship between SERCA activity and Ca2+f for 10 to 90% Vmax. The observations made in Chapter Two indicated that b-adrenergic signaling, activated by epinephrine, increased (P<0.05) Ca2+-sensitivity, as shown by a left-shift in Ca50 (i.e. reduced Ca50), without altering Vmax in LV and SOL but had no effect (P<0.05) on EDL, RG, or WG. Further analysis using a combination of cAMP, the PKA activator forskolin, and/or the PKA inhibitor KT5270 indicated that the reduced Ca50 in LV was activated by cAMP- and PKA-signaling mechanisms. However, although the reduced Ca50 in SOL was cAMP-dependent, it was not influenced by a PKA-dependent mechanism. In contrast to the effects of b-adrenergic signaling, CaMKII activation increased SERCA Ca2+-sensitivity, as shown by a left-shift in Ca50 and increased nh, without altering SERCA Vmax in LV but was without effect in any of the skeletal muscles examined. The PKC activator PMA significantly reduced SERCA Ca2+-sensitivity, by inducing a right-shift in Ca50 and decreased nH in the LV and all skeletal muscles examined. PKC activation also reduced Vmax in the fast-twitch skeletal muscles (i.e. EDL, RG and WG), but did not alter Vmax in LV or SOL. The results of Chapter Three indicated that insulin signaling increased SERCA Ca2+-sensitivity, as shown by a left-shift in Ca50 (i.e. reduced Ca50) and an increased nH, without altering SERCA Vmax in crude muscle homogenates prepared from LV, SOL, EDL, RG, and WG. An increase in SERCA Ca2+-sensitivity was also observed in enriched SERCA1a and SERCA2a vesicles when an activated form of the insulin receptor (A-INS-R) was included during biochemical analyses. Co-immunoprecipitation experiments were conducted and indicated that IRS-1 and IRS-2 proteins bind SERCA1a and SERCA2a in an insulin-dependent manner. However, the binding of IRS proteins with SERCA does not appear to alter the structural integrity of the SERCA Ca2+-binding site since no changes in NCD-4 fluorescence were observed in response to insulin or A-INS-R. Moreover, the increase in SERCA Ca2+-sensitivity due to insulin signaling was not associated with changes in the phosphorylation status of phospholamban (PLN) since Ser16 or Thr17 phosphorylation was not altered by insulin or A-INS-R in LV tissue. The data described in Chapter Four was collected from 15 untrained human participants (peak O2 consumption, VO2peak= 3.45 ?? 0.17 L/min) who completed a standardized cycle test (~60% VO2peak) on two occasions during which they were provided either an artificially sweetened placebo (PLAC) or a 6% glucose (GLUC) beverage (~1.00 g CHO per kg body mass). Muscle biopsies were collected from the vastus lateralis at rest, after 30 min and 90 min of exercise and at fatigue in both conditions to allow assessment of metabolic and SR data. Glucose supplementation increased exercise ride time by ~19% (137 ?? 7 min) compared to PLAC (115 ?? 6 min). This performance increase was associated with elevated plasma glucose and insulin concentrations and reduced catecholamine concentrations during GLUC compared to PLAC. Prolonged exercise reduced (p<0.05) SR Ca2+-uptake, Vmax, Phase 1 and Phase 2 Ca2+-release rates during both PLAC and GLUC. However, no differences in SR Ca2+-handling properties were observed between conditions when direct comparisons were made at matched time points between PLAC and GLUC. In summary, the results of the first study (Chapter Two) indicate that b-adrenergic and CaMKII signaling increases SERCA Ca2+-sensitivity in the LV and SOL; while PKC signaling reduces SERCA Ca2+-sensitivity in all tissues. PKC activation also reduces Vmax in the fast-twitch skeletal muscles (i.e. EDL, RG, and WG) but has no effect on Vmax in the LV and SOL. The results of the second study (Chapter Three) indicate that insulin signaling acutely increases the Ca2+-sensitivity of SERCA1a and SERCA2a in all tissues examined, without altering the Vmax. Based on our observations, it appears that the increase in SERCA Ca2+-sensitivity may be regulated, in part, through the interaction of IRS proteins with SERCA1a and SERCA2a. The results of the final study (Chapter Four) indicate that alterations in plasma glucose, epinephrine and insulin concentrations associated with glucose supplementation during exercise, do not alter the time course or magnitude of reductions in SERCA or Ca2+-release channel (CRC) function in working human skeletal muscle. Although glucose supplementation did increase exercise ride time to fatigue in this study, our data does not reveal an association with SR Ca2+-cycling measured in vitro. It is possible that the strength of exercise signal overrides the hormonal influences observed in resting muscles. Additionally, these data do not rule out the possibility that glucose supplementation may influence E-C coupling processes or SR Ca2+-cycling properties in vivo.
10	Rôle de l'Annexine-A5 dans la réparation membranaire du muscle strié squelettique et du placenta humains / Role of Annexin-A5 in cell membrane repair in human skeletal muscle and placenta Carmeille, Romain 27 November 2015 (has links) La membrane plasmique est un assemblage supramoléculaire qui délimite la cellule. C’est une structure fine, complexe et dynamique assurant des fonctions multiples et vitales pour la cellule. Sa rupture est un évènement physiologique pour les cellules soumises à des stress mécaniques fréquents et/ou importants, comme les cellules épithéliales, les cellules endothéliales ou les cellules musculaires. Dans des conditions physiopathologiques, la membrane plasmique peut également être endommagée par l’insertion de toxines bactériennes formant des pores (PFTs, pour « pore forming toxins »). Le processus de réparation membranaire et la machinerie protéique associée sont encore mal connus. Connaître les partenaires protéiques et comprendre les mécanismes mis en jeu durant le processus de réparation de la membrane plasmique sont deux enjeux fondamentaux majeurs. En effet, il a été établi qu’une défaillance du processus de réparation membranaire pour les fibres musculaires est la cause principale de certaines dystrophies musculaires. La machinerie protéique de réparation comprend des protéines comme la dysferline, la cavéoline-3 et certaines Annexines (Anx). Les Anx appartiennent à une superfamille de protéines répandue chez la plupart des eucaryotes, qui ont la propriété commune de se lier aux membranes biologiques en présence de calcium (Ca2+). Certaines Anx, comme l’AnxA5, une fois liées aux membranes biologiques s’auto-assemblent spontanément en réseau-2D. Lors de ce travail de thèse, nous avons étudié le rôle de l’AnxA5 dans la réparation membranaire des trophoblastes placentaires et des cellules du muscle squelettique humain. Pour les deux types cellulaires, nous avons montré que l’AnxA5 est un acteur indispensable du processus de réparation membranaire dans le cas de ruptures mécaniques. En associant des approches de microscopie de fluorescence et de microscopie électronique à transmission (MET), nous avons mis en évidence que dans ces cellules, le mécanisme de réparation est principalement basé sur la formation d’un « patch » lipidique. Dans les cellules musculaires, les expériences de MET ont mis en évidence qu’un pool d’AnxA5 endogène se lie aux bords du site de rupture quelques secondes après la lésion du sarcolemme. Ceci suggère qu’après rupture de la membrane plasmique, l’augmentation locale de la concentration calcique intracellulaire provoque la liaison de l’AnxA5 spécifiquement aux bords de la région membranaire lésée où elle forme un réseau-2D. Le réseau-2D stabiliserait localement la membrane et préviendrait sa déchirure, induite par les forces de tensions exercées par le cytosquelette cortical. Nous avons également montré que l’AnxA5 ne semble pas impliquée dans la réparation de la membrane plasmique après insertion de PFTs. Ceci suggère que différents mécanismes de réparation existent et que leur mise en place dépend probablement du type ou de l’importance des dommages. Finalement nous avons étendu notre étude à des lignées cellulaires établies à partir de patients diagnostiqués comme souffrant de dystrophies des ceintures de type 2B (déficience en dysferline) et 1C (déficience en cavéoline-3), respectivement. Nous avons montré, pour ces lignées, que la déficience en dysferline ou cavéoline-3 provoque un défaut de réparation dans le cas des ruptures mécaniques de la membrane plasmique. Dans ces cellules musculaires pathologiques intactes ou endommagées, l’AnxA5 a le même comportement, ce qui suggère que l’action de l’AnxA5 est indépendante de ces protéines. A la différence des cellules déficientes en dysferline, nous avons observé que les cellules déficientes en cavéoline-3 sont capables de réparer efficacement des lésions créées par l’insertion de PFTs dans le sarcolemme. Ce résultat supporte l’hypothèse de l’existence de plusieurs mécanismes de réparation. En conclusion, ce travail montre que l’AnxA5 est un composant clé de la machinerie de réparation dans le cas des ruptures mécaniques. / Plasma membrane is the supramolecular assembly that delimits the cell. It is a thin, dynamic and complex structure, ensuring multiple and vital cell functions. Its disruption is a physiological event occurring in cells submitted to frequent mechanical stresses, such as endothelial cells, epithelial cells and muscle cells. It is also a physiological event for cells exposed to pore forming bacterial toxins (PFTs). Membrane repair mechanisms and associated protein machinery are still poorly understood. This knowledge is, however, essential for obvious physiopathological issues. Indeed, a defect of membrane repair in muscle cells leads to some muscular dystrophies. Membrane repair machinery includes proteins such as dysferlin, MG-53, caveolin-3 and some Annexins (Anx). Anx belong to a superfamily of proteins widely spread in most of eukaryotes, which share the property of binding to biological membranes in the presence of calcium (Ca2+). Here, we investigated the role of AnxA5 in cell membrane repair of human trophoblastic and skeletal muscle cells. We showed that AnxA5 is required for membrane repair of mechanical damages in the two cell types. By combining fluorescence and transmission electron microscopy approaches, we evidenced that membrane repair mechanism in these cells is based on the formation of a lipid “patch”. In human muscle cells, TEM experiments revealed that a pool of endogenous AnxA5 binds to the edges of the torn sarcolemma as soon as a few seconds after membrane disruption. Our results suggest the following mechanism: triggered by the local increase in Ca2+ concentration, AnxA5 molecules bind to PS exposed at the edges of the torn membrane, where they self-assemble into 2D arrays. The formation of 2D arrays strengthens the damaged sarcolemma, counteracts the tensions exerted by the cortical cytoskeleton and thus prevents the expansion of the tear. We showed also that a pool of endogenous AnxA5 binds to intracellular vesicles that obstruct the wounding site. It is likely these vesicles, once associated one to each other, ensure membrane resealing. Our results suggest that sarcolemma repair of damages caused by PFTs is independent of AnxA5. Therefore, different membrane repair mechanisms may exist, their occurrence probably depending on the type and/or the size of damages. Finally, we performed studies on muscle cells established from patients diagnosed with limb girdle muscular dystrophies type 2B (dysferlin-deficient) and 1C (caveolin-3-deficient), respectively. We found that dysferlin or caveolin-3 deficiency leads to a defect of membrane repair, in the case of mechanical damages. AnxA5 behaved similarly in these damaged cells and wild-type cells, suggesting that its function is independent of dysferlin or caveolin-3. Unlike dysferlin-deficient cells, damages created by PFTs are efficiently repaired in caveolin- 3-deficient cells. This result supports the hypothesis that different mechanisms occur in muscle cells, depending on the type of damage. In conclusion, this work indicates that AnxA5 is a key component of the membrane repair machinery, in the case of mechanical disruptions. Our results enable to propose a detailed mode of action for AnxA5. Annexine-A5 Réparation membranaire Muscle strié squelettique humain Trophoblastes humains Dystrophies musculaires Annexin-A5 Cell membrane repair Human skeletal muscle Human trophoblasts Muscular dystrophies

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