Global ETD Search

451	Sarcopenia : Mechanisms and Prevention : Role of Exercise and Growth Hormone : Involvement of oxidative stress and Glucose-6- phosphate dehydrogenase / Sarcopenie : mécanismes et prévention : rôle de l'exercice et de l'hormone de croissance : implication du stress oxydant et de la glucose-6-phosphate déshydrogénase Brioche, Thomas 09 April 2014 (has links) Le vieillissement est caractérisé par une diminution de la masse et la force musculaire entraînant une détérioration des performances physiques, appelée sarcopénie. L'atrophie musculaire peut être expliquée par un turnover protéique négatif, une détérioration des dynamiques mitochondriales, une diminution de la capacité de régénération du muscle ainsi que par l'apoptose des noyaux musculaires. La diminution de la sécrétion d'hormones anabolisantes et un stress oxydant (OS) chronique conduisant à des dommages oxydatifs excessifs, seraient impliqués dans ces modifications. L’Exercice physique et les thérapies de remplacement hormonales sont efficaces pour lutter contre la sarcopénie. Une restauration de l’homéostasie redox pourrait avoir un rôle central dans la lutte contre la sarcopénie et impliquerait une activation de la glucose-6-phosphate déshydrogénase.Les principaux objectifs de cette thèse étaient de déterminer in vivo, si un SO chronique dans le muscle âgé altère les voies de signalisation impliquées dans la sarcopénie, et de chercher si le retour à un fonctionnement normal de ces voies nécessite une restauration de l'homéostasie redox. Certains paramètres et leurs mécanismes pouvant intervenir sur le maintien ou la restauration du SO ont été recherchés.Dans une première, nous avons confirmé que la sarcopénie est associée au OS chez le rat. Puis nous avons constaté qu’un traitement à l'hormone de croissance chez le rat peut prévenir la sarcopénie via un effet antioxydant et myogénique, associé à une activation de la G6DPH.Une seconde étude a monté des souris transgéniques surexprimant G6PDH présentaient une amélioration de la composition corporelle et des performances physiques.Une dernière étude a montré que la surexpression de G6DPH diminuait les dommages oxydatifs de l'ADN au repos. De façon surprenante, la surexpression de la G6PDH n’a pas d’effet protecteur vis à vis du SO induit par les divers stimuli pro-oxydants. / Aging is characterized by a decrease in muscle mass and strength causing a deterioration of physical performance, called sarcopenia. Muscle atrophy can be explained by a negative protein turnover, impaired mitochondrial dynamics, a decreased muscle regeneration capacity and myonuclei apoptosis. A decreased production of anabolic hormones and a chronic oxidative stress (OS) which leads to excessive oxidative damage would be involved in these alterations. Physical exercise and hormone replacement therapies are effective to combat sarcopenia. The restoration of a redox homeostasis may play a central role in their beneficial effects and would involve an up-regulation of the glucose-6-phosphate dehydrogenase enzyme.The main objectives of this thesis were to determine in vivo to what extent a pro-oxidant redox status in aged muscle may modulate signaling pathways involved in sarcopenia, and to investigate whether return to their normal functioning requires a restoration of the redox homeostasis. The third objective was to identify actors and their possible cellular mechanisms in the maintenance and/or the restoration of the redox status.In a first study in old rats, we first confirmed that sarcopenia is associated with OS. In a second time, we found that a growth hormone replacement therapy in olds rats prevents sarcopenia by acting as a double-edged sword, antioxidant as well as myogenic, associated with an up-regulation of G6DPH. Hormone de croissance G6DPH Muscle Growth hormone G6DPH Skeletal muscle 612.67
452	Ion movements during contraction of the guinea pig ileum longitudinal smooth muscle James, Marilyn Rosamond January 1977 (has links) The excitation-contraction-relaxation cycle of the guinea pig ileum longitudinal smooth muscle was studied in muscles contracted by a muscarinic agent, cis-2-methyl-4-dimethylaminomethyl-1,3-dioxolane methiodide (CD) and by 60 mM KC1. Aspects of the cycle were investigated by analyzing the active transport enzyme activities in the sarcolemma, the tissue Ca depots which could release Ca for contraction and the sensitivity of the contractile responses to extracellular ion changes. Essentially net changes of intracellular Ca, Mg, Na and K content during contractions were measured by a modified 'La method'. The tissues were washed for 30 min in 160 mM Tris-HCl solution (pH 7.4) containing 10 mM LaCl₃ at 4°C in order to seal the intracellular ions in the cell and displace extracellular ions. A method to loosen the 'intercellular cementing' substance by reducing the tissue Ca and Mg was developed as an adjunct to the preparation of a sarcolemmal enriched microsomal fraction. The method reduced the tenacity of the tissue and made the tissue easy to disrupt by a mild homogenizing procedure. The method also appeared to aid the extraction of contractile proteins. The microsomal fraction was not detectably contaminated by mitochondria and was enriched with vesicles of sarcolemma, probably originating from the muscle caveolae. The sarcolemma enriched microsomal fraction had a Ca-ATPase activity that was progressively stimulated by 10⁻⁷ to 2.4 x 10⁻⁴ M free Ca²⁺ , did not require Mg and was inhibited by La. The microsomal Ca-ATPase activity was not due to contamination by actomyosin. The actomyosin Ca-r-ATPase in the soluble fraction had a higher affinity than the microsomal Ca-ATPase for Ca and for La. The microsomal Ca-ATPase activity was postulated to be associated with an active Ca pump thought to he located in the cayeolae. The microsomal fraction had a Mg-dependent ATPase that could Be stimulated by Na, but K and ouabain had very little additional effect. The addition of an activating factor in the soluble fraction conferred some K and ouabain sensitivity to the Mg-dependent Na-ATPase, which indicated that a Na,K-ATPase was present in this tissue. Low doses of ouabain contracted the longitudinal ileum but the responses were not antagonized by raising the external K concentration five fold, as would be expected if ouabain acted by inhibiting the Na,K-ATPase. However, the ouabain response was rapidly lost when extracellular Ca was removed from the medium and the decline of the response followed the same time course as the loss of extracellular Ca. The peak of the ouabain contraction coincided with significant increases of intracellular Ca and Na, but K loss was not apparent until relaxation ensued. The results suggested that ouabain has an early direct effect on membrane permeability before it inhibited the Na,K-ATPase. CD (2 x 10⁻⁷ M) and 60 mM KCl induced phasic and tonic contractions of the longitudinal muscle of the ileum. The phasic contraction declined from 100% to 7% over 10 min when Ca was omitted from the physiological medium. This decline followed the time course of the loss of extracellular Ca. This, together with the fact that low concentrations of LaCl₃ inhibited the phasic component, indicated that Ca bound to the outer aspect of the cell was responsible for the phasic component. The tonic component was lost more rapidly than the phasic component when the Ca was removed from the Tyrode's solution. The tonic component seemed activated by free Ca mobilized from the extracellular space. The extracellular origin of the Ca for contraction was consistent with the observed small net gain of intracellular Ca that occurred during the phasic and tonic contractions. The minimal volume of the sarcoplasmic reticulum and the abundance of caveolae was also consistent with the high sensitivity of the tissue to extracellular Ca concentrations. The intracellular Ca gained during contraction wa,s extruded within 30 sec after the CD or 60 mM KCl were washed out of the tissue bath, Following washout of CD, the muscle was quiescent for the 20 to 30 min 'equilibration' phase. Spontaneous activity was absent during this phase and tension was below baseline. After a maximal CD contraction, a second response to CD or to 60 mM KCl induced during the 'equilibration' phase had an altered or desensitized biphasic appearance. Responses of the muscle to CD for 10 min were accompanied by a cytoplasmic loss of K. After washout of CD, the K was regained slowly over 20 to 30 min. Stimulation of the tissue by 60 mM KCl did not cause a loss of K from the muscle nor did it cause desensitization of the muscle. Higher extracellular K concentrations decreased the time required after CD contractions for the return of spontaneous activity and prevented muscle desensitization to repeated doses of CD, probably by accelerating the return of intracellular K levels to normal. It was proposed that during contraction, elevated intracellular Ca activated K channels, thereby increasing K permeability and causing the 'after-hyperpolarization' and subsequent desensitization which follows muscarinic induced contractions. / Pharmaceutical Sciences, Faculty of / Graduate Ileum Ions Guinea pigs Muscle, Smooth Smooth muscle
453	Noncovalent Crosslinking of SH1 and SH2 to Detect Dynamic Flexibility of the SH1 Helix Park, Hyunguk 08 1900 (has links) In this experiment, fluorescent N- (1-pyrenyl) iodoacetamide modified the two reactive thiols, SH1 (Cys 707) and SH2 (Cys 697) on myosin to detect SH1-SH2 a -helix melting. The excimer forming property of pyrene is well suited to monitor the dynamics of the SH1 and SH2 helix melting, since the excimer should only form during the melted state. Decreased anisotropy of the excimer relative to the monomeric pyrene fluorescence is consistent with the disordering of the melted SH1-SH2 region in the atomic model. Furthermore, nucleotide analogs induced changes in the anisotropy of the excimer, suggesting that the nucleotide site modulates the flexibility of SH1-SH2 region. Myosin. Muscle contraction. myosin muscle contraction pyrene excimer forming
454	Treinamento de força com oclusão vascular: adaptações neuromusculares e moleculares / Strength training and vascular occlusion: neuromuscular and molecular adaptations Gilberto Candido Laurentino 23 April 2010 (has links) Estudos têm mostrado que o treinamento de força de baixa intensidade com oclusão vascular (TFOV) tem apresentado resultados similares nos ganhos de força e hipertrofia comparado ao treinamento de força (TF) de alta intensidade. O objetivo deste estudo foi comparar os efeitos de três diferentes programas de TF nos ganhos de força e hipertrofia musculares e na expressão da miostatina (MSTN) e seus antagonistas. Para isso, vinte e nove jovens do sexo masculino, sem experiência em TF, foram recrutados e divididos randomicamente nos grupos: treinamento de força de baixa intensidade sem oclusão (BI), treinamento de força de baixa intensidade com oclusão (BIO) e treinamento de força de alta intensidade sem oclusão (AI). Os grupos BIO e BI treinaram com intensidade de 20% 1RM, enquanto o grupo AI treinou com intensidade de 80% 1RM. A ANOVA one way foi utilizada para testar as diferenças percentuais nos ganhos de força (1RM) e na área de secção transversa (AST) do músculo quadríceps femoral. O modelo misto para análise das medidas repetidas foi utilizado para testar as diferenças nas variáveis miostatina (MSTN), folistatina-3 (FLST-3), SMAD-7 e GASP-1 nos grupos BI, BIO e AI nas condições pré e pós-treinamento. Os resultados mostraram que os aumentos de força e hipertrofia musculares nos grupos BIO e AI foram similares, entretanto superiores ao grupo BI. Esses resultados podem ser atribuídos a maior diminuição na expressão da MSTN nos grupos BIO (45%) e AI (41%) comparados com o grupo BI (16%) e o aumento na expressão dos genes que antagonizam sua atividade (SMAD-7, FLST-3 e GASP-1). Podemos concluir que a inibição na atividade da MSTN dos grupos BIO e AI podem responder em parte a similaridade nos ganhos de força e hipertrofia entre os grupos e a diferença para o grupo BI / It has been demonstrated that low intensity training associated to vascular occlusion (LIO) promotes similar gains in strength and muscle mass when compared to high intensity strength training (HI). The aim of the present study was to evaluate the effect of three different training programs on skeletal muscle hypertrophy and atrophy related gene expression. Twenty nine young male, with no previous experience in strength training were randomly allocated in three groups: low intensity strength training (i.e. 20% - 1-RM) (LI); low intensity strength training associated to vascular occlusion (i.e. 20% - 1-RM) (LIO); high intensity strength training (HI) (i.e. 80% - 1-RM). One-way ANOVA was used to assess differences in % delta change values of 1-RM and cross sectional area (CSA) of the quadriceps femoris. Mixed model analysis was used to compare myostatin (MSTN), folistatyn-3 (FLST-3), SMAD-7 e GASP-1 changes between groups pre and post training. Results demonstrated similar increases in strength and muscle hypertrophy for LIO and HI groups. Moreover, such increases were significantly greater when compared to LI. These results may be, at least in part, explained by a significant decrease in MSTN mRNA expression in LIO (45%) and HI (41%) when compared to LI (16%); additionally, SMAD-7; FLST-3 and GASP-1 mRNA expression were significantly increased. In conclusion, LIO training promotes similar gains than HI training. The results may be explained by changes in MSTN and related genes mRNA expression Biópsia Hipertrofia Miostatina Muscle biopsy Myostatin Skeletal muscle hypertrophy
455	Impact of heat therapy on skeletal muscle structure and function Kyoungrae Kim (8088134) 06 December 2019 (has links) <div> <div> <div> <p>Skeletal muscle occupies approximately 40 to 50 percent of body mass and is responsible for respiration, postural control, and locomotion and plays a pivotal role in regulating glucose, lipid, and protein metabolism. Acute muscle trauma and chronic disease conditions such as muscular dystrophies are associated with structural abnormalities, enhanced fatigability and impaired metabolism and consequently lead to exercise intolerance and poor quality of life. Despite the clinical importance and a number of studies on the treatment of muscle damage, few modalities have shown to elicit beneficial effects. Heat treatment has been used for a long time to treat soft tissue injuries in the field of physical therapy and sports medicine. However, the underlying mechanisms by which heat treatment accelerates muscle recovery following injury are not clear. </p> <p>The primary aim of my dissertation studies was to determine the impact of heat therapy on skeletal muscle structure and function in humans and animals. In Chapter 2, we report that a single session of local heat treatment promotes the expression of angiogenic and myogeneic mediators including vascular endothelial growth factor (VEGF) and angiopoietin 1(ANGPT1) in healthy human skeletal muscle. In Chapter 3, we report repeated exposure to heat therapy stimulates factors involved in muscle repair process and accelerates functional recovery from exercise-induced muscle damage. In Chapter 4, we show that 8 weeks of local heat therapy improves muscle strength of knee extensor and increases skeletal muscle capillarization in type II muscle fibers. In Chapter 5, we describe the effects of heat therapy in a mouse model of ischemia induced-muscle damage. Animals that were exposed to heat therapy at 39°C had improved maximal absolute force and relative muscle mass in the soleus muscle. These observations reveal that the beneficial effects of heat therapy are muscle fiber type specific and dependent on the treatment temperature. In Chapter 6, we review and summarize the outcomes described in Chapters 2-5 and provide a general conclusion as well the clinical implications of our findings. </p> </div> </div> </div> Exercise Physiology Heat therapy Muscle damage Muscle recovery Angiogenesis
456	The Role of Mitophagy in Muscle Stem Cell Fate and Function During Muscle Regeneration Thumiah-Mootoo, Madhavee 01 June 2021 (has links) Skeletal muscles have a remarkable capacity to repair and regenerate in response to injury by virtue of their unique population of resident muscle stem cells (MuSCs). Recently, several studies have reported that mitochondria are important regulators of fate and function in various types of stem cells including MuSCs. Furthermore, emerging evidence has shown that accumulation of dysfunctional mitochondria leads to stem cell aging, premature commitment and impaired self-renewal. Preliminary evidence from publicly available transcriptomics datasets processed by our lab showed that Phosphatase and tensin homolog (PTEN)-induced putative kinase 1(PINK1) and Parkin/PARK2 genes, two key regulators of mitophagy are expressed in quiescent MuSCs and are transiently down-regulated as MuSCs activate. This led us to hypothesize that maintenance of an optimally functioning population of mitochondria through mitophagy would be important for self-renewal and muscle repair. In vitro single myofiber cultures isolated from mitophagy reporter mice (mito-QC mice), show that mitophagy is active in quiescent MuSCs and is transiently decreased upon MuSCs activation. We also show that mitophagy is re-activated in differentiating and self-renewing MuSCs. To further study muscle regeneration, we used a cardiotoxin (CTX) injury model of the Tibialis anterior (TA) muscle in mouse models harboring a knockout (KO) of PINK1 and Parkin. We show that loss of PINK1 in vivo promotes commitment of MuSCs in response to acute injury and ultimately leads to depletion of the MuSC pool and impaired muscle regeneration compared to wild type (WT) mice following repetitive injuries. Similarly, loss of Parkin in MuSCs in vivo impaired their self-renewal capacity. Consistent with these results, in vitro single myofiber cultures isolated from PINK1-deficient mice showed increased MuSCs commitment and impaired self-renewal. In vitro preliminary results from MuSCs-specific KO of Parkin revealed altered lineage progression, differentiation and self-renewal of MuSCs. Together, these findings suggest that PINK1/Parkin-dependent mitophagy acts as an important mitochondrial quality control mechanism which could be required for regulating MuSCs fate and function during muscle regeneration. Mitophagy Muscle stem cells PINK1 Parkin Muscle regeneration
457	Changes in Isometric Function Following Rhythmic Exercise Hoffman, M. D., Williams, C. A., Lind, A. R. 01 August 1985 (has links) Seven male subjects exercised for 1, 3, 10 and 20 min on a cycle ergometer at 20, 60 and 80% {Mathematical expression}, and then held to fatigue a sustained contraction of the quadriceps at 40% maximal voluntary contraction in order to determine what influence various levels of dynamic exercise would have on isometric function of the same group of muscles. Muscle temperature was measured before and within 15 s of the completion of the cycling to determine whether changes in muscle temperature might influence the subsequent isometric perormance. Isometric endurance was shorter as the severity of the cycling increased beyond 20% {Mathematical expression}, and as the duration of cycling increased up to 10 min. There were discrete linear relationships between muscle temperature and isometric endurance associated with cycling at 60% and 80% {Mathematical expression}. There was a direct inverse relationship between quadriceps strength after cycling and muscle temperature, yet a significant reduction in strength occurred only after cycling at 80% {Mathematical expression}. These results suggest that the encroachment on endurance and strength are controlled by different mechanisms. The heart rates during the isometric contractions were dependent on the preceding rhythmic exercise and decreased after exercise at 60 or 80% {Mathematical expression}. In contrast, the blood pressure always increased during the isometric contractions, reaching similar values at the point of fatigue, regardless of the severity of the previous rhythmic exercise. These data provide additional evidence that separate mechanisms control changes in heart rate and blood pressure. cycle ergometry isometric exercise muscle endurance muscle strength
458	The architecture of the vascular smooth muscle cells of venules in the rat intestinal microvascular bed during maturation Bizuneh, Moges January 1990 (has links) This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu). Vascular smooth muscle Rats Venules Muscle, Smooth, Vascular Intestine, Small
459	Characterization of the role and regulation of the RNA binding protein HuR in muscle cell differentiation Van der Giessen, Kate. January 2007 (has links) No description available. RNA-Binding Proteins. Muscle Fibers. Muscle Development -- genetics.
460	The role of SWI/SNF in regulating smooth muscle differentiation Zhang, Min 08 December 2009 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / There are many clinical diseases involving abnormal differentiation of smooth muscle, such as atherosclerosis, hypertension and asthma. In these diseases, one important pathological process is the disruption of the balance between differentiation and proliferation of smooth muscle cells. Serum Response Factor (SRF) has been shown to be a key regulator of smooth muscle differentiation, proliferation and migration through its interaction with various accessory proteins. Myocardin Related Transcrition Factors (MRTFs) are important co-activators of SRF that induce smooth muscle differentiation. Elucidating the mechanism of how MRTFs and SRF discriminate between genes required to regulate smooth muscle differentiation and those regulating proliferation will be a significant step toward finding a cure for these diseases. We hypothesized that SWI/SNF ATPdependent chromatin remodeling complexes, containing Brg1 and Brm, may play a role in this process. Results from western blotting and quantitative reverse transcription - polymerase chain reaction (qRT-PCR) analysis demonstrated that expression of dominant negative Brg1 or knockdown of Brg1 with silence ribonucleic acid (siRNA) attenuated expression of SRF/MRTF dependent smooth muscle-specific genes in primary cultures of smooth muscle cells. Immunoprecipitation assays revealed that Brg1, SRF and MRTFs form a complex in vivo and that Brg1 directly binds MRTFs, but not SRF, in vitro. Results from chromatin immunoprecipitation assays demonstrated that dominant negative Brg1 significantly attenuated SRF binding and the ability of MRTFs to increase SRF binding to the promoters of smooth muscle-specific genes, but not proliferation-related early response genes. The above data suggest that Brg1/Brm containing SWI/SNF complexes play a critical role in differentially regulating expression of SRF/MRTF-dependent genes through controlling the accessibility of SRF/MRTF to their target gene promoters. To examine the role of SWI/SNF in smooth muscle cells in vivo, we have generated mice harboring a smooth muscle-specific knockout of Brg1. Preliminary analysis of these mice revealed defects in gastrointestinal (GI) development, including a significantly shorter gut in Brg1 knockout mice. These data suggest that Brg1-containing SWI/SNF complexes play an important role in the development of the GI tract. Smooth muscle -- Differentiation

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