Global ETD Search

361	LKB1 Regulation of High-Fat Diet-induced Adaptation in Mouse Skeletal Muscle Chen, Ting 01 March 2017 (has links) Ad libitum high-fat diet (HFD)-induced obesity leads to insulin resistance in skeletal muscle, altered gene expression, and altered growth signaling, all of which contributes to pathological changes in metabolism. Liver kinase B1 (LKB1) is an important metabolism regulator. The purpose of this dissertation was to understand how knocking out LKB1 influences HFD induced adaptations in mouse skeletal muscle. To do so, control and skeletal muscle LKB1 knock-out (LKB1-KO) mice were put on either standard diet (STD) or HFD for 1 week or 14 weeks, or put on the HFD for 14 weeks and then switched to STD for 1 week (switched diet). The major differences in adaptation in the LKB1-KO mice include: 1) lower fasting blood glucose levels but impaired glucose tolerance compared to WT mice (although conflicting results are generated if the data is not normalized to fasting blood glucose levels), 2) altered expression of 16 HFD-induced genes, and 3) decreased muscle weight. The lower fasting blood glucose in LKB1-KO mice was likely due to elevated serum insulin levels, and the impaired glucose tolerance was associated with decreased phosphorylation of TBC1D1, an important regulator of insulin stimulated glucose uptake. 16 potential important target genes (metabolism, mitochondrial, cytoskeleton, cell cycle, cell-cell interactions, enzyme, ion channel) were identified in the context of HFD feeding and LKB1-KO. These genes were quantified by RT-PCR and grouped according to changes in their patterns of expression among the different groups. Among several other interesting changes in gene expression, the muscle growth-related protein, Ky was not affected by short-term HFD, but increased after long-term HFD, and did not decrease after switched diet, showing that its expression may be an important long-term adaptation to HFD. LKB1-KO promoted anabolic signaling through increasing t-eIF2α and eIF4E expression, and promoted protein degradation through increasing protein ubiquitination. Because the degradation is the main effect and lead to muscle weight decrease. The effect of HFD and/or LKB1-KO on the LKB1-AMPK system was also determined. The results showed that knocking-out LKB1 decreased AMPK activity, decreased nuclear distribution for AMPK α2 and increased AMPK α1 expression. Long-term HFD increased t-AMPK expression in LKB1-KO mice, decreased the cytoplasm p-AMPK and nuclear p/t-AMPK ratio in CON mice. Together the findings of this dissertation demonstrated HFD induced glucose/insulin tolerance, while LKB1-KO had a controversial effect on glucose/insulin sensitivity. Both HFD and LKB1-KO affect AMPK expression and cellular location, while LKB1-KO also affects AMPK activity. LKB1-KO promoted protein degradation through ubiquitination in skeletal muscle. high-fat diet LKB1 skeletal muscle AMPK insulin/glucose tolerance test GLUT4 Physiology
362	Assessment of low-force exercise in human paralyzed muscle Petrie, Michael Arlyn 01 May 2016 (has links) The loss of physical activity after a spinal cord injury results in musculoskeletal deterioration and metabolic dysfunction. Rehabilitation often overlooks the importance of physical activity in the paralyzed limbs for systemic metabolic health. There is a need for safe, feasible exercise interventions to increase physical activity levels in the paralyzed limbs of people with chronic paralysis that have severe musculoskeletal loss. The goal of this work is to 1) develop a gene expression signature after a single dose and long term training using a high force exercise in people with an acute spinal cord injury; 2) develop a novel low force exercise intervention using electrical muscle stimulation to limit force production and increase routine physical activity for chronically paralyzed human skeletal muscle; 3) determine the gene expression signature after a single dose of this novel low force exercise in people with long term paralysis; 4) develop a dose estimate of this low force exercise needed to initiate a phenotype transformation of chronically paralyzed skeletal muscle. The major findings of this research are 1) a single dose of high force exercise increases the expression of key regulatory genes needed for the transformation of paralyzed skeletal muscle observed after long term training; 2) our novel low force exercise intervention challenges chronically paralyzed muscle but not non-paralyzed muscle; 3) a single dose of low force exercise increases the expression of key regulatory genes needed to improve skeletal muscle health; 4) a dose of at least 4 days per week of our low force exercise is needed to initiate a phenotype transformation of chronically paralyzed skeletal muscle. Together, this work supports the use of a low force exercise intervention for people with long term spinal cord injury and establish the need for future work assessing effects of our low force exercise on the systemic health and quality of life of people with long term spinal cord injury. publicabstract electrical muscle stimulation gene expression skeletal muscle spinal cord injury Rehabilitation and Therapy
363	Mechanisms of Skeletal Muscle Hypertrophy Stone, Michael H. 01 July 2010 (has links) No description available. skeletal muscle hypertrophy Sports Medicine Sports Sciences
364	Development of Skeletal Muscle Hypertrophy Stone, Michael H. 01 June 2010 (has links) No description available. skeletal muscle hypertrophy Sports Medicine Sports Sciences
365	β-CATENIN REGULATION OF ADULT SKELETAL MUSCLE PLASTICITY Wen, Yuan 01 January 2018 (has links) Adult skeletal muscle is highly plastic and responds readily to environmental stimuli. One of the most commonly utilized methods to study skeletal muscle adaptations is immunofluorescence microscopy. By analyzing images of adult muscle cells, also known as myofibers, one can quantify changes in skeletal muscle structure and function (e.g. hypertrophy and fiber type). Skeletal muscle samples are typically cut in transverse or cross sections, and antibodies against sarcolemmal or basal lamina proteins are used to label the myofiber boundaries. The quantification of hundreds to thousands of myofibers per sample is accomplished either manually or semi-automatically using generalized pathology software, and such approaches become exceedingly tedious. In the first study, I developed MyoVision, a robust, fully automated software that is dedicated to skeletal muscle immunohistological image analysis. The software has been made freely available to muscle biologists to alleviate the burden of routine image analyses. To date, more than 60 technicians, students, postdoctoral fellows, faculty members, and others have requested this software. Using MyoVision, I was able to accurately quantify the effects of β-catenin knockout on myofiber hypertrophy. In the second study, I tested the hypothesis that myofiber hypertrophy requires β-catenin to activate c-myc transcription and promote ribosome biogenesis. Recent evidence in both mice and human suggests a close association between ribosome biogenesis and skeletal muscle hypertrophy. Using an inducible mouse model of skeletal myofiber-specific genetic knockout, I obtained evidence that β-catenin is important for myofiber hypertrophy, although its role in ribosome biogenesis appears to be dispensable for mechanical overload induced muscle growth. Instead, β-catenin may be necessary for promoting the translation of growth related genes through activation of ribosomal protein S6. Unexpectedly, we detected a novel, enhancing effect of myofiber β-catenin knockout on the resident muscle stem cells, or satellite cells. In the absence of myofiber β-catenin, satellite cells activate and proliferate earlier in response to mechanical overload. Consistent with the role of satellite cells in muscle repair, the enhanced recruitment of satellite cells led to a significantly improved regeneration response after chemical injury. The novelty of these findings resides in the fact that the genetic perturbation was extrinsic to the satellite cells, and this is even more surprising because the current literature focuses heavily on intrinsic mechanisms within satellite cells. As such, this model of myofiber β-catenin knockout may significantly contribute to better understanding of the mechanisms of satellite cell priming, with implications for regenerative medicine. skeletal muscle image analysis ribosome biogenesis β-catenin plasticity Cellular and Molecular Physiology Exercise Physiology
366	VITAMIN D WORKS THROUGH THE LIPID DROPLET PROTEIN PLIN2 TO AUGMENT MITOCHONDRIAL FUNCTION IN SKELETAL MUSCLE Schnell, David M. 01 January 2018 (has links) Vitamin D has been connected with increased intramyocellular lipid (IMCL) mitochondrial function in skeletal muscle. It is also shown to prevent lipotoxicity in several tissues, but this has not yet been examined in skeletal muscle. Perilipin 2 (PLIN2), a lipid droplet protein upregulated with vitamin D treatment, is integral to managing IMCL capacity and lipid oxidation in skeletal muscle. Increased lipid storage and oxidation is associated with increased tolerance to a hyperlipidic environment and resistance to lipotoxicity. Therefore, I hypothesized that vitamin D increases β-oxidation and lipid turnover though a PLIN2 mediated mechanism, thereby preventing lipotoxicity. This hypothesis was divided into two specific aims: 1) Characterize the effect of vitamin D and PLIN2 on lipid turnover and β-oxidation in mature myotubes, and 2) Determine the role of vitamin D and PLIN2 in regulating key markers of lipotoxicity. To address these aims, cells were treated with or without vitamin D, palmitate, and PLIN2 siRNA in an eight group, 2x2x2 design. Key experiments included quantitative real time polymerase chain reaction for markers of lipid accumulation, lipolysis, and lipotoxicity; Seahorse oxygen consumption assay; 14C-palmitate oxidation assay; and analyses of lipid accumulation and profile. Failure of the palmitate treatment to produce a reliable model for lipotoxicity resulted in negative data for Aim 2 of this dissertation and a focus on vitamin D and PLIN2 knockdown treatments as a four group, 2x2 model. Aim 1 showed that vitamin D reliably increases markers of lipolysis and lipid accumulation. Most of these markers were in turn decreased after PLIN2 knockdown, and DGAT2 exhibited an interaction effect between the two treatments. Contrary to our hypothesis and some published research, PLIN2 knockdown did not prevent lipid accumulation. Vitamin D increased oxygen consumption, especially consumption driven by mitochondrial complex II. PLIN2 knockdown decreased oxygen consumption and demonstrated an interaction effect specific to mitochondrial complex II. Data in this dissertation show that vitamin D increases mitochondrial function, and these effects are at least in part accomplished through a PLIN2 mediated mechanism. However, this work lacks the data required to make specific claims regarding β-oxidation and lipid turnover. This research is some of the first to show that PLIN2 knockdown carries negative impacts for skeletal muscle mitochondria and makes valuable contributions to general knowledge of how vitamin D and lipid storage impact muscle health and function. This ultimately provides additional evidence to advocate for vitamin D supplementation as a means of improving musculoskeletal health and function. Future research should investigate how vitamin D and PLIN2 impact markers of lipotoxicity in skeletal muscle. Vitamin D PLIN2 Skeletal Muscle Mitochondrial Metabolism Lipid Droplets Life Sciences Nutrition
367	ASSOCIATION OF SKELETAL MUSCLE AND PSYCHOLOGICAL RESPONSES TO IMMOBILITY AFTER MAJOR INJURY Higgins, Jacob T. 01 January 2019 (has links) The purpose of this dissertation was to explore the physical and psychological responses to the combination of major trauma (Injury Severity Score [ISS] > 15) and variable periods of immobility. Specific aims were to: 1) develop a conceptual model that illustrates physiological and psychological alterations that occur after injury and subsequent immobility, and their association with skeletal muscle responses and recovery; 2) evaluate daily measures of skeletal muscle strength (bicep and quadricep) using dynamometry and skeletal muscle (rectus femoris and biceps brachii) muscle thickness measured with ultrasound in patients after major trauma; and 3) assess the predictive ability of anxiety and depressive symptoms after traumatic injury on delayed ambulation (> 48 hours) following hospital admission. Specific Aim 1 was addressed by development of a conceptual model to describe the association between injury responses, immobility and skeletal muscle after trauma based on a comprehensive review of the state of the science. This model guided the research reported in Aims 2 and 3. The second specific aim was addressed with the conduct of an observational study in which we evaluated daily skeletal muscle strength with dynamometry and muscle thickness with ultrasound to evaluate the impact of trauma and immobility on skeletal muscle in patients after major trauma (n = 19). Participants with delayed ambulation after trauma (more than 48 hours immobility) demonstrated significantly less muscle strength compared with those who had early ambulation (bicep: delayed ambulation 12.9 ± 3.8, early ambulation 17.7 ± 4.7, p = 0.004; quadriceps: delayed ambulation 9.9 ± 3.1, early ambulation 17.1 ± 4.6, p = 0.001). Muscle thickness was unchanged over time in those with delayed ambulation; however, in those who ambulated early, muscle thickness significantly increased by 0.17 cm (p = 0.008) from baseline to day 5. The third specific aim was addressed with data collected during the same observational study of patients after trauma (n = 19). Participants provided measures of anxiety and depressive symptoms at baseline. Anxiety was not a predictor of delayed ambulation; however, depressive symptoms increased the likelihood of delayed ambulation by 67% (Odds Ratio [OR]: 1.67, 95% CI: 1.02 – 2.72, p = 0.041). Early ambulation was associated with significantly greater muscle strength and thickness as determined by dynamometry and muscle ultrasound, and depressive symptoms significantly increased the likelihood of delayed ambulation. Systematic evaluation of the association between trauma injury, immobility, skeletal muscle function and structure, and psychological state will provide an opportunity for the appropriate evaluation after injury and development of effective, tailored interventions to improve short- and long-term physiological and psychological recovery. trauma immobility ambulation skeletal muscle anxiety depressive symptoms Critical Care Nursing Nursing Trauma
368	Rôle du récepteur nucléaire Rev-erb-α dans la fonction du réticulum sarcoplasmique du muscle squelettique : implications physiologiques et pathologiques / Role of the nuclear receptor Rev-erb-α in the function of the sarcoplasmic reticulum of skeletal muscle : physiological and pathological implications Boulinguiez, Alexis 05 April 2019 (has links) Au sein du muscle squelettique, le réticulum sarcoplasmique occupe une place essentielle dans la régulation de l’homéostasie calcique et de la contraction musculaire. En particulier, le transporteur calcique SERCA, situé à la membrane du réticulum endoplasmique permet de reconstituer le contenu calcique réticulaire suite à une contraction musculaire. Dans le muscle squelettique, l’activité de SERCA est contrôlée par un peptide inhibiteur spécifique appelé la myoréguline. Nous nous intéressons au rôle du récepteur nucléaire Rev-erb-α, un répresseur de transcription connu pour favoriser la fonction musculaire et dont l’activité peut être modulée par des ligands pharmacologiques. Nos résultats montrent que Rev-erb-α réprime l’expression de la myoréguline en se fixant sur son promoteur, ce qui a pour conséquence l’augmentation de l’activité de SERCA et la hausse du contenu calcique réticulaire. Un traitement avec un agoniste de Rev-erb-α, le SR9009, améliore l’homéostasie calcique et la contractilité musculaire de souris mdx/utr+/-, un modèle de la myopathie de Duchenne. Par ailleurs, le réticulum endoplasmique est le siège de la conformation des protéines de la voie sécrétoire. Des altérations de la conformation protéique provoquent un stress réticulaire et le déclenchement de la réponse aux protéines mal-conformées qui peut conduire jusqu’à l’apoptose. Il est décrit que le stress réticulaire est un phénomène impliqué dans l’activation de la cellule satellite musculaire suite à une blessure. Nous avons établi que Rev-erb-α, en augmentant l’interaction entre le réticulum endoplasmique et la mitochondrie accroit l’activation de la réponse aux protéines mal-conformées et l’apoptose de cellules satellites activées, ce qui pourrait impacter le potentiel de régénération musculaire. En conclusion, nous avons identifié Rev-erb-α comme un modulateur de la fonction du réticulum endoplasmique dans le muscle squelettique. Dans le futur, des thérapies ciblant spécifiquement Rev-erb-α pourraient être développées dans le cadre de pathologies musculaires chez l’Homme. / Within skeletal muscle, the sarcoplasmic reticulum plays an essential role in the regulation of calcium homeostasis and muscle contraction. In particular, the SERCA transporter, located at the membrane of the endoplasmic reticulum, by pumping calcium from cytosol from reticular lumen, allows the reticular calcium content to be reconstituted following muscle contraction. In skeletal muscle, SERCA activity is controlled by a specific inhibitory peptide called myoregulin. We are interested in the role of the nuclear receptor Rev-erb-α, a transcription repressor known to promote muscle function and whose activity can be modulated by pharmacological ligands. Our results show that Rev-erb-α represses the expression of myoregulin by binding to its promoter, which results in an increase in SERCA activity and an increase in reticular calcium content. Treatment with a Rev-erb-α agonist, SR9009, improves calcium homeostasis and muscle contractility in mdx/utr+/- mice, a model of Duchenne myopathy. In addition, the endoplasmic reticulum is the site of protein conformation of the secretory pathway. Alteration in protein conformation causes reticular stress and triggers the unfolded protein response that can lead to apoptosis. It is described that reticular stress is a phenomenon involved in the activation of skeletal muscle satellite cell following an injury. We have established that Rev-erb-α, by increasing the interaction between endoplasmic reticulum and mitochondria enhances the activation of unfolded protein response and apoptosis of activated satellite cells, which could impact the muscle regeneration capacity. In conclusion, we have identified Rev-erb-α as a modulator of endoplasmic reticulum function in skeletal muscle. In the future, specific Rev-erb-α targeting therapies may be developed for human muscle diseases. Rev-erb-α Muscle squelettique Réticulum endoplasmique Rev-erb-α Skeletal muscle Endoplasmic reticulum
369	Striated muscle action potential assessment as an indicator of cellular energetic state Burnett, Colin Michael-Lee 01 May 2012 (has links) Action potentials of striated muscle are created through movement of ions through membrane ion channels. ATP-sensitive potassium (KATP) channels are the only known channels that are gated by the intracellular energetic level ([ATP]/[ADP] ratio). KATP channels are both effectors and indicators of cellular metabolism as part of a negative feedback system. Decreased intracellular energetic level alters the gating of KATP channels, which is reflected in alterations of the action potential morphology. These changes protect the cell from exhaustion or injury by altering energy-consuming processes that are driven by membrane potential. Assessing the effects of KATP channel activation on resting membrane potential and action potential morphology, and the relationship to cellular stress is important to the understanding of normal cellular function. To better understand how muscle cells adapt to energetic stress, the monophasic action potential (MAP) electrode and floating microelectrode were used to record action potentials in intact hearts and skeletal muscles, respectively. Intact organs provide a more physiological environment for the study of energetics and membrane electrical phenomena. Utilizing these techniques, a stress on the intracellular energetic state resulted in greater and faster shortening of the duration of cardiac action potentials, and hyperpolarization of the membrane of skeletal muscle in a KATP channel dependent manner. Motion artifacts are a limitation to studying transmembrane action potentials, but the MAP and floating microelectrode techniques uniquely allow for reading of action potential morphology uncoupled from motion artifacts. The use of the floating microelectrode in skeletal muscles is a novel approach that provides previously unavailable data on skeletal muscle membrane potentials in situ. action potential cardiac muscle floating microelectrode KATP channel membrane potential skeletal muscle
370	Molecular mechanisms of skeletal muscle atrophy Ebert, Scott Matthew 01 December 2012 (has links) Skeletal muscle atrophy is a common and often debilitating complication of diverse stresses including muscle disuse, fasting, aging, critical illness and many chronic illnesses. However, the pathogenesis of muscle atrophy is still poorly understood. The thesis herein describes my studies investigating the molecular mechanisms of skeletal muscle atrophy. Using mouse skeletal muscle and cultured skeletal myotubes as experimental systems, I discovered a novel stress-induced pathway in skeletal muscle that causes muscle atrophy. The pathway begins with stress-induced expression of ATF4, a basic leucine zipper (bZIP) transcription factor with an evolutionarily ancient role in cellular stress responses. I found that diverse stresses including fasting and muscle disuse increase expression of ATF4 in skeletal muscle. ATF4 then activates the growth arrest and DNA damage-inducible 45a (Gadd45a) gene, leading to increased expression of Gadd45a protein, an essential and inducible subunit of DNA demethylase complexes. Gadd45a localizes to skeletal myonuclei where it interacts with and stimulates demethylation of a specific region in the promoter of the cyclin dependent kinase inhibitor 1a (Cdkn1a) gene. By demethylating the Cdkn1a promoter, Gadd45a activates the Cdkn1a gene, leading to increased expression of Cdkn1a protein, also known as p21WAF1/CIP1. Cdkn1a stimulates protein breakdown (a critical pro-atrophy process) and inhibits anabolic signaling, protein synthesis and PGC-1α expression (processes that maintain healthy skeletal muscle and protect against atrophy). As a result, Cdkn1a causes skeletal muscle fibers to undergo atrophy. Importantly, interventions that reduce any one component of this pathway (ATF4, Gadd45a or Cdkn1a) reduce skeletal muscle atrophy during fasting, muscle disuse, and perhaps other skeletal muscle stresses such as illness and aging. Conversely, forced expression of any one component of this pathway is sufficient to cause skeletal muscle fiber atrophy in the absence of upstream stress. These data suggest the ATF4/Gadd45a/Cdkn1a pathway as a potential therapeutic target. Collectively, my studies demonstrate that the sequential, stress-induced expression of ATF4, Gadd45a and Cdkn1a is a critical process in the pathogenesis of skeletal muscle atrophy. This significantly advances our understanding of how muscle atrophy occurs and it opens up new avenues of investigation into the causes and treatment of muscle atrophy. ATF4 Cdkn1a DNA methylation Gadd45a Muscle atrophy Skeletal muscle Cell Biology

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