Global ETD Search

1	Cardiovascular and ventilatory responses to exercise in chronic heart failure Piepoli, Massimo F. January 1996 (has links) No description available. 612
2	The Effects of a 5-Day High-Fat Diet on Skeletal Muscle O-GlcNAcylation Nealon, Lily Irene 06 July 2016 (has links) Continual intake of high-fat foods, coupled with limited physical activity, can lead to metabolic inflexibility. Eventually, this may lead to significant health issues such as obesity, insulin resistance, cardiovascular disease, and other chronic diseases. Metabolic flexibility of human skeletal muscles is influenced by changes to mitochondrial, nuclear, and cytosolic proteins, in part as a result of posttranslational modifications (PTMs). O-linked B-D-N-acetylglucosamine, known as O-GlcNAc, has recently been identified as an important posttranslational modification that responds to nutrient sensing and cellular stress. Unlike other PTMs, O-GlcNAc has only two cycling enzymes. Because of its novelty, little research has been performed on the role of O-GlcNAc in human skeletal muscle and metabolic flexibility. The purpose of the current study was to establish the effects of a 5-day high-fat diet on skeletal muscle O-GlcNAcylation. In the proposed study, 13 non-obese, sedentary, college-aged males consumed a controlled diet for two weeks followed by a high-fat diet composed of 55% fat, 30% carbohydrate, and 15% protein. Muscle biopsies were taken from the vastus lateralis both fasted and four hours after a high-fat meal, following both the control diet and the high-fat diet. Western blot analysis was used to assess global O-GlcNAc and protein concentrations of O-GlcNAc transferase (OGT) and O-GlcNAcase (OGA) in whole-homogenates and isolated mitochondria from skeletal muscle. Results were analyzed using independent, two-tailed t-tests and 2-way ANOVA analysis with repeated measures and Bonferroni corrections; a p-value was set to α less than or equal to 0.05. It was found that O-GlcNAc and OGT levels remained stable, although fasting levels of OGA significantly decreased after the 5-day high-fat diet. It is possible that healthy individuals are capable of maintaining normal levels of O-GlcNAc and its cycling enzymes, but there is still more to learn about O-GlcNAc and its role in metabolic flexibility. / Master of Science O-GlcNAc skeletal muscle metabolism Nutrition physiology
3	Effects of creatine supplementation on muscle metabolism in an Alzheimer mouse model Farshidfar, Farnaz 15 February 2016 (has links) Alzheimer’s disease (AD), the most common form of dementia in the elderly, is a global issue affecting about 24 million individuals. Because AD is a systemic pathology, dementia is not the only leading factor contributing to loss of independence in AD patients. AD may also impair skeletal muscle metabolism and function. Creatine (CR) supplementation may enhance skeletal muscle hypertrophy/mass and function in sarcopenia and muscular dystrophies, but has yet to be studied in AD. This study examined the effect of oral CR on muscle metabolism in a triple-transgenic (3xTg) AD mouse model. Twenty-four, 3×Tg AD mice (~8 month-old) were randomly assigned to control (CON) or CR (3% w/w) diet. Bodyweights and feed intakes were measured throughout the 8-week study. Lower limb (quadriceps muscle; QM and gastrocnemius; GM) and upper limb muscles (triceps; TM) were collected to analyze levels of CR, total protein, DNA, RNA, amino acids (AA), adenosine triphosphate (ATP), adenosine diphosphate (ADP), total and phosphorylated p70 ribosomal S6 kinase (p70S6K). Data (mean ± SEM) were assessed by analysis of variance (ANOVA) and Fisher’s least significant difference (LSD) post hoc test. In comparison to the CON group, CR supplementation increased CR content in both GM (p=0.002) and QM (p=0.037), with higher (p=0.032) ATP/ADP ratio in CR in comparison with CON in QM. A higher protein concentration (p<0.0001) was notable in GM of CR supplemented group vs. CON. Total branched-chain AA levels in QM increased 2-fold (p< 0.0001) in CR groups. Additionally, CR resulted in a higher (p<0.05) protein/DNA ratio; an index of muscle cell size, in both QM and GM for CR groups. The index of cell capacity for protein synthesis (RNA/DNA ratio) in GM was also higher (p=0.001) in CR groups. However, phosphorylation (activation) level of p70S6K, an integral component in protein synthesis signalling pathway, did not show any significant differences in female (p=0.161) and male (p=0.292) CR supplemented groups compared with CON. To conclude, CR supplementation is capable of inducing muscle hypertrophy/growth parameters in the 3×Tg AD mouse model, thereby enhancing protein synthesis capacity in skeletal muscles, thus possibly promoting muscle function in AD. / May 2016 Alzheimer’s disease creatine supplementation skeletal muscle metabolism amino acids
4	SLN Upregulation and Metabolic Alterations: An Underlying Theme during Cold Stress, Infection and Muscle Dystrophy Pant, Meghna 21 May 2015 (has links) No description available. Biochemistry Physiology
5	Signaling pathways regulating skeletal muscle metabolism and growth Zumbaugh, Morgan Daughtry 05 January 2021 (has links) Skeletal muscle can perceive cellular energy status and substrate availability and demonstrates remarkable plasticity in response to environmental changes. Nonetheless, how skeletal muscle and its resident stem cells (satellite cells; SCs) sense and respond to nutrient flux remains largely undefined. The dynamic post-translational modification O-GlcNAcylation has been shown to serve as a cellular nutrient sensor in a wide range of cells and tissues, yet its role in skeletal muscle and SCs remains unexplored. Here, we ablated skeletal muscle O-GlcNAc transferase (OGT), and thus O-GlcNAcylation, and found the knockout mice exhibited enhanced glucose uptake, insulin sensitivity, and resistance to high-fat diet induced obesity. Additionally, mKO mice had a 3-fold increase in circulating levels of interleukin-15 (IL-15), a potent anti-obesity cytokine, potentially through epigenetic regulation of Il15 by OGT. To further investigate if there was a causal relationship between OGT ablation and the lean phenotype, we generated muscle specific OGT and interleukin-15 receptor alpha (IL-15ra) double knockout mice (mDKO). As a result, mDKO mice had blunted IL-15 secretion and minimal protection against HFD-induced obesity. Together, these data indicate the skeletal muscle OGT-IL15 axis plays an essential role in the maintenance of skeletal muscle and whole-body metabolic homeostasis. As satellite cells (SCs) play an indispensable role in postnatal muscle growth and adult regenerative myogenesis, we investigated the role of O-GlcNAcylation in SC function. To this end, we conditionally ablated OGT in SCs (cKO) and found cKO mice had impaired SC proliferation, in vivo cycling properties, population stability, metabolic regulation, and adult regenerative myogenesis. Together these findings show that SCs require O-GlcNAcylation, presumably to gauge nutritional signals, for proper function and metabolic homeostasis. Another critical yet often neglected player in myogenesis are mitochondria. Traditionally depicted as a power plant in cells, mitochondria are critical for numerous nonconventional, energy-independent cellular process. To investigate the role of both mitochondrial energy production and alternative mitochondrial functions in myogenic regulation, we ablated ATP synthase subunit beta (ATP5b) and ubiquinol-cytochrome c reductase (UQCRFS1) in C2C12 myoblasts to disrupt mitochondrial ATP production and mitochondrial membrane potential, respectively. Ablation of UQCRFS1, but not ATP5b, impaired myoblast proliferation, although lack of either gene compromised myoblast fusion. Interestingly, addition of the potent myogenic stimulator IGF-1 rescued ATP5b fusion but could not override UQCRFS1 knockout effects on proliferation or differentiation. These data demonstrate mitochondrial ATP production is not the "metabolic switch" that governs myogenic progression but rather an alternative mitochondrial function. In summary, skeletal muscle and their resident stem cell population (SCs) both use O-GlcNAcylation, feasibly to sense and respond to nutritional cues, for the maintenance of metabolic homeostasis and normal physiology. A deeper understand of both muscle and SC metabolic regulation may provide therapeutic targets to improve global metabolism and muscle growth. / Doctor of Philosophy / Skeletal muscle is responsible for approximately 20% of basal energy expenditure and 70-90% of insulin-mediated glucose disposal, and as such changes in skeletal muscle metabolism and insulin sensitivity have profound impacts on whole body metabolism. Skeletal muscle is a plastic tissue that can perceive nutrient availability, which permits metabolic adaptations to environmental changes. Deletion of the nutrient sensing pathway O-GlcNAcylation in skeletal muscle (mKO) protected mice from high-fat diet induced obesity and ameliorates whole-body insulin sensitivity. Skeletal muscle can secrete myokines to elicit endocrine effects on other tissues in the body, and as such, we proposed perturbation of this nutrient sensing pathway in skeletal muscle alters myokine secretion to elicit responses in other metabolically active tissues to support its energy requirements. Indeed, circulating levels of interleukin-15, a potent anti-obesity myokine, increased 3-fold in mKO mice. To determine the contribution of IL-15 to the mKO phenotype, we used a genetic approach to blunt IL-15 secretion from skeletal muscle (mDKO), which partially negated the lean mKO phenotype. Our findings show the ability of skeletal muscle to "sense" changes in nutrients through O-GlcNAcylation is necessary for proper muscle and whole-body metabolism. Moreover, this nutrient sensing mechanism is also important for proper muscle stem cell function, also known as satellite cells (SCs). Loss of O-GlcNAcylation in SCs impairs their ability to regenerate muscle after injury, which can be attributed to a reduced capacity to proliferate and an inability to maintain a healthy SC population. Interestingly, SCs lacking O-GlcNAcylation have a greater mitochondrial content. Using a myoblast cell line, we investigated the contribution of mitochondria to myogenesis, the formation of muscle, and found mitochondrial energy production is dispensable in the myogenic process. Our studies show skeletal muscle and SCs rely on highly integrated signaling cascades that sense and respond to intrinsic metabolic changes and extrinsic nutritional cues to function properly. skeletal muscle metabolism metabolic reprogramming O-GlcNAcylation interleukin-15 myogenesis
6	Nox4 mediates metabolic stress responses Specht, Kalyn Sloane 08 June 2022 (has links) Deficits in skeletal muscle mitochondrial metabolism are associated with a wide variety of chronic skeletal muscle and metabolic-related diseases, including diabetes and sarcopenia. Even in patients with advanced skeletal muscle-related diseases, exercise is a well-established method to improve skeletal muscle mitochondrial metabolism, culminating in enhanced whole-body metabolism and decreased disease severity. In response to exercise, there is an increase in reactive oxygen species (ROS) production. Historically, ROS were solely considered to drive disease development. However, ROS are also required for physiological adaptation and many questions still remain regarding their downstream pathways. One significant producer of skeletal muscle ROS with exercise is Nadph oxidase 4 (Nox4). Nox4 is unique compared to other Nox members as it predominantly produces hydrogen peroxide (H2O2), an effective signaling molecule. Here we demonstrate an essential role for Nox4 in mediating the beneficial effects of exercise. This work will contribute to our understanding of physiological ROS and their downstream targets by identifying a novel role for Nox4 in exercise adaptation. Further defining the molecular events that promote exercise adaptation will be essential for formulating new treatment strategies for patients with chronic metabolic diseases. / Doctor of Philosophy / Exercise is a widely effective tool for both preventing and reversing disease. Even patients with advanced skeletal muscle and metabolic-related diseases can benefit from continual and repeated exercise training. While decades of work have supported the effectiveness of exercise as a therapeutic intervention, the mechanistic understanding of what occurs at the cellular level remains incomplete. Here, we elucidate a novel pathway mediating important metabolic adaptations to exercise. In response to exercise stress, reactive oxygen species (ROS) are produced in skeletal muscle. ROS facilitate metabolic adaptations to meet the body's need for increased energy. One significant source of ROS comes from Nadph oxidase 4 (Nox4) which plays an essential role in metabolic regulation. The skeletal muscle metabolic response to stress is largely dependent on adaptations that include changes in gene expression, substrate oxidation, and mitochondrial metabolic adaptations. These mitochondrial adaptations include mitochondrial recycling after exercise in skeletal muscle (referred to as mitophagy). We have shown that Nox4 increases the expression of a subset of metabolic genes, is required for substrate oxidation after exercise, and is important for exercise-induced mitophagy. Reactive oxygen species skeletal muscle metabolism mitochondria mitophagy exercise adaptation
7	Papel dos microRNAs (miR-1, miR-133, miR-206, miR-208b, miR-499 e miR-223) no músculo esquelético de camundongos C57BL/6 durante o estado de resistência à insulina. / MicroRNAs role (miR-1, miR-133, miR-206, miR-208b, miR-499 e miR-223) in skeletal muscle of C57BL/6 mice during insulin resistance state. Frias, Flávia de Toledo 13 May 2016 (has links) No músculo esquelético (ME) resistente à insulina, a disponibilidade elevada de ácidos graxos (AGs) livres observada na obesidade provoca alterações na função mitocondrial. Sendo os microRNAs (miRs) moléculas recentemente apontadas na regulação gênica de vias metabólicas, nosso objetivo foi investigar em ME de camundongos com resistência à insulina (RI) induzida por dieta hiperlipídica durante 8 semanas, tratados com fenofibrato (CF e HF) ou metilcelulose (veículo; grupos C e H) nas duas semanas antes do sacrifício, se os miRs-1a, 133a/b, 206, 208b, 499 e miR-223 participam da patogênese da RI. O quadro de RI foi induzido no grupo H e o fenofibrato reverteu parcialmente a RI (grupo HF) observada através das alterações em parâmetros metabólicos e enzimáticos, que parecem ser mediados pelo miR-1a regulando a proteína AMPKα2. O aumento na transcrição de AMPKα2 ativa processos catabólicos tais como a captação de glicose e oxidação de AGs, sendo considerada a principal enzima reguladora do metabolismo celular ao estimular a expressão de genes mitocondriais via PGC-1α. / In skeletal muscle (SM) tissue, evidences suggest that the high availability of free fatty acids (FFAs) observed in obesity plays a central role in the development of insulin resistance (IR) by causing changes in mitochondrial function. Since microRNAs (miRs) are recently identified molecules acting as gene regulators of metabolic pathways, we aimed to investigate in SM of insulin resistant mice induced by 8 weeks of high-fat diet (HFD) feeding, treated with fenofibrate (CF and HF) or metilcelulose (vehicle, C and H) two weeks before euthanasia, if miRs-1a, 133a/b, 206, 208b, 499 and 223 are involved in IR pathogenesis. IR was induced after 8 weeks of HFD (H), and fenofibrate treatment (HF) partially reverted this condition by causing alterations on metabolic and enzymatic parameters, which seems to be mediated by miR-1a regulating AMPKα2 protein. AMPKα2 increased translation active catabolic processes such as glucose uptake and FFAs oxidation, being considered the main regulator of cell metabolism by stimulating mitochondrial genes expression via PGC-1α. Insulin resistance Metabolismo muscular MicroRNAs MicroRNAs Mitochondria Mitocôndria Resistência à insulina Skeletal muscle metabolism
8	Papel dos microRNAs (miR-1, miR-133, miR-206, miR-208b, miR-499 e miR-223) no músculo esquelético de camundongos C57BL/6 durante o estado de resistência à insulina. / MicroRNAs role (miR-1, miR-133, miR-206, miR-208b, miR-499 e miR-223) in skeletal muscle of C57BL/6 mice during insulin resistance state. Flávia de Toledo Frias 13 May 2016 (has links) No músculo esquelético (ME) resistente à insulina, a disponibilidade elevada de ácidos graxos (AGs) livres observada na obesidade provoca alterações na função mitocondrial. Sendo os microRNAs (miRs) moléculas recentemente apontadas na regulação gênica de vias metabólicas, nosso objetivo foi investigar em ME de camundongos com resistência à insulina (RI) induzida por dieta hiperlipídica durante 8 semanas, tratados com fenofibrato (CF e HF) ou metilcelulose (veículo; grupos C e H) nas duas semanas antes do sacrifício, se os miRs-1a, 133a/b, 206, 208b, 499 e miR-223 participam da patogênese da RI. O quadro de RI foi induzido no grupo H e o fenofibrato reverteu parcialmente a RI (grupo HF) observada através das alterações em parâmetros metabólicos e enzimáticos, que parecem ser mediados pelo miR-1a regulando a proteína AMPKα2. O aumento na transcrição de AMPKα2 ativa processos catabólicos tais como a captação de glicose e oxidação de AGs, sendo considerada a principal enzima reguladora do metabolismo celular ao estimular a expressão de genes mitocondriais via PGC-1α. / In skeletal muscle (SM) tissue, evidences suggest that the high availability of free fatty acids (FFAs) observed in obesity plays a central role in the development of insulin resistance (IR) by causing changes in mitochondrial function. Since microRNAs (miRs) are recently identified molecules acting as gene regulators of metabolic pathways, we aimed to investigate in SM of insulin resistant mice induced by 8 weeks of high-fat diet (HFD) feeding, treated with fenofibrate (CF and HF) or metilcelulose (vehicle, C and H) two weeks before euthanasia, if miRs-1a, 133a/b, 206, 208b, 499 and 223 are involved in IR pathogenesis. IR was induced after 8 weeks of HFD (H), and fenofibrate treatment (HF) partially reverted this condition by causing alterations on metabolic and enzymatic parameters, which seems to be mediated by miR-1a regulating AMPKα2 protein. AMPKα2 increased translation active catabolic processes such as glucose uptake and FFAs oxidation, being considered the main regulator of cell metabolism by stimulating mitochondrial genes expression via PGC-1α. Metabolismo muscular MicroRNAs Mitocôndria Resistência à insulina Insulin resistance MicroRNAs Mitochondria Skeletal muscle metabolism
9	Iron deficiency and human hypoxia physiology Frise, Matthew January 2016 (has links) This thesis is concerned with a very common disorder of iron homeostasis: iron deficiency. The specific focus is the manner in which iron deficiency influences physiological responses to hypoxia in humans. This work is predicated on observations made over many decades in vitro and in vivo, suggesting that variations in the bioavailability of iron have important consequences for certain biological processes known to depend on oxygen availability. Three separate but related studies together form the basis for this thesis. The first two, Study A and Study B, adopt a similar approach in recruiting healthy volunteers who differ according to iron status, yielding iron-deficient and iron-replete groups in both cases. In Study A, the behaviour of the pulmonary circulation is investigated during a sustained hypoxic exposure, before and after an intravenous infusion of iron. In Study B, skeletal muscle metabolism is explored, both at the level of high-energy phosphate metabolism and the integrated physiological responses to exercise on a cycle ergometer. In the third study, Study C, a different approach is taken, recruiting patients with chronic obstructive pulmonary disease (COPD), and exploring the prevalence and associations of iron deficiency in this condition. Chapters 2 and 3 describe experiments using sustained hypoxia in a normobaric chamber, during which the pulmonary circulation is assessed non-invasively using Doppler echocardiography. These reveal augmented hypoxic pulmonary vasoconstriction (HPV) in iron-deficient individuals, who also exhibit greater sensitivity to the effects of an infusion of intravenous iron. Additionally, the way in which certain circulating mediators important for iron haemostasis change over the course of these hypoxic exposures, and how iron status influences these responses, is explored. Chapter 4 reports the findings of experiments using 31P-magnetic resonance spectroscopy and cardiopulmonary exercise testing, which demonstrate abnormal whole-body metabolism in iron-deficient individuals during large muscle-mass exercise, despite the absence of a clear defect in mitochondrial oxidative phosphorylation. Intravenous iron is found to have significant effects to alter the lactate threshold in healthy individuals, but the effects are more striking in iron-deficient individuals. Collectively, these experiments imply that iron deficiency promotes a more glycolytic phenotype. Chapter 5 explores iron deficiency in COPD, a condition in which pulmonary vascular disease, hypoxia and skeletal muscle dysfunction coexist, and examines some of the difficulties in assessing iron status in the setting of a chronic inflammatory disorder. Iron deficiency is found to be common, and unexpectedly associated with significantly more severe hypoxaemia, in patients with COPD. Possible reasons for these findings, and their clinical implications, are considered. Chapter 6 provides a summary of the main conclusions to be drawn from the studies presented in this thesis.
10	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.

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