326 resultados para Skeletal-muscle Mass
Resumo:
Twenty two, young, healthy individuals participated in three studies aiming to assess the effect of various types of physical activity - acute exercise of moderate intensity and duration, varying intensity, short-term training - on skeletal muscle GLUT-4 gene and protein expression as well as on a range of genes encoding the proteins involved in carbohydrate metabolism in skeletal muscle.
Resumo:
Focuses on discovering and investigating altered gene expression in the skeletal muscle of Psammomys obesus which is a unique model of obesity and Type II diabetes in which its development is similar to that of the human population. Defects in the skeletal muscle are pivotal to the development of Type II diabetes. Using the latest techniques in molecular biology the regulation of a number of genes was confirmed to be altered in obese or diabetic animals compared to lean. This indicates that changes to gene expression contribute to the metabolic disturbances associated with obesity and Type II diabetes.
Resumo:
Intense exercise results in muscular inflammation. Molecular techniques were used to identify novel inflammatory proteins in human muscle. Males and females displayed different levels of exercise-induced inflammatory proteins. Interestingly, dairy protein supplements reduced these inflammatory proteins post-exercise. Increased dietary red meat consumption, with training, had no impact on muscle inflammation, although strength gain was improved.
Resumo:
Creatine is an important molecule involved in providing energy to the body. Its major stores are in skeletal muscle. The creatine transporter protein (CreaT) mRNA is believed to be responsible for the uptake of the majority of creatine in skeletal muscle. This thesis examined factors that might have affected the expression of the creatine transporter in skeletal muscle.
Resumo:
The ability of skeletal muscle to adapt fat oxidation rates is important for human health. Lipid metabolism requires the involvement of many proteins encoded by their corresponding genes. This thesis demonstrates that manipulating plasma free fatty acid levels alters the expression of selected genes involved in regulating fatty acid metabolism.
Resumo:
The effects of exercise on novel signalling enzymes in skeletal muscle of humans was investigated. It was shown that exercise increased the activity of a calcium and calmodulin activated kinase. High-intensity, but submaximal, exercise increased the activity of some but not all isoforms of protein kinase C, a lipid-activated kinase family. These findings suggest that these enzymes may be part of the signalling process leading to beneficial adaptation to repeated exercise as well as the control of function within skeletal muscle during exercise.
Resumo:
Skeletal muscle is the most significant site for whole body fat utilisation. The ability to regulate fat use has a significant impact on the development of obesity and Type II diabetes. The studies conducted during this PhD provided significant insight into the complex molecular regulation of skeletal muscle fat utilisation.
Resumo:
Increasing the number of glucose transporters in muscle ameliorates many of the symptoms associated with type 2 diabetes. This thesis identifies mechanisms regulating glucose transporter gene expression, and therefore glucose transporter number, in human skeletal muscle and provides potential targets for the treatment and management of type 2 diabetes.
Resumo:
Ý-lactoglobulin enriched whey protein isolate, but not carbohydrate, increased growth signalling in human skeletal muscle when consumed in conjunction with resistance exercise. Ageing did not impair the anabolic signalling response; however this response was attenuated after training. These findings help identify strategies to prevent, or delay the onset of sarcopenia.
Resumo:
In this study, AHI1 and NDRG2 gene function in the insulin signalling pathways regulating skeletal muscle homeostasis was investigated. Findings implicate AHI1 in the regulation of insulin-stimulated glucose transport and the development of insulin resistance, whilst associating NDRG2 with the regulation of myoblast proliferation and differentiation; possible via interactions with PICK1 and arfaptin2.
Resumo:
Human skeletal muscle precursor cells (myoblasts) have significant therapeutic potential and are a valuable research tool to study muscle cell biology. Oxygen is a critical factor in the successful culture of myoblasts with low (1–6%) oxygen culture conditions enhancing the proliferation, differentiation, and/or viability of mouse, rat, and bovine myoblasts. The specific effects of low oxygen depend on the myoblast source and oxygen concentration; however, variable oxygen conditions have not been tested in the culture of human myoblasts. In this study, muscle precursor cells were isolated from vastus lateralis muscle biopsies and myoblast cultures were established in 5% oxygen, before being divided into physiological (5%) or standard (20%) oxygen conditions for experimental analysis. Five percent oxygen increased proliferating myoblast numbers, and since low oxygen had no significant effect on myoblast viability, this increase in cell number was attributed to enhanced proliferation. The proportion of cells in the S (DNA synthesis) phase of the cell cycle was increased by 50%, and p21Cip1 gene and protein expression was decreased in 5 versus 20% oxygen. Unlike in rodent and bovine myoblasts, the increase in myoD, myogenin, creatine kinase, and myosin heavy chain IIa gene expression during differentiation was similar in 5 and 20% oxygen; as was myotube hypertrophy. These data indicate for the first time that low oxygen culture conditions stimulate proliferation, whilst maintaining (but not enhancing) the viability and the differentiation potential of human primary myoblasts and should be considered as optimum conditions for exvivo expansion of these cells.
Resumo:
This study identified the protein PARL (Presenilin-associated rhomboid like) as a potential mediator of the mitochondrial abnormalities that are observed in diabetic skeletal muscle. This was demonstrated by analysing PARL expression in an animal model of type 2 diabetes and by investigating the biological effects of genetic variation in the human PARL gene.
Resumo:
Understanding muscle adaptation and repair is vital for preserving muscle loss with aging. Analysis of the inflammatory-responsive signalling pathway, JAK/STAT was performed. After intense exercise, the STAT3 pathway is highly activated, potentially by the pro-inflammatory regulator IL-6. This pathway is suppressed in older individuals, possible leading to altered inflammatory regulation.
