Growth hormone is responsible for normal postnatal growth, is an important metabolic regulator in starvation, and has many useful therapeutic applications, including forms of cardiac insufficiency, Crohns disease and, it is thought, amelioration of ageing. The means whereby GH brings about these changes are not known, although we do know a considerable amount about how the individual domains within the GH receptor signal. What we do not know is which genes are regulated by GH in these processes, ....Growth hormone is responsible for normal postnatal growth, is an important metabolic regulator in starvation, and has many useful therapeutic applications, including forms of cardiac insufficiency, Crohns disease and, it is thought, amelioration of ageing. The means whereby GH brings about these changes are not known, although we do know a considerable amount about how the individual domains within the GH receptor signal. What we do not know is which genes are regulated by GH in these processes, and how this will change the state of the cell. We propose here to use the new technique of gene arrays to uncover the programs, or groups of genes, which GH regulates to change important cellular processes. When used in conjunction with cells expressing GH receptor mutants which are unable to signal to defined pathways, we will be able to know which functional families genes are regulated, and how they are regulated. This information will enable us to know how GH regulates cell growth and metabolism, and therfore to understand what goes wrong when GH or its mediator, IGF-1 , are abnormal. We can also use this information to validate small molecules designed to mimic GH through activating its receptor, to be certain that they are acting in the same way as GH.Read moreRead less
Genetic Programs Regulated By The Nuclear Hormone Receptor, LXR, In Muscle: Control Of Cholesterol And Lipid Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$425,250.00
Summary
The heightened occurrence of cardiovascular disease has been linked to disorders in lipid metabolism. Obesity, insulin resistance, and atherosclerosis are prevalent diseases associated with these dyslipidemias. Lipid homeostasis is regulated by dietary intake, de novo synthesis and catabolism. Disorders of lipid metabolism are associated with cardiovascular disease, insulin resistance-diabetes, obesity and hypertension. Raised levels of serum TGs, and low high density lipoprotein (HDL) cholester ....The heightened occurrence of cardiovascular disease has been linked to disorders in lipid metabolism. Obesity, insulin resistance, and atherosclerosis are prevalent diseases associated with these dyslipidemias. Lipid homeostasis is regulated by dietary intake, de novo synthesis and catabolism. Disorders of lipid metabolism are associated with cardiovascular disease, insulin resistance-diabetes, obesity and hypertension. Raised levels of serum TGs, and low high density lipoprotein (HDL) cholesterol levels are characteristic of lipotoxic diseases. HDLs have a defensive role in the prevention of atherogenic dyslipidemia by mediating cholesterol efflux from peripheral tissues through the hormone -dependent ATP-binding cassette (ABC) transporters back to the liver for excretion and elimination. Agents that raise the levels of high density lipoprotein cholesterol (HDLc) through cholesterol efflux provide a pharmaceutical solution for the prevention of hypercholesterolemia, atherogenic and cardiovascular disease. These hormone dependent cholesterol and lipid effluxing proteins are regulated by a protein named LXR. Understanding the functional role of LXR in skeletal muscle, a peripheral tissue that accounts for 40% of total body weight is of paramount importance in understanding whole body cholesterol homeostasis and lipid metabolism. Furthermore, LXR and LXR target genes that facilitate cholesterol efflux and consequently raise HDLc levels are important pharmaceutical targets. Identification of novel LXR targets in skeletal muscle, which has a significant role in insulin sensitivity and the blood lipid profile provides an additional platform for therapeutic intervention.Read moreRead less
Genetic Programs Induced By The Nuclear Hormone Receptor PPARdelta In Muscle: Control Of Lipid And Energy Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
Lipid homeostasis is regulated by dietary intake, de novo synthesis and catabolism. Lipid disease is associated with hyperinsulinemia, and anomalous levels of the lipid triad, i.e. low HDL-cholesterol, high LDL-cholesterol and elevated triglycerides. Increased incidence of cardiovascular disease has been linked to dyslipidemias associated with diet and lifestyle. Diabetes, atherosclerosis, and obesity are comorbidities with these lipid disorders. HDLs have a defensive role in the prevention of d ....Lipid homeostasis is regulated by dietary intake, de novo synthesis and catabolism. Lipid disease is associated with hyperinsulinemia, and anomalous levels of the lipid triad, i.e. low HDL-cholesterol, high LDL-cholesterol and elevated triglycerides. Increased incidence of cardiovascular disease has been linked to dyslipidemias associated with diet and lifestyle. Diabetes, atherosclerosis, and obesity are comorbidities with these lipid disorders. HDLs have a defensive role in the prevention of dyslipidemia by mediating cholesterol efflux from tissues. In contrast, the LDLs accumulate in the arterial wall leading to atherosclerosis. Physiological maintenance of lipid homeostasis requires a dynamic balance between metabolic signalling cascades, diet, lifestyle etc. PPPARs are nuclear hormone receptors that function as fatty acid activated transcription factors that regulate lipid and cholesterol homeostasis. PPARs are bona fide targets for the development of therapeutic compounds useful in the treatment of lipid disorders. PPAR delta is abundantly expressed in skeletal muscle, a major mass peripheral tissue that accounts for ~40% of total body weight. Muscle is a major site of glucose metabolism and, fatty acid oxidation. Furthermore, it is an important regulator of cholesterol homeostasis and HDL levels. Consequently, it has a significant role in insulin sensitivity, the blood lipid profile and lipid metabolism. Understanding the functional role of PPAR delta in skeletal muscle, a peripheral tissue that accounts for 40% of total body weight is of paramount importance in understanding whole body lipid homeostasis. Understsanding these receptors may provide a pharmaceutical solution for the prevention of hyper-lipidemia--cholesterolemia, and atherogenic disease. Moreover, it may lead to the identification of agents that influence a major mass tissue in terms of lipid absorption, and increased fatty acid oxidation, and consequently normalize the blood lipid profile.Read moreRead less