Alteration Of Glucose Metabolism By GPCR Activation
Funder
National Health and Medical Research Council
Funding Amount
$444,796.00
Summary
In type 2 diabetes the effect of insulin to stimulate glucose transport in fat cells and skeletal muscle is impaired so there is great interest in identifying insulin-independent mechanisms that increase glucose transport. Several G protein-coupled receptors (GPCRs) regulate glucose transport independently of insulin but the mechanisms involved in these effects are largely unknown. This project investigates how GPCRs regulate glucose homeostasis and will evaluate them as potential treatments.
Hormonal Modulation Of Prostatic Growth And Contractility
Funder
National Health and Medical Research Council
Funding Amount
$324,237.00
Summary
With increasing age human males are likely to develop benign prostatic hyperplasia (BPH), a disorder characterized by urethral obstruction due to an increase in size of the prostate gland. Drug treatments of this condition are not entirely satisfactory and the current project is to examine the mechanisms by which the prostate grows and occludes the urethra. We will use human prostate cells grown in artificial conditions to determine which hormones alter the types of cells and especially examine ....With increasing age human males are likely to develop benign prostatic hyperplasia (BPH), a disorder characterized by urethral obstruction due to an increase in size of the prostate gland. Drug treatments of this condition are not entirely satisfactory and the current project is to examine the mechanisms by which the prostate grows and occludes the urethra. We will use human prostate cells grown in artificial conditions to determine which hormones alter the types of cells and especially examine those cells which can contract as these may be of critical importance in the urethral obstruction. We hypothesize that an enzyme called protein kinase C may be implicitly involved in both cell growth and contractile function and we will examine the role of protein kinase C with a view ultimately to develop drugs which may interfere with this process and therefore aid in non-surgical treatment of the condition.Read moreRead less
Understanding The Mechanisms Used By G-protein Coupled Receptors To Regulate Insulin-independent Glucose Transport
Funder
National Health and Medical Research Council
Funding Amount
$105,590.00
Summary
In type 2 diabetes, stimulation of glucose transport in fat cells and skeletal muscle by insulin is impaired. As a result there is great interest in identifying insulin-independent mechanisms that increase glucose transport. Several G-protein coupled receptors (GPCRs) regulate glucose transport independently of insulin but the mechanisms involved in these effects are largely unknown. This project investigates how GPCRs regulate glucose transport for potential as treatments.
Alternate Signalling Pathways Regulating The Human Arachidonate Epoxygenase CYP2J2 In Response To Stress Stimuli
Funder
National Health and Medical Research Council
Funding Amount
$369,000.00
Summary
Hypoxia, or oxygen deprivation, is caused by the decreased supply of blood to cells and is a component of ischaemic injury to the cardiovascular system (e.g. stroke, atherosclerosis) and numerous other organs (e.g. cancer and chemical mediated injury). It is now known that an important group of proteins that switch on specialised target genes in response to hypoxia is Activator-Protein-1 (AP-1). We have found that cytochrome P450 2J2 (CYP2J2), which is an enzyme that forms beneficial fatty acid ....Hypoxia, or oxygen deprivation, is caused by the decreased supply of blood to cells and is a component of ischaemic injury to the cardiovascular system (e.g. stroke, atherosclerosis) and numerous other organs (e.g. cancer and chemical mediated injury). It is now known that an important group of proteins that switch on specialised target genes in response to hypoxia is Activator-Protein-1 (AP-1). We have found that cytochrome P450 2J2 (CYP2J2), which is an enzyme that forms beneficial fatty acid products inside cells, is decreased in hypoxia and that this is due to increased activity of AP-1. We know that similar stressful stimuli can also result in a loss of CYP2J2. Again, AP-1 is involved but we have further evidence for the role of another pathway. This project will explore how these pathways operate individually and together to decrease CYP2J2. Studying the regulation of human genes is difficult because we can not readily monitor their levels in cells in either healthy or sick individuals. So we will make transgenic mouse models to study human CYP2J2 regulation, which will provide information on the human situation. In this project we will identify which factors switch off the CYP2J2 transgene and will analyse the signalling pathways within cells that control this response. The importance of these studies is that they will help us to design pharmacological strategies to prevent the loss of CYP2J2 in cells that are stressed. Such agents may be effective in the treatment of ischaemic injury seen in stroke and atherosclerosis. If we can maintain CYP2J2 levels we may be able to maintain the beneficial fatty acid levels in cells and have a novel therapeutic approach for keeping cells alive.Read moreRead less