The Effect Of PKC Epsilon On The Insulin Receptor And Whole Body Glucose Homeostasis.
Funder
National Health and Medical Research Council
Funding Amount
$82,261.00
Summary
Increased fat availability is strongly associated with insulin resistance and type 2 diabetes. Data from this lab has shown animals lacking a particular enzyme (Protein Kinase C epsilon) are able to compensate for this insulin resistance and maintain normal blood glucose levels by elevating insulin availability, with a major site of action being the liver. This project therefore aims to examine the action of PKC epsilon on insulin clearance by the liver.
Defining The Insulin-signalling Defect In Human Insulin Resistance And Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$94,280.00
Summary
Problems with the way insulin removes glucose from the circulation contribute to developing type 2 diabetes. Despite research to date, controversy remains regarding the nature of known defects in insulin action and their relevance to humans. We plan to measure molecules involved in insulin action in muscle of people with insulin resistance, which is linked to diabetes. These studies will define new defects that cause insulin resistance and type 2 diabetes in humans.
Adiponectin: Key Factors Determining Its Metabolic Actions And Influences On Insulin Sensitivity
Funder
National Health and Medical Research Council
Funding Amount
$604,793.00
Summary
Diabetes and obesity are growing at alarming rates due to poor lifestyle and other factors. Adiponectin is a complex molecule secreted by fat tissue that may help to burn fat in other tissues such as muscle and liver. We investigate what are the main determinants of adiponectin action and how these might counteract defective insulin action caused by excessive fat intake. This promises to provide new therapeutic targets to lessen the metabolic derangement associated with diabetes and obesity
Insulin-like Growth Factor Binding Protein-3 (IGFBP-3) Sensitivity And Signalling In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$414,343.00
Summary
The growth of all tissues in the body depends on many growth factors, hormones and other proteins which work together to control cell division. Some of these factors stimulate the division of the cells which make up the body tissues, and some inhibit it, so that a balance of these stimulators and inhibitors ensures that tissues do not grow too fast, or too large. The development of breast cancer and the growth of breast tumours is thought to be due to uncontrolled or faulty actions of the protei ....The growth of all tissues in the body depends on many growth factors, hormones and other proteins which work together to control cell division. Some of these factors stimulate the division of the cells which make up the body tissues, and some inhibit it, so that a balance of these stimulators and inhibitors ensures that tissues do not grow too fast, or too large. The development of breast cancer and the growth of breast tumours is thought to be due to uncontrolled or faulty actions of the proteins and hormones which regulate the way breast cells multiply. One protein which normally regulates the division of breast cells is IGFBP-3. We have found that in some breast cancer cells, IGFBP-3 is no longer able to inhibit cell division, and this may lead to tumour growth and invasion of other tissues. We are interested in finding out how IGFBP-3 normally controls breast cell proliferation, and why some breast cancers are resistant to IGFBP-3. To do this, we will use normal breast cells in culture to examine how IGFBP-3 interacts with other cellular factors to prevent cell division. We will then look at whether the breast cancer cells have changed so that they are no longer able to recognise IGFBP-3 as an inhibitory protein. This may be because of changes in the way IGFBP-3 binds to the breast cancer cell, or because of changes in the way it interacts with other proteins in the cell. Because IGFBP-3 is made by normal and breast cancer cells, we will also study whether the IGFBP-3 being made by breast cancer cells is normal, or if it changed in some way that makes it inactive. By understanding why some breast cancers are not inhibited by IGFBP-3, we will be able to design new and better methods of preventing, detecting and treating the growth of all breast tumours.Read moreRead less
Inhibition Of Glucose-stimulated Insulin Secretion By Protein Kinase C Epsilon
Funder
National Health and Medical Research Council
Funding Amount
$555,693.00
Summary
Type 2 diabetes is a chronic disease which occurs when the pancreas is unable to produce enough insulin for the body to cope with rising blood glucose levels after a meal, and is strongly linked to obesity. We have discovered that fat oversupply activates an enzyme in the pancreas causing defects in insulin release due to glucose. Inhibiting this enzyme helps overcome diabetes, through poorly defined mechanisms that we aim to clarify here. Our work could lead to new therapies for diabetes.
The Mechanism Of Growth Hormone Receptor Activation
Funder
National Health and Medical Research Council
Funding Amount
$679,500.00
Summary
Growth hormone GH excess or deficit results in considerably shortened lifespan. While cardiovascular disease is a major element in this mortality, GH status has also been linked to kidney disease and diabetic retinopathy. Importantly, GH produced locally in breast cells and prostate cells transform s these cells, creating cancers. We aim to define how GH activates its receptor, to facilitate a GH antagonist which results from understanding how GH activates its cell surface receptor.
Comparison Between AICAR And Exercise-induced Stimulation Of Skeletal Muscle AMP-K On Fat/glucose Metabolism In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$347,036.00
Summary
Background and Rationale: Exercise is important in the life of the diabetic. In well controlled diabetes, the rates of whole body sugar usage and energy production in skeletal muscle (SkM) in response to acute exercise are similar to non-diabetics. However in diabetics, little information is available as to how SkM processes sugar and produces energy during exercise. Insulin controls SkM sugar and energy processing in sedentary subjects. During exercise, these processes are controlled by non-ins ....Background and Rationale: Exercise is important in the life of the diabetic. In well controlled diabetes, the rates of whole body sugar usage and energy production in skeletal muscle (SkM) in response to acute exercise are similar to non-diabetics. However in diabetics, little information is available as to how SkM processes sugar and produces energy during exercise. Insulin controls SkM sugar and energy processing in sedentary subjects. During exercise, these processes are controlled by non-insulin factors. The chemical catalyst AMP activated protein kinase (AMP-K), which has been investigated only in normal exercising rats, is an important alternative regulator of acute sugar processing and energy supply for exercising SkM. No studies of AMP-K activity are available in diabetes. Our studies will focus on i) how important is the stimulation of SkM AMP-K in diabetes to efficient SkM sugar processing and energy production; ii) if the benefits of exercise can be simulated by pharmacological stimulation of AMP-K in sedentary diabetic subjects. We aim to i) compare the metabolic effects of exercise vs pharmacological stimulation of AMP-K in normal and diabetic subjects; ii) define the molecular mechanisms which trigger the AMP-K metabolic responses; iii) determine if the circulating levels of insulin, blood sugar and-or blood fat influence the AMP-K metabolic responses. Likely Outcomes: pharmacological stimulation of AMP-K will improve SkM sugar metabolism, but less so in diabetes. The associated AMP-K stimulation of SkM fat metabolism may blunt the beneficial SkM sugar responses, particularly in diabetes. This information will be used in future drug developments for diabetics which aim to simulate the beneficial AMP-K metabolic effects of exercise.Read moreRead less