The Role Fructose-1,6-bisphosphatase On The Regulation Of Hepatic Gluconeogenesis
Funder
National Health and Medical Research Council
Funding Amount
$212,485.00
Summary
Type 2 or adult onset diabetes is a disease characterised by high blood sugar that causes damage to the kidneys, eyes and to the circulation and many patients die from heart attack or stroke. There is an increase in the prevalence of diabetes in Australia and a substantial portion of the health budget is utilised by caring for people with diabetes. Determining what exactly causes the increase in blood sugar levels is critical in the treatment of the disease. It is known that the sugar produced a ....Type 2 or adult onset diabetes is a disease characterised by high blood sugar that causes damage to the kidneys, eyes and to the circulation and many patients die from heart attack or stroke. There is an increase in the prevalence of diabetes in Australia and a substantial portion of the health budget is utilised by caring for people with diabetes. Determining what exactly causes the increase in blood sugar levels is critical in the treatment of the disease. It is known that the sugar produced and released by the liver is an important contributor to the high blood sugar levels found in patients with diabetes. The main biochemical pathway responsible for this is called gluconeogenesis, a complex arrangement of enzymes, which convert amino acids and fat into sugar. Although it is known that this pathway is overactive in patients with diabetes, the exact reason for this is not clearly understood. The aim of this proposal is to produce a transgenic mouse that has an increase in liver sugar production as a result of an increase in gluconeogenesis, and to study its effects on blood sugar levels. Furthermore, studies will be performed to understand the regulation of this pathway by infusing the transgenic mice with insulin, the hormone that inhibits gluconeogenesis. The mechanism of action of insulin will be determined by the measurement of key enzymes that regulate gluconeogenesis. The significance of this grant is to identify possible sites for the development of new drugs or gene therapy that will lead to a decrease in the production of sugar by the liver. This will lead to better control of blood sugar levels and slow down or even prevent the onset of diabetes complications.Read moreRead less
Mechanisms Of Insulin Resistance And Diabetes Susceptibility
Funder
National Health and Medical Research Council
Funding Amount
$633,783.00
Summary
The two main forms of diabetes - types 1 (T1D) and 2 (T2D) - pose a major problem. It is difficult to identify what causes diabetes. Recently, people at risk of T1D were found to have insulin resistance, a condition thought typical only of T2D. Excitingly, we discovered that the best T1D animal model also shows insulin resistance, and we used it to map important genes. We will now identify these genes. This will help us understand the disease process and to develop better treatments for it.
The Role Of Androgens In Osteoblast Development And Bone Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$64,631.00
Summary
Male hormones are essential for the growth and maintenance of bone in men, but exactly how and when they act on the bone forming cells is unclear. We aim to find out what happens when the target for male hormones (receptor) is removed in the bone forming cells at different stages of their development. This project will increase our understanding of how male hormones regulate bone formation and may assist in the design of new therapies for osteoporosis.
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.
The Role Of Liver Fructose-1,6-phosphatase (FBPase) In Body Weight Regulation
Funder
National Health and Medical Research Council
Funding Amount
$494,718.00
Summary
We have shown that fructose-1,6-bisphosphatase (FBPase), an enzyme important in producing sugar from the liver and one that is connected to Type 2 diabetes, does not cause an increase in sugar production when there is more of the enzyme in mouse livers. It does, however, lower both body weight and the amount of food the mice consume. We therefore hypothesise that liver FBPase is important in controlling body weight in humans and our project aims to find out exactly how and why this happens.
Investigation Of Transgenic Mouse Models Of Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$412,200.00
Summary
Type 2 diabetes is a common condition characterised by high blood glucose, that afflicts 700,000 Australians. It causes blindness, kidney failure and an increased risk of heart attack and stroke. despite intensive study over many years, the reasons for the elevated blood glucose in this condition are not fully understood. Several abnormalities can contribute to the high glucose and different researchers have proposed different defects as the initial cause. It has proven difficult to unravel the ....Type 2 diabetes is a common condition characterised by high blood glucose, that afflicts 700,000 Australians. It causes blindness, kidney failure and an increased risk of heart attack and stroke. despite intensive study over many years, the reasons for the elevated blood glucose in this condition are not fully understood. Several abnormalities can contribute to the high glucose and different researchers have proposed different defects as the initial cause. It has proven difficult to unravel the sequence of events in the evolution of the syndrome because high glucose can cause insulin resistance and a defect in insulin secretion, both of which can lead to high blood glucose. One approach to study the consequences of specific defects is to genetically engineer them. The aims of this project are to: 1. make a mouse with reduced ability to store glucose in muscle. 2. test the metabolic consequences of a defect in the manufacture of glycogen (starch) in muscle. 3. study the effects of combining a defect in glucose storage with one that results in an oversupply of glucose. 4. study the effects on a mouse with a genetic predisposition for failure of beta cells (insulin making cells) of a defect in muscle glucose storage and over production of glucose. A successful completion of this grant will greatly enhance our understanding of how blood glucose is increased in Type 2 diabetes.Read moreRead less
Osteoporosis is a major health burden resulting from bone fractures in older men and women due to progressive loss of bone and weakening of the skeleton. Although there are currently therapies to reduce bone loss, no current treatment effectively reconstructs lost bone. In this project, which is designed to identify new genes that may in the future be targeted by drugs to reverse osteoporosis, we have identified specific sets of genes that appear to work together to increase bone formation. This ....Osteoporosis is a major health burden resulting from bone fractures in older men and women due to progressive loss of bone and weakening of the skeleton. Although there are currently therapies to reduce bone loss, no current treatment effectively reconstructs lost bone. In this project, which is designed to identify new genes that may in the future be targeted by drugs to reverse osteoporosis, we have identified specific sets of genes that appear to work together to increase bone formation. This proposal is aimed at characterising these genes and the ways in which they work to determine whether they may be good targets for new osteoporosis treatments. We will examine the patterns of these genes in bone. We will also use cell cultures in which bone forming cells develop and function, to determine when the genes are expressed and how they function. We will test the ability of the candidate genes to cause an increase in the amount of bone forming activity in these cell cultures. An increase in bone formation may be caused by an increase in the number bone-forming cells, an increase in the activity of the cells, a decrease in cell death, or a combination of these changes. Each possibility will be tested. This research is important because of the need for new osteoporosis therapies to repair weakened bones. The knowledge resulting from this proposal has the potential to provide an important contribution to skeletal health and thus aged health worldwide.Read moreRead less
Regulation Of Insulin Signalling And Glucose Homeostasis By Protein Tyrosine Phosphatases
Funder
National Health and Medical Research Council
Funding Amount
$542,462.00
Summary
A common feature of type 2 diabetes is high blood glucose due to peripheral insulin resistance. Protein tyrosine phosphatases (PTPs) that antagonise insulin signalling might be important targets for therapeutic intervention in type 2 diabetes; inhibition of specific PTPs may allow for enhanced IR signalling to alleviate insulin resistance. This proposal will examine the roles of PTPs and in particular TCPTP in insulin signalling and glucose homeostasis.
The Mechanisms Of The Anabolic Actions Of Androgens In Bone.
Funder
National Health and Medical Research Council
Funding Amount
$470,960.00
Summary
Androgens (male sex hormones) are one of the few agents that increase bone formation. Androgens act by binding to a specific protein, the androgen receptor (AR). To understand exactly how androgens increase bone formation, we will study mice in which the AR is inactivated only in bone forming cells at specific stages of their development. Understanding the way in which androgens act on bone to increase size and strength will be of great benefit in the design of new treatments for osteoporosis.