Type 2 diabetes causes significant health problems. The fundamental reasons underlying this disease are not fully known and will require molecular analysis of proteins critical to blood glucose control. This work aims to define a novel pathway that responds to circulating nutrients. The research will enhance our understanding of the links between diet and metabolic disease, with potential to reveal much needed therapeutic targets and/or dietary interventions for the treatment of Type 2 diabetes.
Type 2 diabetes is caused by multiple genetic defects, resulting in high blood sugar levels. These high sugar levels are primarily due to a decrease in the concentration of insulin, a hormone produced by the pancreas. A number of recent studies have aimed to identify which genes are regulated under conditions that mimic diabetes. One gene shown to have altered expression levels under these conditions is an enzyme called fructose-1,6-bisphosphatase (or FBPase). This enzyme is involved in the meta ....Type 2 diabetes is caused by multiple genetic defects, resulting in high blood sugar levels. These high sugar levels are primarily due to a decrease in the concentration of insulin, a hormone produced by the pancreas. A number of recent studies have aimed to identify which genes are regulated under conditions that mimic diabetes. One gene shown to have altered expression levels under these conditions is an enzyme called fructose-1,6-bisphosphatase (or FBPase). This enzyme is involved in the metabolism of sugar and is usually expressed at undetectable levels in the pancreas, but when blood sugar levels are high, the amount of FBPase in the pancreas increases considerably. We hypothesise that this increase in FBPase may contribute to the decrease in insulin secretion by the pancreas, seen in the diabetic state. The aim of this proposal therefore is to study mice that we have modified to express increased FBPase specifically in the pancreas, in order to determine whether this will lead to a decrease in insulin release and to diabetes. If this is the case, then FBPase could be targeted for the development of drugs that would improve the control of blood sugar levels in diabetes.Read moreRead less
Development Of A Specific Activin Antagonist For Therapeutic Applications
Funder
National Health and Medical Research Council
Funding Amount
$504,287.00
Summary
Activin is a key regulator of homeostasis in several organs and tissues, including ovaries, testes, liver and skin, and alterations in activin�s activity can result in fibrosis, cachexia and cancer. In this grant we propose to develop a specific activin antagonist by modifying the activin A propeptide. This novel reagent could be used to promote liver growth in severe hepatic disease and prevent fibrosis in numerous tissues.
Regulation Of Insulin Signalling & Glucose Homeostasis By Protein Tyrosine Phosphatases
Funder
National Health and Medical Research Council
Funding Amount
$503,776.00
Summary
Type 2 diabetes has reached epidemic proportions afflicting roughly 6% of the adult population in Western society. Although the underlying genetic causes and the associated pathological symptoms are heterogenous, a common feature is high blood glucose due to peripheral insulin resistance. The molecular basis of insulin resistance is believed to be attributable to defects in insulin receptor (IR) signalling. The IR is a protein tyrosine kinase that phosphorylates itself and downstream substrates ....Type 2 diabetes has reached epidemic proportions afflicting roughly 6% of the adult population in Western society. Although the underlying genetic causes and the associated pathological symptoms are heterogenous, a common feature is high blood glucose due to peripheral insulin resistance. The molecular basis of insulin resistance is believed to be attributable to defects in insulin receptor (IR) signalling. The IR is a protein tyrosine kinase that phosphorylates itself and downstream substrates on tyrosine in response to insulin. Protein tyrosine phosphatases (PTPs) that dephosphorylate the IR and its substrates might be important targets for therapeutic intervention in type 2 diabetes; inhibition of specific PTPs may allow for enhanced insulin-induced signalling to alleviate insulin resistance. This proposal will examine the roles of PTPs and in particular TCPTP in IR signalling in vivo. Our studies will shed light on the molecular mechanisms of IR regulation and function and may provide important insights into novel strategies for enhancing insulin sensitivity in type 2 diabetes.Read moreRead less
Identification Of Novel Genes Influencing Development Of Type 2 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$558,920.00
Summary
Type 2 diabetes is usually associated with obesity and is often part of a wider disturbance affecting an individual's energy metabolism. The number of affected people with type 2 diabetes has trebled since 1981 in Australia and is still increasing. Apart from individual suffering, this presents a major public health burden for the country (approx $3 billion annually). Currently available lifestyle based and pharmaceutical therapies are inadequate to control the increasing numbers of affected ind ....Type 2 diabetes is usually associated with obesity and is often part of a wider disturbance affecting an individual's energy metabolism. The number of affected people with type 2 diabetes has trebled since 1981 in Australia and is still increasing. Apart from individual suffering, this presents a major public health burden for the country (approx $3 billion annually). Currently available lifestyle based and pharmaceutical therapies are inadequate to control the increasing numbers of affected individuals. Unfortunately the cause of disease is poorly understood, although genetic factors are known to be important, in other words it runs in the family. This project proposes to identify some of these factors (genes) and how they contribute to the disease. Using molecular flags on the DNA (like DNA fingerprinting) we have previously found that a small region on chromosome 12 is likely to carry one or more of these disease genes. But there are over 100 genes in the region. To help choose the most likely candidates first for testing, we have developed an automated computer database searching program ranked the genes based on what is already known about them. We have also taken a large number of physiological measures in a large group of people. Some of these measures are controlled by the same chromosome 12 region - thus to improve our chances of finding the genes quickly we will look at those that change the most between people with diabetes and people without diabetes. In this project we shall investigate the 20 genes most likely affect diabetes based on changes in physiological measures and what is already known about them. A successful finding means we will know more about the mechanism of disease development and be able to better develop new therapies for treatment and prevention. If none of these genes are the culprit, we would continue examination of the next set of genes likely to be involved and so on until we are successful.Read moreRead less
How Does Disruption Of Circadian Rhythms Induce Diabetes?
Funder
National Health and Medical Research Council
Funding Amount
$631,782.00
Summary
Increasing evidence suggests that disturbed circadian rhythms initiate and amplify metabolic and cardiovascular disease. The increasing and already high proportion of workers engaged in shiftwork, and increased frequency of disruption of these rhythms in the population more generally, implicate this body system as contributing to the growing epidemic of obesity and diabetes and related disorders in our community and world-wide. While we are now beginning to understand how our rhythms are synchro ....Increasing evidence suggests that disturbed circadian rhythms initiate and amplify metabolic and cardiovascular disease. The increasing and already high proportion of workers engaged in shiftwork, and increased frequency of disruption of these rhythms in the population more generally, implicate this body system as contributing to the growing epidemic of obesity and diabetes and related disorders in our community and world-wide. While we are now beginning to understand how our rhythms are synchronised to night and day, how this rhythmicity is linked to our organs in the normal and common disease states such as diabetes is poorly understood. The discovery of a special set of genes, called clock genes that function in all of the cells in our bodies and strongly influence the function of our organs such as the liver, pancreas and heart has been particularly important. We hypothesise that both environmentally (exogenous) and genetically (endogenous) induced disruption of circadian rhythms causes metabolic dysfunction. This is due to altered central and peripheral clock gene expression rhythms, which in turn alter metabolic rhythms and impair glucose homeostasis. This project aims to determine the impact of disrupted rhythmicity on metabolism with a particular emphasis on the possibility that the disrupted rhythmicity may be a predisposing factor for the development of diabetes.Read moreRead less