Analysis Of The Role Of Vesicle Docking/Fusion Proteins In Trafficking Of The Glut4 Glucose Transporter In Adipocytes
Funder
National Health and Medical Research Council
Funding Amount
$212,036.00
Summary
The objective of these studies is to understand the molecular mechanisms that are involved in the control of blood glucose levels by the hormone insulin. Elevated blood glucose levels following a meal stimulate the pancreas to release insulin into the circulation. Insulin acts to reduce blood sugar levels by stimulating the uptake of glucose into fat and muscle and suppressing glucose production by the liver. Defects in insulin action in these tissues are the primary cause of Type II diabetes. T ....The objective of these studies is to understand the molecular mechanisms that are involved in the control of blood glucose levels by the hormone insulin. Elevated blood glucose levels following a meal stimulate the pancreas to release insulin into the circulation. Insulin acts to reduce blood sugar levels by stimulating the uptake of glucose into fat and muscle and suppressing glucose production by the liver. Defects in insulin action in these tissues are the primary cause of Type II diabetes. The debilitating effects of Type II diabetes, the dramatic increase its incidence, and the expense of treating the symptoms of diabetic complications have lead to the realization that the disease represents a major health problem requiring substantial research and development efforts. The project will focus on insulin regulation of glucose uptake in fat cells. Insulin promotes glucose uptake into fat by activating an intracellular signaling pathway that triggers the translocation of a unique glucose transporter protein (Glut4) from storage sites inside the cell to the cell surface. Glut4 translocation is mediated by small membrane vesicles that function to sequester the glucose transporter inside cells in the absence of insulin, and to shuttle Glut4 to the cell surface in response to the hormone. Despite the central importance of this event to the maintenance of normal blood glucose levels, it is poorly understood. The studies will be directed towards investigating the cellular machinery involved in the latter stages of insulin-stimulated glucose uptake- the vesicle-mediated delivery of Glut4 to the cell surface. The objective of these studies is to better understand the molecular basis for Glut4 translocation, and regulation by the insulin signaling cascade. Accomplishment of this goal may suggest potential drug intervention strategies aimed at enhancing insulin-stimulated Glut4 translocation and promoting improved control of blood glucose levels in Type II diabetes.Read moreRead less
Therapeutical Potential And Mechanisms Of Action Of New Compounds From Bitter Melon For Insulin Resistant States
Funder
National Health and Medical Research Council
Funding Amount
$115,155.00
Summary
Type 2 Diabetes is a major disease with major economic and health implications. Current medications are either insufficient or have serious adverse effects. Bitter melon is a vegetable in many countries including Australia and it has been used as a traditional medicine to control blood sugar. This project intends to identify the active ingredients from bitter melon for the treatment of type 2 diabetes. The results will indicate their potential as new agents for this disease.
Investigation Of Novel Triterpenoids As New Potent AMPK Activators For The Treatment Of Insulin Resistant States
Funder
National Health and Medical Research Council
Funding Amount
$574,075.00
Summary
Type 2 Diabetes has major economic and health implications. Current medications are inadequate or have serious adverse effects. Triterpenoids have been used in traditional medicines for various diseases. This project builds on our recent discovery of novel triterpenoids with antidiabetic properties to investigate their efficacy and mechanisms of action. The results will provide valuable information about this class of molecules as potential new therapeutics for Type 2 diabetes.
Cancer arises through a combination of common DNA mutations which are associated with very poor survival in certain cancers. However, the cause of these mutations was always believed to be external factors (eg. UV light, toxins), Our exciting preliminary results show internal molecules, called circular RNAs, can drive these mutations and this project will investigate how this occurs and study whether targeting these molecules can reduce the incidence of cancers.
Insulin triggers glucose uptake into fat and muscle tissue, a process that is defective in type 2 diabetes. Insulin does this by triggering a complex cascade of actions once it binds to muscle and fat cells. We will analyse the function of a crucial protein within this cascade. This protein is mutated in humans with severe insulin resistance and our proposed project will dissect how this protein works potentially providing a novel drug target to treat diabetes.