Studies On The Role Of The P101 Component Of The Class 1B PI 3-Kinase In Cell Migration And Activation.
Funder
National Health and Medical Research Council
Funding Amount
$457,267.00
Summary
This research will determine the biological role of a protein of unknown function that is likely to participate in movement of white blood cells through the body. The outcome of this research will increase our basic knowledge of how the immune system functions and could lead to alternate therapeutic strategies for the control of autoimmune diseases.
Following a meal glucose circulates in the blood and is taken up into cells via movement of an intracellular glucose transporter from the inside of the cell to fuse with the cell membrane and subsequent transfer of the glucose into the cell. This process is triggered by insulin. One of the commonest diseases resulting from a failure of this cellular process is diabetes. A common form of diabetes which occurs in many adults in Australia results from insulin resistance, whereby the effects of insu ....Following a meal glucose circulates in the blood and is taken up into cells via movement of an intracellular glucose transporter from the inside of the cell to fuse with the cell membrane and subsequent transfer of the glucose into the cell. This process is triggered by insulin. One of the commonest diseases resulting from a failure of this cellular process is diabetes. A common form of diabetes which occurs in many adults in Australia results from insulin resistance, whereby the effects of insulin are diminished and cells become increasingly unable to uptake glucose. Recent studies have demonstrated that a novel enzyme known as SHIP-2 may play a role in regulating insulin action in cells. Deletion of SHIP-2 in mice results in these animals have increased sensitivity to insulin, low blood glucose levels, and a greatly enhanced ability to take up glucose in cells in response to low dose insulin. Our laboratory has been working on the cellular mechanisms regulating SHIP-2 function. We have recently revealed the intracellular location of SHIP-2 and also demonstrated how SHIP-2 is localized in the cell. These studies have shown that SHIP-2, via interactions with other proteins, regulates the actin cytoskeleton immediately beneath the cell membrane and this may be a mechanism for facilitating cellular glucose uptake. This research proposal aims to determine how SHIP-2 facilitates glucose uptake into cells. We will make cell lines and transgenic animals which express high levels of this enzyme and determine the functional consequences on insulin stimulated glucose uptake. Collectively these studies in the long term may facilitate better treatment strategies for diabetic patients.Read moreRead less
Investigation Of A New Approach To Regulate Fibrin Clot Retraction And Arterial Thrombolysis
Funder
National Health and Medical Research Council
Funding Amount
$483,171.00
Summary
Pathological blood clots are removed in patients by administering clot dissolving drugs (fibrinolytics). However these drugs are quite often ineffective and cause bleeding. We have identified a new platelet-mediated pathway controlling contraction of blood clots, important for clot stability. In this proposal, we will examine the potential for inhibitors of this pathway to loosen blood clots, and facilitate the actions of fibrinolytics to promote clot dissolution.
Investigation Of Negative Signalling Mechanisms In Platelets
Funder
National Health and Medical Research Council
Funding Amount
$292,500.00
Summary
Platelets are specialised blood cells essential for normal blood clotting. We are studying the processes that control platelets sticking to the exposed vessel wall, to each other and to other cells to form a stable blood clot at the site of injury to stop bleeding. The same processes, when unchecked, could lead to the formation of harmful large blood clots that may block blood vessels in the heart or brain, resulting in heart attack or stroke. Platelets stick to the blood vessel wall and each ot ....Platelets are specialised blood cells essential for normal blood clotting. We are studying the processes that control platelets sticking to the exposed vessel wall, to each other and to other cells to form a stable blood clot at the site of injury to stop bleeding. The same processes, when unchecked, could lead to the formation of harmful large blood clots that may block blood vessels in the heart or brain, resulting in heart attack or stroke. Platelets stick to the blood vessel wall and each other through sticky proteins called receptors on the cell surface. Receptors are able to bind to their specific ligands such as von Willebrand factor (vWf) and collagen which become exposed following vessel wall damage. The interaction between the ligands and receptors will trigger many biochemical changes within platelets, called signal transduction, that control platelet stickiness. The aim of this research project is to investigate the signalling processes that are utilised by the major platelet receptor called integrin alpha IIb beta 3. We are particularly interested in identifying the negative signalling process utilised by this receptor to dampen the positive signals required for platelet stickiness, to achieve a balanced clotting process. The identification of these specific signalling pathways will not only increase our knowledge of blood clot formation in health and disease, but also help develop potential new therapies for the prevention of heart diseases and strokes.Read moreRead less
Biological And Clinical Characterisation Of Human Phosphatidylinositide 3-kinase Mutations
Funder
National Health and Medical Research Council
Funding Amount
$33,626.00
Summary
The frequency of PI3K mutations in tumours, suggests that PI3K is one of the most common human oncogenes. Understanding the biological and biochemical significance of these mutations will provide new insights into the biology of human tumourigenesis and further our understanding of the consequence pathways and the progression of human tumours. Such knowledge will help us to identify more effective markers of prognosis, diagnosis, early detection of cancer and design new anti-cancer therapy.
Targeting A Novel Anti-platelet Mechanism For Improved Anti-thrombotic Therapy
Funder
National Health and Medical Research Council
Funding Amount
$985,938.00
Summary
Blood clots cause heart attacks and most strokes, which are the most common cause of death in the world. Platelets are the cells in the blood that form these clots, and drugs that prevent platelet function are the major approach for heart attack and stroke prevention. However, many patients are resistant to the effects of existing therapies. These studies will develop a unique approach to prevent platelet function that may help overcome the limitations of current drugs.
Characterisation Of Autophagy Deficiency In Skeletal Muscle Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$956,237.00
Summary
Defects in skeletal muscle are a cause of muscle disease, and also have broad health implications for diabetes, obesity and liver disease. As such, it is important to understand the processes required for healthy muscle and how signals communicate from muscle to the liver and fat, which integrate whole body metabolism. This application examines how the cellular degradation process known as autophagy integrates these important processes by investigating a novel gene regulator of this pathway.