Molecular Dissection Of The Munc18c:Syntaxin4 Complex Required For Insulin-regulated Exocytosis In Adipocytes
Funder
National Health and Medical Research Council
Funding Amount
$601,008.00
Summary
When blood glucose levels are high, insulin signals to fat and muscle cells to remove glucose from the blood. The uptake of glucose relies on membrane fusion events that deliver a specific glucose transporter protein to the cell surface in response to insulin signals. This process is affected in Type II diabetes. Our research will characterise the regulation of these membrane fusion events and will be important for understanding how insulin signals are communicated in health and disease.
Many bacterial pathogens invade host cells to replicate and avoid detection by the host. These pathogens interact with the host and by manipulating it to its benefit they establish an environment to survive in. A detailed understanding of the targeted hosts pathways and which are essential for pathogen survival is knowledge that will allow future development of therapeutic intervention strategies.
The Role Of Dysferlin In Muscular Dystrophy And Skeletal Muscle Membrane Repair.
Funder
National Health and Medical Research Council
Funding Amount
$316,667.00
Summary
Patients who lack the protein dysferlin have muscular dystrophy. These patients are unable to repair their muscle membranes, which get damaged during normal activities. A defect in membrane repair is a new pathway implicated in the muscular dystrophies, and it is likely that other patients will also have defective muscle membrane repair. We will find out how dysferlin mediates its role in membrane repair, and identify other dysferlin-interacting proteins, as these may also underlie disease.
Insulin resistance (the inability of ordinarily insulin-sensitive tissues such as muscle and adipose tissue to respond to insulin) contributes to a number of diseases including diabetes and obesity. A key metabolic step in these tissues is the uptake of glucose from the blood stream. This step is accelerated by insulin thus allowing efficient clearance of glucose from the bloodstream after a meal. Our laboratory has played a major role in showing that insulin regulates glucose uptake into muscle ....Insulin resistance (the inability of ordinarily insulin-sensitive tissues such as muscle and adipose tissue to respond to insulin) contributes to a number of diseases including diabetes and obesity. A key metabolic step in these tissues is the uptake of glucose from the blood stream. This step is accelerated by insulin thus allowing efficient clearance of glucose from the bloodstream after a meal. Our laboratory has played a major role in showing that insulin regulates glucose uptake into muscle and adipose tissue by stimulating the movement of a glucose transport protein from inside the cell to the cell surface (see http:--www.imb.uq.edu.au-groups-james-glut4 for an animated description of this process). The purpose of this proposal is to dissect the molecular mechanisms by which this glucose transporter can be held inside the cell in the absence of insulin and then allowed to be released from this site moving to the surface in the presence of insulin. Our studies over the past 5 years have brought us much closer to understanding this process in detail. The identification of the molecules responsible for this regulatory step will not only aid our understanding of this process but it will also provide a valuable target for development of therapeutic agents that can be used to combat insulin resistance.Read moreRead less
In this fellowship I will develop methods to improve the way drugs are delivered through the use of nanotechnology. Nanoparticles can be used to protect delicate drugs from degrading, and to make sure drugs are delivered where they are required. This helps to lower side effects and improve efficacy of a range of drugs. I lead a multi-disciplinary research team dedicated to understanding of how nanoparticles interact with biological systems, so we can engineer better drug delivery systems.
Molecular Characterisation Of Clathrin-independent Endocytosis In Migrating Cells
Funder
National Health and Medical Research Council
Funding Amount
$870,495.00
Summary
Cell migration is an essential feature of physiological processes involved in embryo development, as well as disease conditions such as cancer metastasis. Cell movement requires extensive changes to the cell surface. We have identified a vital pathway involved in membrane trafficking during cell migration. This proposal aims to identify the cellular components involved in this pathway, screen for new inhibitors, and characterise the role of this pathway in migrating cancer cells.
INHIBITORS OF DENGUE VIRUS NONSTRUCTURAL PROTEIN 5 NUCLEAR TRAFFICKING AS PROBES OF DENGUE BIOLOGY
Funder
National Health and Medical Research Council
Funding Amount
$741,136.00
Summary
Viral disease is one of the most significant health problems world-wide, making the identification of new therapeutics of critical importance. We aim to characterise in detail novel compounds which inhibit the interaction of the host cell with Dengue virus, and test them in a series of relevant infectious models for Dengue.