Investigation Of A New Leukocyte Recruitment Mechanism At Sites Of Vascular Injury
Funder
National Health and Medical Research Council
Funding Amount
$547,216.00
Summary
Blood clots formed at sites of small vessel injury can cause damage of vital organs by obstructing blood flow and promoting a proinflammatory response by efficiently recruiting and activating leukocytes. The molecular mechanisms responsible for the latter event are poorly defined. We have established a new mouse model, gained novel insights into the leukocyte recruitment by blood clots, and aim to define the precise mechanism for this process in this application.
Investigating The Link Between Oxidative Stress And Biomechanical Integrin Activation In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$653,742.00
Summary
Diabetes represents a serious healthcare problem globally. A large proportion of deaths associated with diabetes can be attributed to the development of blood clots in the circulation of the heart and brain (heart attack/stroke). The blood clotting mechanism is ‘hyperactive’ in diabetes, although the reason for this is not well defined. In this proposal we will investigate a new mechanism promoting blood clots, and will investigate innovative approaches to reduce this clotting mechanism.
Defining The Role Of Glycosylation In Basement Membrane Failure During Muscular Dystrophy
Funder
National Health and Medical Research Council
Funding Amount
$824,664.00
Summary
This project aims to utilize mutations within the zebrafish fkrp gene to understand the pathogenic basis of the human diseases associated with mutation of this gene which results in a spectrum of muscular dystrophies. By generating models of alleles that represent the range of phenotypes seen in humans we will have a directly translatable model system to human pathology.
Characterisation Of The Molecular Mechanisms Of Abeta-induced Proteolysis Of The Neural Cell Adhesion Molecule 2 (NCAM2)
Funder
National Health and Medical Research Council
Funding Amount
$374,666.00
Summary
Neurons in the brain are connected by synaptic contacts. Amyloid beta peptide accumulating in the brain in Alzheimer’s disease destroys synaptic contacts by degrading synaptic cell adhesion molecules which maintain the structure of the contacts. The aim of the project is to characterise the molecular mechanisms of amyloid beta-dependent degradation of synaptic cell adhesion molecules. The project will identify strategies that can be used to inhibit synapse loss in Alzheimer’s disease.
Regulation Of Receptors That Control Platelet Function Under Shear Stress
Funder
National Health and Medical Research Council
Funding Amount
$507,273.00
Summary
Specialized human blood cells that control blood loss and clotting (platelets) are currently difficult to test in the clinical laboratory, meaning patients are at risk of excessive bleeding or serious clot formation during disease or treatment. The aim of this proposal is to use our new reagents and assays to develop more reliable methods for evaluating relative bleeding or clotting risk in individuals.
How Caveolae Condition Tissue Mechanics For An Anti-tumor Niche.
Funder
National Health and Medical Research Council
Funding Amount
$1,091,226.00
Summary
The outcome of cancer is determined not only by the behaviour of the cancer cell, but also by how the normal tissue cells of the body respond to it. This project investigates how tissue cells that surround cancer cells can eliminate early cancers from the body. It develops on newly-discovered mechanisms that allow epithelial tissues to detect and physically expel cancer cells. This mechanism can protect us from cancer, but potentially allow cancer to develop when it fails.
The Impact Of The Changes In Levels Of Adhesion Molecules NCAM2 And DsCAM On Synapse Formation And Function: Implications For Down Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$334,053.00
Summary
Down syndrome (DS) results from triplication of chromosome 21 and leads to mental retardation, molecular mechanisms of which are not understood. We found that two proteins, NCAM2 and DSCAM, encoded at chromosome 21 are highly expressed in synapses. Synapses are specialized contacts between neurons which allow neurons to process information in the brain. In this project we will test a hypothesis that changes in NCAM2 and DSCAM expression result in synapse abnormalities observed in DS.
Transplantation of pancreatic islets is the only cure for type 1 diabetes (T1D). Unfortunately, many of the transplanted islet cells die quickly due to an inadequate supply of blood. Herein, we investigate a novel cell surface protein for its role in islet and blood vessel survival and function. Furthermore, we use nanotechnology to provide said protein to the islet cells during transplantation for increased survival and function. Ultimately, this work may cure more patients with diabetes.
A Mechanotransduction Apparatus To Coordinate Epithelial Collective Cell Migration.
Funder
National Health and Medical Research Council
Funding Amount
$994,596.00
Summary
Epithelial cells migrate as physically coherent collective groups, which is necessary for normal development and is disrupted as cancers progress to become invasive and spread. Collective migration requires communication so that the behaviour of individual cells is properly coordinated. In this project we investigate how the transmission of physical force between cells allows them to communicate; and test how its disruption contributes to cancer invasion.
Regulation Of ICAM-1 Expression In Human Retinal Endothelial Cells
Funder
National Health and Medical Research Council
Funding Amount
$565,967.00
Summary
Posterior uveitis is an inflammation that occurs within the eye and may result in blindness. Present treatments are not directed specifically at the inflamed tissues, and they may be ineffective and cause toxicity. This research aims to identify molecules controlling the entry into the eye from the bloodstream of the white blood cells that cause the disease. The results should suggest new targets for safer drugs to treat patients with posterior uveitis.