Mechanisms Of Oxidised Protein Accumulation In Ageing Cells
Funder
National Health and Medical Research Council
Funding Amount
$429,000.00
Summary
Australia has one of the world's most rapidly ageing populations. It is estimated that in 30 years time over 30% of the population will be over 65; many will suffer from a debilitating, age-related disease. The diseases of ageing represent one of the major health challenges this century. Despite their increasing incidence, our understanding of the underlying causes is limited. A common feature is the accumulation of damaged proteins in cells and tissues. Damaged proteins are usually broken down ....Australia has one of the world's most rapidly ageing populations. It is estimated that in 30 years time over 30% of the population will be over 65; many will suffer from a debilitating, age-related disease. The diseases of ageing represent one of the major health challenges this century. Despite their increasing incidence, our understanding of the underlying causes is limited. A common feature is the accumulation of damaged proteins in cells and tissues. Damaged proteins are usually broken down by the cells and replaced, but in many age-related diseases this process fails. The most common source of protein damage is attack by oxygen-derived free radicals. These are by-products of our body's need for oxygen and can originate from atmospheric pollutants. Oxygen rusts metal, makes fat go rancid and can cause irreparable damage to proteins and other biological molecules. Free radical damage contributes to the development of many age-related diseases such as atherosclerosis and neurodegenerative diseases such as Alzheimer's disease. The accumulation of damaged proteins can cause cell death. Our knowledge of the mechanisms by which cells remove proteins damaged by oxygen and the reasons for their accumulation is limited. In this project we will use a novel technique we have developed to generate oxidised proteins in ageing cells. We will identify cellular mechanisms required for the efficient removal of damaged proteins and those mechanisms which fail in ageing cells. We will focus on a group of proteins which protect damaged proteins from aggregating and accumulating and we will examine how we can prevent the accumulation of oxidised proteins by stimulating the body s defence mechanisms. Since the population of Australia is ageing, diseases of ageing are going to consume an increasing amount of the national health budget. A better knowledge of these cellular mechanisms will allow us to design effective prevention and treatment strategies which are at present lacking.Read moreRead less
Identification Of The Molecular Mechanisms By Which Mutations In FHL1 Lead To Protein Misfolding And Skeletal Muscle Disease
Funder
National Health and Medical Research Council
Funding Amount
$609,424.00
Summary
Skeletal muscle diseases result in debilitating muscle loss and may result from an error (mutation) within a gene. Mutations in FHL1 were identified as the cause of four different muscle diseases. Using purified FHL1, skeletal muscle cells and animal models we will investigate how FHL1 mutations cause muscle wasting, and loss of muscle strength.
Understanding The Role And Mechanism Of Interaction Of Small Heat-shock Proteins In Age-related Disease
Funder
National Health and Medical Research Council
Funding Amount
$270,827.00
Summary
Protein precipitation is associated with a diversity of age-related diseases such as cataract and Alzheimer's. Within cells, a group of chaperones called the small heat-shock proteins (sHSPs) function by binding to destabilized proteins, however, common in vivo modifications can disrupt their cellular role leading to co-aggregation in a number of age-related diseases. This study will use state of the art mass spectrometry to examine the mechanism by which sHSPs interact with client proteins.
CHARACTERISATION OF A NOVEL REGULATOR OF PHOSPHOINOSITIDE 3-KINASE-MEDIATED CELL PROLIFERATION AND PLATELET SIGNALLING
Funder
National Health and Medical Research Council
Funding Amount
$500,091.00
Summary
Critical functions such as cell growth, cell death and metabolism, are tightly controlled by key proteins which respond to specific stimuli. Perturbation of this process may lead to uncontrolled growth and cancer. This project proposes to examine the potential of a novel protein (an enzyme) as a physiological regulator of cell growth. It is proposed that this enzyme may function as a brake in preventing the evolution of a cancerous state. We will also study the ability of the novel enzyme to inf ....Critical functions such as cell growth, cell death and metabolism, are tightly controlled by key proteins which respond to specific stimuli. Perturbation of this process may lead to uncontrolled growth and cancer. This project proposes to examine the potential of a novel protein (an enzyme) as a physiological regulator of cell growth. It is proposed that this enzyme may function as a brake in preventing the evolution of a cancerous state. We will also study the ability of the novel enzyme to influence other diverse functions, such as uptake of glucose, and blood clot initiation.Read moreRead less
Regulation Of The Cardiovascular Disease-Associated Protease Inhibitor Cystatin C For Therapeutic Application
Funder
National Health and Medical Research Council
Funding Amount
$498,505.00
Summary
Proteases can contribute to atherosclerosis, so they are normally controlled by the endogenous inhibitor, Cystatin C (Cst C). Some conditions cause reduction in Cst C levels and hence disease. On the other hand, excess Cst C can form toxic aggregates. In this project, we will identify mechanisms controlling Cst C expression and aggregation to find therapeutic strategies to treat cardiovascular diseases associated with Cst C.
To Investigate How The Aggregation Of Proteins During Neuronal Injury Promotes Neurotoxic Plasmin Formation
Funder
National Health and Medical Research Council
Funding Amount
$586,428.00
Summary
tPA is an enzyme given to patients to remove stroke-causing blood clots but can have harmful effects in the brain. tPA needs a cofactor to function optimally. In the blood, this cofactor is fibrin. However the cofactor that allows tPA to function in the brain is unknown. This project explores a novel cofactor for tPA in the injured brain. We will attempt to block this harmful cofactor in the brain while still allowing tPA to remove clots thereby improving stroke outcome.
Ligand Interactions Of Platelet Glycoprotein Ib-IX-V In Thrombosis
Funder
National Health and Medical Research Council
Funding Amount
$363,098.00
Summary
The transition of circulating blood platelets from a fluid-phase, non-adherent state to an adherent, activated and aggregated state (thrombus formation) is critical in the normal haemostatic response to blood vessel injury and in thrombotic diseases such as heart attack and stroke. One unique platelet receptor, the glycoprotein Ib-IX-V complex, is of particular interest, because it initiates platelet aggregate or thrombus formation at high fluid shear stress in flowing blood, including the patho ....The transition of circulating blood platelets from a fluid-phase, non-adherent state to an adherent, activated and aggregated state (thrombus formation) is critical in the normal haemostatic response to blood vessel injury and in thrombotic diseases such as heart attack and stroke. One unique platelet receptor, the glycoprotein Ib-IX-V complex, is of particular interest, because it initiates platelet aggregate or thrombus formation at high fluid shear stress in flowing blood, including the pathological shear stress that occurs in a sclerotic coronary artery. Our published and preliminary results show how GPIb-dependent interaction of platelets with von Willebrand factor, the major adhesive ligand for GPIb-IX-V, is dependent on the level of shear stress. Using a cross-species (human to canine) homology-swap approach, where human sequence is replaced by the corresponding canine sequence within discrete structural domains, a sequence of GPIb has been identified which becomes increasingly important as hydrodynamic shear stress increases. It is proposed to further define the interactive surface of GPIb that recognizes von Willebrand factor at increasing shear, and to define the relationship between the shear-dependent alteration of GPIb conformation and its ability to interact with other pro-thrombotic or pro-inflammatory binding partners.Read moreRead less