Characterisation Of Antioxidant Pathways Involving Gpx-1: Implications For Neural Ischemic Reperfusion Injury.
Funder
National Health and Medical Research Council
Funding Amount
$458,250.00
Summary
Neural damage following stroke can be grouped into two stages. The first occurs immediately following the ischemic insult and results in the rapid loss of neural cell viability; the second stage (which usually results in severe neural dysfunction) occurs over many hours following reperfusion. There is however, a window of opportunity shortly following the ischemia-reperfusion where damage to the brain can be minimized if appropriate therapeutic intervention was available. However, our ability to ....Neural damage following stroke can be grouped into two stages. The first occurs immediately following the ischemic insult and results in the rapid loss of neural cell viability; the second stage (which usually results in severe neural dysfunction) occurs over many hours following reperfusion. There is however, a window of opportunity shortly following the ischemia-reperfusion where damage to the brain can be minimized if appropriate therapeutic intervention was available. However, our ability to identify novel targets and devise strategies for the treatment of stroke relies on our understanding of (a) the molecular processes that are initiated following brain ischemia and (b) the delayed molecular events that follow reperfusion and hypoperfusion and result in extensive neuronal loss. A major component that accompanies stroke is the generation of oxidative stress. Reactive oxygen species (ROS) are thought to make a significant contribution to neuronal cell injury and death during both the early and late stages following ischemia. Therefore the molecular pathways that are involved in ROS generation are prime targets for the development of improved therapies. It has already been established by us that the antioxidant enzyme, glutathione peroxidase-1 (Gpx-1) is essential in protecting neurons from ischemic injury-death. A clearer understanding of how Gpx-1 confers this protection in vivo would make an important contribution towards the design of improved treatments. In this proposal, we plan to determine the role of Gpx-1 in an in vivo model of stroke to: (1) demonstrate in a broader sense the functional importance of this antioxidant enzyme in neuronal survival and (2) to demonstrate in a more specific manner, the impact of this enzyme on two signaling molecules, PI3kinase (PI3K) and NFkB (both of which are redox sensitive and play important roles in neuronal cell viability) and their relevance to ischemic cell injury and death.Read moreRead less
Influences Of Oestrogen On Neurodegeneration And Behaviours
Funder
National Health and Medical Research Council
Funding Amount
$620,352.00
Summary
More women develop Alzheimer's disease whereas more men develop Parkinson's disease. This study will try to understand whether sex hormones play a part in the devlopment of these diseases. This study will also try to answer how the female sex hormone, oestrogen, influences behaviour and or development of mental health problems such as depression and obsessive-compulsive disorder.
Deciphering The Neuroprotective Mechanism Of Parkinsons Disease-Associated Protein Kinase PINK1
Funder
National Health and Medical Research Council
Funding Amount
$547,994.00
Summary
Parkinson's disease is caused by premature death of nerve cells that control body movements. The enzyme PINK1 protects against nerve cell death by chemically modifying specific cellular proteins that maintain cell survival. We aim at identifying these proteins and investigating how PINK1-catalysed modification modulates their ability to maintain nerve cell survival. The study will benefit development of drugs that protect against nerve cell death for treatment and prevention of the disease.
The Sulphate Anion Protects Against Stroke: Characterisation Of Neuroprotective Potential And Mechanism Of Action.
Funder
National Health and Medical Research Council
Funding Amount
$189,170.00
Summary
Stroke-cerebral ischaemia affects approximately 40,000 - 50,000 Australians every year and is Australia's leading single cause of disability and second greatest cause of death after heart disease. About 25% of people who suffer a stroke die within one month while most survivors are disabled because of impaired speech, memory, thought processes, vision, balance, or motor control of the limbs (paralysis). The direct and indirect cost of stroke to the Australian community is over $2 billion annuall ....Stroke-cerebral ischaemia affects approximately 40,000 - 50,000 Australians every year and is Australia's leading single cause of disability and second greatest cause of death after heart disease. About 25% of people who suffer a stroke die within one month while most survivors are disabled because of impaired speech, memory, thought processes, vision, balance, or motor control of the limbs (paralysis). The direct and indirect cost of stroke to the Australian community is over $2 billion annually. Hence preventing or reducing brain damage following stroke is of fundamental clinical, social and economic significance. A stroke occurs when there is a reduced blood supply to the entire brain (Global ischaemia; eg. cardiac arrest, heart bypass surgery, closed head injury) or when there is a reduced blood supply to a specific region of the brain, usually as a result of a blockage in a brain artery (thrombo-embolic stroke or focal ischaemia). Despite decades of research, there is no totally satisfactory clinical treatment to reduce brain damage following stroke; the search for new treatments is paramount. We have shown that sodium sulphate can prevent brain damage in rat models of focal and global ischaemia. Importantly we demonstrated that sodium sulphate could prevent brain damage when given up to 8 hours after the stroke was induced in the global model. Delayed treatment following stroke is of clinical significance, since most patients do not receive medical attention until several hours after initial stroke symptoms. It is not known how sodium sulphate protects the brain from stroke. This project has three main aims: 1. To determine the how well sodium sulphate treatment protects the brain in rats following stroke. 2. To determine if sodium sulphate treatment can reduce brain damage in the rat model of focal ischaemia when given 4 - 8 hours after the stroke. 3. To determine how sodium sulphate protects the brain from stroke.Read moreRead less