The Role Of Central And Peripheral Synaptic Activity In The Developmental Death Of Motoneurons.
Funder
National Health and Medical Research Council
Funding Amount
$463,145.00
Summary
Information processing in the nervous system relies on the effective communication between neurons and their target cells which make up our neuronal circuitry. At the centre of all this is the synapse, the specialized contact between a neuron and its target cell, be it another neuron in the brain or a target organ such as skeletal muscle. Our primary goal is to determine how the formation of synaptic connections during development regulates neuronal survival. In this proposal we have focussed on ....Information processing in the nervous system relies on the effective communication between neurons and their target cells which make up our neuronal circuitry. At the centre of all this is the synapse, the specialized contact between a neuron and its target cell, be it another neuron in the brain or a target organ such as skeletal muscle. Our primary goal is to determine how the formation of synaptic connections during development regulates neuronal survival. In this proposal we have focussed on the neuromotor system as it is a well characterised part of the nervous system. During development, 50% of motoneurons die at a time when they are making contact with skeletal muscle, and when contacts onto motoneurons by other neurons are being established. We believe that the formation of effective synaptic contacts onto motoneurons, as well as connections by motoneurons onto muscle are the key regulators of motoneuron survival. We are in a position to be able to address what regulates motoneuron death; as we have a number of mice which lack key molecules needed for the formation of specialisations that allow neuronal contacts to be made between motor neurons and their muscle, and with other neurons within the spinal cord. By examining the function of motoneurons, counting them and screening for molecular changes in these mice, we will be able to dissect out the mechanism of how a motoneurons' fate is determined during developmental motoneuron death. This research could help in developing strategies aimed at improving neuronal connections to improve neuronal viability. Our research will have important implications for our understanding about the basis of adult neuro-degenerative diseases, such as motor neuron disease and Alzheimer's, which are in part characterised by a molecular breakdown in neuronal connections that ultimately result in neuronal death.Read moreRead less
The Role Of Store-operated Calcium Entry In Neuronal Development
Funder
National Health and Medical Research Council
Funding Amount
$353,140.00
Summary
Defects in brain development can manifest in a range of disorders including autism and mental retardation. The highly complex, precise network that is our nervous system forms during development. Our work will determine the role of key proteins in guiding developing neurons. Understanding the function of such proteins will improve our ability to predict the outcome caused by mutations in these proteins, in the developing foetus.
How Does Iron Accumulation Affect Parkinson’s Disease And What Controls It?
Funder
National Health and Medical Research Council
Funding Amount
$545,517.00
Summary
Currently there is no cure for Parkinson's disease, and although we have a number of treatments to manage the disease there is an urgent need for a further understanding of the disease process. This proposal will investigate the critical role that iron plays in the cause of neuronal cell death that results in Parkinson's disease, and will investigate methods for regulating metal levels in the brain.
A Comparative Study Between The Effects Of C-terminally Truncated A-synuclein Metabolites And Full Length A-synuclein In Aged Rat Hippocampal Neurons
Funder
National Health and Medical Research Council
Funding Amount
$231,284.00
Summary
I am a neurologist from Xi�an Jiaotong University, China. My major research interest is in neurodegenerative diseases, especially Parkinson and Alzheimer�s disease. I enter this field because I know ageing population will have an enormous impact on the world�s economy. I started collaboration with Dr. Weiping Gai in Flinders University. We are interested in the toxic effects of both a-synuclein and its metabolites, their mechanisms and ways to block them.
Role Of The Microglial Adaptor Molecule TYROBP In Alzheimer’s Disease Pathology
Funder
National Health and Medical Research Council
Funding Amount
$469,433.00
Summary
Immune activation characterizes Alzheimer’s disease (AD) brains; however, how it impacts AD progression is not understood. Our previous studies in AD brains identified the immune molecule TYROBP, pointing at both beneficial and detrimental effects triggered by this molecule. Here, we aim to understand in detail how TYROBP is involved in AD and how we can enhance its beneficial effects and decrease its unintended actions.
Neuronal Membranes And Connections In Dementia: Targets For Intervention
Funder
National Health and Medical Research Council
Funding Amount
$720,144.00
Summary
This research aims to understand why some people with Mild Cognitive Impairment (MCI) progress to dementia, whilst others do not. The fact that some people’s cognitive abilities can improve provides an opportunity to study the mechanisms that protect their brain cells from the degeneration associated with dementia. Understanding the cellular changes will lead to therapies that can be tested in the lab for individuals.
The research outlined in this application seeks to examine the role of calcium in the pathogenesis of AD. It will examine the hypothesis that the build-up of a protein known as the Abeta causes an increase in levels of calcium in nerve cells of the brain. This increase in calcium may trigger nerve cell damage and dementia. The ultimate aim of the research is to identify new targets for drug development in Alzheimer's disease.
Wnt-Ryk Signaling In The Establishment Of Major Axon Tracts In The Embryonic Mouse Brain
Funder
National Health and Medical Research Council
Funding Amount
$513,946.00
Summary
The corpus callosum is the major interhemispheric commissure in the human brain, comprising approximately 3 million myelinated fibers which connect homologous regions in the neocortex. To date more than 50 different human congenital syndromes have been described in which the corpus callosum does not form leading to epilepsy and mental retardation. We have identified a new guidance molecule (Ryk) which is crucial for corpus callosum formation. This project aims to dissect that molecular mechanism ....The corpus callosum is the major interhemispheric commissure in the human brain, comprising approximately 3 million myelinated fibers which connect homologous regions in the neocortex. To date more than 50 different human congenital syndromes have been described in which the corpus callosum does not form leading to epilepsy and mental retardation. We have identified a new guidance molecule (Ryk) which is crucial for corpus callosum formation. This project aims to dissect that molecular mechanisms controlling Ryk signaling during corpus callosum development. Our analysis of Ryk function will advance our understanding of the molecular mechanisms underlying the formation of this important commissure.Read moreRead less
Deciphering The Mechanisms Underlying LRP-mediated Axon Guidance
Funder
National Health and Medical Research Council
Funding Amount
$370,659.00
Summary
Nerve damage can develop post injury or disease and are often very debilitating, slow to heal and cause increased pain. Our work aims to examine a new class of molecules that we show can activate selected fat-receptors on nerve cells to guide the growth of regenerating nerves. We will determine how these receptors function with the aim of developing a novel class of therapeutics directed at healing nerve damage.
Aberrant Ependymal Development And The Formation Of Hydrocephalus
Funder
National Health and Medical Research Council
Funding Amount
$660,005.00
Summary
Foetal hydrocephalus is a prevalent neurodevelopmental condition associated with severe intellectual impairment. Breakdown of the ependymal cell layer, which acts as a barrier between brain tissue and the ventricular space, is a major cause of hydrocephalus. Despite the importance of these cells, we have little understanding of the molecular mechanisms that regulate their production. This project will identify critical signalling pathways governing the establishment of the ependymal layer.