The Role Of Neuronal Hyperactivity And Neurotrophic Factor Signalling In Synaptogenesis, Dendrogenesis And Neuron Death In Motor Neuron Disease
Funder
National Health and Medical Research Council
Funding Amount
$700,331.00
Summary
Using mice with mutant genes causing amyotrophic lateral sclerosis, we will test whether motor neuron hyper-excitability during early development causes excessive synapse and dendrite formation, ultimately leading to neuronal death. We will also test whether activity-dependent secretion of neurotrophic factors and activation of their receptors plays a role in this disease. This will show whether neuronal hyper-activity and neurotrophic factor signaling plays a causal role in this disease.
The Role Of BDNF In Central Nervous System Myelination
Funder
National Health and Medical Research Council
Funding Amount
$478,235.00
Summary
Multiple Sclerosis (MS) is the most common neurological cause of disability in young adult Australians. The cause of MS is unknown and therapies are limited to reducing inflammation, which does not address the major problem of the disease: loss of myelin. This project directly investigates how myelin is formed and will identify key mechanisms in this process, which may eventually be developed into treatments for diseases such as MS.
I am a neurologist and neuroscientist studying the causes and mechanisms of Parkinson's disease and the physiology in health and diseases of the nervous system affected by movement disorders
The Combined Use Of Transplantation And Gene Therapy Techniques To Promote Regeneration After Neurotrauma
Funder
National Health and Medical Research Council
Funding Amount
$521,026.00
Summary
Trauma in the adult mammalian central nervous system causes long-lasting functional deficits. The resulting physical and financial burdens to the individual, to his or her family, and to the community at large, are immense. When fibre tracts are damaged there is disruption of circuits and there may be death of associated nerve cells. Interventions are therefore necessary to promote repair and to try to restore function. Highly modified, non-harmful viruses can be used as vectors to introduce gen ....Trauma in the adult mammalian central nervous system causes long-lasting functional deficits. The resulting physical and financial burdens to the individual, to his or her family, and to the community at large, are immense. When fibre tracts are damaged there is disruption of circuits and there may be death of associated nerve cells. Interventions are therefore necessary to promote repair and to try to restore function. Highly modified, non-harmful viruses can be used as vectors to introduce genes into cells, a method that allows targeted supply of molecules to the injured brain. Gene and cell therapy may eventually be of clinical benefit to injured patients. In a range of different experiments we will combine two different gene therapy approaches, various pharmacological agents and novel transplantation strategies in attempts to enhance the survival of affected nerve cells and promote the regrowth of damaged nerve fibres across injury sites in the injured adult rat visual system. Long-term vector-mediated expression of growth factors in neurons and in grafts may 'trap' regenerating axons, potentially reducing their outgrowth into distal, denervated target areas. It is therefore important to determine if temporal regulation of growth-promoting genes has additional beneficial effects on the ability of regenerating neurons to recognise and selectively regrow axons into appropriate CNS targets. An additional series of studies will thus be undertaken. We will test a new generation of regulatory vectors in which it is possible to switch the virally encoded genes on or off and thus control the level and timing of gene expression over a therapeutic range. We will then determine if the use of these regulatory viral vectors results in more consistent and robust growth of nerve fibres with better reconnections, in the longer term leading to better recovery of function.Read moreRead less