A hierarchical quantum mechanical and classical simulation of biological ion channels. I aim to develop a methodology incorporating molecular quantum
mechanics and classical Brownian mechanics in a way that can be
applied practically to large macromolecular systems, thus relating
fine structural details to experimentally measurable
properties. Specifically, I will apply this methodology to study ion
channels in which the challenge is to relate electronic and atomic
structure to the conduct ....A hierarchical quantum mechanical and classical simulation of biological ion channels. I aim to develop a methodology incorporating molecular quantum
mechanics and classical Brownian mechanics in a way that can be
applied practically to large macromolecular systems, thus relating
fine structural details to experimentally measurable
properties. Specifically, I will apply this methodology to study ion
channels in which the challenge is to relate electronic and atomic
structure to the conductance properties of the channel. Accurately
determining these relationships provides a pathway to developing cures
for many neurological, cardiac, and muscular diseases.
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Rapid mapping of genes for complex traits. This project will develop a new resource that will allow rapid identification of genes controlling complex traits. This world-leading resource will improve knowledge of diseases like diabetes and neurological diseases.
From causative genes to establishing therapies for patients with neuromuscular diseases. A major focus of this project will be pursuing multiple therapeutic approaches for a class of skeletal muscle diseases, which are most often severe and lethal within the first year of life. It will also hunt down the defective genes in human patients with other neuromuscular diseases and explore how these cause disease.
The development of tools to study carbohydrate-processing enzymes implicated in human disease. Diseases caused by improper function of carbohydrate-processing enzymes are a major health burden. This research aims to find ways to restore the function of these enzymes bringing a better quality of life to people suffering from these diseases.
The molecular role of ADAM12 in maintenance of skeletal muscle, myogenesis and adipogenesis. An understanding of the molecular control of skeletal muscle growth, maintenance and balance between muscle and fat production is of fundamental importance for a competitive meat industry, for the promotion of strong muscles in the ageing population and for disorders such as muscle diseases, diabetes and obesity. This project will enhance strong international collaborations and expand cutting-edge resear ....The molecular role of ADAM12 in maintenance of skeletal muscle, myogenesis and adipogenesis. An understanding of the molecular control of skeletal muscle growth, maintenance and balance between muscle and fat production is of fundamental importance for a competitive meat industry, for the promotion of strong muscles in the ageing population and for disorders such as muscle diseases, diabetes and obesity. This project will enhance strong international collaborations and expand cutting-edge research within Australia with many potential economic benefits for the meat industry, biotechnology and health. The expertise developed by this pioneering research will ensure that Australia is well placed to harness new technologies and exploit future advances in this fast-moving field of muscle biology.Read moreRead less
Novel Bioinformatics approaches for genetics and data linkage. The research project will involve creation of novel data and communications formats to fulfil the vital task of integrating the vast heterogeneous biological resources available. We will apply this new infrastructure to a large data linkage project. In parallel, we will undertake methodological research in informatics to design high throughput research methods and tools to analyse and visualise genetic data. These will be applied to ....Novel Bioinformatics approaches for genetics and data linkage. The research project will involve creation of novel data and communications formats to fulfil the vital task of integrating the vast heterogeneous biological resources available. We will apply this new infrastructure to a large data linkage project. In parallel, we will undertake methodological research in informatics to design high throughput research methods and tools to analyse and visualise genetic data. These will be applied to linkage disequilibrium mapping and haplotyping in human, animal and plant diseases. Improving informatics integration and designing novel methods and implementations of algorithms will be beneficial to local and international researchers in a range of fields.Read moreRead less
Rhinovirus impairs physiological and immunological lung development and causes exacerbation of allergic airways disease. Rhinovirus (RV) infections account for around 90 per cent of asthma exacerbations, yet the mechanisms behind this are unknown. This project will use mouse models to study the effects of early life RV infection and allergic sensitisation on respiratory and immunological development, with the expectation that early life RV infection disrupts anitgen presenting cell function.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100217
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
In-Vivo Multispectral and X-ray Micro-CT Imaging: Founding a Western Australian small animal imaging core facility. The Western Australian Small Animal Imaging facility will provide wide access for the West Australian research community to a multimodality functional and dynamic core bioimaging facility to characterise in-vivo animal models, including extensive postgraduate research training. Wide-ranging research outcomes of national and community benefit include imaging tumour development, bone ....In-Vivo Multispectral and X-ray Micro-CT Imaging: Founding a Western Australian small animal imaging core facility. The Western Australian Small Animal Imaging facility will provide wide access for the West Australian research community to a multimodality functional and dynamic core bioimaging facility to characterise in-vivo animal models, including extensive postgraduate research training. Wide-ranging research outcomes of national and community benefit include imaging tumour development, bone metabolism (osteoporosis), neural function (Alzheimer's disease) and regeneration, and infection mechanisms in live animals, which will result in improvements in human health. Imaging and monitoring coral growth, fish age, and soil structure will improve the economics and sustainability of Australia's marine ecosystems and agricultural food production.Read moreRead less
Determining how calcium regulates mitochondrial function in models of cardiomyopathy. Heart failure is the leading cause of death in Australia. This project will determine the mechanisms by which the failing heart is associated with disorganisation of the cell and poor energy supply so that interventions aimed at reducing the development of heart failure can be developed.
Novel Statistical Methods For Genetic Epidemiology
Funder
National Health and Medical Research Council
Funding Amount
$481,505.00
Summary
We are in the midst of a genomics revolution that is transforming epidemiology, medicine and drug discovery. However, the scarcity of sophisticated statistical techniques to deal with the complicated problems inherent in genetic investigations of complex diseases is currently the critical factor limiting the success of human gene discovery programs. Statistical genetic methodology is currently one of the fastest developing areas of epidemiology. In information-intensive' areas such as genetic ep ....We are in the midst of a genomics revolution that is transforming epidemiology, medicine and drug discovery. However, the scarcity of sophisticated statistical techniques to deal with the complicated problems inherent in genetic investigations of complex diseases is currently the critical factor limiting the success of human gene discovery programs. Statistical genetic methodology is currently one of the fastest developing areas of epidemiology. In information-intensive' areas such as genetic epidemiology, genomics, and proteomics, there is a high demand for data analysis and statistical skills. WA has some world class expertise in statistical science, both in academia and in industry. However, this expertise has not yet been applied in a system way to genetic data analysis. We propose to undertake advanced methodological research in statistical genetics and bioinformatics, to produce easy-to-use and accessible software tools and resources that allow methodological advances to be accessed by the Australian research community, and to apply our new methods and tools both to specific disease research and to the developing human genome epidemiology (HuGE) enterprise in WA. These new initiatives in methodological research will draw together a number of currently separate research strands and will provide new tools and resources that will allow applied Australian programs to improve the efficiency of their research into the causes of important. Methodological development in both bioinformatics and statistical genetics are recognized international areas of need.Read moreRead less