I work on mitochondrial diseases, which are inherited disorders of metabolism that block conversion of food energy into chemical energy needed by our cells. We focus on understanding (i) the genetic basis of these disorders using approaches such as massively parallel sequencing, systems biology and experimental studies, and (ii) the detailed mechanisms of disease by studying cell lines from patients and animal models. We aim to develop better methods for diagnosis, treatment and prevention.
Novel Gene Identification And Characterisation In Epilepsy.
Funder
National Health and Medical Research Council
Funding Amount
$303,964.00
Summary
Epilepsy is a serious neurological disorder affecting up to 5% of the population at some point in their lives. Approximately 70% cases of epilepsy are genetic, but very few of the genes involved have been identified. This project will use state-of-the-art techniques to identify genetic mutations causing an inherited form epilepsy affecting infants. This research is expected to reveal new gene families involved in the genesis of epilepsy and thus new targets for the development of treatments.
Cis Regulatory And Functional Analysis Of Genomic Loci With Implication In Hypothalamic Obesity Using The Zebrafish As A Model System
Funder
National Health and Medical Research Council
Funding Amount
$480,936.00
Summary
Gene regulatory mutations cause changes in gene activity (expression -level, -time, -site) and therefore decide about the availability of proteins. Regulatory mutations in uncharacterized genomic loci that are related to obesity and further their effects shall be identified, with emphasis on those affecting the hypothalamic food intake control circuits. Since the energy metabolism system and the obesity candidate genes are conserved, the model system zebrafish will be used for these analyses.
Approaches To Therapy For The Skeletal Muscle Actin Diseases
Funder
National Health and Medical Research Council
Funding Amount
$912,078.00
Summary
We have shown that errors in a crucial muscle protein called actin cause muscle diseases that affect newborn children. These diseases are mainly very severe, causing death within the first year of life. Currently there is no cure. This project will investigate possible therapies for these diseases, such as viral delivery of a normal version of actin and finding a drug to overcome the weakness. Successful outcomes will crucially bring treatment closer for the patients.
Viral Therapy For Skeletal Muscle Alpha-actin Disease And Discovery Of Novel Neuromuscular Disease Genes And Mechanisms
Funder
National Health and Medical Research Council
Funding Amount
$324,028.00
Summary
This research project is the next logical step towards treating patients with skeletal muscle actin disease - using viral delivery of normal actin genes in animal models of actin disease. Another arm of this project is to investigate the genetics and mechanisms causing two very different groups of muscle disorders in the Australian population: devastating muscle weakness in the foetal akinesias and enhanced muscle strength and bulk in individuals with strongman syndromes.
Transforming The Diagnosis Of Mitochondrial Disorders Using High-throughput Sequencing, Functional Prediction And Experimental Validation
Funder
National Health and Medical Research Council
Funding Amount
$670,794.00
Summary
The human genome project sparked enormous improvements in our ability to sequence DNA. “Next Generation” DNA sequencing can potentially sequence an individual’s entire genome in a week and has the ability to transform the diagnosis of inherited diseases but is as yet unproven in a medical genetics context. We will develop and validate the use of Next Generation sequencing to enable the rapid sequencing of over 1000 genes in which mutations cause inherited metabolic diseases.
Gene Discovery And Characterisation In The Familial Focal Epilepsies
Funder
National Health and Medical Research Council
Funding Amount
$428,065.00
Summary
Around 2% of people have epilepsy at some time in their lives. A large proportion of cases are thought to have a genetic cause, but genes have not yet been identified for most patients. The aim of this project is to use state-of-the-art genetic methods to identify genetic mutations causing epilepsy and to then study the effects of these mutations to better understand the biological causes of epilepsy. This in turn will lead to better diagnosis of epilepsy and improved treatment for patients.
P2X7 Mediated Phagocytosis Of Apoptotic Cells: A Common Mechanism Underlies Neurological And Eye Disorders
Funder
National Health and Medical Research Council
Funding Amount
$527,033.00
Summary
We have found a strong genetic linkage between a protein called P2X7 and a number of neurological disorders, in line with our recent discovery of a novel function of this protein in clearance of dying cells as removal of unhealthy neurons is essential to keep brain function promptly. Further study using genetic association, cell biology and animal models will lead to a conceptual advance on how neurological diseases are occurred and developed.
Nemaline myopathy is a neuromuscular condition characterised by muscle weakness, low muscle tone and the finding of nemaline bodies or rods on muscle biopsy. This study encompasses a natural history study of nemaline myopathy, genetic diagnosis and gene discovery using new methods of genetic testing, characterisation of a new disease gene for this condition, and reviewing patient experience with tyrosine, a medication commonly used in patients with nemaline myopathy.
The Effects Of ?-actinin-3 On Muscle Metabolism, Human Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$643,060.00
Summary
We have identified a common genetic variant that results in absence of the fast muscle fibre protein ?-actinin-3 in more than one billion humans worldwide. Loss of ?-actinin-3 influences elite athletic performance, muscle bulk and strength in the general population, response to diet and exercise, and susceptibility to obesity and developing type 2 diabetes. We have also demonstrated that ?-actinin-3 influence disease severity in a variety of inherited and acquired muscle disorders.