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.
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.
Developing Bone Marrow Transplant And Novel Therapeutic Vectors To Treat Friedreich Ataxia
Funder
National Health and Medical Research Council
Funding Amount
$598,163.00
Summary
We aim to develop effective therapies for the neuromuscular disease Friedreich ataxia (FRDA). The neurodegeneration inherent to FRDA slowly robs a person of the ability to move freely and care for themselves. It needs life-long medical support and there is no cure. FRDA lowers frataxin, a critical mitochondrial protein. Evidence indicates increasing frataxin can be beneficial. Using disease models, we will determine if increasing frataxin via bone marrow transplant or gene therapy improves FRDA.
Shaping the vertebrate brain: defining the cellular and genetic drivers . This project aims to uncover specific cellular and genetic mechanisms that control growth and shape of the brain. How brain shape and size changes during evolution of vertebrates is enigmatic but important to know for better understanding of behaviour and function of intact and diseased brain. The project aims to assemble team of national and international experts to build international capacity and unique genetics model t ....Shaping the vertebrate brain: defining the cellular and genetic drivers . This project aims to uncover specific cellular and genetic mechanisms that control growth and shape of the brain. How brain shape and size changes during evolution of vertebrates is enigmatic but important to know for better understanding of behaviour and function of intact and diseased brain. The project aims to assemble team of national and international experts to build international capacity and unique genetics model to generate new knowledge of the cellular and genetic components that drive evolution of different brain parts and shapes the vertebrate brain. In doing so the project aims to provide research training, excellence and knowledge that in future may benefit health and the society. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101033
Funder
Australian Research Council
Funding Amount
$315,220.00
Summary
Genomic Diversity in the Human Brain: the Functional Role of Expandable DNA Repeats. Neuronal cells accumulate genetic changes during development and adult life, and recent evidence suggests that the resulting genomic diversity may underlie neuronal functional diversity. To date only a few types of somatic genetic variation have been characterised in the human brain. Trinucleotide repeats (TNR) are hotspots of genomic instability and TNR expansions at specific loci cause dozens of brain disorder ....Genomic Diversity in the Human Brain: the Functional Role of Expandable DNA Repeats. Neuronal cells accumulate genetic changes during development and adult life, and recent evidence suggests that the resulting genomic diversity may underlie neuronal functional diversity. To date only a few types of somatic genetic variation have been characterised in the human brain. Trinucleotide repeats (TNR) are hotspots of genomic instability and TNR expansions at specific loci cause dozens of brain disorders, suggesting that the human brain is particularly vulnerable to this type of genetic variation. This project aims to investigate, for the first time, TNR somatic instability in the human brain on a genome-wide scale, therefore, addressing the genetic diversity of the brain from a novel and highly relevant angle. Read moreRead less
Prevalence And Genetic Mechanisms Of Neurological And Gynaecological Changes In Women Carrying Small FMR1 Expansions
Funder
National Health and Medical Research Council
Funding Amount
$411,895.00
Summary
Fragile X syndrome is one of the commonest genetic forms of mental retardation. The abnormal gene is passed from mothers to their sons or daughters, on their X chromosome. The gene abnormality is unstable, tending to worsen each time it is passed on. But if this gene abnormality is passed from fathers to their daughters, it does not worsen. Therefore, grandfathers of the affected children on their mother's side, as well as the mothers, may carry a mildly abnormal gene (a premutation), insufficie ....Fragile X syndrome is one of the commonest genetic forms of mental retardation. The abnormal gene is passed from mothers to their sons or daughters, on their X chromosome. The gene abnormality is unstable, tending to worsen each time it is passed on. But if this gene abnormality is passed from fathers to their daughters, it does not worsen. Therefore, grandfathers of the affected children on their mother's side, as well as the mothers, may carry a mildly abnormal gene (a premutation), insufficient to cause mental retardation. However, it has recently been discovered that these grandfathers may develop a syndrome (FXTAS) of tremor, incoordination, slowness of movements and mild dementia in their later years. Women were thought to be protected, as they carry TWO X chromosomes, one of which is normal even if the other has a premutation. But very recent reports suggest that they may also develop the FXTAS syndrome, as well as early menopause. This study aims to see how common and severe these abnormalities are in women who carry the premutation, using clinical, MRI and electronic measurements, and to relate the abnormalities to the severity of the gene malfunction and familial predisposition.Read moreRead less
Copper Homeostasis And APP-induced Neurodegeneration In Drosophila
Funder
National Health and Medical Research Council
Funding Amount
$381,223.00
Summary
Alzheimer s disease, a debilitating neurodegenerative disorder suffered by many of our elderly, is characterised by the presence of abnormal protein accumulations called plaques in the brains of affected patients. Plaques contain amyloid protein and also have high levels of the essential metals copper and zinc. Copper is needed for the formation of these protein aggregations and increases the toxic effects of amyloid, leading to the idea that copper-binding chemicals could be used to treat Alzhe ....Alzheimer s disease, a debilitating neurodegenerative disorder suffered by many of our elderly, is characterised by the presence of abnormal protein accumulations called plaques in the brains of affected patients. Plaques contain amyloid protein and also have high levels of the essential metals copper and zinc. Copper is needed for the formation of these protein aggregations and increases the toxic effects of amyloid, leading to the idea that copper-binding chemicals could be used to treat Alzheimer s disease. However experiments in animal models have produced conflicting results, some suggesting that increased copper levels protect against neuronal damage while others claim the opposite effect. Comparison of these studies is hampered by the different experimental systems used. We will clarify the role of copper in the progression of Alzheimer s disease using a simple insect model, the fly Drosophila melanogaster. Production of amyloid in Drosophila neuronal tissues produces a neurodegenerative effect similar to that seen in human brains, but in a matter of weeks rather than the years required in humans. We will combine production of amyloid with production of copper uptake and export proteins to investigate the effect of changing copper levels. We will also test the effect of increasing copper and other metals in the diet to see whether dietary levels are an important factor in disease progression. Finally, we will use the Drosophila model to test large numbers of metal binding compounds and drugs for ones that slow or halt the neuronal damage caused by amyloid production, identifying potential therapeutics for the treatment of Alzheimer s disease. This work will provide a vital and definitive clarification of the role of copper in the progression of Alzheimer s disease and potentially lead to the development of novel treatments for this disease that is rapidly becoming a major social and economic problem in the developed world.Read moreRead less
Investigating the intercellular trafficking of proteins and RNA and its relevance to neurodegenerative diseases. Alzheimer's and prion diseases are neurodegenerative disorders associated with protein misfolding. This project brings together similar features of these diseases using novel cell- and animal-based studies to develop a greater understanding of the molecular basis of these disorders.