Role Of Oxidative Stress In Activating ATM To Protect Against Neurodegeneration
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
ATM is the protein defective in the human genetic disorder ataxia-telangiectasia (A-T). This project is designed to investigate how this protein is activated by oxidative stress. The study is largely a mechanistic one, to investigate changes occurring in ATM as part of the activation process. There is evidence that ATM exists in the cytoplasm in neuronal cells and understanding its function in these cells may assist in understanding the basis for neurodegeneration in A-T.
Regulation Of Gene Expression In Mitochondrial Disease
Funder
National Health and Medical Research Council
Funding Amount
$338,362.00
Summary
Mitochondrial diseases affect 4000 children every year and most of these children do not reach adulthood. These diseases result from defects in mitochondria, energy producing compartments within cells. We have discovered a protein that controls mitochondrial gene expression and used it to rescue dysfunction in cells from patients with mitochondrial disease. We will determine its function and role in cell health, allowing us to evaluate its importance in mitochondrial disease.
Oxidative Phosphorylation Regulation And Neuroprotection In Optic Neuropathies
Funder
National Health and Medical Research Council
Funding Amount
$430,231.00
Summary
We have shown clear differences in the mitochodria, cellular organelles that generate energy, between optic atrophy patients who have good vision and those of patients who have poor vision. We believe that these changes represent a compensation mechanisms that preserves mitochondrial energy production and protects optic nerve cells. This study will characterize these differences further with the aim of identfying new treatments for preventing nerve loss and preserving vision.
First Generation Mouse Models Of MtDNA Disease: Testing Genotype/phenotype Predictions
Funder
National Health and Medical Research Council
Funding Amount
$256,527.00
Summary
Mitochondrial diseases comprise a diverse group of inherited diseases affecting infants, children and adults. These disorders result from defective energy production by the mitochondria, tiny structures in all cells which have their own unique DNA. This mitochondrial DNA is inherited only from our mothers. To make energy for cells to function normally, special enzymes are produced in the mitochondria from mitochondrial and nuclear genes. In their most severe form mitochondrial disease results in ....Mitochondrial diseases comprise a diverse group of inherited diseases affecting infants, children and adults. These disorders result from defective energy production by the mitochondria, tiny structures in all cells which have their own unique DNA. This mitochondrial DNA is inherited only from our mothers. To make energy for cells to function normally, special enzymes are produced in the mitochondria from mitochondrial and nuclear genes. In their most severe form mitochondrial disease results in infants with muti-system failure. Adult forms are less severe, with symptoms including epilepsy, cardiomyopathy, late-onset blindness or deafness, and commonly diabetes. We do not understand why different mitochondrial mutations result in such diverse symptoms, and no therapies have been consistently successful. Unusual features of mitochondrial DNA has meant that it has remained beyond the reach of techniques which are commonly used now to produce mice with altered genes. These so-called 'mouse models' are powerful tools to better understand human diseases and importantly, to enable experimental therapies to be tested and improved. This grant proposes a novel method of producing such mouse models, for the first time allowing mice with different levels of defective mitochondrial function to be produced to model the human diseases. In the proposed work, mitochondria from different mouse species will be introduced into laboratory mice. This unusual approach is based on previous work by the investigators who have shown that this produces defective mitochondria in cultured mouse cells. These mice will be allowed to age and the function of mitochondria from different organs tested as the animals age. Secondly, a range of mitochondrial DNA mutations will be produced in cultured cells and mutants selected to make other mice which should accurately model the diverse human diseases.Read moreRead less
Phosphatase Regulators Mediate Long-term Changes In Presynaptic Terminals
Funder
National Health and Medical Research Council
Funding Amount
$984,163.00
Summary
The strength of communication between each nerve cell in the brain depends on how active that nerve cell has been. This enables the brain to be adaptable and is a way for the brain to set up circuits that underlie how we learn and remember. More or less release of chemical messengers (neurotransmitters) into nerve cell junctions changes the strength of nerve cell communication. We have discovered a new chemical signalling pathway controlling neurotransmitter release.
Chemical Aided Phospoproteome Sequencing With Mass Spectrometry
Funder
National Health and Medical Research Council
Funding Amount
$141,000.00
Summary
Essentially all of the body's functions from muscle contraction, energy expenditure through to appetite are controlled by a complex molecular communications system. One of the key elements involves the modification of proteins to alter their properties by adding and removing phosphate. By analysing this process in response to diet and exercise we will obtain a greater understanding of their health benefits and understand how type 2 diabetes and obesity develop at the molecular level.