Characterisation And Regulation Of Chloride Channels In Cardiac And Skeletal Sarcoplasmic Reticulum In Mammals
Funder
National Health and Medical Research Council
Funding Amount
$381,856.00
Summary
An understanding of the operation of ion channels in cell membranes is fundamental to our knowledge of the function of muscles under normal conditions and in pathological states that modify cell function, e.g. myotonia and cardiac failure. Ion channels control the flow of currents and the transport of substances which ultimately determine whether cells live or die, and hence whether cell pathologies are expressed as muscle failure, as when hypoxia causes tissue damage to the heart, or as severe ....An understanding of the operation of ion channels in cell membranes is fundamental to our knowledge of the function of muscles under normal conditions and in pathological states that modify cell function, e.g. myotonia and cardiac failure. Ion channels control the flow of currents and the transport of substances which ultimately determine whether cells live or die, and hence whether cell pathologies are expressed as muscle failure, as when hypoxia causes tissue damage to the heart, or as severe arrythmia or cardiac arrest. The objective is to understand channel involvement in the mechanisms underlying the function of cardiac and skeletal muscle. We believe that by mimicking the factors that occur in pathological conditions we can understand how ion channels are altered and controlled, and find ways of reversing harmful alterations, thereby reversing cell damage and failure of vital muscle function.Drugs will be used to modify the 'gating' of the channels. By comparing the effects of different drugs, we hope to determine the important features of the mechanisms that control the gating of the channels, making them more or less sensitive to different influences, especially those that occur in pathological states. The study has great application to the study of other pathologies, e.g. cystic fibrosis, severe diarrhoea, paralysis and chronic fatigue. The pharmacological emphasis offers the fundamental science needed to design novel and specific drugs to combat the many serious pathologies related to ion channel effects. Aside from its importance to basic science and to immediate issues of health, the study offers considerable economic gains, both through improved public health and through development of pharmaceuticals.Read moreRead less
Carolyn Sue is a neurologist and scientist investigating the role of disturbed mitochondrial function in human disease. Mitochondria play a key role in maintaining energy levels and the cell’s health. When this function is impaired, cells may degenerate or die, and thus cause human disease. Dr Sue’s research is aimed at seeking improved treatments to treat mitochondrial disease and to further understanding about how brain cells degenerate when the mitochondria fail.
Functional Genomic Analyses Of Mitochondrial Disorders
Funder
National Health and Medical Research Council
Funding Amount
$577,001.00
Summary
Mitochondria produce most of the energy required by our bodies. Mutations in genes that make mitochondrial proteins cause mitochondrial dysfunction and lead to neurodegenerative and muscular diseases. We will identify mutations in mitochondrial genes in members of different Bulgarian and Gypsy families and discovery the mechanisms by which the mutations lead to disease.
Mitochondrial Enzyme Regulates RNA Metabolism In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$67,381.00
Summary
Mitochondria are microscopic, energy producing machines that are found in all human cells. Mitochondria contain a small set of genes that must work properly to make the energy our bodies require for health. Defects in the expression of genes coding for mitochondrial proteins causes debilitating diseases for which there are effective treatments. I will investigate how a mitochondrial protein whose dysfunction is known to cause a metabolic disease regulates mitochondrial gene expression.
Regulation Of RNA Processing In The Mitochondrial Disease MELAS
Funder
National Health and Medical Research Council
Funding Amount
$520,977.00
Summary
Mitochondria are microscopic, energy producing machines that are found in all human cells. Mitochondria contain a small set of genes that must work properly to make the energy our bodies require for health. Defects in the expression of mitochondrial genes cause debilitating diseases for which there are currently no cures. We have developed a new set of technologies that will be applied to understand how these mutations cause disease and provide insights into possible treatments.
Regulation Of Mitochondrial Gene Expression In Disease
Funder
National Health and Medical Research Council
Funding Amount
$697,209.00
Summary
Mitochondria are microscopic powerplants that produce most of the energy in cells. Genes that make mitochondrial proteins must work properly to make the energy our bodies require for health. Defects in the expression of mitochondrial genes cause debilitating diseases for which there are no cures currently. A/Prof Filipovska will use new technologies to understand how these mutations cause disease and develop therapeutics for treatments of diseases caused by defects in mitochondrial genes.
The Role Of Mitochondrial Dysfunction In Metabolic Disease
Funder
National Health and Medical Research Council
Funding Amount
$61,383.00
Summary
We have previously found that PTCD1 can regulate mitochondrial gene expression and metabolism in cells (Mercer et al., 2011 and Lopez Sanchez et al., 2011). There is still much to learn about the mitochondria and their DNA. Charactering PTCD1, a protein that has previously seen little research, will enable us to elucidate the role of this protein in mitochondria and energy metabolism in an effort to increase understanding of obesity and type 2 diabetes.
Mitophagy And Mitochondrial Biogenesis In Mitochondrial Disease
Funder
National Health and Medical Research Council
Funding Amount
$307,946.00
Summary
Mutations in mitochondrial DNA and nuclear encoded mitochondrial genes cause mitochondrial disease, with one in every 250 Australians carrying a pathogenic mutation. In this project, we will further define the basic function of mitophagy (process that results in the recycling of defective mitochondria) and mitochondrial biogenesis (production of new mitochondria). Additionally, experimentally induced enhancement of mitophagy or biogenesis will be assessed as a potential therapy for patients with ....Mutations in mitochondrial DNA and nuclear encoded mitochondrial genes cause mitochondrial disease, with one in every 250 Australians carrying a pathogenic mutation. In this project, we will further define the basic function of mitophagy (process that results in the recycling of defective mitochondria) and mitochondrial biogenesis (production of new mitochondria). Additionally, experimentally induced enhancement of mitophagy or biogenesis will be assessed as a potential therapy for patients with mitochondrial disease.Read moreRead less
Recognising And Improving Management Outcomes Of Adult Patients With Mitochondrial Diseases
Funder
National Health and Medical Research Council
Funding Amount
$87,199.00
Summary
Mitochondrial diseases comprise the most common diagnostic group amongst neuromuscular and neurogenetic diseases, but are not well known in the community, with no established standards of management. The Study aims to devise strategies to deliver better care for patients with mitochondrial diseases, from their screening and diagnosis, continued monitoring and prognostication, to the potential treatment and promotion of a better management paradigm; as well as facilitation of ongoing research int ....Mitochondrial diseases comprise the most common diagnostic group amongst neuromuscular and neurogenetic diseases, but are not well known in the community, with no established standards of management. The Study aims to devise strategies to deliver better care for patients with mitochondrial diseases, from their screening and diagnosis, continued monitoring and prognostication, to the potential treatment and promotion of a better management paradigm; as well as facilitation of ongoing research into the management of patients with these diseases.Read moreRead less
Systems Approaches To Understanding The Assembly Of Mitochondrial Machines
Funder
National Health and Medical Research Council
Funding Amount
$600,005.00
Summary
Mitochondria produce the energy for our bodies. Defects in this process cause mitochondrial disease, which affects at least 1/5000 people. Diagnosis is often inconclusive as we do not understand the function of many proteins important in mitochondrial energy production. State of the art CRISPR gene-editing tools will be coupled with advanced proteomics techniques to model different types of mitochondrial disease and identify the functions of new candidate disease genes.