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
Neurologic Effects Of Mutational Load In MELAS Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$505,786.00
Summary
This project will use a new stem cell model to discover what happens to brain cells in patients with the MELAS 3243A>G mutation, a common genetic mutation found in 1-500 Australians. Brain cells will be grown from our stem cell model and used to find out how this mutation causes problems in the affected brain cells. We will find out what happens to the brain when the amount of mutation is reduced in vitro. By understanding what happens, we will be able to design new treatments for this disord ....This project will use a new stem cell model to discover what happens to brain cells in patients with the MELAS 3243A>G mutation, a common genetic mutation found in 1-500 Australians. Brain cells will be grown from our stem cell model and used to find out how this mutation causes problems in the affected brain cells. We will find out what happens to the brain when the amount of mutation is reduced in vitro. By understanding what happens, we will be able to design new treatments for this disorder.Read moreRead less
Evaluation Of Pathogenic Mechanisms Involved In Nuclear And Mitochondrial DNA-encoded Mitochondrial Disorders
Funder
National Health and Medical Research Council
Funding Amount
$196,527.00
Summary
Mitochondria produce energy for the cell. Disorders of mitochondrial function can cause human disease. These diseases are referred to as the mitochondrial disorders. Mitochondrial disorders usually involve multiple tissues, particularly the muscle and brain.These disorders are usually caused by mutations in two different types of DNA; nuclear and mitochondrial DNA. There are many forms of mitochondrial disorders; some affect young children or infants and others cause adult disease. In some cases ....Mitochondria produce energy for the cell. Disorders of mitochondrial function can cause human disease. These diseases are referred to as the mitochondrial disorders. Mitochondrial disorders usually involve multiple tissues, particularly the muscle and brain.These disorders are usually caused by mutations in two different types of DNA; nuclear and mitochondrial DNA. There are many forms of mitochondrial disorders; some affect young children or infants and others cause adult disease. In some cases, genetic defects may cause the same disease and other mutations may cause a wide range of symptoms. The reason why this occurs is unknown. This study investigates several factors that may determine why some mutations lead to a certain disease and why others may cause different diseases. These factors include the variation in energy levels that are produced by the mutant cells, and the different levels of vunerability that mutated cells may have to induced cell death. The goal of this proposal is to identify the factors that lead to mutations causing different clinical symptoms with the overall aim being to design treatment for these chronic diseases.Read moreRead less
I am a biochemical geneticist working on the genetics and pathogenesis of mitochondrial energy generation disorders. I have a particular focus on the severe mitochondrial diseases of childhood but am also studying mitochondrial involvement in common disor
Defining The Genomic Basis Of Mitochondrial Complex I Deficiency
Funder
National Health and Medical Research Council
Funding Amount
$639,682.00
Summary
The human genome project led to new technologies that will revolutionise genetic testing. Previously, we could only sequence genes one at a time. Next Generation sequencing allows analysis of hundreds or thousands of genes simultaneously. We will analyse 90 genes in 100 children with severe disorders of mitochondrial energy generation. This will provide proof of principle for the introduction of this technology into routine medical testing and identify new genes causing these diseases.
Genetic Variation Of Mitochondrial Complex I: Its Role In Rare And Common Diseases
Funder
National Health and Medical Research Council
Funding Amount
$628,415.00
Summary
Our bodies convert food into energy in tiny cellular power plants called mitochondria. Each year about 50 Australian children inherit disorders of mitochondrial energy generation. The most severe disorders cause infant death, while others cause degenerative diseases in later life, particularly affecting brain and muscle. In most cases we lack effective treatments. The genetic causes of mitochondrial disorders are incredibly diverse, with over 70 disease genes known. Some are located on the uniqu ....Our bodies convert food into energy in tiny cellular power plants called mitochondria. Each year about 50 Australian children inherit disorders of mitochondrial energy generation. The most severe disorders cause infant death, while others cause degenerative diseases in later life, particularly affecting brain and muscle. In most cases we lack effective treatments. The genetic causes of mitochondrial disorders are incredibly diverse, with over 70 disease genes known. Some are located on the unique mitochondrial DNA we inherit only from our mothers. Many more genes await discovery. This grant focuses on the most common energy generation disorder, known as Complex I deficiency. Complex I requires 46 separate components to be assembled together in order to work properly, but mutations in the 46 genes encoding these components only seem to explain disease in about half of all patients. Our aim is to identify new disease genes and to determine whether some patients have mutations in two different genes that interact to cause disease, rather than in a single gene. We will use a number of methods to pinpoint where in the genome the causative genes are located and then home in on the exact changes in the genes that cause disease. Identifying these genes will allow us to improve future diagnosis and prevention of mitochondrial disease. We will also generate mice in which one of the Complex I genes has been knocked out. These mice will allow us to better understand the basic disease mechanisms that link gene changes to disease. Understanding the basic biology may allow us to develop new methods of treatment. The mouse models will also be useful for trialling new treatments and for investigating the role of milder mitochondrial problems in common diseases such as diabetes and Parkinson disease. Any new treatments could potentially have wide application.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.
Molecular Basis Of Mitochondrial Complex I Deficiency, The Most Common Energy Generation Disorder
Funder
National Health and Medical Research Council
Funding Amount
$515,750.00
Summary
Oxygen is needed by every cell in the body to burn fuels (ie sugar, fat and protein) in small power plants inside each cell called mitochondria. In Australia, about 50 children born each year have inherited disorders of mitochondrial energy generation. The most severe disorders cause infant death, while others cause a range of degenerative diseases later in life, particularly affecting brain, muscle and heart. In most cases we do not have any effective treatments. A major problem in understandin ....Oxygen is needed by every cell in the body to burn fuels (ie sugar, fat and protein) in small power plants inside each cell called mitochondria. In Australia, about 50 children born each year have inherited disorders of mitochondrial energy generation. The most severe disorders cause infant death, while others cause a range of degenerative diseases later in life, particularly affecting brain, muscle and heart. In most cases we do not have any effective treatments. A major problem in understanding mitochondrial energy generation disorders is that the genetic causes are incredibly diverse. So far more than 20 genes have been shown to cause mitochondrial disorders, and it is likely that over one hundred more genes remain to be discovered. In addition to the regular genes that cause these and other genetic disorders, mitochondria are unique in carrying 37 extra genes located in a different part of the cell away from the rest of the human genome, and inherited only from the mother. This grant focuses on the most common energy generation disorder, known as Complex I deficiency. Complex I requires 43 separate components to be assembled together in order to work properly, but mutations in the 43 genes encoding these components are not present in most patients. We believe that the most common problems will be in genes involved in assembling the 43 components rather than in the components themselves. We will use a number of methods to pinpoint where in the genome the causative genes are located and then home in on the exact changes in the genes that cause disease. Identifying these genes will allow us to improve future diagnosis and prevention of mitochondrial disease. Understanding the basic biology may also allow us to develop new methods of treatment. Recent studies suggest that milder mitochondrial problems also contribute to a range of more common diseases such as diabetes and Parkinson disease, so any new treatments could potentially have wide application.Read moreRead less
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.