Molecular And Clinico-pathological Investigation Of Congenital Myopathies
Funder
National Health and Medical Research Council
Funding Amount
$743,290.00
Summary
Congenital myopathies are inherited disorders causing muscle weakness from birth. Some types lead to early death of the affected child, while others are compatible with life to adulthood. Like any disease of childhood, the congenital myopathies cause considerable trauma to the families concerned. Couples at risk of having another affected child frequently wait for prenatal diagnosis to become available for their particular disease before attempting to have further children. However, prenatal dia ....Congenital myopathies are inherited disorders causing muscle weakness from birth. Some types lead to early death of the affected child, while others are compatible with life to adulthood. Like any disease of childhood, the congenital myopathies cause considerable trauma to the families concerned. Couples at risk of having another affected child frequently wait for prenatal diagnosis to become available for their particular disease before attempting to have further children. However, prenatal diagnosis is only possible once the gene causing a disorder and the mutation in an individual family are identified. In the past, the Laboratories collaborating in this project, the Molecular Neurogenetics Laboratory, Australian Neuromuscular Research Institute, Perth, and the Neurogenetics Research Unit, New Children s Hospital, Sydney, have identified disease genes for congenital myopathies. Prenatal diagnosis is now possible for families whose disease-causing mutation is identified. However the genetic cause of many of the congenital myopathies remains unknown. DNA and other samples have been sent to the Laboratories from around the world, making us reference centres for congenital myopathy research. Part one of the project is to study these and Australasian samples, to identify other congenital myopathy genes. This will help families who currently cannot have prenatal diagnosis. Finding the genes also increases understanding of the diseases by clarifying which proteins are involved. In part two of the project we shall study the mutated proteins, to try to unravel how the gene mutations cause the diseases. The third part of the project is to reevaluate the highly variable muscle pathology in congenital myopathies in cases where the disease gene is now known, in order to investigate genotype-phenotype correlations. Understanding the pathologic basis of the congenital myopathies will ultimately allow us to begin to think rationally about possible treatments.Read moreRead less
Molecular Regulation Of The Serine-Threonine Kinase ULK1 In Autophagy
Funder
National Health and Medical Research Council
Funding Amount
$299,431.00
Summary
Autophagy or self eating is a basic cellular process and can have either beneficial or adverse effects in cancer. It is essential to determine the status of autophagy in patients before considering drugs that block autophagy for therapy. A protein called ULK1 is needed for autophagy and may emerge as a pathological marker for autophagy in cancer as well as a potential drug target. This grant proposal will study ULK1 regulation and will lay the scientific foundation for its medical application.
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
Role Of Laminin-mediated Adhesion In Regulating Muscle Cell Attachment In Development And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$490,202.00
Summary
Muscular dystrophies and myopathies are amongst the largest group of inherited disorders to afflict the human condition. It is our hope that the results of this research will lead to a better understanding of how treatments could be employed to correct such disorders. Our development of zebrafish models of common muscular dystrophies allows us to study these disorders utilising the advantages of the zebrafish system.
CBS Domain Modulation Of Muscle Chloride Channels; Molecular Mechanism And Physiological Role.
Funder
National Health and Medical Research Council
Funding Amount
$523,455.00
Summary
Muscle chloride channels regulate how readily muscles are activated, particularly during muscle fatigue. Recently we have identified a feed-back mechanism linking chloride channel function to muscle acidosis and energy depletion, key factors in fatigue. Here we will investigate the molecular details of this mechanism and its role in muscle physiology and fatigue. This mechanism may present a future target for the treatment of myotonia, a condition where muscles are too readily activated.