Genes Controlling The Development Of Lung Disease In Normal And Cystic Fibrosis Mice.
Funder
National Health and Medical Research Council
Funding Amount
$362,582.00
Summary
Patients with cystic fibrosis have a lethal predisposition to bacterial infection which causes irreversible lung disease. It is clear that even when patients carry the same mutation in the defective gene (CFTR), genetic background influences the course of the disease. Very little is known of the nature of these other genes and this proposal will identify those genes which influence the response of the CF lung to pathogens and in doing so may indicate novel therapeutic strategies.
The Influence Of Alpha Actinins On Human Performance
Funder
National Health and Medical Research Council
Funding Amount
$542,500.00
Summary
There is a wide variation in skeletal muscle function in the general population. At one end of the spectrum are elite athletes who excel in a specialised area of sprint, power or endurance performance, while at the other end of the spectrum are individuals with muscle weakness due to inherited muscle disease. Part of this variation in human muscle performance is due to the genetic makeup of the individual. For example, world class sprinters have muscles which are genetically predisposed to gener ....There is a wide variation in skeletal muscle function in the general population. At one end of the spectrum are elite athletes who excel in a specialised area of sprint, power or endurance performance, while at the other end of the spectrum are individuals with muscle weakness due to inherited muscle disease. Part of this variation in human muscle performance is due to the genetic makeup of the individual. For example, world class sprinters have muscles which are genetically predisposed to generate maximal force at high speed. Similarly, the severity of muscle disease in an affected individual is influenced, in part, by other genes that affect normal muscle performance. The genes responsible for normal variations in muscle function in humans are unknown. The alpha-actinins are structural components of skeletal muscle. The two forms of alpha-actinin in skeletal muscle interact with a number of proteins involved in human muscle disease and thus likely contribute to the severity of muscle weakness in affected patients. Alpha-actinin-3 is present only in fast (type 2) fibres - the muscle fibres responsible for perfomance at high speed. We have identified a genetic change that results in absence of this protein in 1 in 5 people in the general population, without causing disease. We now have evidence that this genetic change, and hence whether or not muscle contains alpha-actinin-3, influences muscle performance in elite athletes. We will now use a variety of approaches to study the alpha-actinins in normal and diseased skeletal muscle. We will study the effect of changes (mutations) in the alpha-actinins in the muscle cells grown in the laboratory and in animal models. This work will impact on our understanding of how normal skeletal muscle functions, and the factors that influence human diversity in the general population.Read moreRead less
The Influence Of Alpha Actinins On Human Performance In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$480,989.00
Summary
We have identified a common genetic variation that results in absence of the fast muscle fibre protein, a-actinin-3, in over 1 billion people worldwide. Loss of a-actinin-3 influences elite athletic performance and skeletal muscle function in the general population by altering efficiency of muscle metabolism. We will now study mice and humans to determine how a-actinin-3 deficiency influences normal muscle function with age, response to exercise and the severity of human muscle disease.
Identification And Characterisation Of Novel Mouse Models For Recessively Inherited Deafness.
Funder
National Health and Medical Research Council
Funding Amount
$504,750.00
Summary
Hearing loss affects 10% of Australians. Approximately 1 in 1000 children is born deaf. Another 1 in 1000 people develops hearing loss by adulthood. A progressive hearing impairment occurs with age so that more than 50% of people over the age of 75 have a substantial hearing loss. The financial, social and personal costs of deafness are significant. Deafness is caused by environmental and- or inherited factors. Environmental risk factors include premature birth, infections and exposure to loud n ....Hearing loss affects 10% of Australians. Approximately 1 in 1000 children is born deaf. Another 1 in 1000 people develops hearing loss by adulthood. A progressive hearing impairment occurs with age so that more than 50% of people over the age of 75 have a substantial hearing loss. The financial, social and personal costs of deafness are significant. Deafness is caused by environmental and- or inherited factors. Environmental risk factors include premature birth, infections and exposure to loud noise. Inherited factors include changes (mutations) in one of many genes whose products are essential for normal hearing. In the majority of children and young people with a hearing impairment the underlying cause is genetic. It is also thought that genetic predisposition frequently contributes to the early onset and the severity of age-related hearing loss. However, it has been difficult to identify the genes causing deafness, and as a consequence we know relatively little about what these genes do. The mouse ear is very similar to the human ear and in this application we propose to use mice to identify and study deafness genes. Australia has a unique resource of mice that are being especially bred to uncover genetic diseases. We have shown that 1 in a 1,000 of these mice have a genetic hearing loss similar to that found in most newborns and young people. These mice therefore provide us with an exceptional opportunity to discover novel deafness genes, which again will provide us with more information about how we hear. We will investigate why changes in these genes causes hearing loss and this information will allow us to determine in detail how genetic and environmental factors lead to hearing loss in young and old. The results will immediately allow us to offer earlier diagnosis and better counselling to affected families, and in the longer term we believe our research will enable us to develop improved or novel treatments to delay or prevent deafness.Read moreRead less