Cancer cachexia is a devastating disease characterised by muscle wasting, weakness and fatigue. It impairs patient quality of life and accounts for >20% of cancer-related deaths. This project will identify factors responsible for cancer cachexia and develop new strategies to alleviate wasting and weakness in cancer patients, to improve their quality of life and reduce mortality.
Therapeutic Potential Of Modulating Heat Shock Protein Expression For Muscle Wasting Disorder
Funder
National Health and Medical Research Council
Funding Amount
$1,172,146.00
Summary
Heat shock proteins help stressed proteins fold back to their original conformation and restore function. In a discovery published in Nature we identified induction of heat shock protein 72 (Hsp72) as a novel approach for muscular dystrophy and other conditions where there is inflammation and muscle weakness. This proposal will investigate whether Hsp72 induction is similarly effective in tackling the muscle wasting and weakness in conditions like ageing and frailty and in muscle injury.
Nutrient-training Interactions In Human Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$53,659.00
Summary
Skeletal muscle accounts for 50% of total body mass with critical roles in body movement and blood glucose regulation. Exercise is a potent stimulus for maintaining/ increasing muscle mass, an effect that is augmented when combined with protein ingestion. The aims of this proposal are to better understand this exercise-nutrient interaction to optimize the prescription of programs and recovery strategies as a countermeasure for muscle degeneration with aging and disease.
Determining The Pathomechanics Of Muscle Weakness In Older Individuals With Toe Deformities In Order To Develop Evidence-based Intervention Strategies To Restore Foot Function
Funder
National Health and Medical Research Council
Funding Amount
$316,251.00
Summary
Hallux valgus and lesser toe deformities are highly prevalent foot problems in older people that can cause foot disfigurement, physical discomfort, and increase the risk of falling. This study will investigate how toe muscle weakness is affected by these toe deformities as the basis upon which to develop interventions that can restore foot function in older individuals, in order to reduce falls risk, foot pain and, in turn, improve independence and quality of life throughout ageing.
Molecular And Cellular Basis For Muscle Regeneration In Zebrafish.
Funder
National Health and Medical Research Council
Funding Amount
$541,104.00
Summary
Muscle repair occurs via the use of muscle stem cells, which provide skeletal muscle with its regenerative capacity. Muscle stem cells are particularly important in muscle diseases such as muscular dystrophies where muscle regeneration is an important factor in disease progression. We will identify the processes controlling muscle regeneration utilising zebrafish as a model organism. We hope this research will lead to an understanding of how muscle stem cells are generated.
We have discovered a single tumour factor which causes cancer cachexia, a wasting condition that is one of the worst complications of malignancy, for which there is no current effective treatment. We have developed antibodies which effectively block this condition in preclinical models and have produced human/humanised version of this. This application is to characterise these human antibodies to allow us proceed to clinical trials.
Can Exercise Early After Spinal Cord Injury Prevent Deterioration Of Muscle And Bone?
Funder
National Health and Medical Research Council
Funding Amount
$775,049.00
Summary
Spinal cord injury leads to a profound deterioration of the muscles and bones in the paralysed limbs. This project will examine the effects of exercising the paralysed limbs as early as possible after injury to prevent muscle and bone loss rather than restoring the tissues once changes have occurred. The time course and mechanisms underlying the microstructural decay of bone over the first year after injury will also be examined to provide a basis for determining fracture risk in this group.
Novel Transcriptional Regulation In Skeletal Muscle Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$344,592.00
Summary
It has been assumed that once genes are activated in a particular type of cell, they remain 'on'. From work described in this laboratory, we now know that gene activity may come and go. Instead of the analogy of a light switch that has been turned on and stays on, it appears that at least in muscle, gene activity is more like blinking lights. If you take an image of muscle tissue, which is just a snapshot in time, a gene may not appear to be activated if it was temporarily 'flashing off' at the ....It has been assumed that once genes are activated in a particular type of cell, they remain 'on'. From work described in this laboratory, we now know that gene activity may come and go. Instead of the analogy of a light switch that has been turned on and stays on, it appears that at least in muscle, gene activity is more like blinking lights. If you take an image of muscle tissue, which is just a snapshot in time, a gene may not appear to be activated if it was temporarily 'flashing off' at the time of viewing. This may occur in all tissue types, but it is more easily detected in muscle because the cell is large with many nuclei, rather than small with a single nucleus. Another reason why this phenomenon is more readily detectable in muscle cells is that they are very dynamic cells that can undergo fairly radical changes in shape. An actively growing or hypertrophying muscle cell may have all of its genes at a high pitch of transcriptional activity to support rapid growth. However, once a muscle cell has reached its appropriate size, then muscle genes switch to a flashing mode of transcription to maintain rather than build structures. SIGNIFICANCE: (1) This may be a fundamental mechanism of gene regulation that occurs in virtually all cell types. As such, our finding will open an area of research into the types of molecules involved in this novel mechanism. (2) Our studies will result in a better understanding of the mechanisms of muscle cell hypertrophy in response to excercise and drugs, as well as atrophy due to nerve damage or inherited muscle disease. (3) This mechanism may explain the expression of foreign DNA in muscle cells delivered via gene therapy approaches. Our findings could result in a more efficacious means of expressing the introduced gene that might require tricking the muscle fibre into believing that it is in a perpetual growth mode.Read moreRead less
Disease Gene Discovery And Improved Genetic Diagnosis In Neuromuscular Disorders
Funder
National Health and Medical Research Council
Funding Amount
$473,321.00
Summary
Paediatric nerve and muscle disorders result in weakness, chronic disability and often early death. Over half of all affected children do not yet have a genetic diagnosis. This project will use advanced sequencing technology to increase genetic diagnosis rates and identify new disease-causing genes. This will result in improved patient care and a better understanding of the biological pathways altered by these disorders. It will also facilitate the identification of targets for future therapies.
Advancing Glycine To The Clinic For Duchenne Muscular Dystrophy
Funder
National Health and Medical Research Council
Funding Amount
$248,978.00
Summary
We have identified the therapeutic potential of the amino acid glycine for Duchenne muscular dystrophy (DMD), the most common and severe of the muscular dystrophies. To facilitate rapid translation to the clinic, this proposal will; 1) examine the effect of glycine on lifespan and quality of life in mouse models of DMD; 2) determine glycine’s mode of action; and 3) investigate whether these effects represent further benefits to those currently used gold standard treatments.