Dysferlin And The Emergency Vesicle Fusion Of Membrane Repair
Funder
National Health and Medical Research Council
Funding Amount
$481,496.00
Summary
Membrane repair is a vital cell survival mechanism of all eukaryotic cells, using calcium-triggered vesicle fusion to ‘patch’ membrane ruptures. The muscular dystrophy protein dysferlin is a key mediator of membrane repair, although, exactly how dysferlin mends membranes has been unclear. We show that the calcium that floods through membrane tears, activates a group of enzymes called calpains, that specifically cleave dysferlin to release a specialist vesicle-fusion module for membrane repair.
Dysferlinopathy: A Genetic Disease Sheds Light On Membrane Repair For Muscle And Cardiac Injury
Funder
National Health and Medical Research Council
Funding Amount
$782,806.00
Summary
Muscles are damaged all of the time, as we stretch and contract them, but we don't fully understand how they repair themselves. We are studying the molecular steps taken by a muscle cell to repair membrane damage. Our research will provide valuable insights into how to treat muscular dystrophy and other conditions characterised by membrane damage to cells, such as heart attack and stroke.
Dysferlin Coordinates Membrane Repair For Skeletal And Cardiac Injury
Funder
National Health and Medical Research Council
Funding Amount
$459,270.00
Summary
Muscles are damaged all of the time, as we stretch and contract them, but we don't fully understand how they repair themselves. We are studying the molecular steps taken by a muscle cell to repair membrane damage. Our research will provide valuable insights into how to treat muscular dystrophy and other conditions characterised by membrane damage to cells, such as heart attack and stroke.
Regulatory Mechanisms And Roles Of Calpains In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$439,813.00
Summary
The objectives are to understand the regulation and roles of calpains, which are proteases that break proteins in the building and repair of skeletal muscle. We will determine targets that calpains cleave and whether their location changes following activation, as well as the cellular factors regulating their activity. In addition, we will obtain information about the specific type of calpain dysfunction that occurs in particular patients with limb girdle muscular dystrophy 2A.