Molecular Basis Of Ca2+-dependent Disruption Of EC-coupling And Weakness In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$530,976.00
Summary
One major cause of weakness in skeletal muscle appears to stem from damage to the mechanism controlling release of calcium ions from internal stores and consequent contraction. This project examines whether the damage is due to excessive levels of intracellular calcium ions activating enzymes that cut a particular vital molecule controlling calcium release. The findings could identify a major factor in muscle weakness in muscular dystrophy and other conditions and lead to specific therapies.
DHPR ? Subunit Binding To A Variably Spliced Region Of RyR1: A Role In EC Coupling And Myotonic Dystrophy
Funder
National Health and Medical Research Council
Funding Amount
$555,892.00
Summary
We have uncovered a communication pathway between two ion channel molecules in muscle cells that underlies human movement. The pathway is critical in normal mobility and is disrupted in myotonic dystrophy. We will study the molecular components of this pathway to understand normal body function and abnormal function in mytotonic dystrophy. The work will facilitate the design of drugs to relieve the mytotonic dystrophy myopathy and form new and much needed class of specific muscle relaxants.
Many human muscle diseases are caused by mutations in genes encoding skeletal muscle actin. Actin is a major building block of the sarcomere, the engine of muscle contraction. Our studies have identified a mutation in chaperonin, the main protein-folding complex responsible for actin folding, which results in a muscle defect. These results have led to a novel hypothesesis, which we test in this grant, namely that as the chaperonin complex can act as a modulator of of muscle disease.
Decrypting The Excitation Contraction Coupling Machinery In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$914,869.00
Summary
Skeletal muscle function is dependent upon the fine control of calcium levels. When communication of key proteins in muscle are compromised, calcium levels are uncontrolled leading to severe disabilities. The molecular pathways that control signalling between key muscle proteins is currently unknown and shedding light on this topic will aid in the discovery of therapies for muscle-associated disabilities in disease and with aging.
Physiological And Pathological Effects Of Oxidation On Contractile Function In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$613,311.00
Summary
Reactive oxygen molecules generated within muscle fibres in normal exercise and in pathological conditions, greatly affect muscle function by altering the responsiveness of the contractile proteins. This study investigates how various oxidative stresses affect particular reactive sites on key proteins controlling muscle contraction. The findings should identify key molecular changes involved in normal activity and the role oxidation plays in chronic muscle weakness in particular conditions.
Manipulating Store-operated Ca2+ Entry To Improve Muscle Function In Dystrophy
Funder
National Health and Medical Research Council
Funding Amount
$516,163.00
Summary
Muscle function is regulated in a complex manner by calcium and is impaired in Duchenne muscular dystrophy (DMD). Changes in calcium regulation will be investigated in DMD patients and in an animal model using a novel approach. We will use a combination of novel experimental approaches to manipulate muscles in dystrophic mice and test for improvement in function. Results will determine the viability of a potential treatment.
Interactions Between The ? And ? Subunits Of The DHPR - A Missing Link In Skeletal Muscle Excitation-contraction Coupling And A Role In Sarcopenia
Funder
National Health and Medical Research Council
Funding Amount
$690,832.00
Summary
Calcium signaling is disrupted in muscle diseases, including muscle weakness in the elderly. This is a significant problem as all mobility depends on calcium signaling and its disruption can cause serious disability and death. To alleviate defective calcium signaling, the underlying molecular machinery must be fully understood, yet we have only a broad outline of the processes. We will address this problem to provide a platform for alleviating age-related muscle weakness.
Anthracyclines Disrupt Ca2+ Signalling In Cardiomyocytes: A Contribution To Cardiac Toxicity
Funder
National Health and Medical Research Council
Funding Amount
$525,620.00
Summary
Anthracyclines are one of the most effective drugs used in chemotherapy, but cause side effects resulting in serious heart problems which can be fatal. The link between anthracycline therapy and the problems they cause in the heart is not fully defined. We will investigate mechanisms leading to these side effects and define specific targets of anthracyclines in the heart. It is hoped this will lead to the design of new drugs which counteract the side effects of anthracycline treatment.
Understanding The Regulation Of HERG Potassium Channel In The Myometrium At The Time Of Labour
Funder
National Health and Medical Research Council
Funding Amount
$597,661.00
Summary
We have shown that a potassium channel known as hERG falls precipitously at the time of term labour and that blocking this channel causes powerful uterine contractions. This grant will determine how the expression of this channel is regulated in the myometrium and whether changes in hERG channels also occur in premature labour.
Establishing STARS As A Therapeutic Target To Reduce Muscle Wasting And Improve Muscle Function
Funder
National Health and Medical Research Council
Funding Amount
$446,189.00
Summary
Muscle wasting occurs rapidly with disuse after injuries occurring at work, during sport, with chronic disease and in road accidents. It is also a consequence of ageing. Muscle wasting and reduced muscle function places considerable financial strain on our health care system. We aim to use gene therapy and pharmacological interventions to increase the levels of a protein called STARS. We hypothesize that STARS will reduce disuse-induced muscle wasting, increase recovery and improve function.