Investigation Of Childhood Onset Distal Myopathy Myosin Variants
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
Summary
This project aims to continue the research of this laboratory into the distal myopathies, a group of largely enigmatic genetic disorders, which most severely affect selected distal limb muscles, in other words mostly hand and foot muscles. The project has two parts. The first part aims to determine what causes the childhood onset distal myopathy which we first identified in a West Australian family. We localised the disease gene in this family to chromosome 14 in the first linkage of a distal my ....This project aims to continue the research of this laboratory into the distal myopathies, a group of largely enigmatic genetic disorders, which most severely affect selected distal limb muscles, in other words mostly hand and foot muscles. The project has two parts. The first part aims to determine what causes the childhood onset distal myopathy which we first identified in a West Australian family. We localised the disease gene in this family to chromosome 14 in the first linkage of a distal myopathy and researching this family and similar families from Europe we may have identified the gene. This project aims to prove that the candidate disease gene is the disease gene. The second part of the project aims to investigate another unknown distal myopathy in another Australian family, to try to localise and identify this disease gene.Read moreRead less
Using Gene Delivery Technologies To Define Novel Mechanisms Of Skeletal Muscle Adaptation, And Develop Muscle-directed Interventions For Frailty And Serious Illness
Funder
National Health and Medical Research Council
Funding Amount
$631,370.00
Summary
The focus of my research is to investigate the cellular mechanisms underlying regulation of skeletal muscle size and function in health and disease. By defining these processes we can establish the events contributing to muscle wasting and frailty commonly associated with serious illness and advancing age, and develop interventions to prevent/overcome this important contributor to poor health prospects and reduced survival.
I am a physiologist investigating the molecular basis of normal function in skeletal muscle and the dysfunctions occurring in various muscle diseases and in fatigue. In addition, I investigate analogous dysfunction of calcium release and excitability occu
Targeting Calcineurin For Improving Muscle Regeneration In Skeletal Muscle Disease
Funder
National Health and Medical Research Council
Funding Amount
$303,000.00
Summary
Muscular dystrophy is a term that covers a diverse group of inherited disorders characterised by progressive muscle weakness and wasting. Duchenne muscular dystrophy (DMD) is the most severe form, caused by a lack of a protein called dystrophin, which renders muscles fragile, susceptible to damage, and with a compromised ability to regenerate or repair after injury. The disease progresses to all muscles and DMD patients are dependent on a wheelchair before their early teens and die in their twen ....Muscular dystrophy is a term that covers a diverse group of inherited disorders characterised by progressive muscle weakness and wasting. Duchenne muscular dystrophy (DMD) is the most severe form, caused by a lack of a protein called dystrophin, which renders muscles fragile, susceptible to damage, and with a compromised ability to regenerate or repair after injury. The disease progresses to all muscles and DMD patients are dependent on a wheelchair before their early teens and die in their twenties. There is a profound need for treatments that can ameliorate the dystrophic condition and improve patient quality of life. Restoring or increasing a muscle's capacity to regenerate would help improve muscle function. We have convincing evidence that the calcineurin signal transduction pathway is important for successful muscle regeneration in mice with muscular dystrophy. There is growing excitement worldwide that stimulating calcineurin could attenuate the dystrophic pathology, however, little is known about the role of calcineurin signalling in human muscle disease. Our goals are to investigate the role of calcineurin signalling in muscular dystrophy and to examine its therapeutic potential for enhancing muscle regeneration. Our aim is to better understand the mechanisms controlling calcineurin signalling in muscles of dystrophic mice and in muscles of patients with DMD. A comprehensive series of physiological, molecular, biochemical, and immunohistochemical experiments will be performed to rigorously test our research aim. Understanding the role of the calcineurin pathway in muscle regeneration is important for the development of novel therapeutic strategies to delay the onset or slow the progression of muscle wasting and weakness. The findings will have broad clinical application for our understanding of muscular dystrophy with relevance to other conditions including ageing, AIDS, burns, cancer cachexia, and disuse atrophy, where muscle wasting occurs.Read moreRead less
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.
Role Of Nitric Oxide And Reactive Oxygen Species In Excitation-contraction Coupling In Skeletal Muscle.
Funder
National Health and Medical Research Council
Funding Amount
$163,250.00
Summary
Excitation-contraction (E-C) coupling is a term used to broadly describe the sequence of cellular events that starts with an electrical signal at the surface membrane of a muscle cell and which then ultimately leads to muscle contraction. Although the overall sequence is known, there remain many gaps in our understanding of the mechanisms involved not only related to normal muscle function but to how this function may be impaired by excessive exercise and disease. Many cellular metabolites contr ....Excitation-contraction (E-C) coupling is a term used to broadly describe the sequence of cellular events that starts with an electrical signal at the surface membrane of a muscle cell and which then ultimately leads to muscle contraction. Although the overall sequence is known, there remain many gaps in our understanding of the mechanisms involved not only related to normal muscle function but to how this function may be impaired by excessive exercise and disease. Many cellular metabolites contribute towards the normal control of muscle contraction, while others contribute to its impairment. Reactive oxygen species (ROS), which includes nitric oxide (NO) and related molecules, are metabolic factors often referred to as cellular oxidants. They are thought to have an essential role in controlling normal muscle function. Paradoxically, they are also implicated in the impairment of muscle function associated with fatigue, disease and aging. How these molecules both control normal muscle activity and also contribute to impairment of such function remains unclear. Thus, the central aim of this project is to identify the mechanisms by which the cellular oxidants, NO and other ROS, both control normal E-C coupling in skeletal muscle fibres and how they contribute to muscle fatigue. Clearly, understanding how skeletal muscle normally contracts is essential in order to better understand how muscle function can become impaired with exercise, disease and age. The work from this study will provide insight into both normal muscle physiology and how muscles fatigue and ultimately provide new methodologies and drugs that may combat fatigue, disease and age related changes to muscle function.Read moreRead less
The Molecular Mechanisms Of Anabolic Androgen Actions In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$487,500.00
Summary
We are studying the role of male sex hormones, androgens, in controlling muscle function. Muscle wasting occurs in a variety of disorders, including cancer, burns and trauma, and also during normal ageing. Treatment with androgens helps prevent muscle wasting, and causes increased muscle size, although current therapies can also have side effects. Little is known about how androgens prevent wasting and promote muscle growth. Therefore, we propose to study the actions of male sex hormones in musc ....We are studying the role of male sex hormones, androgens, in controlling muscle function. Muscle wasting occurs in a variety of disorders, including cancer, burns and trauma, and also during normal ageing. Treatment with androgens helps prevent muscle wasting, and causes increased muscle size, although current therapies can also have side effects. Little is known about how androgens prevent wasting and promote muscle growth. Therefore, we propose to study the actions of male sex hormones in muscle. We will study the growth of mouse muscle cells in culture, and measure their rate of growth when treated with androgens. All cells contain certain factors that control their growth and replication, and we will test whether androgens activate these factors to increase growth. We will also study the effect of androgens on muscle in mice, to investigate complex effects that only occur in real muscle. We will neuter male mice, which causes muscle wasting. Neutered mice will then be treated with androgens or placebo, and we will compare the muscle growth effect of androgen treatment versus placebo. We will measure muscle strength, size, and the number of muscle cells in treated and placebo mice. We will also see if the effects of androgen require a particular protein, the androgen receptor, which acts as a lock-key mechanism in cells, to allow them to respond to androgens. We will make a strain of mouse with a non-functional version of the androgen receptor only in muscle cells. This will determine if the muscle growth effects of androgens occur through a direct action on muscle, or indirectly through acting on other tissues in the body. This information will ultimately allow us to design more targeted androgen therapies for muscle wasting, that act only on muscle.Read moreRead less
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.