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
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.
A Single Fibre Approach To The Study Of Regulation Of Protein Synthesis In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$420,039.00
Summary
Skeletal muscle is the most abundant tissue in the human body and accounts for more than 40% of body weight. Loss of muscle mass is a major cause of frailty and loss of functionality in the elderly and is also a common feature of many chronic diseases such as cancer, HIV, arthritis and chronic heart failure. Changes in protein synthesis are intrinsically associated with alterations in muscle mass, which is integral to health, physical performance and independent living. In this project we aim to ....Skeletal muscle is the most abundant tissue in the human body and accounts for more than 40% of body weight. Loss of muscle mass is a major cause of frailty and loss of functionality in the elderly and is also a common feature of many chronic diseases such as cancer, HIV, arthritis and chronic heart failure. Changes in protein synthesis are intrinsically associated with alterations in muscle mass, which is integral to health, physical performance and independent living. In this project we aim to answer some important outstanding questions regarding the regulation of protein synthesis in mammalian skeletal muscle using a novel, single cell approach. Results obtained within the framework of the project will contribute to the understanding of the regulation of cellular and molecular events underpinning protein synthesis in muscle, which is critical for developing effective strategies of treatment and management of various medical conditions to prevent muscle wasting.Read moreRead less