Excitation-contraction Coupling In Skeletal Muscle In Health, Exercise And Disease
Funder
National Health and Medical Research Council
Funding Amount
$623,621.00
Summary
Skeletal muscle dysfunction occurs in certain diseases, aging and exercise, and can deleteriously affect lifestyle and mobility. This project investigates the molecular mechanisms involved in the complex sequence of events that occur in each individual muscle fibre, starting from stimulation by a nerve through to the fibre contracting. This should give information about causes of skeletal muscle dysfunction in myotonia, heart failure and other situations, and help development of therapies.
Characterisation And Regulation Of Chloride Channels In Cardiac And Skeletal Sarcoplasmic Reticulum In Mammals
Funder
National Health and Medical Research Council
Funding Amount
$381,856.00
Summary
An understanding of the operation of ion channels in cell membranes is fundamental to our knowledge of the function of muscles under normal conditions and in pathological states that modify cell function, e.g. myotonia and cardiac failure. Ion channels control the flow of currents and the transport of substances which ultimately determine whether cells live or die, and hence whether cell pathologies are expressed as muscle failure, as when hypoxia causes tissue damage to the heart, or as severe ....An understanding of the operation of ion channels in cell membranes is fundamental to our knowledge of the function of muscles under normal conditions and in pathological states that modify cell function, e.g. myotonia and cardiac failure. Ion channels control the flow of currents and the transport of substances which ultimately determine whether cells live or die, and hence whether cell pathologies are expressed as muscle failure, as when hypoxia causes tissue damage to the heart, or as severe arrythmia or cardiac arrest. The objective is to understand channel involvement in the mechanisms underlying the function of cardiac and skeletal muscle. We believe that by mimicking the factors that occur in pathological conditions we can understand how ion channels are altered and controlled, and find ways of reversing harmful alterations, thereby reversing cell damage and failure of vital muscle function.Drugs will be used to modify the 'gating' of the channels. By comparing the effects of different drugs, we hope to determine the important features of the mechanisms that control the gating of the channels, making them more or less sensitive to different influences, especially those that occur in pathological states. The study has great application to the study of other pathologies, e.g. cystic fibrosis, severe diarrhoea, paralysis and chronic fatigue. The pharmacological emphasis offers the fundamental science needed to design novel and specific drugs to combat the many serious pathologies related to ion channel effects. Aside from its importance to basic science and to immediate issues of health, the study offers considerable economic gains, both through improved public health and through development of pharmaceuticals.Read moreRead less
Theoretical Investigations Into Permeation Dynamics In Calcium- And Potassium-Selective Membrane Ion Channels
Funder
National Health and Medical Research Council
Funding Amount
$517,243.00
Summary
All electrical activities in the brain are regulated by opening and closing of ion channels. Thus, understanding their mechanisms at a molecular level is a fundamental problem in biology. There are many different types of ion channels, each type fulfilling a different role. We now know the exact atomic structures of several types of the proteins forming ion channels. Using this newly unveiled information, we propose to build exact physical models of two important classes of ion channels, namely, ....All electrical activities in the brain are regulated by opening and closing of ion channels. Thus, understanding their mechanisms at a molecular level is a fundamental problem in biology. There are many different types of ion channels, each type fulfilling a different role. We now know the exact atomic structures of several types of the proteins forming ion channels. Using this newly unveiled information, we propose to build exact physical models of two important classes of ion channels, namely, the calcium channels and potassium channels, using the technique known as 'homology' modelling. Then, making use of powerful supercomputers and the special computer programs we have devised, we propose to follow the motion of ions as they move through the channel and study how some chemical compounds or drugs interfere with the normal functioning of the channel. Specifically, we will attempt to understand how verapamil, which is used to treat irregular heart beats and high blood pressure, interact with the calcium channel. Once we fully understand how these channels work, we will be able to understand the causes of, and possibly find the cures for, many neurological and muscular disorders, such as cardiac arhythmia and hypertension.Read moreRead less
Theoretical Studies On The Dynamics Of Ion Permeation Across Membrane Channels
Funder
National Health and Medical Research Council
Funding Amount
$381,000.00
Summary
All electrical activities in the brain are regulated by opening and closing of ion channels. Thus, understanding their mechanisms at a molecular level is a fundamental problem in biology. There are many different types of ion channels, each type fulfilling a different role. We now know the exact atomic structures of several types of the proteins forming ion channels. Using this newly unveiled information, we propose to build exact physical models of many different types of ion channels. Then, ma ....All electrical activities in the brain are regulated by opening and closing of ion channels. Thus, understanding their mechanisms at a molecular level is a fundamental problem in biology. There are many different types of ion channels, each type fulfilling a different role. We now know the exact atomic structures of several types of the proteins forming ion channels. Using this newly unveiled information, we propose to build exact physical models of many different types of ion channels. Then, making use of powerful supercomputers, we propose to follow the motion of ions as they move through the channel, study how a channel can select only the correct type of ions to traverse it and determine how many ions a single channel is capable of processing per second. The predictions made by our theory and computer simulations will be checked experimentally. Once we fully understand how these channels work, we will be able to understand the causes of, and possibly find the cures for, many neurological, muscular and renal disorders.Read moreRead less