Determining The Cellular Mechanisms Involved In The Airway Response To Topical Citrate
Funder
National Health and Medical Research Council
Funding Amount
$444,491.00
Summary
The air passages of the lungs are lined by mucous membranes. These membranes are covered by a thin layer of fluid to protect the airways from drying. This fluid allows the cilia, the hair like projections on top of the airway cells to beat more effectively to remove mucous and inhaled particles from the lungs. The volume and composition of this fluid is determined by the salt and water movement across the mucous membranes of the airways. These processes are abnormal in cystic fibrosis (CF), the ....The air passages of the lungs are lined by mucous membranes. These membranes are covered by a thin layer of fluid to protect the airways from drying. This fluid allows the cilia, the hair like projections on top of the airway cells to beat more effectively to remove mucous and inhaled particles from the lungs. The volume and composition of this fluid is determined by the salt and water movement across the mucous membranes of the airways. These processes are abnormal in cystic fibrosis (CF), the most common lethal inherited disease affecting Australians. In CF, an abnormal gene disrupts one of the major mechanisms for salt and water movement in the air passages. This abnormal salt transport causes drying of the airway surface which impairs the working of the cilia. This leads to retention of mucous in the airways with repeated bacterial infections damaging the lungs. Over the last 10 years, we have developed a series of simple tests to measure the abnormalities in the CF airway of human subjects. We have isolated an exciting new clinical application for sodium citrate, a substance used in blood transfusions. Citrate appears to alter both the salt transport abnormalities found in CF. This research proposal seeks to better understand the dual effects of citrate and to test similar compounds that may have stronger effects. The ultimate aim of our research is to have sufficient knowledge to work out the best way to develop a new treatment for CF.Read moreRead less
EPITHELIAL ION TRANSPORT DEFECTS IN CYSTIC FIBROSIS: PATHOPHYSIOLOGY AND TREATMENT
Funder
National Health and Medical Research Council
Funding Amount
$290,440.00
Summary
The thin layer of fluid covering the surface of the air passages acts to protect the airway surface from drying. This fluid also allows the hair-like projections, or cilia, on the top of the airway cells to beat more effectively. The volume and composition of this fluid is determined by the movement of salt and water across the mucous membranes of the air passages. The importance of this fluid is shown by the problems that occur in Cystic Fibrosis (CF), the most common lethal inherited disease a ....The thin layer of fluid covering the surface of the air passages acts to protect the airway surface from drying. This fluid also allows the hair-like projections, or cilia, on the top of the airway cells to beat more effectively. The volume and composition of this fluid is determined by the movement of salt and water across the mucous membranes of the air passages. The importance of this fluid is shown by the problems that occur in Cystic Fibrosis (CF), the most common lethal inherited disease affecting Australians. In CF, altered salt transport causes drying of the airway surface which impairs the working of the cilia. This leads to retention of mucous in the airway with repeated bacterial infections damaging the lungs. Simple tests have been designed to directly measure the movement of salt across the surface of the nasal passage using a fine soft rubber tube. Movement of mucous in the nose is measured using other simple techniques that are currently used diagnostically. Together, these tests in the nose provide vital information about how the surface of normal human airway moves salt, water and mucous. Any differences found in CF patients will then give us a good idea of the problems found in the CF lung. We will study the interactions between calcium, sodium and chloride in the fluid lining the airways, measuring changes in salt and mucous movement. A range of testing procedures will be used in human volunteers, anaesthetised mice and isolated tissues from sheep. We have already demonstrated important links between the fluid lining the airways and salt movement, and we expect that this may lead to the development of new treatments for Cystic Fibrosis. This therapy will focus on treating the lung problems of CF patients, the major cause of disability. We anticipate that this preventative therapy may offer real benefits in the fight to cure CF.Read moreRead less
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
Intramuscular Interstitial Cells Of Cajal; Ion Channels And Their Modulation By Calcium Ions And Neurotransmitters.
Funder
National Health and Medical Research Council
Funding Amount
$523,261.00
Summary
Disorders of gut motility manifest themselves in several ways, as either patterns of hyperactivity or patterns of reduced activity. Under normal conditions gut motility reflects a balance between myogenic, neuronal and hormonal factors but as yet how this balance is normally achieved is not understood. This project will examine the properties of a class of cells, whose importance in both myogenic and neural control mechanisms has only been recognized over the last 10 years. The muscular wall of ....Disorders of gut motility manifest themselves in several ways, as either patterns of hyperactivity or patterns of reduced activity. Under normal conditions gut motility reflects a balance between myogenic, neuronal and hormonal factors but as yet how this balance is normally achieved is not understood. This project will examine the properties of a class of cells, whose importance in both myogenic and neural control mechanisms has only been recognized over the last 10 years. The muscular wall of the gut is made up of two distinct types of cells. One group, smooth muscle cells, contains contractile elements and the coordinated behavior of these cells leads to the contractions of the gut wall, so ensuring the controlled passage of gut contents along the gastrointestinal tract. The other group of cells, Interstitial cells of Cajal, lack contractile elements. One set of these cells have recently been found to be the pacemaker cells of the gut responsible for the initiation of myogenic activity. They generate pacemaker waves which ensure that the gut contracts rhythmically. Another set of these cells are densely innervated, they receive messages from the nervous system and translate these messages into signals which alter the activity of the gut. Thus these cells play a key role in the neural control of the gut. In many disease states, the numbers of interstitial cells of Cajal have been found to be reduced. However as yet we know very little about these cells. This project will, for the first time, examine the properties of the interstitial cells involved in neural control and will determine how they carry out these essential functions.Read moreRead less
A Novel Ionic Current Contributing To Spasm Of Small Blood Vessels
Funder
National Health and Medical Research Council
Funding Amount
$287,500.00
Summary
Vascular smooth muscle can produce strong constrictions or spasms that can severely limit blood flow. Disorders arising from such spasms include sudden death, neurological deficits, visual and hearing loss or impairment, Raynaud's phenomenon (painful episodic contraction of the fingers and toes) and intestinal necrosis. Common mechanisms are likely to underlie the spasms associated with these disparate disorders. In a recent electrophysiological study of vascular smooth muscle, we discovered a n ....Vascular smooth muscle can produce strong constrictions or spasms that can severely limit blood flow. Disorders arising from such spasms include sudden death, neurological deficits, visual and hearing loss or impairment, Raynaud's phenomenon (painful episodic contraction of the fingers and toes) and intestinal necrosis. Common mechanisms are likely to underlie the spasms associated with these disparate disorders. In a recent electrophysiological study of vascular smooth muscle, we discovered a novel membrane current which we refer to as the plateau current. This current has a strong depolarizing influence that is likely to make a major contribution to the spasms, particularly in arterioles and small arteries which are more dependent on depolarization for contraction. Block of this current is expected to minimize the depolarization and therefore prevent or ameliorate spasm of the vessels. Thus the plateau current represents a new field of therapeutic potential for addressing vascular problems that have significant health implications. However, therapeutic manipulation of the current requires knowledge of its properties. In this project we will determine the biophysical and pharmacological properties of this current using voltage-clamp techniques. We will then use this information to assess its functional significance by recording membrane potential with intracellular microelectrodes simultaneously with contractile activity. We will also compare small vessels obtained from volunteers with or without the vasospastic disorder of Raynaud's phenomenon. Our previous work using these techniques was described in J Physiol as a microelectrode, patch clamp and myograph study of the highest quality and of supreme technical difficulty and scored a Top-Ten hit rate. Since we are the only ones to record the plateau current, we are in a unique position to make significant progress to our understanding of contraction, including spasm, in small blood vessels.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