Modulation Of Asthmatic Airway Inflammation By Activation Of Epithelial Proteinase Activated Receptors
Funder
National Health and Medical Research Council
Funding Amount
$188,912.00
Summary
Children and adults feel the symptoms of asthma because their airways close up too easily. We have discovered a new mechanism that the healthy lung uses to keep airways open. The epithelial cells which line the airway release an enzyme that cuts of a small part of another protein, called a PAR receptor, that sits on the same cell. When this happens the epithelial cell releases relaxing substances from their lower surface. The relaxing substances keep the airways open. This grant application is d ....Children and adults feel the symptoms of asthma because their airways close up too easily. We have discovered a new mechanism that the healthy lung uses to keep airways open. The epithelial cells which line the airway release an enzyme that cuts of a small part of another protein, called a PAR receptor, that sits on the same cell. When this happens the epithelial cell releases relaxing substances from their lower surface. The relaxing substances keep the airways open. This grant application is designed to test whether the relaxing system also stops the airways from developing inflammation. If the relaxing system does this we will be able to use the knowlege we have that lets us activate the PAR receptors artificially to design new types of drugs. These drugs would be better than existing asthma drugs because they would prevent inflammation and relax the airways at the same time. These drugs could also be useful in other lung diseases such as chronic bronchitis.Read moreRead less
The In Vivo And In Vitro Biology Of The Novel Intracellular Ion Channel CLIC1 (NCC27)
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
Ion channels are complex proteins that regulate the transports of salts, and essential cell function. We have recently cloned a new ion channel, CLIC1, unique in its location on the nuclear membrane as well as other sites. The function of this channel is uncertain, although we have suggested its association with cell growth and inflammation. We propose to investigate the function of CLIC1, dominantly based on gene knockout animals, in which the CLIC1 gene has been deleted.
Targeting Arginase In Peripheral Arterial Occlusive Disease
Funder
National Health and Medical Research Council
Funding Amount
$243,945.00
Summary
Peripheral artery occlusive disease causes narrowing of large peripheral blood vessels which can result in severe pain, gangrene and stroke. Its prevalence is steadily increasing in western countries. This proposal aims to characterize the role of an enzyme (arginase) in PAOD and determine whether it may be a new drug target for treatment of this disease.
Identification And Characterization Of Novel Bioactive Peptides From Australian Conesnails Targeting Pain Pathways
Funder
National Health and Medical Research Council
Funding Amount
$320,803.00
Summary
In recent years, significant advances have been made in the identification of new targets in the central or peripheral nervous systems which may be used to develop new pain killers. However, molecules specifically targeting these receptors and channels are lacking to date. This project will use novel cell-based approaches to find new molecules from conesnails which specifically target receptors involved in pain. These will be useful to increase our understanding of the mechanisms of pain.
Characterisation Of PAR2 Knockout And Transgenic Mice: Towards Gene Therapy For Epithelia Based Inflammatory Diseases
Funder
National Health and Medical Research Council
Funding Amount
$486,943.00
Summary
Debilitating and sometimes fatal diseases like asthma and rheumatoid arthritis urgently require new approaches for their effective management and hopefully, cure. We have recently discovered that the airways posses a powerful and naturally-occuring protective mechanism which is regulated by unique molecules in the membranes of the lining cells of the air passages. These molecules are called protease-activated receptors, or PARs, and are also found on cells lining the inner surfaces of blood vess ....Debilitating and sometimes fatal diseases like asthma and rheumatoid arthritis urgently require new approaches for their effective management and hopefully, cure. We have recently discovered that the airways posses a powerful and naturally-occuring protective mechanism which is regulated by unique molecules in the membranes of the lining cells of the air passages. These molecules are called protease-activated receptors, or PARs, and are also found on cells lining the inner surfaces of blood vessels and joints as well as in skin. We are fortunate to have strains of mice - a species in which the PAR-mediated protective mechanism is well developed - in which the gene for the most important of the PARs found in the lung, PAR2, is missing. These animals are called PAR2 'knock-outs'. We also have another strain of mouse in which the human PAR2 gene has been inserted back into PAR2 knock-out mice. These animals will allow us to determine the importance of PAR2 in protection against asthma, arthritis, vascular disease and deficiencies in skin healing, as well as how PAR2 might be a more effective protective agent in mice rather than humans. Thus, modification of the human gene to make the protective system work as effectively as in the mouse might provide an effective therapy or cure for diseases of the lungs, joints and skin as well as in vascular diseases.Read moreRead less
Impact Of Airway Wall Fibrosis On The Efficacy Of Anti-asthma Drugs
Funder
National Health and Medical Research Council
Funding Amount
$432,750.00
Summary
Most episodes of asthma are controlled or prevented by current medications. In a small, but significant proportion of asthmatics (5-10%) symptoms persist despite the use of the best combinations of anti-asthma drugs. One of the reasons that acute episodes of asthma occur is that the airway tubes slowly change in structure. These changes involve an increase in the amount of collagen (part of the cement between cells) making the airway stiffer. In this project, we are exploring the impact of the s ....Most episodes of asthma are controlled or prevented by current medications. In a small, but significant proportion of asthmatics (5-10%) symptoms persist despite the use of the best combinations of anti-asthma drugs. One of the reasons that acute episodes of asthma occur is that the airway tubes slowly change in structure. These changes involve an increase in the amount of collagen (part of the cement between cells) making the airway stiffer. In this project, we are exploring the impact of the stiffening of the airway on the way that different cells within the airway wall respond to drugs used to treat asthma. Our initial findings suggest that when the airway wall becomes stiffer with more collagen, there is a diminished benefit from the anti-asthma drugs. This new study is designed to identify the molecular mechanisms for the poor response to the anti-asthma drugs. With this knowledge it will be easier to design and test new drugs that are more effective in severe asthma.Read moreRead less
Epithelium-fibroblast Interactions In Response To Allergic Airway Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$235,526.00
Summary
The airways of an asthmatic patient undergo dramatic structural changes over time. This remodelling is thought to be responsible for producing the changes in lung function that are frequently observed in someone with the disease. However, in contrast to normal wound repair, it is unclear why in the majority of asthmatics, inflammation leads to ongoing remodelling rather than a self limiting healing process. In this context, cells that line the airways (epithelium) as well as cells that sit immed ....The airways of an asthmatic patient undergo dramatic structural changes over time. This remodelling is thought to be responsible for producing the changes in lung function that are frequently observed in someone with the disease. However, in contrast to normal wound repair, it is unclear why in the majority of asthmatics, inflammation leads to ongoing remodelling rather than a self limiting healing process. In this context, cells that line the airways (epithelium) as well as cells that sit immediately beneath them (fibroblasts) are important sources of mediators and structural matrix proteins that contribute to these processes. Under normal conditions, signals from these structural proteins are transmitted to the cells via specific adhesion molecules. However, in asthma epithelial cells are frequently damaged and detached, and fibroblasts appear to proliferate and undergo changes in their appearance. This projects aims to investigate the expression and function of specific cell adhesion molecules in the epithelium and fibroblasts following airway inflammation. Specifically, this proposal aims to determine which adhesion molecules are associated with upregulated proliferation and production of matrix proteins. We will also examine the effects of two novel mediators, thought to play a role in remodelling on the expression and function of these adhesion molecules. Proliferation of these cells and the altered deposition of matrix proteins may be a key feature of airway wall thickening and hyperreactivity that is a characteristic feature of asthma. The balance of deposition and breakdown of matrix proteins is regulated by a variety of mediators. Defining what regulates the expression and activity of adhesion molecules is of fundamental importance in determining how the normal repair processes may evolve into airway wall remodelling.Read moreRead less