Many serious inflammatory diseases, such as arthritis, septic shock, lung shock and heart disease are poorly controlled with currently available drugs. There is much evidence that a circulating hormone system called complement is involved with exacerbating these diseases, yet there are no drugs available to counteract its effects. One powerful component of the complement system, called C5a, causes inflammation and is suspected of causing tissue damage and suffering in these and many other immune ....Many serious inflammatory diseases, such as arthritis, septic shock, lung shock and heart disease are poorly controlled with currently available drugs. There is much evidence that a circulating hormone system called complement is involved with exacerbating these diseases, yet there are no drugs available to counteract its effects. One powerful component of the complement system, called C5a, causes inflammation and is suspected of causing tissue damage and suffering in these and many other immune diseases. An agent that could block the effects of C5a could be very useful clinically. There is no such drug available as yet. We have developed powerful agents which specifically block C5a in laboratory tests on isolated cells and tissues, and now propose to test their effectiveness in rats in which the above human disease conditions are mimicked. Our preliminary results are very promising, and we will conduct further testing to determine the scope of the actions of the new drugs. One of our new agents is orally active in rats, and we will determine how the blood levels of the drug relate to its beneficial effects. We are also planning to develop agents that are more effective when given by mouth. The results could lead to a new type of anti-inflammatory drug for humans suffering from a variety of diseases that are poorly treatable at present.Read moreRead less
Pharmacological Targeting Of Arylamine N-Acetyltransferase I
Funder
National Health and Medical Research Council
Funding Amount
$474,653.00
Summary
This project will investigate a novel approach to controlling how cancer cells grow and spread. It plans to study whether a protein termed N-acetyltransferase is a key to determining whether cancer cells can change thier characteristics, allowing them to invade other tissues. In addition, novel approaches to target this protein are proposed. If successful, the work outlined in this project will open new avenues to understanding and trerating cancers.
Pharmacological Regulation Of Airway Smooth Muscle Phenotype
Funder
National Health and Medical Research Council
Funding Amount
$276,742.00
Summary
In Australia there is a high incidence of asthma which impairs quality of life and can sometimes cause death if sufficiently severe. The main cause of asthma is the shortening of muscle surrounding the airway passages that cause the narrowing of these tube-like passages. When airway passages narrow a feeling of chest tightness is perceived by the asthmatic patient. When the narrowing is severe the amount of oxygen being delivered to the blood can be reduced to dangerous levels. When there is mus ....In Australia there is a high incidence of asthma which impairs quality of life and can sometimes cause death if sufficiently severe. The main cause of asthma is the shortening of muscle surrounding the airway passages that cause the narrowing of these tube-like passages. When airway passages narrow a feeling of chest tightness is perceived by the asthmatic patient. When the narrowing is severe the amount of oxygen being delivered to the blood can be reduced to dangerous levels. When there is muscle growth in the airways even small amounts of shortening of the muscle can cause severe narrowing of the airway passages. This research will investigate how muscle grows in asthmatic airways and look for new ways to use drugs to treat this muscle growth. We hope to improve drug treatment of asthma by limiting the amount of airway narrowing caused by muscle contraction.Read moreRead less
Heme-oxidised Soluble Guanylyl Cyclase, A Mechanism-based Target For Vascular Diagnostics And Vasoprotective Therapy
Funder
National Health and Medical Research Council
Funding Amount
$524,456.00
Summary
Nitric oxide is produced in the inner lining of blood vessels and maintains blood flow via binding to a specific protein, sGC. In disease, sGC is defective and can be targeted by a novel group of drugs which are more active in diseased versus normal blood vessels. This project will examine the use of these drugs as markers of cardiovascular disease and in the treatment of high cholesterol and may lead to the development of new diagnostic tools and therapies for vascular complications.
Cytochrome P450-mediated Epoxides Of Polyunsaturated Fatty Acids That Regulate Cell Death And Survival
Funder
National Health and Medical Research Council
Funding Amount
$495,710.00
Summary
Omega-3 polyunsaturated fatty acids (PUFAs) decrease cancer risk in man whereas omega-6 PUFA, which are common in western diets, increase risk. In cells cytochrome P450 converts PUFAs to epoxides. Omega-6 epoxides stimulate growth of cells and tumours but we have found that epoxides of the omega-3 eicosapentaenoic acid inhibit cell growth. We will now evaluate the mechanisms of these effects, which could lead to new anticancer treatments, perhaps based on altered diet.
The Role Of Connexins In Blood Pressure Regulation: Use Of A Conditional Gene Expression System
Funder
National Health and Medical Research Council
Funding Amount
$583,767.00
Summary
Cell coupling through gap junctions is said to play an important role in regulating blood flow and blood pressure. However data obtained from mice, in which specific gap junctions are deleted, may be compromised by compensatory changes in other junctions. We have validated a new method for rapidly and reversibly altering gap junctions in adult mice with oral sugar. This technique will enable us to directly determine whether interference with cell coupling affects blood flow and blood pressure.
Protective Roles For Protease-activated Receptor 2 (PAR2) In Parasitic And Autoimmune Diseases
Funder
National Health and Medical Research Council
Funding Amount
$483,421.00
Summary
Parasite infection has unique and specific effects on the human immune system which can prevent allergy and diseases such as diabetes and multiple sclerosis (MS). We have discovered a drug which can cause the immune system to behave in a similar way to that observed during a parasite infection. This project will explore how the drug mimics a parasite and examine the potential of this treatment to prevent MS using a mouse model of this disease.
HYPOXIA AND THE TRANSCRIPTIONAL REGULATION OF CYP GENES IN CELLS
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
Hypoxia, or oxygen deprivation caused by the decreased supply of blood to cells, is a component of ischaemic injury of the cardiovascular system (as in angina or atherosclerosis) and numerous other organs (e.g. in cancer and chemical-mediated injury). It is now known that the content of certain proteins that activate specialised target genes is increased rapidly in cells in response to oxygen deprivation. Some of the most important of these proteins are hypoxia-inducible factor-1 (or HIF-1) and ....Hypoxia, or oxygen deprivation caused by the decreased supply of blood to cells, is a component of ischaemic injury of the cardiovascular system (as in angina or atherosclerosis) and numerous other organs (e.g. in cancer and chemical-mediated injury). It is now known that the content of certain proteins that activate specialised target genes is increased rapidly in cells in response to oxygen deprivation. Some of the most important of these proteins are hypoxia-inducible factor-1 (or HIF-1) and activator protein-1 (or AP-1). We have identified a novel target gene that is activated in hypoxia. This gene produces an enzyme, termed cytochrome P450 2J2, that acts on fatty acids which are present in cell membranes and converts them into molecules that control the flow of potassium and calcium ions into cells. Alterations in the flow of such ions into cells have been observed previously in hypoxia but the mechanism of this effect is unclear. Thus, cytochrome P450 2J2 is switched on in hypoxia and generates fatty acid metabolites that control protective ion fluxes in cells.Read moreRead less
Alternate Signalling Pathways Regulating The Human Arachidonate Epoxygenase CYP2J2 In Response To Stress Stimuli
Funder
National Health and Medical Research Council
Funding Amount
$369,000.00
Summary
Hypoxia, or oxygen deprivation, is caused by the decreased supply of blood to cells and is a component of ischaemic injury to the cardiovascular system (e.g. stroke, atherosclerosis) and numerous other organs (e.g. cancer and chemical mediated injury). It is now known that an important group of proteins that switch on specialised target genes in response to hypoxia is Activator-Protein-1 (AP-1). We have found that cytochrome P450 2J2 (CYP2J2), which is an enzyme that forms beneficial fatty acid ....Hypoxia, or oxygen deprivation, is caused by the decreased supply of blood to cells and is a component of ischaemic injury to the cardiovascular system (e.g. stroke, atherosclerosis) and numerous other organs (e.g. cancer and chemical mediated injury). It is now known that an important group of proteins that switch on specialised target genes in response to hypoxia is Activator-Protein-1 (AP-1). We have found that cytochrome P450 2J2 (CYP2J2), which is an enzyme that forms beneficial fatty acid products inside cells, is decreased in hypoxia and that this is due to increased activity of AP-1. We know that similar stressful stimuli can also result in a loss of CYP2J2. Again, AP-1 is involved but we have further evidence for the role of another pathway. This project will explore how these pathways operate individually and together to decrease CYP2J2. Studying the regulation of human genes is difficult because we can not readily monitor their levels in cells in either healthy or sick individuals. So we will make transgenic mouse models to study human CYP2J2 regulation, which will provide information on the human situation. In this project we will identify which factors switch off the CYP2J2 transgene and will analyse the signalling pathways within cells that control this response. The importance of these studies is that they will help us to design pharmacological strategies to prevent the loss of CYP2J2 in cells that are stressed. Such agents may be effective in the treatment of ischaemic injury seen in stroke and atherosclerosis. If we can maintain CYP2J2 levels we may be able to maintain the beneficial fatty acid levels in cells and have a novel therapeutic approach for keeping cells alive.Read moreRead less