The foot soldiers of the immune system, the white blood cells, constantly march through the body seeking out invaders, but kept in check by the barrier of endothelial cells that lines the inside of blood vessels. When infection occurs, molecular messages are transmitted amongst the white cells and between white cells and edothelium, to activate the immune cells to pass out of the blood vessels and mount a defence. Unfortunatley, the activation system sometimes goes awry, resulting in inflammator ....The foot soldiers of the immune system, the white blood cells, constantly march through the body seeking out invaders, but kept in check by the barrier of endothelial cells that lines the inside of blood vessels. When infection occurs, molecular messages are transmitted amongst the white cells and between white cells and edothelium, to activate the immune cells to pass out of the blood vessels and mount a defence. Unfortunatley, the activation system sometimes goes awry, resulting in inflammatory or allergic disease, such as arthritis or asthma. This team of researchers from the Hanson Institute in Adelaide, combining expertise in molecular and cell biology, protein chemestry, structual biology and animal models, has been working together for over 10 years, investigating the molecular mechanisms involved in controlling the formation and activities of blood vessels and white blood cells. This program seeks to further that understanding, and to develop drugs that have the potential of ameliorating the inflammatory condition.Read moreRead less
This program brings together a team of researchers from The Walter and Eliza Hall Institute of Medical Research to study how the body regulates antibody production to fight disease. Antibodies are made by B-cells and are essential for a functional immune system. B cells circulate in the body, searching for signs of infection. When they encounter an invader, they mature, with the help of other immune cells, into antibody-producing cells. A small proportion of the cells are set aside as _memory� c ....This program brings together a team of researchers from The Walter and Eliza Hall Institute of Medical Research to study how the body regulates antibody production to fight disease. Antibodies are made by B-cells and are essential for a functional immune system. B cells circulate in the body, searching for signs of infection. When they encounter an invader, they mature, with the help of other immune cells, into antibody-producing cells. A small proportion of the cells are set aside as _memory� cells that can rapidly become antibodyproducing cells should the same infection occur again in the future. This is the basis of vaccination. This program aims to understand how a B cell changes into an antibody-producing cell, by studying the genes that are known to be required for the cells to form, or to do their work. We will study animals whose immune systems are under- or over-active, to find out what part of the antibody-producing process is faulty. Using this information, we hope eventually to be able to study diseases of antibody producing cells in humans (as occur in allergy, asthma, rheumatoid arthritis and leukaemia), to be able to identify the precise cause of the problem, and to suggest a therapy. This information may also be used to improve the outcome of vaccination where an enhanced antibody response is desired.Read moreRead less
Novel Therapeutic Strategies To Reduce The Burden Of Chronic Heart Failure
Funder
National Health and Medical Research Council
Funding Amount
$4,928,323.00
Summary
The broad aims of the Program are to develop novel strategies in the prevention and treatment of chronic heart failure. This will involve investigating new targets for pharmacological therapies, evaluating whether common co-morbid disease states such as diabetes alter the efficacy of these therapies and investigating the role of stem-cell therapy in this setting. The Program will also evaluate the contribution of non-heart failure drugs to the burden of heart failure, determine the impact of rur ....The broad aims of the Program are to develop novel strategies in the prevention and treatment of chronic heart failure. This will involve investigating new targets for pharmacological therapies, evaluating whether common co-morbid disease states such as diabetes alter the efficacy of these therapies and investigating the role of stem-cell therapy in this setting. The Program will also evaluate the contribution of non-heart failure drugs to the burden of heart failure, determine the impact of rurality on prescribing for this condition and explore systems of optimising delivery of best practice to the community. This research formalises the existing collaborative efforts of a team of investigators that span all aspects of research into the therapeutics of CHF from basic laboratory research to evaluation of patients in clinical trials and public health translational aspects of this condition. The Chief Investigators and Principal Investigators have an existing successful research collaboration which will be greatly expanded via Program.Read moreRead less
Understanding G Protein-Coupled Receptors (GPCRs): Accelerating Discovery From Concept To Clinic.
Funder
National Health and Medical Research Council
Funding Amount
$6,871,789.00
Summary
G Protein-Coupled Receptors (GPCRs) form the largest family of receptors (and thus drug targets) in living organisms. Currently, the major reason that new drugs fail to reach the clinic is lack of appropriate drug effect (approx. 30%). Thus, we need a better understanding of how GPCRs work and how this relates to disease. Our Program addresses this knowledge gap, using GPCR models that are relevant to treatment of metabolic, cardiovascular and central nervous system disease.
Molecular Regulation Of Blood Cell Production And Function
Funder
National Health and Medical Research Council
Funding Amount
$18,333,174.00
Summary
The blood-forming system is an intricately controlled balance of cell proliferation, maturation and functional activity that is essential for oxygen transport throughout the body, blood clotting, and effective immune responses. Defining the genes and molecules that orchestrate blood cell production and function is crucial, not only for understanding the role of blood in health, but for establishing the bases of blood cell disorders such as autoimmunity and leukaemia, and for devising new clinica ....The blood-forming system is an intricately controlled balance of cell proliferation, maturation and functional activity that is essential for oxygen transport throughout the body, blood clotting, and effective immune responses. Defining the genes and molecules that orchestrate blood cell production and function is crucial, not only for understanding the role of blood in health, but for establishing the bases of blood cell disorders such as autoimmunity and leukaemia, and for devising new clinical strategies for fighting these lethal diseases. This program is conducted by a large, established team of investigators that have made world-class contributions to understanding blood cell formation and function for more than 30 years. Their work established the modern era of molecular haematology via discovery and analysis of blood cell hormones (colony-stimulating factors or CSFs), their receptors and intracellular mediators, which resulted in development of treatments for millions of cancer patients. The program is a multidisciplinary, team approach to fundamental biological questions with a focus on potential clinical and commercial outcomes involving collaborations with clinical medicine and the pharmaceutical industry. Research will focus on meshing novel genetic approaches in mice with translation studies in humans to identify new validated targets for therapeutic intervention in blood cell diseases, as well as building on the team s expertise in cytokine action with emphasis on the actions of the suppressor of cytokine signalling (SOCS) molecules, a key family of proteins that controls cytokine actions.Read moreRead less