The team has been at the forefront of research on type 1 diabetes for over a decade. This form of diabetes is a major chronic disease from childhood, as well as accounting for at least 10% of adult-onset diabetes. It occurs when the body�s immune system attacks and destroys the beta cells in the pancreas that make insulin, the hormone that controls the level of glucose in the blood. The team was one of the first in the world, and is the only one in Australia, to develop screening programs to tes ....The team has been at the forefront of research on type 1 diabetes for over a decade. This form of diabetes is a major chronic disease from childhood, as well as accounting for at least 10% of adult-onset diabetes. It occurs when the body�s immune system attacks and destroys the beta cells in the pancreas that make insulin, the hormone that controls the level of glucose in the blood. The team was one of the first in the world, and is the only one in Australia, to develop screening programs to test and identify people at risk for type 1 diabetes. They showed that the underlying disease could start years before symptoms occurred and discovered genes that determine the rate at which the underlying disease progresses. They have also found evidence that the disease may be triggered by gut viruses called rotaviruses in genetically-susceptible individuals. They showed that type 1 diabetes could be prevented in a mouse model by getting the immune system to make a protective response to insulin, and then went on to apply this in at-risk humans in a controlled trial of intranasal insulin, the first of its kind. They have used genetic techniques not only to pinpoint the mechanisms responsible for killing the beta cells but also to modify the beta cells to make them resistant to attack by these mechanisms. The multidisciplinary approach of the team will be directed to further understanding the genetic and environmental factors underlying type 1 diabetes and the immune mechanisms, particularly involving special white blood cells called T cells, that kill beta cells. A molecular target of the immune attack, the parent of insulin called proinsulin, will be used, paradoxically, as a tool to regulate the immune system and avert the attack. This will be achieved by giving proinsulin via the mucosa of the naso-respiratory tract or via the bone marrow-derived stem cells, initiallyin the mouse model as a test of feasibility for human application. In parallel with these approaches to prevention, specially constructed viruses will be used to transfer several new genes into beta cells to improve their resistance to immune attack, so that they can be transplanted into people with established diabetes without the need for potentially toxic drugs that suppress the immune system overall. The integrated research of the team is helping to provide a sound, rational base for the eventual prevention and cure of type 1 diabetes.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
Heart Failure And Its Antecedents: Pathophysiology, Prevention And Treatment
Funder
National Health and Medical Research Council
Funding Amount
$9,061,084.00
Summary
Heart failure is mainly a result of coronary artery disease. It is a major cause of disability and mortality in Australia and is projected to increase markedly over the next two decades. This program brings together clinical and basic science expertise to address aspects of the prevention and control of coronary disease and heart failure. The outcomes that will arise will provide a better understanding of the mechanisms involved in the progression from stable heart disease to failure.
Prevention And Treatment Of Chronic Heart And Kidney Disease Via Epidemiological, Pharmacol Device And Cell-Based Approaches
Funder
National Health and Medical Research Council
Funding Amount
$5,795,334.00
Summary
Heart failure describes where the heart cannot pump adequately to meet the needs of the body. This condition has a high mortality despite recent advances in therapy, therefore, there is an urgent need for new approaches to this condition. The present grant aims to: (1) identify patients at high-risk for future development of this condition where early intervention with drugs may reduce or prevent the development of new heart failure; (2) use novel drugs, devices and stem cell therapies to identi ....Heart failure describes where the heart cannot pump adequately to meet the needs of the body. This condition has a high mortality despite recent advances in therapy, therefore, there is an urgent need for new approaches to this condition. The present grant aims to: (1) identify patients at high-risk for future development of this condition where early intervention with drugs may reduce or prevent the development of new heart failure; (2) use novel drugs, devices and stem cell therapies to identify ways to better treat patients with existing disease; (3) focus on the effect of heart failure on the kidney and vice versa via early diagnosis and treatment strategiesRead moreRead less
Integration Of Risk Evaluation In Cardiovascular Disease Management Programs.
Funder
National Health and Medical Research Council
Funding Amount
$5,162,176.00
Summary
This study will determine the feasibility of a coordinated health care team approach to the treatment of cardiovascular disorders. It will examine a range of issues – who would most benefit from this approach, its value for money, the relative importance of health care services to consumers, and where to invest additional health funds. Built on strong collaborations between expert researchers in advanced diagnostic techniques, coordinated health care, community health care and health economics, ....This study will determine the feasibility of a coordinated health care team approach to the treatment of cardiovascular disorders. It will examine a range of issues – who would most benefit from this approach, its value for money, the relative importance of health care services to consumers, and where to invest additional health funds. Built on strong collaborations between expert researchers in advanced diagnostic techniques, coordinated health care, community health care and health economics, this provides a unique opportunity to benefit millions of Australians.Read moreRead less
Molecular Mechanisms Of Cardiac Function And Disease
Funder
National Health and Medical Research Council
Funding Amount
$8,213,642.00
Summary
Heart disease remains the leading cause of death in our society. Almost two million Australians suffer from the debilitating effects of heart disease and it is the leading cause of premature permanent disability in our workers. Heart defects are also the most common type of birth defect and the leading cause of deaths in infants dying from birth defects. Many of these problems can be attributed directly to defects in the development, repair and-or function of heart muscle and, at the cellular le ....Heart disease remains the leading cause of death in our society. Almost two million Australians suffer from the debilitating effects of heart disease and it is the leading cause of premature permanent disability in our workers. Heart defects are also the most common type of birth defect and the leading cause of deaths in infants dying from birth defects. Many of these problems can be attributed directly to defects in the development, repair and-or function of heart muscle and, at the cellular level, of heart muscle cells or cardiomyocytes. Understanding the cardiomyocyte as well as integrated heart development, biology, physiology and function, therefore, holds great promise for major advances in the prevention and treatment of contemporary heart diseases. This Program Grant brings together a unique team of interactive researchers with expertise in cardiovascular physiology, as well as developmental, cellular and molecular biology. The outcomes anticipated from new insights into heart biology that will result from the proposed studies, are the development of novel therapeutic approaches for the prevention and treatment of heart attacks and heart failure.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
Roles Of Impaired Apoptosis And Differentiation In Tumourigenesis And Therapy
Funder
National Health and Medical Research Council
Funding Amount
$21,656,910.00
Summary
The ten scientific laboratories in this program have joined forces to investigate two ways in which tumours develop. Both are of particular interest, because they suggest new ways in which cancer might be overcome. Most of our tissues are continually renewed throughout life by production of new cells. Therefore many of the old cells in each tissue must die off to maintain the proper cell numbers. To eliminate cells that are no longer needed or have become damaged, the body has developed a remark ....The ten scientific laboratories in this program have joined forces to investigate two ways in which tumours develop. Both are of particular interest, because they suggest new ways in which cancer might be overcome. Most of our tissues are continually renewed throughout life by production of new cells. Therefore many of the old cells in each tissue must die off to maintain the proper cell numbers. To eliminate cells that are no longer needed or have become damaged, the body has developed a remarkable cell suicide process termed apoptosis. Unfortunately, however, occasionally a random accident to the genes in one of our cells prevents the machinery for apoptosis from being turned on. In that case, the cell will not die when it should and, by continually dividing, it may eventually give rise to a cancer. Since most cancer cells still retain most of the machinery for apoptosis, however, a drug that could switch on this natural cell death machinery would provide a promising new approach to cancer therapy. Identifying and developing such drugs is one major long-term goal of this program. The other focus of our program concerns stem cells. These are rare cells with the remarkable ability to generate an entire tissue. For example, one of our laboratories has identified stem cells that can generate all the cells in the breast. The almost unlimited regenerative capacity of stem cells has a built-in danger. If a stem cell acquires the ability to proliferate excessively, it can go on to form a tumour. Indeed, many cancer researchers now suspect that rare stem cells within a tumour cause its inexorable growth. If tumour growth is maintained by stem cells, it will be essential to develop new forms of therapy that target these rare cancer stem cells rather than merely the bulk of the tumour cells. This is another key long-term goal of our program.Read moreRead less
Antigen Presentation, Recognition And The Immune Response
Funder
National Health and Medical Research Council
Funding Amount
$15,738,750.00
Summary
The early events in immunity require various molecular interactions. We will examine the structural and biophysical basis for some of these interactions, including those associated with transplant rejection and autoimmunity. We will explore the impact of variation in immune response genes on immune evasion and disease susceptibility. Our basic research will determine the mechanisms by which the immune system discriminates between different self and micro-organism associated determinants. We will ....The early events in immunity require various molecular interactions. We will examine the structural and biophysical basis for some of these interactions, including those associated with transplant rejection and autoimmunity. We will explore the impact of variation in immune response genes on immune evasion and disease susceptibility. Our basic research will determine the mechanisms by which the immune system discriminates between different self and micro-organism associated determinants. We will address the structural and biochemical basis for operation of an immune molecule called tapasin and unravel the basis for how some viruses escape the function of this molecule, thus allowing their immune evasion. We will also explore the use of modified small proteins called peptides in a humanized model of gluten hypersensitivity resembling that of Celiac disease. The molecular basis of the natural human immune system's capacity to recognise and reject grafts will be examined. This complements work aimed at improving the prediction of clinical graft rejection in transplantation. Dendritic cells play a central role in immunity, responsible for capturing material, whether from micro-organisms or self tissues, and presenting it to cells of the immune system. Our program will study the development and immunological function of the different dendritic cell subtypes. We will determine the relative contribution of each to the maintenance of immune tolerance and to the induction of immunity to several pathogens, including herpes simplex virus and malaria. Novel dendritic cell surface molecules that we have discovered will be tested for their ability to enhance the effectiveness of vaccines. Overall, this program utilises a broad array of immunological techniques designed to dissect the development and function of various immune system cell types and determine the structure-function relationships between important cell surface molecules involved in immunity.Read moreRead less