Prevention Of Autoimmune Diabetes By Immune Tolerance To Proinsulin
Funder
National Health and Medical Research Council
Funding Amount
$504,597.00
Summary
In type 1 diabetes, insulin is the first target of the immune system. Strategies to prevent the immune system targeting insulin in mice early in the disease process work, but it is not clear if such strategies would be effective if applied late. This is important because preventive therapies for human type 1 diabetes are currently feasible only late in the disease process. We aim to address this by removing T cells specific for insulin at different stages of the disease.
In Vivo Investigation Of Human PR3 Transgenic Mice: A Novel Animal Model To Understand The Role Of PR3 In Chronic Inflammation And Autoimmune Vasculitis
Funder
National Health and Medical Research Council
Funding Amount
$378,615.00
Summary
Granulomatosis with polyangiitis (GPA) is a form of vasculitis and is associated with antibodies directed against proteinase 3 (PR3). PR3 is expressed in neutrophils, monocytes and macrophages and has a number of well-characterized pro-inflammatory functions. The aim of this project is to understand the role of PR3 in inflammation and autoimmune vasculitis in vivo. This will be achieved using a transgenic mouse model expressing human PR3.
Understanding The Critical Mechanisms That Govern Regulatory T Cell Life And Death Decisions
Funder
National Health and Medical Research Council
Funding Amount
$338,811.00
Summary
Autoimmune diseases impose an increasingly large health burden. Treg cells prevents the immune system from attacking “self” offering the promise of using these cells to restore immune balance in autoimmune diseases. However, there are currently no protocols that reliably modify Treg cell numbers. This study will elucidate the mechanisms that govern Treg cell survival and death, revealing potential molecular targets to manipulate the quality and quantity of Treg cell for therapeutic benefit.
Mechanism Of Protection Of Islet Beta Cells From T1D By Heparan Sulfate
Funder
National Health and Medical Research Council
Funding Amount
$602,453.00
Summary
Type 1 diabetes (T1D) is an autoimmune disease which destroys the insulin-producing beta cells in the pancreas. Current insulin therapy does not prevent the development of serious secondary complications. We have discovered that beta cells require a complex sugar (heparan sulfate; HS) for their survival and that T1D is prevented when an enzyme, heparanase, that degrades HS is inhibited. Understanding these mechanisms will identify new therapeutic strategies for preventing T1D progression.
Antiphospholipid Antibodies, Beta 2-Glycoprotein I And Control Of Coagulation.
Funder
National Health and Medical Research Council
Funding Amount
$471,000.00
Summary
Antiphospholipid antibodies are associated with an autoimmune condition characterised by the presence of clots and recurrent miscarriages. Although the name implies that the antibodies bind phospholipid the disorder is characterised by circulating antibodies which bind a protein in the blood known as Beta 2-Glycoprotein I. The exact role of Beta 2-GPI in the body has not been determined, although there are numerous studies looking at this protein. This protein has been thought to be important in ....Antiphospholipid antibodies are associated with an autoimmune condition characterised by the presence of clots and recurrent miscarriages. Although the name implies that the antibodies bind phospholipid the disorder is characterised by circulating antibodies which bind a protein in the blood known as Beta 2-Glycoprotein I. The exact role of Beta 2-GPI in the body has not been determined, although there are numerous studies looking at this protein. This protein has been thought to be important in controlling the clotting system in humans and other mammals. The evidence for this has been contradictory, however, we have recently made a major new finding on the function of this protein on the clotting system. We will be using sophisticated molecular biology techniques to further characterise the role that Beta 2-GPI has in controlling clotting factors in the body. We have been able to eliminate the gene for Beta 2-GPI in mice thus deriving mice that do not produce any Beta 2-GPI protein. These mice are called Beta 2-GPI knockout mice and will be an ideal animal model to examine the function of Beta 2-GPI and its new role in controlling the clotting cascade by targetting a specific part of this pathway. In addition, these findings may be able to provide new information on how Beta 2-GPI controls clotting factors and the effect of antiphospholipid antibodies on this system, which may lead to new treatments for antiphospholipid antibodies and more generally clotting disorders.Read moreRead less
Translational Study Of The Genetics Of Systemic Autoimmunity Based On Mouse Mutagenesis
Funder
National Health and Medical Research Council
Funding Amount
$518,500.00
Summary
Lupus is the prototypic autoimmune disease. It is characterised by inflammation that can damage virtually any organ in the body. This inflammation is the outcome of a complex interplay between the environment and genetic predisposition, resulting in production of antibodies against components of normal tissue. Better characterisation of the genetic basis of lupus is a priority because it is the single best path towards a clearer understanding of the mechanism of this debilitating disease, and ul ....Lupus is the prototypic autoimmune disease. It is characterised by inflammation that can damage virtually any organ in the body. This inflammation is the outcome of a complex interplay between the environment and genetic predisposition, resulting in production of antibodies against components of normal tissue. Better characterisation of the genetic basis of lupus is a priority because it is the single best path towards a clearer understanding of the mechanism of this debilitating disease, and ultimately, new therapeutic options. Strategies used to identify the genetic basis of human disease fall into two categories. The first involves gathering genetic information from families with more than one affected member, which is then compared with genetic information from unaffected people. This can identify genetic regions likely to contain disease-causing genes, but so far, this approach has met with limited success in lupus. Although regions of the genome that harbour disease-associated genes have been found, few actual disease causing genes have been confirmed. The second approach begins with known genes that might plausibly cause the disease, based on prior knowledge then tests are performed to see whether particular variants of these genes are more common in patients than in healthy controls. Obviously this approach is usually biased towards investigation of candidate genes that are already well-characterised. In this project, we will combine information obtained from a large-scale mouse-based programme in which genetic changes that cause features of lupus are generated randomly. In other words, there is an unbiased search for candidate genes, which should lead to the discovery of new disease pathways. Since the mouse and human immune systems are remarkably similar, genetic abnormalities that cause features of lupus in mice are highly likely to be informative about the genetic basis of human lupus, a hypothesis we will test with genetic studies in humans with lupus.Read moreRead less
Defining The Cellular And Molecular Mechanisms Underlying Autoimmunity Using A Model Of SLE
Funder
National Health and Medical Research Council
Funding Amount
$624,960.00
Summary
The immune system has to recognize the difference between foreign pathogens, which it should attack, and ourselves, which it should not. Autoimmune diseases, like lupus, occur when our immune systems attack our own tissues due to problems in regulation. We have developed an animal model of lupus that has allowed us to identify major points where immune regulation has failed. Identifying these checkpoints will allow us to design and trial novel therapeutics in lupus.
Identifying The Underlying Mechanisms Responsible For The Generation Of Pathogenic B Cells In Type 1 Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$163,755.00
Summary
Type 1 diabetes (T1D) occurs when the body's own immune system mistakenly attacks and destroys all the beta cells of the pancreas which produce insulin, a hormone essential for regulating sugar levels in the blood. The non-obese diabetic (NOD) mouse develops a form of T1D closely resembling the human disease, and as a model, has led to numerous important insights into its cause. Based on studies in NOD mice, it is now well accepted that a class of cell in the immune system, termed T cells, are r ....Type 1 diabetes (T1D) occurs when the body's own immune system mistakenly attacks and destroys all the beta cells of the pancreas which produce insulin, a hormone essential for regulating sugar levels in the blood. The non-obese diabetic (NOD) mouse develops a form of T1D closely resembling the human disease, and as a model, has led to numerous important insights into its cause. Based on studies in NOD mice, it is now well accepted that a class of cell in the immune system, termed T cells, are responsible for most of the damage to the beta cells in T1D. Recent work in this model, however, has demonstrated that another class of immune cell, termed B cells, also play an important role in T1D as NOD mice made deficient in these cells no longer develop disease. In addition to producing antibodies, B cells are one of the few cell types which are able to take up and present protein fragments in a form recognizable to T cells. Normally, this only leads to the activation of T cells recognising foreign insults, like viruses or bacteria, resulting in their destruction. We have shown that a dangerous population of B cells can arise in NOD mice that can specifically take up beta cell proteins and present them to the T cells, which subsequently become armed to recognise and destroy the beta cells. Just like T cells, B cells that recognize the body's own proteins are normally eliminated in healthy mice and human individuals. This research proposal aims to determine the faulty immune mechanisms that give rise to the beta cell specific B cells in NOD mice. We have also set out to identify the diabetes susceptibility genes which control the generation of this dangerous population of B cells in this model. By understanding how these dangerous B cells are generated in NOD mice, we hope to form the basis for new therapies aimed at inhibiting these cells from forming in T1D susceptible humans, thus preventing the disease at an early stage.Read moreRead less
How Does Genetic Variation For Trig Affect Autoimmune Responses Mediated By Toll-like Receptors?
Funder
National Health and Medical Research Council
Funding Amount
$671,114.00
Summary
Juvenile diabetes is an autoimmune disease that affects more than 120,000 Australians. We have recently discovered a novel gene, named Trig, in a genetic study of mice that develop juvenile diabetes similar to children. This research proposal aims to determine the function of Trig in the immune system and how it contributes to the development of autoimmune diseases, such as juvenile diabetes.