Helminth Secreted Proteins – From Anthelmintic Vaccines To Therapies For Autoimmunity
Funder
National Health and Medical Research Council
Funding Amount
$739,893.00
Summary
Human helminths (worms) cause chronic disease in developing countries, yet their disappearance from developed countries has been accompanied by an increase in the prevalence of autoimmune and allergic diseases. My resesarch focuses on the proteins these worms secrete and their use in (1) the development of anthelmintic vaccines, and (2) the development of novel anti-inflammatory molecules to treat autoimmunity, particularly diseases affecting the gut.
Regulation Of Leukocyte Trafficking By Macrophage Migration Inhibitory Factor (MIF).
Funder
National Health and Medical Research Council
Funding Amount
$239,250.00
Summary
The entry of white blood cells in to tissues is a primary event which drives tissue and organ damage in a number of inflammatory and immune mediated conditions. Diseases as diverse as rheumatoid arthritis, lupus or shock due to bacterial infection (septic shock) have many different triggers and manifestations. However almost all autoimmune and inflammatory diseases have one common feature: white blood cells must leave the blood and enter tissue in order to cause tissue inflammation and ultimatel ....The entry of white blood cells in to tissues is a primary event which drives tissue and organ damage in a number of inflammatory and immune mediated conditions. Diseases as diverse as rheumatoid arthritis, lupus or shock due to bacterial infection (septic shock) have many different triggers and manifestations. However almost all autoimmune and inflammatory diseases have one common feature: white blood cells must leave the blood and enter tissue in order to cause tissue inflammation and ultimately tissue damage and loss of function. The mechanism whereby white blood cells leave the blood stream and cross blood vessel walls to get into tissues is a multi-step process often referred to as white blood cell trafficking. Most of the current treatments for immune and inflammatory conditions have the primary aim of keeping white blood cells out of tissue in order to prevent damage. Some of these treatments, like steroids (cortisone), are very effective but cannot be used for prolonged periods because of the risk of problems like bone thinning (osteoporosis), high blood pressure or diabetes. Other treatments and immunosuppressive agents can also be effective but are themselves associated with toxicity and risk of organ damage. Although substantial progress has been made in the management of immune and inflammatory conditions in the last 50 years, the current treatment options are far from ideal. Macrophage migration inhibitory factor (MIF) is an inflammatory substance released by cells which comprise the blood vessel wall as well as by white blood cells themselves. It is known to contribute to the build up of white blood cells in inflamed tissue. The effect of MIF on white blood cell trafficking has never been examined. Understanding how MIF promotes white cell entry in to tissues could be crucial in our understanding of this important process and blocking MIF may prove to be a useful and effective way to prevent it.Read moreRead less
A Novel Role For The IL-2 Pathway In Type-1-diabetes.
Funder
National Health and Medical Research Council
Funding Amount
$548,548.00
Summary
Genes encoding IL-2 and its receptor are strongly linked to susceptibility to multiple autoimmune diseases, including type-1-diabetes. Despite the importance of this pathway in the immune system, it is not yet understood how the associated genes affect disease. In this study, a novel function for IL-2 expression by dendritic cells in normal self-tolerance is investigated. The impacts of dendritic cell produced IL-2 expression and linkage to autoimmunity will be elucidated in both mouse and man.
The Generation And Function Of Tissue-specific Regulatory T Cells
Funder
National Health and Medical Research Council
Funding Amount
$488,577.00
Summary
The immune system normally protects against invasion by pathogens such as harmful viruses and bacteria. In autoimmune diseases the same mechanisms that are used to protect us are erroneously targeted to our own tissues. We will discover how regulatory lymphocytes, are able to protect against autoimmune disease. Such regulatory lymphocytes are attractive therapeutic agents to prevent a variety of immune-mediated diseases, including autoimmune diseases, allergy and transplantation rejection.
An Autoantibody In Type 1 Diabetes That Mediates Autonomic Complications
Funder
National Health and Medical Research Council
Funding Amount
$254,591.00
Summary
Type 1 diabetes is a chronic autoimmune disease characterised by destruction of insulin producing cells in the pancreas. One of the most common and serious complications of type 1 diabetes is disruption of the autoimmune nervous system, and once symptoms appear the 5-year mortalityrate is approximately 50%. Symptoms of autonomic dysfunction can be extensive, and involve the stomach, intestine, bladder, heart and reproductive organs. Currently, the management of autonomic dysfunction remains prim ....Type 1 diabetes is a chronic autoimmune disease characterised by destruction of insulin producing cells in the pancreas. One of the most common and serious complications of type 1 diabetes is disruption of the autoimmune nervous system, and once symptoms appear the 5-year mortalityrate is approximately 50%. Symptoms of autonomic dysfunction can be extensive, and involve the stomach, intestine, bladder, heart and reproductive organs. Currently, the management of autonomic dysfunction remains primative due to our poor understanding of the mechanisms underlaying the disease. Recent work from our group has identified an excitatory autoantibody (an antibody against the self) to calcium channels in patients with type 1 diabetes. The anti-calcium channel autoantibody profoundly disrupts gut and bladder function by interfering with autonomic regulation of smooth muscle within these organs. The anti-calcium channel autoantibody is the first functional autoantibody to be detected in type 1 diabetes, and represents a conceptual advance in our understanding of immune mechanisms in this disease. Using animal models and a panel of novel, functional assays of colon, stomach and bladder we will investigate how the anti-calcium channel autoantibodies contribute to autonomic dysfunction in type 1 diabetes. Understanding the mechanisms by which this autoantibody effects autonomic regulation of organ function will enable the development of new therapeutic strategies for better management of patients.Read moreRead less
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
Organ-specific Autoimmunity: The Role Of The Thymus And Periphery In Shaping The Gastric-specific T Cell Repertoire
Funder
National Health and Medical Research Council
Funding Amount
$579,763.00
Summary
The immune system normally protects against invasion by pathogens such as harmful viruses and bacteria. In autoimmune diseases the same mechanisms that are used to protect us are erroneously targeted to our own tissues. White blood cells, called T lymphocytes are responsible for attacking our own tissues in autoimmune diseases. Our studies will employ a range of molecular, genetic and imaging technologies to track the rare and potential harmful white blood cells. Our studies should reveal the me ....The immune system normally protects against invasion by pathogens such as harmful viruses and bacteria. In autoimmune diseases the same mechanisms that are used to protect us are erroneously targeted to our own tissues. White blood cells, called T lymphocytes are responsible for attacking our own tissues in autoimmune diseases. Our studies will employ a range of molecular, genetic and imaging technologies to track the rare and potential harmful white blood cells. Our studies should reveal the mechanisms by which these self destructive T lymphocytes are silenced in healthy individuals on the one hand, and on the other hand escape to cause destruction in individuals with autoimmune diseases. This fundamental information will allow the development of therapeutic strategies to selectively turn-off these destructive T lymphoctyes in individuals with autoimmune disease and thereby remove the damaging immune response and cure the disease.Read moreRead less
Immunopathogenesis Of Organ-specific Autoimmune Disease
Funder
National Health and Medical Research Council
Funding Amount
$284,638.00
Summary
The immune system normally protects against invasion by pathogens such as harmful viruses and bacteria. In autoimmune diseases the same mechanisms that are used to protect us are erroneously targeted to our own tissues. Our studies will employ state-of-the art technologies to further our knowledge of this class of diseases and to uncover the normal mechanisms that allow the immune system to differentiate foreign and self components.