Inflammatory diseases, such as autoimmune diseases, result from an overactive immune system. A new therapy that is currently under trial is the use of special blood cells, called Treg cells, whose function is to suppress unwanted immune responses. This application evaluates the efficacy and safety of such treatments.
Understanding The Pathogenesis And Heterogeneity Of Autoimmunity As Failure Of Multiple Steps
Funder
National Health and Medical Research Council
Funding Amount
$504,023.00
Summary
Autoimmune diseases like diabetes, thyroid disease or rheumatoid arthritis affect around 1 in 15 people in Australia. It is clear that defects in a number of different genetic mechanisms can contribute to the development of autoimmunity. But it is currently not clear how these different mechanisms need to interact to prevent the onset of disease. This grant seeks to understand these interactions and how defects in two or more tolerance mechanisms can lead to autoimmunity.
Thymic Epithelial Cell Apoptosis, Aire And Autoimmune Disease.
Funder
National Health and Medical Research Council
Funding Amount
$470,799.00
Summary
Autoimmune diseases, like diabetes and multiple sclerosis are a significant disease burden. Their root cause is the failure of the immune system to distinguish between the body's own tissues and potential pathogens. We propose to study how potentially dangerous immune cells are destroyed in the thymus before they can develop. This research will significantly improve our understanding of how autoimmune diseases begin.
De Novo Mutations And The Pathogenesis Of Childhood-onset Autoimmune Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,406,510.00
Summary
This project aims to reveal the gene abnormalities that cause devastating autoimmune diseases to develop in some children, such as Type 1 diabetes, juvenile arthritis and autoimmune destruction of blood cells. The project will use new technologies to identify alterations in the DNA sequence of a child compared to either of their parents, and to test suspicious DNA alterations in laboratory mice in order to understand the gene effects and evaluate new treatments.
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
The Molecular Determinants Of Immunological Tolerance
Funder
National Health and Medical Research Council
Funding Amount
$473,477.00
Summary
Autoimmune diseases, such as type I diabetes and multiple sclerosis, are debilitating disorders that impose a massive toll on wellbeing in Australia and worldwide. This fellowship will support research aimed at determining the genes and mechanisms that control autoimmunity. New technologies will be brought to bear to track immune cells throughout their development, maturity and malfunction in disease settings. We aim to uncover new therapeutic targets to prevent and reverse autoimmune disease.
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.