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.
The Role Of NF-?B Transcription Factor RelA In Regulatory T Cell Homeostasis And Function
Funder
National Health and Medical Research Council
Funding Amount
$637,114.00
Summary
Treg cells constitute an immune regulatory cell population that is essential for the prevention of fatal autoimmunity; however, they also limit immunity against cancer. We have discovered that the factor RelA is of critical importance for Treg development and function. We now aim to illuminate the functions of RelA in detail. Understanding the molecules that impact on Treg cell biology is critical to harness their potential for clinical intervention such as treatment of autoimmunity and cancer.
How Does Disruption Of Serinc1 Expression Affect Lymphocyte Function And The Development Of Autoimmunity?
Funder
National Health and Medical Research Council
Funding Amount
$681,555.00
Summary
Autoimmune diseases affect up to 8% of the population. We have recently discovered a novel gene mutation in mice that results in increased levels of anti-nuclear antibodies, a hallmark of various autoimmune diseases in humans. The mutated gene, Serinc1, has not been previously implicated in autoimmune disease, but it is important for synthesis of key molecules in immune cells. This research proposal aims to determine how disruption of Serinc1 contributes to the development of autoimmune disease.
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 Role Of Interleukin-21 In The Pathogenesis Of Autoimmune Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$519,000.00
Summary
T cells are a component of our blood (white blood cells) and a major component of the body's defense system against infection, known as immunity. Without T cells, we would fail to resist infection by foreign agents, such as viruses, bacteria and fungi. Autoimmune (type 1) diabetes is a disease in which T cells attack our own pancreatic islet self tissues as if they were foreign. T cells that react against the islets of the pancreas cause destruction of the insulin producing beta cells so that th ....T cells are a component of our blood (white blood cells) and a major component of the body's defense system against infection, known as immunity. Without T cells, we would fail to resist infection by foreign agents, such as viruses, bacteria and fungi. Autoimmune (type 1) diabetes is a disease in which T cells attack our own pancreatic islet self tissues as if they were foreign. T cells that react against the islets of the pancreas cause destruction of the insulin producing beta cells so that the pancreas can no longer make insulin. Diabetes is a life-threatening disease because insulin is a hormone that enables people to get energy from food. Type 1 diabetes is usually diagnosed in childhood and insulin must be administered daily by injection or through a pump in order to survive. Unfortunately, taking insulin doesn t cure diabetes and people continue to suffer from an extensive list of complications affecting most vital organs. Interleukin-21 (IL-21) is a soluble protein that is produced by cells enabling them to communicate with other cells. IL-21 helps cells to produce factors that cause inflammation and assist in clearance of viruses and bacteria from the body. However, our studies show that IL-21 is a major factor in the development of the T cells that destroy beta cells and cause diabetes. Our studies show that IL-21 is over-expressed in an important murine model of spontaneous type-1 diabetes. We have isolated the T cells that cause diabetes and show that they are distinguished from other T cells by very high levels of the receptor for IL-21. This project focuses on the IL-21-responsive T cells that cause diabetes and aims to determine the mechanisms by which the cytokine IL-21 causes destructive immune responses and ways to modulate its production. This project applies basic science to the important public health issue of type 1 diabetes for the development of therapeutic intervention strategies.Read moreRead less
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.
How Deletional And Non-Deletional Tolerance Mechanisms Integrate To Prevent Autoimmune Disease
Funder
National Health and Medical Research Council
Funding Amount
$509,944.00
Summary
The body produces millions of immune cells every day to fight infection. Some of these immune cells are defective and dangerous because they can cause autoimmune diseases, like Type I diabetes and multiple sclerosis. To defuse this risk, such immune cells are either caused to die or are inactivated to prevent autoimmunity. We propose to investigate how the processes of immune cell death and inactivation work in health and disease so we may harness these mechanisms to cure autoimmunity.