The Control Of Autoimmunity Originating From Somatically Hypermutated B Cells
Funder
National Health and Medical Research Council
Funding Amount
$530,337.00
Summary
Our immune systems are capable of producing long-lived antibodies that can last a lifetime. Sometimes, this powerful process can however become abnormal and result in autoimmune diseases such as lupus. We have recently developed the first experimental mouse model that allows researchers to study this process in great detail. This funding will extend our initial observations by identifying the exact mechanisms by which important regulators of autoimmune disease act.
How BANK1 Pathway Defects In B Cells Cause Human Lupus
Funder
National Health and Medical Research Council
Funding Amount
$1,316,839.00
Summary
Autoimmune diseases affect 1 in 20 Australians and are incurable. To find effective therapies, we need to understand the genes that cause disease in humans. We have sequenced the entire genome of patients with an autoimmune disease and found several patients carrry two mutations in genes important for activation of B cells and shown these mutations cause disease. We plan to understand how these genes prevent autoimmunity, and to identify the best treatment for patients with these mutations.
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
Src Family Kinases: Regulation Of Phosphoinositol-3 Kinase Signaling And Autoimmune Disease Development.
Funder
National Health and Medical Research Council
Funding Amount
$526,683.00
Summary
The immune system has to be capable of responding to an unlimited array of pathogens, but at the same time remain unresponsive to, or tolerant of, self-antigens. A breakdown in the tolerance to self-antigens results in autoimmunity. Autoimmune disease includes more than 70 chronic disorders that affect about 1 in 20 people in the Western population. Improving our understanding of the mechanisms that underlie autoimmune disease is essential for the design of more successful treatments. The Lyn ty ....The immune system has to be capable of responding to an unlimited array of pathogens, but at the same time remain unresponsive to, or tolerant of, self-antigens. A breakdown in the tolerance to self-antigens results in autoimmunity. Autoimmune disease includes more than 70 chronic disorders that affect about 1 in 20 people in the Western population. Improving our understanding of the mechanisms that underlie autoimmune disease is essential for the design of more successful treatments. The Lyn tyrosine kinase is an enzyme that is found within blood cells. It participates in transmitting information across the cell membrane to turn off cellular responses. Studies in mutant mice have shown that Lyn is critically important for maintaining stability in the immune system. Mice that are unable to make Lyn protein (Lyn-deficient mice) as well as mice that express an activated form of the Lyn enzyme (Lyn-up mice) develop autoimmune disease with characteristics similar to the human autoimmune disease systemic erythematosus (SLE). These studies suggest that Lyn is an important severity gene in autoimmunity. The aim of this grant will be to identify Lyn-dependent signaling pathways that lead to autoimmune disease, with a major focus being on the lipid kinase pathway. We will use a combination of genetic and biochemical approaches to reveal critical genes and pathways. Cataloging the molecular changes related to alterations in Lyn activity will, we believe, provide insight into the genetic defects or signal perturbations underlying human autoimmune diseases. In this way, our study will aid in the diagnosis of human autoimmune diseases and uncover useful targets for more specific and effective treatments.Read moreRead less