Glomerulonephritis (Bright's Disease) is the commonest cause of destruction of kidney function that leads to patients requiring artificial kidney treatment (dialysis) and renal transplantation. The glomeruli or filters of the kidney are attacked by inflammation and destroyed. The attack is usually auto-immune, that is the bodys' immune system loses tolerance to kidney tissue and mounts a destructive attack on the glomeruli. In many patients, this attack is mild and resolves with current treatmen ....Glomerulonephritis (Bright's Disease) is the commonest cause of destruction of kidney function that leads to patients requiring artificial kidney treatment (dialysis) and renal transplantation. The glomeruli or filters of the kidney are attacked by inflammation and destroyed. The attack is usually auto-immune, that is the bodys' immune system loses tolerance to kidney tissue and mounts a destructive attack on the glomeruli. In many patients, this attack is mild and resolves with current treatments to dampen the immune response. In others, current treatment is inadequate to dampen the attack and the kidney is destroyed. This research uses experimental models of nephritis to examine how the immune system injures the glomeruli. In particular, how T cells attack and mediate injury. This is a novel concept, as hither to it has been thought antibodies and other factors in the blood (complement) mediate injury. Our group was one of the first to identify T cells mediate injury in forms of glomerulonephritis, previously thought to be solely mediated by antibody and complement. This project will further define which molecules produced by the T cell effect injury of glomeruli. With the potential aim of turning off the T cell attack mechanisms in a more specific way than is achieved by non specific immunosuppressive drugs such as corticosteroids, cytotoxic (anti-cancer) drugs or cyclosporine (an anti-rejection drug). A major part of this project will be to examine the role of cytokines, hormone like molecules that are produced by white cells and mediate injury or regulate other white cells, in effecting injury and in turning off the immune injury.Read moreRead less
Molecular Diagnosis And Therapy Of Autoimmune Disease Using Translational And Reverse Translational Approaches
Funder
National Health and Medical Research Council
Funding Amount
$2,331,372.00
Summary
We plan to translate our recent discoveries on human gene variants and molecules produced by immune cells (follicular T cells) into effective therapies for autoimmune diseases. This will involve understanding the mechanisms by which the genes and molecules regulate immune tolerance, stratifying patients with autoimmune disease using newly identified biomarkers, trialling existing biologicals according to affected molecular pathway, and taking novel targets through to commercialisation.
Mechanisms Of Rapid Memory CD8+ T-cell Inactivation
Funder
National Health and Medical Research Council
Funding Amount
$318,517.00
Summary
Type 1 diabetes (T1D) and other autoimmune diseases results from misdirected immune responses that destroy normal body tissues. The ultimate goal of therapeutic strategies is to remove or inactivate the immune cells that attack normal tissues, while leaving other immune cells, for example, those required for protection from infectious diseases and tumours, unaffected. Here we propose to test a new way of turning off inappropriate immune reactions.
Novel Posttranscriptional Pathways The Control Tfh Cell Numbers
Funder
National Health and Medical Research Council
Funding Amount
$647,539.00
Summary
T follicular helper (Tfh) cells are essential for effective antibody responses against infection. Limiting Tfh cells is crucial for selecting the "fittest" B cells and the success of vaccines. Tfh cell accumulation causes autoimmuity and is associated with inadequate B cell responses in HIV infection. We have recently discovered two novel pathways that control Tfh cells. We speculate they regulate different RNAs that influence Tfh homeostasis and aim to elucidate their mechanism of action.
Cancer is one of the leading causes of death in the industrialized world. While therapies to treat cancer have continued to improve one area that, in theory at least, shows great promise in the treatment of tumours is manipulating the immune system to effectively recognize and destroy cancerous lesions. Experiments in human and animal systems have clearly shown that the immune system has the potential to respond to tumour cells and trials of tumour vaccines are underway. It has recently become a ....Cancer is one of the leading causes of death in the industrialized world. While therapies to treat cancer have continued to improve one area that, in theory at least, shows great promise in the treatment of tumours is manipulating the immune system to effectively recognize and destroy cancerous lesions. Experiments in human and animal systems have clearly shown that the immune system has the potential to respond to tumour cells and trials of tumour vaccines are underway. It has recently become apparent that the immune responses to tumours may be inhibited by classes of regulatory immune cells. Eliminating these cells results in a more vigorous and effective anti-tumour response. This project will seek to discover the mechanisms of action of theses regulatory immune cells in order to devise more effective anti-cancer vaccines and therapies.Read moreRead less
Our bodies rely on the production of potent, or ‘high affinity’, antibodies to fight infection. We have found that antibody responses are unexpectedly boosted following the depletion of a specific subset of immune cells. This is especially true for B cells that are poor antibody producers. Our findings are likely to be relevant to (1) the design of vaccines to infectious agents that have important CTL and antibody components (e.g. HIV), (2) for the improved production of antibody for therapeutic ....Our bodies rely on the production of potent, or ‘high affinity’, antibodies to fight infection. We have found that antibody responses are unexpectedly boosted following the depletion of a specific subset of immune cells. This is especially true for B cells that are poor antibody producers. Our findings are likely to be relevant to (1) the design of vaccines to infectious agents that have important CTL and antibody components (e.g. HIV), (2) for the improved production of antibody for therapeutic use (e.g. cancer).Read moreRead less
T cells are a central component of the immune system and without T cells the body is very vulnerable to infections. One subgroup of T cells is the killer T cells that are important for identifying and killing cells infected by viruses and bacteria. The immune system works to maintain T cell numbers at a fairly constant level and part of this process includes sending signals to the killer T cells from other cells via cell surface protein interactions and soluble mediators, such as cytokines. We h ....T cells are a central component of the immune system and without T cells the body is very vulnerable to infections. One subgroup of T cells is the killer T cells that are important for identifying and killing cells infected by viruses and bacteria. The immune system works to maintain T cell numbers at a fairly constant level and part of this process includes sending signals to the killer T cells from other cells via cell surface protein interactions and soluble mediators, such as cytokines. We have been studying killer T cells, which are missing a protein SOCS1. SOCS1 is important for switching off the signals generated by a group of cytokines. As a consequence of being unable to correctly regulate cytokine signals these killer T cells multiply inappropriately and contribute to disease development. Our current work is aimed at achieving a better understanding of the particular interactions between killer T cells and other immune system cells and the soluble factors that deliver important signals for maintaining killer T cells in the immune system. The ability to better understand the factors controlling the maintenance of killer T cells will enable us to more intelligently target the immune system ,which is important for improving vaccine strategies and cancer immunotherapy as well as for controlling T cells that are activated inappropriately, such as in autoimmune disease.Read moreRead less