Identification of novel markers of inflammation. This project will benefit Australia as it will increase basic understanding of inflammatory processes, result in a new generation of diagnostics for inflammatory diseases that could lead to earlier diagnosis and to monitor treatment, resulting in large economic and health benefit. It may lead to development of novel new therapies using monoclonal antibodies to regulate processes in immune, cardiovascular and infectious diseases. The work will gene ....Identification of novel markers of inflammation. This project will benefit Australia as it will increase basic understanding of inflammatory processes, result in a new generation of diagnostics for inflammatory diseases that could lead to earlier diagnosis and to monitor treatment, resulting in large economic and health benefit. It may lead to development of novel new therapies using monoclonal antibodies to regulate processes in immune, cardiovascular and infectious diseases. The work will generate significant economic spin-offs to the Australian biotechnology industry and will further relationships and training between research and development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453839
Funder
Australian Research Council
Funding Amount
$386,892.00
Summary
Adelaide Core Laser Capture Microscopy Facility. Laser Capture Microscopy represents a powerful and essential tool in many aspects of modern cell and molecular biology. Although the applications for these machines are very broad, overall the technology can be viewed as allowing collection of rare cells (or objects as small as bacteria and organelles) from complex tissues and cells. This proposal concerns infrastructure funding to obtain a state-of-the-art core Laser Capture Microscope facility ....Adelaide Core Laser Capture Microscopy Facility. Laser Capture Microscopy represents a powerful and essential tool in many aspects of modern cell and molecular biology. Although the applications for these machines are very broad, overall the technology can be viewed as allowing collection of rare cells (or objects as small as bacteria and organelles) from complex tissues and cells. This proposal concerns infrastructure funding to obtain a state-of-the-art core Laser Capture Microscope facility in Adelaide that will significantly enhance scientific progress in a diverse range of areas including functional genomics of animal, plant and prokaryotic cells.Read moreRead less
The Role Of C-Cbl In The Regulation Of T Cell Signalling And Development
Funder
National Health and Medical Research Council
Funding Amount
$527,250.00
Summary
c-Cbl is a member of a multi-adaptor protein family that can interact with many signalling proteins via its different domains. Cbl proteins have been implicated as negative regulators of signalling pathways involving protein tyrosine kinases (PTKs). PTKs are enzymes which add phosphate groups to tyrosine residues on other protein substrates, and the process of tyrosine phosphorylation acts as a potent biochemical switch to turn signalling cascades on and off. Studies of Cbl-deficient (knockout) ....c-Cbl is a member of a multi-adaptor protein family that can interact with many signalling proteins via its different domains. Cbl proteins have been implicated as negative regulators of signalling pathways involving protein tyrosine kinases (PTKs). PTKs are enzymes which add phosphate groups to tyrosine residues on other protein substrates, and the process of tyrosine phosphorylation acts as a potent biochemical switch to turn signalling cascades on and off. Studies of Cbl-deficient (knockout) mice show that Cbl proteins are important in regulating the development of, and signalling by, cells of the immune system called T cells. c-Cbl knockout mice show greatly enhanced PTK-signalling responses and deregulated activity of a PTK called ZAP-70. The mechanism of this is not known, but analysis of a c-Cbl mutant mouse shows that this is not dependent on the tyrosine kinase binding (TKB) domain of c-Cbl. Therefore other functional domains of Cbl must be responsible for the increased signalling response in the c-Cbl knockout mouse. One candidate is the highly conserved RING finger domain which can modify Cbl-associated PTKs by addition of ubiquitin molecules. Ubiquitination of a protein often, but not always, leads to its degradation, and this could be how Cbl controls the strength and duration of signalling in T cells. However there may be other functions of the conserved RING finger yet to be identified. c-Cbl itself is prominently and very rapidly modified by tyrosine phosphorylation on tyrosine 737 by the Fyn PTK following T cell activation, but the role of this modification is not known and could also be essential for c-Cbl s function in T cells. We plan to investigate the roles of the RING finger domain and Fyn-mediated tyrosine phosphorylation in c-Cbl regulation of T cell signalling by analyzing knock-in mice that carry specific mutations disrupting the RING finger or tyrosine 737 in the c-Cbl gene.Read moreRead less
Systematically Exploring The Contribution Of Immunoproteasome To Immunodominance And T Cell Function
Funder
National Health and Medical Research Council
Funding Amount
$499,860.00
Summary
Vaccine will help us to fight both infectious diseases and malignancy. However, there are few successful vaccines for infectious agents and there is simply no vaccine to cure any tumor at the moment. So, it is essential for us to learn the basics related to vaccine development. Killer T cells eliminate tumour cells or virally infected host cells by recognising fragments (epitopes) derived from tumour- or virus-derived proteins displayed on a host molecule called MHC. Normally multiple epitopes a ....Vaccine will help us to fight both infectious diseases and malignancy. However, there are few successful vaccines for infectious agents and there is simply no vaccine to cure any tumor at the moment. So, it is essential for us to learn the basics related to vaccine development. Killer T cells eliminate tumour cells or virally infected host cells by recognising fragments (epitopes) derived from tumour- or virus-derived proteins displayed on a host molecule called MHC. Normally multiple epitopes are generated as part of the protein recycling program referred as proteine degradation which is mainly conducted by bundled enzyme complex, called proteasome. Two major forms of proteasomes are expressed by most cells. One called house-keeping proteasome and the other, which replaces the house-keeping one during viral infections is called immunoproteasome. The role that the immunoproteasome plays during anti-viral and anti-tumoral immune responses is not fully understood. In addition, the immunoproteasome is also expressed by a few cell types that do not suppose to need it if its function is entirely to generate better epitopes for MHC to display. In this project, we will sytematically explore the contribution of the immunoproteasome to overall anti-viral and anti-tumoral immune responses in three mouse model systems. The shared feature of these systems is that multiple killer T cell epitopes have been defined, which could potentially provide us with very sensitive assessments. The three systems are anti-influenza, anti-vaccinia virus and anti-tumor antigen (NY-ESO-1) mouse models.Read moreRead less
MAIT cells are a recently discovered type of lymphocyte that plays a unique and important role in the immune system. However, these cells vary widely in number between healthy individuals, for reasons that are unclear. This project is designed to understand the factors that control the development of MAIT cells as a step toward regulating their numbers and activity.
Role Of The CD8-Heparan Sulfate Interaction In CD8+ T Cell Development And Function
Funder
National Health and Medical Research Council
Funding Amount
$649,135.00
Summary
The immune system can recognise a large array of foreign pathogens without reacting to self-components. For this to occur T cells, the main mediators of immunity, must be made to tolerate self-molecules as they develop in the thymus. We have identified a novel interaction between a molecule called CD8 on T cells and a complex carbohydrate called heparan-sulfate, which helps auto-reactive T cells to be eliminates in the thymus. The aim of this project is to further investigate this phenomenon.
The Mechanisms Of Epithelial Cell Survival That Govern Thymus Function
Funder
National Health and Medical Research Council
Funding Amount
$620,967.00
Summary
The thymus is an organ dedicated to the production of crucial immune cells, called T lymphocytes. Cancer treatments, such as radiation or chemotherapy, destroy thymic function and impair immune recovery in patients. We aim to uncover molecular processes that govern the life and death decisions of cells in the thymus. Our goal is to then use this information to develop treatments to protect this critical organ from damage and improve immune recovery following radiation or chemotherapy.
T-follicular Helper Cell Subtypes That Induce Protective Anti-malaria Antibodies
Funder
National Health and Medical Research Council
Funding Amount
$431,000.00
Summary
Malaria causes significant disease burden globally. Currently there are no malarial vaccines that are suitable for widespread use. The development of effective vaccines is hampered by limited understanding of how the human immune system fights malaria. This project will use human samples collected to investigate how human blood cells activate the immune system to fight malaria. This research will identify avenues to improve the design of malaria vaccines in the future.
Characterization Of H. Pylori –specific CD4 T Cell Responses And The Evaluation Of The Basic Requirements For The Development Of An Effective Anti-H. Pylori Vaccine
Funder
National Health and Medical Research Council
Funding Amount
$313,161.00
Summary
H. pylori infect over half of the global population. Although infection results in asymptomatic gastritis in most cases 10 % develop gastric ulcers and cancer. Current vaccination strategies have failed to protect humans from infection. We aim to characterise the main immune cells involved in H. pylori infection, specifically the bacteria-specific CD4 T cells. We will then try to understand the basic requirements for a successful vaccine in order to develop new, improved anti-H. pylori vaccines.