Induction Of Natural T-Regulatory Cells By Thymic Dendritic Cell Populations
Funder
National Health and Medical Research Council
Funding Amount
$413,775.00
Summary
In this study, we will determine the roles of the antigen presenting cells, namely denderitic cells, in the induction of T-regulatory cell (T-reg) developemnt in the thymus. T-reg cells play important roles in controlling the development of autoimmunity. This study will help to understand the possible causes of autoimmune diseases and to develop new treatments for these diseases.
The aim of this project is to develop mathematical models and computer software capable of predicting immune responses to infection and disease. This “artificial immune system” should lead to improved vaccine design and better understanding of what causes the immune system to attack its own body, causing autoimmune disease, or fail to respond, causing immunodeficiency. This enabling science could then lead to improvements in treatment for a range of conditions of clinical importance.
Tolerance Induction By Antigen-presenting Cell-targeted Antigen
Funder
National Health and Medical Research Council
Funding Amount
$420,872.00
Summary
We have found that by ‘targeting’ antigen to the cells that ‘train’ the immune system we have been able to prevent the development of autoimmune disease. In the research proposed here we aim to develop new ways in which antigens can be targeted to these cells so that this approach can be applied clinically. The proposed studies will also determine how antigens targeted in this way restore self-tolerance and prevent autoimmune disease.
Regulation Of Monocyte And Macrophage Functions By Leucocyte Immunoglobulin-like Receptors (LILRs) In Human Colon
Funder
National Health and Medical Research Council
Funding Amount
$295,983.00
Summary
The human colon contains many bacteria that can invade through a damaged mucosal barrier and provoke immune cells to cause inflammation with their subsequent removal and a rapid shutdown of inflammation. Failure to clear bacteria or inflammation can lead to inflammatory bowel disease or sepsis. We will investigate how new proteins known as Leucocyte Immunoglobulin-like Receptors allow immune cells to effectively clear microorganisms without provoking uncontrolled inflammation
The Role Of The Dendritic Cell Surface Molecule Clec9A In Dendritic Cell Subset Function And Dead Cell Recognition
Funder
National Health and Medical Research Council
Funding Amount
$526,878.00
Summary
Dendritic cells (DC) are sentinels of the immune system. DC monitor the environment and regulate tolerance to self versus immunity to dangerous material. Different types of DC perform different jobs. We have identified a new surface molecule, Clec9A, on some mouse and human DC. We will investigate the function of Clec9A in the immune response. We will also use Clec9A to help unite mouse and human DC biology, since until now there have been few useful marker molecules common to both species.
“Killer T cells” are specialised cells that help control viral infection. T cells recognize virus via proteins called “T cell receptors” (TCR). TCR are incredibly diverse, allowing us to recognise many different viruses. Recent advances in technology allow us to look at TCR and the genes encoding them, however their complexity makes that data difficult to interpret. I will use mathematical and statistical approaches to analyse and model this data to better understand immune recognition.
This program application seeks to draw on the skills of a world leading group of Australian researchers to bring novel HIV vaccine designs to clinical trials, improve vaccine design and create new opportunities for commercialisation. The Chief Investigators, Prof David Cooper, Prof Peter Doherty (Nobel Prize winner), A-Prof Stephen Kent and Prof Ian Ramshaw, have achieved major scientific developments including: innovative collaborative clinical trials, cutting edge research in T cell immunology ....This program application seeks to draw on the skills of a world leading group of Australian researchers to bring novel HIV vaccine designs to clinical trials, improve vaccine design and create new opportunities for commercialisation. The Chief Investigators, Prof David Cooper, Prof Peter Doherty (Nobel Prize winner), A-Prof Stephen Kent and Prof Ian Ramshaw, have achieved major scientific developments including: innovative collaborative clinical trials, cutting edge research in T cell immunology, the establishment of the only PC3-level nonhuman primate facility in the Southern hemisphere, T cell immunogenicity of the DNA-viral vector prime-boost vaccine regimens and ground-breaking research on cytokine co-expressing viral vector vaccines. The Principle Investigators also have a record of substantial achievement in relation to HIV and T cell biology as well as novel vaccination technologies. There is a strong history of successful collaboration among this group leading to the award of major NIH funding.Read moreRead less
The Investigation Of Immune Function In Mice Deficient In RNA-binding Molecules.
Funder
National Health and Medical Research Council
Funding Amount
$419,737.00
Summary
Our immune system is delicately balanced between fighting off bugs and destroying infected cells yet protecting healthy cells within the body. The ways in which the immune system responds to attack is regulated by certain genes within the body. This project is focussing on cutting edge research that describes a newly identified way of fine-tuning the immune system. We are studying RNA-binding molecules that can bind to and block genes involved in immune function.
Immune Regulation During Uncomplicated And Severe P. Falciparum And P. Vivax Malaria
Funder
National Health and Medical Research Council
Funding Amount
$292,639.00
Summary
Malaria is a major global disease that kills over 1 million people every year. Immune responses induced during infection help fight the infection but can also cause tissue damage and thereby worsen disease. This study will determine differences in cellular immune responses during uncomplicated and severe malaria. Better understanding of the role of immune cells in response to infection and disease progression will assist the development of novel treatment interventions and vaccine development.