Protecting Against Malaria Through Liver-resident Memory T Cells
Funder
National Health and Medical Research Council
Funding Amount
$1,196,853.00
Summary
We have shown that formation of liver-resident memory T cells (Trm), a newly discovered type of immune cells, can be induced by an innovative vaccination strategy called prime and trap for highly efficient protection against malaria in mice. Here, we will enhance prime and trap vaccination efficacy by defining the conditions that maximize liver Trm-mediated protection and will characterize simian and human liver Trm cells, paving the way to create the most efficient human malaria vaccine to date
Direct Characterisation Of Naive Epitope-specific T Cell Populations And Their Influence On Immune Responses
Funder
National Health and Medical Research Council
Funding Amount
$314,983.00
Summary
CytotoxicT cells (CTLs) recognize and remove virus infected cells. Both the number and the diversity of T cells involved in the response influence viral clearance. We plan to use a novel technology to directly analyze the numbers and diversity of such CTLs in mice prior to infection. This will clarify how characteristics of cell populations prior to infection define the immune response after infection. This is critical for vaccine design to maximize the efficiency of the immune response.
Characterisation Of An Antigen Presenting Cell Unique To Spleen
Funder
National Health and Medical Research Council
Funding Amount
$420,606.00
Summary
The body depends on a range of defence mechanisms to remove invaders that enter by various routes. Antigen presenting cells are central to immunity in that they engulf and destroy dead cells and pathogens and present pieces of those pathogens or 'antigens' to white blood cells called T and B lymphocytes. These cells then start to fight the infection or disease. A new type of antigen presenting cell will be investigated for its particular ability to arrest blood-borne pathogens and disease.
Vaccines aim to protect against future infections by inducing memory in the immune system so that the host can react quickly to the next challenge. Defence against viral infections and some cancers depends in part on activating CD8+ T cells, a class of white blood cell that can recognise and kill infected or malignant cells. The ideal vaccines against these challenges would therefore generate high numbers of long-lived CD8+ T cells that are programmed to make the right response if the infection ....Vaccines aim to protect against future infections by inducing memory in the immune system so that the host can react quickly to the next challenge. Defence against viral infections and some cancers depends in part on activating CD8+ T cells, a class of white blood cell that can recognise and kill infected or malignant cells. The ideal vaccines against these challenges would therefore generate high numbers of long-lived CD8+ T cells that are programmed to make the right response if the infection or tumour re-emerges. Little is known about the programming of memory CD8+ T cells. We have recently found that some of these cells have the potential to be reprogrammed to display different functions by exposure to new stimuli. This opens up the possibility that ineffective responses could be improved by using vaccination to control the production of these flexible or multipotential memory cells or to reprogram them once they are formed. Alternatively, effective responses might be subverted by pathogens to the detriment of the host. The goal of this project is to learn how the first exposure to an immune challenge influences the development of these multipotential memory CD8+ cells. Understanding the signals and processes that generate multipotential memory cells will be the first step towards developing ways to manipulate them to improve immune defence.Read moreRead less
Generation And Maintenance Of Effective T Cell Memory In Peripheral Organs
Funder
National Health and Medical Research Council
Funding Amount
$336,767.00
Summary
Infectious diseases represent potentially life-threatening events. Immunity against re-infection relies on different types of memory immune cells that constantly patrol through the organism in search for invading agents. Recently, it has emerged that there exists an additional type of memory cells that permanently reside in peripheral tissues where they confer immediate immune protection. This project will examine the requirements for the generation and maintenance of this important cell type.
Understanding And Controlling Viral Escape In Influenza
Funder
National Health and Medical Research Council
Funding Amount
$433,156.00
Summary
Introduction of a new influenza strain into human circulation leads to a rapid global spread of the virus (e.g. H1N1-09 pandemic) due to minimal antibody immunity. Established T-cell immunity towards conserved viral regions promotes rapid recovery. However, the protective immunity exerts pressure on influenza, leading to "escape" mutations. We will unravel how the viral mutants emerge and propose strategies for T cell-based protective immunity and vaccine design against influenza.