Inhibition Of Alloreactivity By Modulation Of Antigen Presenting Cells
Funder
National Health and Medical Research Council
Funding Amount
$504,097.00
Summary
Bone marrow transplantation (BMT) is the most effect treatment for a number of conditions, especially leukemia. Graft versus host disease (GVHD) is a complication of BMT and results in the death of up to 50% of transplant recipients. GVHD occurs when the newly transplanted immune system recognizes the recipient as foreign and mounts and immune reponse against the patients tissues. These studies will focus on identifying and understanding the function of the immune cells which drive GVHD.
Genetic Modulation Of The Host Response To Pulmonary TB
Funder
National Health and Medical Research Council
Funding Amount
$540,273.00
Summary
Tuberculosis (TB) is an enormous global health problem. The World Health Organisation estimates that TB, which is caused by infection with the bacteria Mycobacterium tuberculosis, infects 2 billion individuals, leading to 2 million deaths and 8 million new cases of disease per year. Most TB disease is not manifest at the time of infection, but is a reactivation of latent disease in people who do not completely eradicate the primary infection. In a latent infection an effective chronic host respo ....Tuberculosis (TB) is an enormous global health problem. The World Health Organisation estimates that TB, which is caused by infection with the bacteria Mycobacterium tuberculosis, infects 2 billion individuals, leading to 2 million deaths and 8 million new cases of disease per year. Most TB disease is not manifest at the time of infection, but is a reactivation of latent disease in people who do not completely eradicate the primary infection. In a latent infection an effective chronic host response contains dormant TB organisms inside activated macrophages. Cells are recruited to wall off infected macrophages and specific T cells continually induce the activate state with minimal tissue damage (immunopathology). Although currently available antibiotics can kill TB organisms, the treatment is prolonged, expensive, difficult to administer in poorly resourced regions and not effective against multi-drug resistant organisms. New therapies to treat both active disease and prevent reactivation in individuals who are latently infected are urgently required. This proposal will address this problem using a novel approach, namely gene manipulation to augment host immunity to TB and limit concurrent immunopathology. We will construct vectors to increase expression of the key immune molecules, the T lymphocyte activating cytokines IL-12 and IL-23, and the macrophage effector molecules LRG-47 and Indoleamine 2,3-Dioxygenase (IDO). These molecules are known to be involved in TB killing. We will determine if increasing their expression increases the killing capacity of TB-infected macrophages and we will examine how these molecules interact to aid clearance of the TB bacilli. This internationally competitive grant will further our detailed understanding of the complex immune response to TB organisms and lead to the development of novel therapies to treat TB infection and prevent reactivation of latent disease.Read moreRead less
Regulation Of T Follicular Helper Cell Development And Effector Function In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$419,197.00
Summary
Immune cells mature into distinct populations with specialized functions. One subsets are T follicular helper (TFH) cells which are important for instructing B cells to produce antibodies following infection or vaccination. The means by which TFH cells are generated are unknown. We will determine mechanisms whereby TFH cells are produced and how they function. We hope to design approaches that will modulate the function of TFH cells in cases of immunodeficiencies, autoimmunity or vaccination.
Follicular T Helper Cells: Critical Regulators Of Humoral Immune Responses
Funder
National Health and Medical Research Council
Funding Amount
$272,591.00
Summary
B cells are important cells of the immune system that are responsible for producing antibodies in response to infection with pathogens, such as bacteria or viruses, or following vaccinations. In order for B cells to accomplish this task, they require help from a specialised popualtion of T cells, which are another type of immune cell - these are known as follicular T helper (TFH) cells. Under normal circumstances, T cells and B cells specifically interact with one another within lymphoid tissues ....B cells are important cells of the immune system that are responsible for producing antibodies in response to infection with pathogens, such as bacteria or viruses, or following vaccinations. In order for B cells to accomplish this task, they require help from a specialised popualtion of T cells, which are another type of immune cell - these are known as follicular T helper (TFH) cells. Under normal circumstances, T cells and B cells specifically interact with one another within lymphoid tissues such as tonsils, spleens and lymph nodes - here, they engage in a dialogue, the end result of which is the B cells being instructed to produce the appropriate type of antibodies by T cells. However, if tis process is not regulated, the T cells can deliver too little of too much help - this can result in several different types of diseases of the immune system, such as immunodeficiencies (ie insufficient production of antibodies, resulting in individuals becoming susceptible to infections) or autoimmunity (ie production of inappropriate types of antibodies that can recognise cells of the host, resulting in tissue damage and organ failure). The means by which TFH cells instruct B cells to produce antibodies is not completely understood. This project will seek to determine the mechanism whereby TFH cells carry out this important function by performing detailed examination of them follwoing their removal from tissues such as human tonsils and spleens. In doing so, we hope to design approaches that will allow the function of TFH cells to be improved in cases of immunodeficiencies, or suppressed in situations of autoimmune diseases.Read moreRead less
Malaria is characterised by defective T cell responses, particularly suppressed T cell growth. T cells are critical to malaria protection and defective immune responses are likely to benefit the parasite. We want to find out how immune-responses are turned off in malaria, so that then we can do something about this, and help fight off the parasite. Malaria kills over 2 million children each year and there is no effective vaccine. We have two important clues as what may be happenning to cause sup ....Malaria is characterised by defective T cell responses, particularly suppressed T cell growth. T cells are critical to malaria protection and defective immune responses are likely to benefit the parasite. We want to find out how immune-responses are turned off in malaria, so that then we can do something about this, and help fight off the parasite. Malaria kills over 2 million children each year and there is no effective vaccine. We have two important clues as what may be happenning to cause suppressed T cell growth during malaria infection. Firstly, we found a massive increase in T cells expressing a surface molecule called CD38 duirng infection. Increases in these cells correlated with decreases in the ability of the T cells from the animals to grow. Indeed, other researchers had observed that in mice CD38 T cells can suppress immunity. Secondly, we hypothesized that they may be responsible for the impaired T cell reactivity observed during acute malaria, and the general poor state of immune responses in humans living in areas where they are being constantly infected by the parasite. Indeed, when we removed cells expressing CD38 from blood cells from such individuals, these 'recovered' and were able to grow much better in our assays. Therefore we propose that CD38 T cells are importnat mediators of malaria immuno-suppression. We now want to understand how the parasite induces these CD38 T cells, and how their ability to suppress T cell responses can benefit the parasite. Knowing this we aim to develop vaccines which can avoid being turned off by malaria. T cells expressing CD38 are also increased in cancer and acute viral disease, such as late stage HIV. Understanding their role in malaria will also give us new clues to fight such diseases.Read moreRead less