The world has suddenly been alerted to the threat of pandemic influenza with the recent deaths in Asia of patients and their close contacts from which the avian influenza H5N1 virus has been isolated. Experts believe that it is only a matter of time before this virus mutates and acquires the ability to rapidly spread within the human population. The currently available vaccines have virtually no capacity to prevent infection by a new pandemic virus. Once the virus strikes appropriate vaccines ca ....The world has suddenly been alerted to the threat of pandemic influenza with the recent deaths in Asia of patients and their close contacts from which the avian influenza H5N1 virus has been isolated. Experts believe that it is only a matter of time before this virus mutates and acquires the ability to rapidly spread within the human population. The currently available vaccines have virtually no capacity to prevent infection by a new pandemic virus. Once the virus strikes appropriate vaccines can be made against it but this procedure takes at least 6 months, the time predicted for the virus to have already spread throughout the globe. We are proposing that a vaccine designed to induce killer T cells (called CTLs) that target the conserved regions shared by all influenza viruses, could be used as a preventative measure without prior knowledge of the exact type of virus that will emerge. This sort of vaccine will not prevent against infection but will greatly lessen the severity of the disease. We have already designed a vaccine that that will induce high levels of CTLs that can greatly speed up the clearance of viruses of the type that are currently in the human population, when tested in animal models. However, we predict that a new pandemic virus will be much more vigorous in its growth and so our vaccines will have to be improved to cope with this. This project looks at ways of increasing the number and effectiveness of the CTLs that are induced by our vaccines. This will require an understanding of how we can modulate the function of other specialised cells, dendritic cells and helper T cells, that play a role in starting and maintaining the CTL response, as well as modulating the CTLs themselves.Read moreRead less
Heterosubtypic T Cell-inducing Vaccines For Influenza In Humans
Funder
National Health and Medical Research Council
Funding Amount
$352,307.00
Summary
Bird flu virus poses a large risk to the world if it mutates to become easily spread between people. If this occurs vaccines will be made to the mutated strain but there will be a time lag before these are available. We have been working on a novel vaccine that induces protective T cell immunity to parts of the virus that are common to all influenza strains and will be effective against any new virus. Our information from animal models will be used to create a human vaccine of this type .
This an integrated program of basic research on antigen discovery and immune mechanisms, and preclinical research on novel vaccine platforms, formulations or delivery systems for the rational design and clinical testing of a next generation vaccine against malaria. This interdisciplinary research fosters strong national and international links and offers the potential for significant economic benefit to Australia.
Improved Vaccines Against Tuberculosis Based On Dendritic Cell Manipulation
Funder
National Health and Medical Research Council
Funding Amount
$257,036.00
Summary
The incidence of tuberculosis (TB) is increasing throughout the world. BCG, the only currently available vaccine is only partially protective and better vaccines are urgently required to help limit the spread of TB. We have recently prepared naked DNA vaccines with the genes for three mycobacterial proteins and found that they partially protected against lung TB in mice. Further improvement is required and this project is to design and test improved DNA vaccines. Vaccines will be more effective ....The incidence of tuberculosis (TB) is increasing throughout the world. BCG, the only currently available vaccine is only partially protective and better vaccines are urgently required to help limit the spread of TB. We have recently prepared naked DNA vaccines with the genes for three mycobacterial proteins and found that they partially protected against lung TB in mice. Further improvement is required and this project is to design and test improved DNA vaccines. Vaccines will be more effective if they generate stronger cellular immune response to mycobacteria. Dendritic cells (DC) are the major cells that present mycobacterial antigens to T lymphocytes and thus stimulate T lymphocytes to generate immune responses that protect against TB. Therefore the aim of this project is to identify ways to manipulate DC to improve their ability to activate protective immunity. We will target membrane molecules on DC to activate the antigen- presenting function of these cells by fusing the genes for mycobacterial proteins to genes either for antibodies to surface molecules on DC or receptors for these molecules. These novel DNA vaccines will be tested for their effects on DC function and their capacity to stimulate the protective pattern of immunity in mice. The cytokine environment at the time of stimulation will be modified by giving the DNA vaccine together with two cytokine-expressing vaccines, to 'push' the T lymphocytes to respond more vigorously. Finally, we shall test whether a combination of the new DNA vaccines and BCG is more effective than BCG at protecting against virulent TB infection.Read moreRead less
Functional Assays Of Immunity To Malaria In Pregnant Women
Funder
National Health and Medical Research Council
Funding Amount
$578,905.00
Summary
Pregnant women are highly susceptible to malaria due to the adhesion of infected erythrocytes to the placenta. Antibodies to these infected erythrocytes can block their placental adhesion and/or facilitate their clearance by immune cells, improving pregnancy outcomes. We aim at informing vaccine design by better understanding the placental adhesion mechanisms and identifying targets of protective immunity as well as antibody correlates of protection from placental malaria and its consequences.
Aetiology, Burden And Causal Pathways Of Acute Lower Respiratory Infections Using Population Linked Data
Funder
National Health and Medical Research Council
Funding Amount
$437,476.00
Summary
Lower respiratory, or chest infections, are a problem for many children. This project will investigate the impact of chest infections on hospitals and emergency departments, the viruses and bacteria that cause them, identify those children who are at an increased risk of having chest infections and investigate the impact of routine immunisations on specific types of infections. This project will greatly add to our understanding of chest infections so appropriate interventions can be developed.