Understanding The Role Of NS Segments In Evading Influenza A Virus-specific Humoral And T Cell Immunity
Funder
National Health and Medical Research Council
Funding Amount
$213,812.00
Summary
Influenza viruses developed two ways to survive against host immune response: (i) mutating in its genes to escape host immune response, which may cause a new pandemic; (ii) using its NS1 protein to impair host immune response. However, little is known on how these two processes occur and whether NS1 could influence the outcome of escape mutants. By using virological and immunological methods, this study will show how viruses use different NS1 to enhance the viral escape mechanism.
Generation And Persistence Of Effective T Cell Immunity Towards Seasonal And Pandemic Influenza Viruses
Funder
National Health and Medical Research Council
Funding Amount
$451,716.00
Summary
Introduction of a new influenza strain into human circulation leads to a rapid global spread of the virus (e.g. H1N1 2009 pandemic) due to minimal antibody immunity. Established T cell immunity towards conserved viral regions promotes rapid recovery. However, it is unclear what determines the effective T cell immunity towards influenza. We will define the optimal human T cell populations, with the ultimate goal of improving vaccine design so it protects against seasonal and pandemic strains.
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.
The majority of stroke results from focal brain infarction, followed by substantial secondary excitotoxic damage in the surrounding areas. Tau has been shown to contribute to excitotoxicity and neurodegeneration in mouse models of Alzheimer’s disease (AD). Preliminary data show that tau reduction also protects against excitotoxic damage after experimental stroke. We aim to dissect the molecular mechanisms of stroke using a tau-deficient mouse model.
Vitamin D Synthesis Within Osteoblasts Increases Bone Mineral By Regulating Remodelling: Is This The Link Between Vitamin D Status And Fractures?
Funder
National Health and Medical Research Council
Funding Amount
$627,082.00
Summary
This project will contribute to understanding mechanism of vitamin D action within bone to modulate bone resorption and offers the exciting prospect of identifying the mechanism by which an adequate vitamin D status can reduce the risk of osteoporotic hip fractures. Thus, this project has great potential to improve community health by being able to recommend vitamin D supplementation made on the basis of maintaining normal bone cell function with psarticular reference to modulating bone resorpti ....This project will contribute to understanding mechanism of vitamin D action within bone to modulate bone resorption and offers the exciting prospect of identifying the mechanism by which an adequate vitamin D status can reduce the risk of osteoporotic hip fractures. Thus, this project has great potential to improve community health by being able to recommend vitamin D supplementation made on the basis of maintaining normal bone cell function with psarticular reference to modulating bone resorption.Read moreRead less
Identifying Novel Antimalarial Targets Using ENU Mutagenesis In The Mouse
Funder
National Health and Medical Research Council
Funding Amount
$760,170.00
Summary
Malaria is estimated to cause 1.2 million deaths per year. The malarial parasite has developed resistance to most drugs and new drugs are needed. We aim to mimic the protective red blood cell diseases common in human populations in malarial endemic areas by identifying host targets that are important in parasite growth.