What is killing the honeybees? The role of RNA viruses. This project aims to determine if the Varroa mite, the most important parasite of honeybees, selects for virulent strains of RNA viruses. Before Varroa’s inevitable arrival in Australia, this project will disentangle the effect of Varroa and the bees’ immune system on the evolution of virulence of bee viruses. Australia’s honeybees are Varroa-naïve and don’t carry virulent viruses. There is a known association between Varroa and colonies dy ....What is killing the honeybees? The role of RNA viruses. This project aims to determine if the Varroa mite, the most important parasite of honeybees, selects for virulent strains of RNA viruses. Before Varroa’s inevitable arrival in Australia, this project will disentangle the effect of Varroa and the bees’ immune system on the evolution of virulence of bee viruses. Australia’s honeybees are Varroa-naïve and don’t carry virulent viruses. There is a known association between Varroa and colonies dying from viruses; however, it is not known what is cause and effect. This project will clarify Varroa’s exact role in the evolution of virulence in RNA viruses. The intended outcome is increased knowledge allowing the design of an effective treatment to prevent the death of honeybee colonies.Read moreRead less
Noncanonical epitope recognition by CD8+ T lymphocytes. This proposed research program will provide significant fundamental insight in the areas of immunology and vaccine design. Vaccines for many diseases remain elusive, and this project aims to improve our understanding of the precise regions within pathogens that are the targets for the killer T cells of the immune system. These regions, called epitopes, are likely to be key ingredients in many future vaccines. Although immunologists have gat ....Noncanonical epitope recognition by CD8+ T lymphocytes. This proposed research program will provide significant fundamental insight in the areas of immunology and vaccine design. Vaccines for many diseases remain elusive, and this project aims to improve our understanding of the precise regions within pathogens that are the targets for the killer T cells of the immune system. These regions, called epitopes, are likely to be key ingredients in many future vaccines. Although immunologists have gathered much information about such epitopes, recent studies have shown that some unexpected regions of pathogens are targets for killer T cells. This project will break new ground by utilising unbiased procedures to assess the relative contribution of these noncanonical epitopes to immunity.Read moreRead less
Regulation of human immunodeficiency virus type 1 (HIV-1) replication by viral and cellular proteins. Using a mouse model, human cells will be treated with a very powerful antiviral protein using a gene therapy approach so as to block the human immunodeficiency virus (HIV) from growing. By learning how this antiviral protein works, this project will assist in the development of new strategies to treat HIV infection.