Using RNA interference to combat the worst emerging disease of wildlife. This project aims to develop a novel method of disease control in wildlife. It will use recent advances in RNA interference technology to knockdown virulence genes in an emerging pathogen that threatens biodiversity. Pathogens such as the amphibian chytrid fungus continue to cause widespread extinction and urgently require better control methods. RNA interference has been used to increase disease resistance to fungi in plan ....Using RNA interference to combat the worst emerging disease of wildlife. This project aims to develop a novel method of disease control in wildlife. It will use recent advances in RNA interference technology to knockdown virulence genes in an emerging pathogen that threatens biodiversity. Pathogens such as the amphibian chytrid fungus continue to cause widespread extinction and urgently require better control methods. RNA interference has been used to increase disease resistance to fungi in plants but adapting this approach for animals will have wide relevance in combatting fungi and other pathogens. The specific outcomes of this method will be to increase survival rates in a broad range of frog species to improve the success of captive release programs worldwide and hence save frogs from extinction.Read moreRead less
Host-tumour interplay in Tasmanian devils with devil facial tumour disease: can immune cells be harnessed for therapy? Tasmanian devils only exist naturally in Tasmania and Devil Facial Tumour Disease, an infectious cancer, could cause the extinction of the Tasmanian devil. This project will determine if Devil Facial Tumour Disease reduces the effectiveness of the devil's immune system and test if activated immune cells can protect against this disease.
Immunisation to protect against transmissible cancers in Tasmanian devils. This project aims to identify the immune escape mechanisms that the transmissible cancers, Devil Facial Tumour Disease (DFTD) use to avoid being killed by the immune system. Since the discovery of the second transmissible cancer (DFT2) mystery surrounds whether the devils immune system can respond to this cancer, hence this project will investigate the immune response to DFT2. The final aims are to develop a vaccine with ....Immunisation to protect against transmissible cancers in Tasmanian devils. This project aims to identify the immune escape mechanisms that the transmissible cancers, Devil Facial Tumour Disease (DFTD) use to avoid being killed by the immune system. Since the discovery of the second transmissible cancer (DFT2) mystery surrounds whether the devils immune system can respond to this cancer, hence this project will investigate the immune response to DFT2. The final aims are to develop a vaccine with the potential to protect healthy devils and cure devils with DFTD.Read moreRead less
Improving disease resilience in ecosystems using synthetic biology. This project aims to use the latest methods in synthetic biology to conserve species threatened by disease, through characterising and enhancing immunity. Emerging infectious diseases are a major threat to ecosystems and new methodologies are needed to fight them. Chytridiomycosis is the most devastating disease of vertebrates, causing population declines in over 200 amphibian species worldwide. The expected outcomes of the proj ....Improving disease resilience in ecosystems using synthetic biology. This project aims to use the latest methods in synthetic biology to conserve species threatened by disease, through characterising and enhancing immunity. Emerging infectious diseases are a major threat to ecosystems and new methodologies are needed to fight them. Chytridiomycosis is the most devastating disease of vertebrates, causing population declines in over 200 amphibian species worldwide. The expected outcomes of the project are improved understanding and increased immunity of frogs to chytridiomycosis and restoration of frogs into the environment. The project will demonstrate the usefulness of synthetic biology to tackle disease and preserve biodiversity in the landscape for similarly threatened wildlife in Australia and overseas.Read moreRead less
Increasing amphibian immunity to combat disease causing mass extinction. This project aims to increase amphibian survival to combat the devastating chytrid fungus by identifying resistance genes and increasing their frequency in the host population. The project is interdisciplinary and uses targeted genetic manipulation techniques developed for agriculture to improve disease resistance in wildlife for the first time. Expected outcomes include 1) enhanced international collaborations in comparati ....Increasing amphibian immunity to combat disease causing mass extinction. This project aims to increase amphibian survival to combat the devastating chytrid fungus by identifying resistance genes and increasing their frequency in the host population. The project is interdisciplinary and uses targeted genetic manipulation techniques developed for agriculture to improve disease resistance in wildlife for the first time. Expected outcomes include 1) enhanced international collaborations in comparative immunology, 2) a comprehensive understanding of immunity to chytridiomycosis, and 3) disease resistant amphibians. The anticipated benefit is ability to apply the optimal method to improve conservation of wildlife threatened by emerging disease, such as marker assisted selective breeding or genetic engineering.Read moreRead less