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
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
Developing a wildlife health intelligence and vaccine distribution system. This project aims to establish an industry-linked pipeline for vaccines to be delivered to animals in edible baits and a near real-time monitoring system for assessing the impact of management actions. This project will develop ultrasensitive diagnostic tests and incorporate biomarkers into baits from Australia's leading pest animal control company. Bait uptake and disease status in the field will be monitored using artif ....Developing a wildlife health intelligence and vaccine distribution system. This project aims to establish an industry-linked pipeline for vaccines to be delivered to animals in edible baits and a near real-time monitoring system for assessing the impact of management actions. This project will develop ultrasensitive diagnostic tests and incorporate biomarkers into baits from Australia's leading pest animal control company. Bait uptake and disease status in the field will be monitored using artificial intelligence technology developed in Tasmania. This integrated wildlife health intelligence and scalable vaccine platform can help protect the iconic Tasmanian devil from disease and increase Australia's preparedness for looming threats to the livestock industry such as African swine fever.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100367
Funder
Australian Research Council
Funding Amount
$389,008.00
Summary
Characterisation of avian circovirus protein complexes. This project aims to better understand how the beak and feather disease virus (BFDV) is assembled. The virus affects Australian native birds, which are currently endangered or critically endangered and has the potential to disrupt native ecosystems. By using interdisciplinary research, this project will generate fundamental knowledge by which BFDV protein complexes are formed. The intended outcomes of the project include the identification ....Characterisation of avian circovirus protein complexes. This project aims to better understand how the beak and feather disease virus (BFDV) is assembled. The virus affects Australian native birds, which are currently endangered or critically endangered and has the potential to disrupt native ecosystems. By using interdisciplinary research, this project will generate fundamental knowledge by which BFDV protein complexes are formed. The intended outcomes of the project include the identification of key binding interfaces involved in viral formation processes. This information intends to guide cost-effective delivery of potential anti-viral options or vaccines for endangered Australian native parrots, and for use as a model to target other pathogenic DNA viruses of interest.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