Developing feasible in situ control of mange disease in wombats. Our goal is the development of feasible in situ control of sarcoptic mange in wombat populations. Globally important, the Sarcoptes scabiei mite infects >100 mammal species and is among the 50 most common human diseases, causing health, welfare and population impacts. This infection is treatable, and we will test a new treatment (fluralaner), develop new models to guide management, and conduct replicated field trials. This will ena ....Developing feasible in situ control of mange disease in wombats. Our goal is the development of feasible in situ control of sarcoptic mange in wombat populations. Globally important, the Sarcoptes scabiei mite infects >100 mammal species and is among the 50 most common human diseases, causing health, welfare and population impacts. This infection is treatable, and we will test a new treatment (fluralaner), develop new models to guide management, and conduct replicated field trials. This will enable science-based guidelines, advancing disease control, local eradication, and regulatory approval for wombats. Our research framework is adaptable to other mange-impacted species, and advance methods and theory for control of treatable disease in wildlife.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
Discovery Early Career Researcher Award - Grant ID: DE180101395
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Effect of disease on reproduction plasticity and evolution in amphibians. The project aims to explore the impact of disease on reproductive success in amphibians by utilizing a holistic approach of both lab and field techniques to understand ecological mechanisms for resilience of wildlife to emerging diseases. The project will explore reproductive effort as a population persistence mechanism of declining species. This should advance knowledge of both reproductive plasticity and evolutionary ada ....Effect of disease on reproduction plasticity and evolution in amphibians. The project aims to explore the impact of disease on reproductive success in amphibians by utilizing a holistic approach of both lab and field techniques to understand ecological mechanisms for resilience of wildlife to emerging diseases. The project will explore reproductive effort as a population persistence mechanism of declining species. This should advance knowledge of both reproductive plasticity and evolutionary adaptation in the face of disease. The expected outcomes include developing targeted approaches for conservation agencies.Read moreRead less