Transport risk pathways for emerging invasive species. Our Australian economy depends on tourism and trade and this carries unavoidable risks for the introduction and establishment of new invasive pests and diseases. This project will build datasets from four real-world problem agenda in global invasion biology. Informed by these data, this project will develop and apply state-of-the-art mathematical transport models to predict the risks and frequency of future biological invasion events. The pr ....Transport risk pathways for emerging invasive species. Our Australian economy depends on tourism and trade and this carries unavoidable risks for the introduction and establishment of new invasive pests and diseases. This project will build datasets from four real-world problem agenda in global invasion biology. Informed by these data, this project will develop and apply state-of-the-art mathematical transport models to predict the risks and frequency of future biological invasion events. The project will contribute directly to safeguarding Australia from invasive pests and diseases.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101558
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
The biodiversity consequences of evolutionary innovation. This project aims to increase knowledge of how evolutionary innovations affect biodiversity. This project will focus on a classic example of evolutionary innovation, the specialized throat jaws found in many fish groups, including damselfishes, wrasses, and cichlids. These unique jaws may explain why these fish groups contain so many species and are such successful invasive species in Australia and elsewhere. This project proposes an inte ....The biodiversity consequences of evolutionary innovation. This project aims to increase knowledge of how evolutionary innovations affect biodiversity. This project will focus on a classic example of evolutionary innovation, the specialized throat jaws found in many fish groups, including damselfishes, wrasses, and cichlids. These unique jaws may explain why these fish groups contain so many species and are such successful invasive species in Australia and elsewhere. This project proposes an integrative combination of methods and functional experiments to reveal the biodiversity consequences of evolutionary innovation. It will also enhance Australian biosecurity through the production of new ways to assess invasion risk from aquaculture and aquarium trade species.Read moreRead less
Asexual reproduction in honey bee invaders. This project aims to determine whether thelytokous parthenogenesis (the ability of queens and workers to clone themselves) is a critical factor in the successful establishment of invasive social insects in Australia and elsewhere. When an exotic social insect species arrives in Australia the population will usually expire due to a lack of conspecifics for mating, and severe inbreeding. Nonetheless, a few ant, bee and wasp species have managed to estab ....Asexual reproduction in honey bee invaders. This project aims to determine whether thelytokous parthenogenesis (the ability of queens and workers to clone themselves) is a critical factor in the successful establishment of invasive social insects in Australia and elsewhere. When an exotic social insect species arrives in Australia the population will usually expire due to a lack of conspecifics for mating, and severe inbreeding. Nonetheless, a few ant, bee and wasp species have managed to establish here and are among our worst invasive animals. The project plans to show how the Asian hive bee became established in Queensland and to assess the risks it poses to industry and the environment. This research should help the nation to respond more effectively to the next social insect invader.Read moreRead less
Rapid evolution via genetic novelty in an invasive social insect. This project aims to determine how introduced Asian honey bee populations in Australia and the Pacific managed to overcome severe genetic bottlenecks to become invasive pests. The project will use advanced molecular techniques to understand rapid evolution at a focal gene that determines fitness in these populations, and to see evolution in action across the genome using a twelve-year timeline of samples. The outcome will be an en ....Rapid evolution via genetic novelty in an invasive social insect. This project aims to determine how introduced Asian honey bee populations in Australia and the Pacific managed to overcome severe genetic bottlenecks to become invasive pests. The project will use advanced molecular techniques to understand rapid evolution at a focal gene that determines fitness in these populations, and to see evolution in action across the genome using a twelve-year timeline of samples. The outcome will be an enhanced capacity to manage new outbreaks of invasive social insects of all kinds via a better understanding of how invasions establish and spread. This should provide significant benefits in the form of protecting Australian agriculture and pollination services from social insect pests.Read moreRead less