Defining the evolution of pathogen virulence to enhance rabbit biocontrol. Rabbits impose a major economic and ecological burden on Australia. Biocontrols involving viruses are the best means to regulate rabbit populations, although they often have transient effectiveness. It is therefore essential to determine why some viruses retain the high virulence essential for effective biocontrol, while others are consistently benign. Through bioinformatic and experimental studies of two rabbit viruses w ....Defining the evolution of pathogen virulence to enhance rabbit biocontrol. Rabbits impose a major economic and ecological burden on Australia. Biocontrols involving viruses are the best means to regulate rabbit populations, although they often have transient effectiveness. It is therefore essential to determine why some viruses retain the high virulence essential for effective biocontrol, while others are consistently benign. Through bioinformatic and experimental studies of two rabbit viruses with markedly different virulence, Rabbit Haemorrhagic Disease virus (high virulence) and Australian rabbit calicivirus (low virulence), this project will determine the molecular mechanisms that control virulence and the factors that shape virulence evolution. Ultimately, this research will help improve rabbit biocontrol in Australia.Read moreRead less
Adapting to a changing world: mothers as drivers of evolutionary change. This project will improve our understanding of how organisms will adapt to the unprecedented speed and magnitude of human-induced environmental change. By identifying how mothers modify their offspring to better match the prevailing environment, it will address the role of mothers in directing and accelerating adaptation in our changing world.
Disentangling climate and evolutionary controls over the temperature dependence of leaf respiration. The project will use field and laboratory studies to establish if there are systematic differences in the temperature responses of leaf respiration in plants adapted to hot and cold environments. The results will enable climate modellers to better predict impacts of climate change on carbon exchange between vegetation and the atmosphere.
Discovery Early Career Researcher Award - Grant ID: DE160100685
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Historical pest genomes inform debate about how rapid evolution proceeds. This project plans to compare the genomes of archived and contemporary specimens to discover how two key Australian pest moths have adapted to insecticides, aiding prediction of how they may respond in the future. Agricultural pest species are often capable of rapid adaptation to insecticides, resulting in widespread genetic resistance. Does this resistance build on existing genetic variation, or are fresh mutations used t ....Historical pest genomes inform debate about how rapid evolution proceeds. This project plans to compare the genomes of archived and contemporary specimens to discover how two key Australian pest moths have adapted to insecticides, aiding prediction of how they may respond in the future. Agricultural pest species are often capable of rapid adaptation to insecticides, resulting in widespread genetic resistance. Does this resistance build on existing genetic variation, or are fresh mutations used to produce a fast adaptive response? How do adaptive strategies differ among key Australian pests? This project aims to answer these questions and advance understanding of mechanisms that underpin rapid evolution to improve approaches toward pest management and agricultural protection.Read moreRead less
Landscape restoration genomics for climate adaptation in eucalyptus foundation species. Understanding the genetic basis of adaptation in foundation species will allow selection of pre-adapted seeds to establish resilient ecosystems which support the broad range of life supporting services. This project will apply genomics to solve real environmental challenges in restoration management and be a model for other foundation species.
The origins, global spread and evolution of novel honey bee parasites. This project aims to study how emergent diseases arise, spread and evolve, studying varroa mites – a parasite of honey bees that will inevitably arrive in Australia and is expected to damage agriculture and the environment. As the mites have a well-characterised native range, independent host switches and a well-documented history of spread, they make good models. Mites have evolved after invasion, although without significan ....The origins, global spread and evolution of novel honey bee parasites. This project aims to study how emergent diseases arise, spread and evolve, studying varroa mites – a parasite of honey bees that will inevitably arrive in Australia and is expected to damage agriculture and the environment. As the mites have a well-characterised native range, independent host switches and a well-documented history of spread, they make good models. Mites have evolved after invasion, although without significant genetic differentiation at neutral markers. This project aims to identify genetic mechanisms associated with the host switches; reconstruct the pattern and demography of varroa’s global spread; and determine how selection acted on the mites after the host switch.Read moreRead less