The role of behavioural interactions in shaping invasion dynamics: A global synthesis using the common myna as a model system. Invasive species have detrimental effects on human health, the economy and native biodiversity. This study will address a major gap in our scientific understanding of invasions by undertaking the first large-scale examination of the role of interactions between species in determining the dynamics and outcomes of biological invasions. The project will integrate data, acro ....The role of behavioural interactions in shaping invasion dynamics: A global synthesis using the common myna as a model system. Invasive species have detrimental effects on human health, the economy and native biodiversity. This study will address a major gap in our scientific understanding of invasions by undertaking the first large-scale examination of the role of interactions between species in determining the dynamics and outcomes of biological invasions. The project will integrate data, across four continents, on dispersal, demography, breeding and behavioural interactions into one framework to create a cutting-edge model of invasion dynamics, using the highly invasive common myna as a model system. This novel approach will significantly advance theoretical developments in invasion biology and will inform pest management and threat mitigation efforts globally.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
Invasion biology: understanding the mechanisms of naiveté towards alien species. Naiveté in local wildlife is central to why alien species are so damaging, yet it is typically viewed as a simple lack of recognition of novel enemies. This project tests for multiple levels of naiveté in Australia’s mammals to demonstrate its many complex forms. It will use field and lab experiments and formal meta-analysis to unravel the three main forms of naiveté, to reveal their role in predator:prey and compet ....Invasion biology: understanding the mechanisms of naiveté towards alien species. Naiveté in local wildlife is central to why alien species are so damaging, yet it is typically viewed as a simple lack of recognition of novel enemies. This project tests for multiple levels of naiveté in Australia’s mammals to demonstrate its many complex forms. It will use field and lab experiments and formal meta-analysis to unravel the three main forms of naiveté, to reveal their role in predator:prey and competitive interactions, and to understand how native and alien mammals might overcome their initial naiveté to novel enemies. These results will identify to ecologists and land managers the complex nature of naiveté, and how it ultimately defines the nature of interactions between aliens and natives.Read moreRead less
Genomic Basis of Resistance to Poisoning by Sodium Fluoroacetate (Compound 1080) in Australian Wildlife. In Australia agricultural conservation activities worth billions of dollars are protected by using sodium fluoroacetate (1080) against pest animals. Target species are Australian rabbits and foxes and New Zealand brushtail possums. Prolonged use of biocontrol agents causes genetic resistance. This occurs naturally in Western Australia in native animals living in areas with high levels of 1080 ....Genomic Basis of Resistance to Poisoning by Sodium Fluoroacetate (Compound 1080) in Australian Wildlife. In Australia agricultural conservation activities worth billions of dollars are protected by using sodium fluoroacetate (1080) against pest animals. Target species are Australian rabbits and foxes and New Zealand brushtail possums. Prolonged use of biocontrol agents causes genetic resistance. This occurs naturally in Western Australia in native animals living in areas with high levels of 1080 in native plants. As part of the Kangaroo Genome project our aim is to discover the genomic basis of this resistance. The outcomes will be improved ability to manage pest animal populations and understanding of the evolution of plant-animal interactions.Read moreRead less
Population fluctuations: models, mechanisms and management. Changes in plant populations lead to extinctions and invasions in Australia and globally. The project will determine the drivers of plant population change and provide new tools to enable better population management.
Population growth, genetic variation and adaptation in two Caulerpa species in southeastern Australia. This project will examine factors that influence the population growth, reproduction, genetic variation and adaptation in two seaweeds; the invasive Caulerpa taxifolia and the possibly invasive C. filiformis. A combination of surveys, modelling, molecular genetics and field experiments will be undertaken to achieve this. The current ambiguity surrounding the status of C. filiformis as an inva ....Population growth, genetic variation and adaptation in two Caulerpa species in southeastern Australia. This project will examine factors that influence the population growth, reproduction, genetic variation and adaptation in two seaweeds; the invasive Caulerpa taxifolia and the possibly invasive C. filiformis. A combination of surveys, modelling, molecular genetics and field experiments will be undertaken to achieve this. The current ambiguity surrounding the status of C. filiformis as an invasive species in Australia will be addressed by comparing DNA sequences of Australian and African plants. This project will provide critical data for managing invasive species, but more broadly, increase the current understanding of their biology and the factors important in their population growth and adaptation.Read moreRead less
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
Messing with their minds: using deception to improve pest management. This project aims to develop new approaches to improve wildlife management by showing how deceit and misinformation can alter decision-making in pest animals. Using wild house mice as a model, it will test new theory on how animals decide whether or not to interact with wildlife control devices, like traps and baits, which is critical to all pest control efforts. The expected outcomes include new pest control tools that make s ....Messing with their minds: using deception to improve pest management. This project aims to develop new approaches to improve wildlife management by showing how deceit and misinformation can alter decision-making in pest animals. Using wild house mice as a model, it will test new theory on how animals decide whether or not to interact with wildlife control devices, like traps and baits, which is critical to all pest control efforts. The expected outcomes include new pest control tools that make strategic use of misinformation to alter decision making, to reduce a pest's ability to damage important agricultural crops such as wheat, boost the attraction of lures to traps, and improve bait uptake. These outcomes should provide significant new options for vertebrate pest control in Australia and globally.Read moreRead less
Dispersal and colonisation in eukaryotes and prokaryotes. The problem of pest or disease organisms for humanity is fundamentally a problem of unwanted colonisation. For example, colonisation of the surfaces of human tissues by bacterial biofilms is responsible for up to 70% of bacterial infections; colonisation of the surfaces of boat hulls by marine organisms costs the marine shipping industry > $5 billion per year. This proposal will generate fundamental information on the ability of both bac ....Dispersal and colonisation in eukaryotes and prokaryotes. The problem of pest or disease organisms for humanity is fundamentally a problem of unwanted colonisation. For example, colonisation of the surfaces of human tissues by bacterial biofilms is responsible for up to 70% of bacterial infections; colonisation of the surfaces of boat hulls by marine organisms costs the marine shipping industry > $5 billion per year. This proposal will generate fundamental information on the ability of both bacteria and higher organisms to disperse and colonise surfaces, allowing for the development of novel technologies for the prevention of unwanted colonisation of surfaces. Read moreRead less
Understanding the origin, epidemiology and transmission threat of chlamydial infections between Australian native animals and livestock. Chlamydial infections of koalas and livestock cause diseases of significant economic and environmental concern. Molecular analysis of livestock and native animal strains will improve understanding of the factors associated with transmission of these important pathogens, improving the ability to manage affected Australian animal populations.