Understanding social cancers: Intra-specific parasitism by honeybee workers. Our project will study the conditions under which normally altruistic honeybee workers parasitise other colonies. Thus we will explore a fundamental question: how is the expression of selfish behaviour normally controlled? Outcomes of this project will be important to our understanding of insect societies but will also have application for those studying the development of tumours in multicellular organisms, the develop ....Understanding social cancers: Intra-specific parasitism by honeybee workers. Our project will study the conditions under which normally altruistic honeybee workers parasitise other colonies. Thus we will explore a fundamental question: how is the expression of selfish behaviour normally controlled? Outcomes of this project will be important to our understanding of insect societies but will also have application for those studying the development of tumours in multicellular organisms, the development of metazoan bodies, and social cohesion in human and non-human societies. Our project will also help protect Australia's honey industry from the devastating social parasites that have ruined the industry in South Africa.Read moreRead less
Development of novel pest management tools for major insect pests. The project will provide new options for environmentally sustainable control of some of the world's worst pests. Cost effective systems will be developed that prevent crop damage, using chemicals identical to naturally occurring plant compounds, combined with tiny quantities of insecticides, to lure and kill adult moths before they lay eggs.
Antimicrobial defences in the evolution of sociality. Disease microorganisms were probably important selective agents during the evolution of most species. Social insects, the ants, bees, wasps and termites, may have been especially vulnerable because their colonies contain large numbers of closely related individuals living in close proximity; ideal conditions for contagious diseases. We will explore the evolution of antimicrobial defences in social insects and related groups. Social insects ....Antimicrobial defences in the evolution of sociality. Disease microorganisms were probably important selective agents during the evolution of most species. Social insects, the ants, bees, wasps and termites, may have been especially vulnerable because their colonies contain large numbers of closely related individuals living in close proximity; ideal conditions for contagious diseases. We will explore the evolution of antimicrobial defences in social insects and related groups. Social insects are important ecologically and economically and understanding their relationships with microbial diseases will facilitate their conservation and control. Knowledge of these interactions may also prove useful to human societies becoming increasingly vulnerable to disease.Read moreRead less
Antimicrobial Defences and Evolution of Sociality. Microbial diseases threaten all societies, human or otherwise. Insect societies present ideal conditions for contagious disease, specifically crowding of closely related individuals. We propose a gradient in the strength and breadth of antimicrobial defences from the solitary to the social condition and this is correlated with increasing crowding and decreasing genetic diversity. To test this hypothesis, we compare the microbial environments o ....Antimicrobial Defences and Evolution of Sociality. Microbial diseases threaten all societies, human or otherwise. Insect societies present ideal conditions for contagious disease, specifically crowding of closely related individuals. We propose a gradient in the strength and breadth of antimicrobial defences from the solitary to the social condition and this is correlated with increasing crowding and decreasing genetic diversity. To test this hypothesis, we compare the microbial environments of nests and colonies, and the antimicrobial mechanisms, of solitary, semi-social and social insects. Outcomes from this research on disease regulation will inform the use, management and conservation of these economically and ecologically important animals.Read moreRead less
Modelling and control of mosquito-borne diseases in Darwin using long-term monitoring. Management of mosquito populations is a high public health priority because these insects can spread diseases such as malaria, dengue, Ross River virus, Barmah Forest virus, Murray Valley encephalitis, Japanese encephalitis and Kunjin/West Nile virus. Our research into the effectiveness of mosquito control programs in Darwin is of immediate national relevance and priority given the need to Safeguard Australia ....Modelling and control of mosquito-borne diseases in Darwin using long-term monitoring. Management of mosquito populations is a high public health priority because these insects can spread diseases such as malaria, dengue, Ross River virus, Barmah Forest virus, Murray Valley encephalitis, Japanese encephalitis and Kunjin/West Nile virus. Our research into the effectiveness of mosquito control programs in Darwin is of immediate national relevance and priority given the need to Safeguard Australia from invasive diseases. There is an urgency to undertake our research because global environmental change and increasing movements of people (particularly military personnel) from overseas regions where these diseases are endemic is increasing the vulnerability of northern Australia to the (re)establishment of mosquito borne diseases.Read moreRead less
Identifying novel insecticides and their targets: probing Australian arachnid venoms. Insect pests destroy an estimated 2-3 billion dollars of crops in Australia. Insect pests also are responsible for the transmission of many new and re-emerging human, animal and plant diseases threatening health, wellbeing and prosperity. Current insecticides are severely limited by toxicity and/or insect resistance, and some are undergoing use cancellation overseas. Thus there is an urgent need to develop safe ....Identifying novel insecticides and their targets: probing Australian arachnid venoms. Insect pests destroy an estimated 2-3 billion dollars of crops in Australia. Insect pests also are responsible for the transmission of many new and re-emerging human, animal and plant diseases threatening health, wellbeing and prosperity. Current insecticides are severely limited by toxicity and/or insect resistance, and some are undergoing use cancellation overseas. Thus there is an urgent need to develop safer and more specific insecticides that are effective against disease vectors and agricultural pest insects, as well as to identify new insecticide targets. This research has a multi-million dollar potential benefit to agricultural, health and pest control sectorsRead moreRead less
Management of coastal lakes to minimise invasion. The European shore crab has the potential to undermine the productivity of Australia's estuaries and devastate our shellfish industries, worth over $50 million p.a. This project will provide estuarine managers with the data urgently needed to prevent spread of this pest species. In doing so, it will help to ensure the future prosperity of our seafood industries and the sustainability of our unique coastal biodiversity. The outcomes of this projec ....Management of coastal lakes to minimise invasion. The European shore crab has the potential to undermine the productivity of Australia's estuaries and devastate our shellfish industries, worth over $50 million p.a. This project will provide estuarine managers with the data urgently needed to prevent spread of this pest species. In doing so, it will help to ensure the future prosperity of our seafood industries and the sustainability of our unique coastal biodiversity. The outcomes of this project will be applicable to the management of many of the > 200 introduced marine species already present within our coastal waters. Importantly, the project will also contribute to research training in new techniques to protect Australia from future pest invasions.Read moreRead less
Get tough, get toxic or get a bodyguard: how root herbivores shape grass defences. The weight of root-feeding beetles can exceed that of sheep on Australian pastures and can result in significant losses in productivity. Grasses fight back against aboveground herbivores using toughness (physical defence), toxicity (chemical defence) and bodyguards (recruitment of the herbivore’s enemies). Little is known about belowground defences however, but grasses depend on roots for re-growth so good root de ....Get tough, get toxic or get a bodyguard: how root herbivores shape grass defences. The weight of root-feeding beetles can exceed that of sheep on Australian pastures and can result in significant losses in productivity. Grasses fight back against aboveground herbivores using toughness (physical defence), toxicity (chemical defence) and bodyguards (recruitment of the herbivore’s enemies). Little is known about belowground defences however, but grasses depend on roots for re-growth so good root defences seem essential. This study will apply optimal defence theory to consider these three defences against belowground herbivory across a range of grasses. The project will ask whether domestication has disarmed grass species and if defensive traits differ between photosynthetic pathways, before field-testing these patterns with root herbivore populations. Read moreRead less
Do artificial structures enhance the spread of exotic marine invertebrates in NSW estuaries? This project will investigate whether artificial structures in estuaries enhance the spread of exotic marine invertebrates and will examine the impacts of exotic species on rocky reef species. The introduction of exotic species is a significant threat to native biodiversity, second only to habitat destruction. These two threats are coincident in urbanised estuaries. This project will also provide infor ....Do artificial structures enhance the spread of exotic marine invertebrates in NSW estuaries? This project will investigate whether artificial structures in estuaries enhance the spread of exotic marine invertebrates and will examine the impacts of exotic species on rocky reef species. The introduction of exotic species is a significant threat to native biodiversity, second only to habitat destruction. These two threats are coincident in urbanised estuaries. This project will also provide information about the possible roles of different types of boating activity in transporting exotic species. Research on the role of artificial structures in invasions has not been done anywhere in the world and is essential if we are to understand, manage and ameliorate the threats of exotic species.Read moreRead less
Time to prime: using silicon to activate grass resistance under higher CO2. This project aims to deliver insight into how CO2 affects defence trade-offs in Australian grasses and establish if silicon (Si) supplementation with an industrial by-product restores resistance. Grasses contain more Si than nearly any other plant, resulting in multiple beneficial functions, including increasing resistance to disease and herbivory. However, increasing atmospheric CO2 reduces Si uptake in some grasses and ....Time to prime: using silicon to activate grass resistance under higher CO2. This project aims to deliver insight into how CO2 affects defence trade-offs in Australian grasses and establish if silicon (Si) supplementation with an industrial by-product restores resistance. Grasses contain more Si than nearly any other plant, resulting in multiple beneficial functions, including increasing resistance to disease and herbivory. However, increasing atmospheric CO2 reduces Si uptake in some grasses and frequently compromises plant defensive responses/signalling to herbivore attack. A key outcome will be identifying and maximising silicon-based resistance in vulnerable grasses against the threat of climate change and invasive herbivores. This will provide benefits such as increased productivity of Australian grasslands using a pollution-free, broad-spectrum and environmentally safer pest control approach.Read moreRead less