Humane Chemical Methods for Population Management of Highly Valued Large Mammals. In many countries valued wild and feral animals are nonetheless too numerous. Their population numbers must be controlled through fertility. Examples are koalas in Australia, deer and seals in North America, cattle in India and dogs in Thailand. We aim to develop benign implants for castration based upon the gonadotrophin releasing hormone (GnRH). These implants are easily administered. The outcomes will be to ....Humane Chemical Methods for Population Management of Highly Valued Large Mammals. In many countries valued wild and feral animals are nonetheless too numerous. Their population numbers must be controlled through fertility. Examples are koalas in Australia, deer and seals in North America, cattle in India and dogs in Thailand. We aim to develop benign implants for castration based upon the gonadotrophin releasing hormone (GnRH). These implants are easily administered. The outcomes will be to protect Australia's ?green? image , worldwide market opportunities for the Australian companies involved in this application and valuable intellectual property for Macquarie. The methodology will in time allow us to apply it to the treatment of cancer.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
Dissecting insect gut function to understand insecticide detoxification. Massive quantities of chemical insecticides are used daily to control the insect pests that threaten agriculture, human health and the welfare of domestic pets. Insects readily evolve resistance to these chemicals reducing the effectiveness of pest control, increasing the amount of chemical used and increasing costs to consumers. This project examines the way in which insects adapt to the extreme stress imposed on them by ....Dissecting insect gut function to understand insecticide detoxification. Massive quantities of chemical insecticides are used daily to control the insect pests that threaten agriculture, human health and the welfare of domestic pets. Insects readily evolve resistance to these chemicals reducing the effectiveness of pest control, increasing the amount of chemical used and increasing costs to consumers. This project examines the way in which insects adapt to the extreme stress imposed on them by chemical insecticides. A thorough understanding of this adaptation process is required before insecticide resistance can be effectively managed or prevented. Read moreRead less
The genomics of adaptation in Wolbachia pipientis, an emerging biocontrol agent. Australians are increasingly exposed to insect-transmitted diseases such as dengue fever. Novel biocontrol methods using the bacterium Wolbachia aim to control insect populations to reduce disease transmission. Our research will be the first to investigate genomic variation and the process of adaptation to new insect hosts in Wolbachia. The novel data and understanding of evolutionary processes we generate will be c ....The genomics of adaptation in Wolbachia pipientis, an emerging biocontrol agent. Australians are increasingly exposed to insect-transmitted diseases such as dengue fever. Novel biocontrol methods using the bacterium Wolbachia aim to control insect populations to reduce disease transmission. Our research will be the first to investigate genomic variation and the process of adaptation to new insect hosts in Wolbachia. The novel data and understanding of evolutionary processes we generate will be critical for screening bacterial biocontrol candidates and designing biocontrol release strategies. It will also strengthen the position of Australian research as a world-leader in the fusion of post-genomics and applied microbiology. Read moreRead less
Using comparative genomics to identify genes responsible for adaptation to environmental toxins. The US National Human Genome Research Institute has committed to sequencing the genomes of ten different Drosophila (fly) species. We will search these genomes, and two others that are already available, for genes that allow flies to cope with environmental toxins found in the plants upon which they feed and breed. These same genes have the potential to degrade many of the insecticides used to con ....Using comparative genomics to identify genes responsible for adaptation to environmental toxins. The US National Human Genome Research Institute has committed to sequencing the genomes of ten different Drosophila (fly) species. We will search these genomes, and two others that are already available, for genes that allow flies to cope with environmental toxins found in the plants upon which they feed and breed. These same genes have the potential to degrade many of the insecticides used to control insect pests. Hence, this research will contribute to ongoing efforts to minimize the threat to agriculture posed by the insecticide resistance that frequently evolves in pest species. Read moreRead less
Evolutionary genetics of the immune system in social insects. Insects possess efficient innate immunity against pathogens, but social insects are suggested to be vulnerable due to their packed colonies of related individuals. We predict that pathogen pressure varies with life history and microhabitat details, and that this variation will be reflected in the molecular evolutionary rates of immune system genes. Sequence information will be obtained to test these predictions. The results should ....Evolutionary genetics of the immune system in social insects. Insects possess efficient innate immunity against pathogens, but social insects are suggested to be vulnerable due to their packed colonies of related individuals. We predict that pathogen pressure varies with life history and microhabitat details, and that this variation will be reflected in the molecular evolutionary rates of immune system genes. Sequence information will be obtained to test these predictions. The results should be of widespread interest as reflecting the importance of pathogens and life pattern, and increase our knowledge of insect immune systems, potentially enabling circumvention of pest defenses and better protection of beneficial species.Read moreRead less
Evolutionary immunology of social insects. Social insects are particularly abundant in Australia. They live in a wide range of habitats with social systems differing greatly in size and structure. They are both ecologically and economically important because they form a large part of terrestrial ecosystems and control much of the energy flow. Their immune system resembles the immune system of humans. Finding how the social insect immune system evolves will have the potential to help us manag ....Evolutionary immunology of social insects. Social insects are particularly abundant in Australia. They live in a wide range of habitats with social systems differing greatly in size and structure. They are both ecologically and economically important because they form a large part of terrestrial ecosystems and control much of the energy flow. Their immune system resembles the immune system of humans. Finding how the social insect immune system evolves will have the potential to help us manage them better, and yield functional insights into the human innate immune system. Placing the observed patterns in context also involves study of the associated microbes, finds how social insects interact with this important part of the environment, and may assist in land management.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101142
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Unravelling the structural evolution of centipede toxins. The project intends to improve understanding of venom evolution in centipedes, and uncover new families of peptides with potential application in the agrochemical and pharmaceutical sectors. Venoms have emerged as a rich source of pharmacological tools with potential for development into therapeutics and bioinsecticides. However, venoms-based discovery has been limited by the narrow taxonomical range studied, and many groups of venomous a ....Unravelling the structural evolution of centipede toxins. The project intends to improve understanding of venom evolution in centipedes, and uncover new families of peptides with potential application in the agrochemical and pharmaceutical sectors. Venoms have emerged as a rich source of pharmacological tools with potential for development into therapeutics and bioinsecticides. However, venoms-based discovery has been limited by the narrow taxonomical range studied, and many groups of venomous animals remain overlooked. One such group is centipedes, whose venoms contain diverse novel toxins. This project aims to provide an insight into centipede toxin evolution, and establish a structure-based approach to understanding their evolution and structural diversification. The outcomes may contribute to our understanding of protein evolution and support the development of new products.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101259
Funder
Australian Research Council
Funding Amount
$371,000.00
Summary
The impact of urbanisation on viral diversity and disease emergence. Urbanisation increases the risk of infectious disease emergence by rapidly altering contact rates between humans and other species. Fortunately, many consequences of urbanisation appear to be universal, suggesting that it is possible to identify factors likely to increase the risk of viral disease emergence and predict their impacts. This project aims to examine the viral response to changes in host and vector population struct ....The impact of urbanisation on viral diversity and disease emergence. Urbanisation increases the risk of infectious disease emergence by rapidly altering contact rates between humans and other species. Fortunately, many consequences of urbanisation appear to be universal, suggesting that it is possible to identify factors likely to increase the risk of viral disease emergence and predict their impacts. This project aims to examine the viral response to changes in host and vector population structure and dynamics that occur as a result of urbanisation, and identify viral characteristics that are associated with survival in an urban environment. This novel fusion of urban and viral ecology will have unprecedented impact on the development of predictive models of viral emergence for risk assessment and management.Read moreRead less
The role of toxin biosynthesis for marine dinoflagellates - an evolutionary ecological approach. Dinoflagellates are a group of microalgae that include coral symbionts and phytoplankton. Many species produce potent toxins that can be a problem in the aquaculture industry. This project will use novel genetic methods to investigate the evolution and ecology of toxin production in a variety of marine dinoflagellates.