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Mass-production of beneficial insects for commercial pest management - physicochemical definition of oviposition sites for development of cost-efficient artificial substrates. The mass-production of beneficial insects for commercial purposes demands the development of cost-effective techniques for breeding and distributing them to growers. Many predatory beneficial insects lay their eggs in sites that prevent effective mass culturing. To circumvent this difficulty, it should be possible to defin ....Mass-production of beneficial insects for commercial pest management - physicochemical definition of oviposition sites for development of cost-efficient artificial substrates. The mass-production of beneficial insects for commercial purposes demands the development of cost-effective techniques for breeding and distributing them to growers. Many predatory beneficial insects lay their eggs in sites that prevent effective mass culturing. To circumvent this difficulty, it should be possible to define such oviposition sites in chemical and physical terms, and then use the information to develop artificial substrates that are convenient for mass rearing the insects and for disseminating them to growers. We will use the mealybug predator Cryptolaemus montrouszieri to test the feasibility of this approach and to assess its application to other beneficial species.Read moreRead less
Surviving in a toad-colonised landscape: manipulating predator behaviour to reduce the impact of the cane toad invasion. Invasive species pose a major threat to biodiversity; and within Australia, cane toads are widely viewed as one of the biggest such problems. Vigorous attempts at toad control have failed to slow the invasion front, and toads are now entering the Kimberley region. If we can’t stop the toads, are there other ways to reduce the numbers of native predators killed by eating thes ....Surviving in a toad-colonised landscape: manipulating predator behaviour to reduce the impact of the cane toad invasion. Invasive species pose a major threat to biodiversity; and within Australia, cane toads are widely viewed as one of the biggest such problems. Vigorous attempts at toad control have failed to slow the invasion front, and toads are now entering the Kimberley region. If we can’t stop the toads, are there other ways to reduce the numbers of native predators killed by eating these poisonous invaders? Predators given nausea-inducing chemicals with their first toad meal rapidly learn to avoid cane toads as prey, enabling them to survive even where toads are present. The study will develop those methods for several vulnerable native species, including techniques for deployment of aversion-inducing baits in advance of the toad invasion.Read moreRead less
Controlling cane toads by turning their own weapons against them. This project aims to prevent cane toads, which are causing ecological havoc across tropical Australia, from breeding successfully. Attempts to control toad populations have had little impact, but recent research has revealed a new possibility — exploiting the toads' own weapons for intraspecific conflict. Larval cane toads compete intensely with other larval cane toads and as a result, have evolved a way to kill off their competit ....Controlling cane toads by turning their own weapons against them. This project aims to prevent cane toads, which are causing ecological havoc across tropical Australia, from breeding successfully. Attempts to control toad populations have had little impact, but recent research has revealed a new possibility — exploiting the toads' own weapons for intraspecific conflict. Larval cane toads compete intensely with other larval cane toads and as a result, have evolved a way to kill off their competitors. Toad tadpoles produce chemicals that have devastating effects on younger members of their own species, but not on native species. By deploying those chemicals, this project could develop a novel and powerful form of invader control.Read moreRead less
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
Discovery of pathways to embryogenesis in pathogenic flatworm parasites using microdissection and transcriptomic technologies. The cost to Australia of flatworm parasites to animal production and human health is substantial (hundreds of millions of dollars per year). This research will give new insights into how flatworms reproduce and equip their progeny for survival, providing impetus for new vaccine or drug therapies to be developed. As these pathogens are more significant in Australia's ne ....Discovery of pathways to embryogenesis in pathogenic flatworm parasites using microdissection and transcriptomic technologies. The cost to Australia of flatworm parasites to animal production and human health is substantial (hundreds of millions of dollars per year). This research will give new insights into how flatworms reproduce and equip their progeny for survival, providing impetus for new vaccine or drug therapies to be developed. As these pathogens are more significant in Australia's near neighbours, this project will strengthen Australia's international leadership in this field. Our study will provide, for the first time for any helminth parasite, a freely available genetic database that profiles the gene expression repertoire of individual parasite tissues, a development likely to enhance the international effort in controlling these harmful diseases.Read moreRead less
Insect host/vector genetic responses to rhabdovirus infection. Rhabdoviruses cause important diseases in humans, animals and plants. These viruses are transmitted by insect vectors in which they persist and propagate, an intimate and specific association. Insect-rhabdovirus interactions will be studied at the molecular level using a planthopper-maize rhabdovirus model. Insect genes specifically induced by rhabdovirus infection as well as the viral genes themselves will be identified and characte ....Insect host/vector genetic responses to rhabdovirus infection. Rhabdoviruses cause important diseases in humans, animals and plants. These viruses are transmitted by insect vectors in which they persist and propagate, an intimate and specific association. Insect-rhabdovirus interactions will be studied at the molecular level using a planthopper-maize rhabdovirus model. Insect genes specifically induced by rhabdovirus infection as well as the viral genes themselves will be identified and characterized using genomics and bioinformatics tools. We will extend the same approaches to a comparative analysis of these planthopper genes with other insect-rhabdovirus systems under investigation in our institutes. Identification of viral genes expressed in insects, the insect genes that respond to virus infection, and interpretation of the roles of these genes in insects, may indicate new opportunities to control serious plant and animal diseases through control of virus transmission.Read moreRead less
Buffering the ecosystem impact of invasive cane toads. This project aims to address the devastating ecological problems caused by invasive species, by developing a novel approach that does not rely upon eradicating the invader through training vulnerable native predators not to eat toxic cane toads. Expected outcomes of this project include building a broad coalition of conservation-focused groups, from private land-owners and local businesses through to Indigenous groups and government and non- ....Buffering the ecosystem impact of invasive cane toads. This project aims to address the devastating ecological problems caused by invasive species, by developing a novel approach that does not rely upon eradicating the invader through training vulnerable native predators not to eat toxic cane toads. Expected outcomes of this project include building a broad coalition of conservation-focused groups, from private land-owners and local businesses through to Indigenous groups and government and non-government agencies across the entire Kimberley region. It will also result in the evaluation of methods for deployment of taste-aversion at a landscape scale. This should provide significant benefits by conserving vulnerable fauna and building a powerful network within a region of high biodiversity in tropical Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100083
Funder
Australian Research Council
Funding Amount
$540,000.00
Summary
A high throughput phenomics facility for pace of life traits in animals. A high throughput phenomics facility for pace of life traits in animals: This project seeks to create the first high-throughput phenomic facility for animals in Australia. The molecular revolution has brought unprecedented capacity to understand genetic variation. Genetic variation is now better understood and more easily and cheaply characterised than the physical traits that organisms exhibit. Linking phenotypic variation ....A high throughput phenomics facility for pace of life traits in animals. A high throughput phenomics facility for pace of life traits in animals: This project seeks to create the first high-throughput phenomic facility for animals in Australia. The molecular revolution has brought unprecedented capacity to understand genetic variation. Genetic variation is now better understood and more easily and cheaply characterised than the physical traits that organisms exhibit. Linking phenotypic variation to genetic variation represents the major challenge in harnessing the power of the biomolecular age. This facility will accommodate animals from marine, freshwater and terrestrial systems across a diverse array of phyla. It will allow Australian researchers to leverage advances in high throughput genomic technologies to address a major bottleneck in biology.Read moreRead less
Biotechnology and epidemiology to control nodavirus in barramundi aquaculture. Production of farmed barramundi has increased more than 1200% in the NT since 2001 but is threatened by nodavirus infection. Three industry partners, Darwin Aquaculture Centre, Marine Harvest and Berrimah Veterinary Laboratory will collaborate with The University of Sydney to:
1. control nodavirus infection
2. develop new technologies to detect nodavirus using immunoassay and surface enhanced laser desorption ionis ....Biotechnology and epidemiology to control nodavirus in barramundi aquaculture. Production of farmed barramundi has increased more than 1200% in the NT since 2001 but is threatened by nodavirus infection. Three industry partners, Darwin Aquaculture Centre, Marine Harvest and Berrimah Veterinary Laboratory will collaborate with The University of Sydney to:
1. control nodavirus infection
2. develop new technologies to detect nodavirus using immunoassay and surface enhanced laser desorption ionisation mass spectroscopy (SELDI)
3. develop an integrated disease control strategy based on epidemiological survey data, and ensure that it is practical and able to be widely adopted
By this means growth targets for barramundi aquaculture in northern Australia will be achieved.
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