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.
To move or not to move: are insect movement strategies driven by plant-induced defences? Plants change chemically when damaged by insects. By showing how movement and feeding is related to these induced defences we can manipulate plant defences to resist insect attack in a more focused way. Our target insects are major pests against which we use large amounts of insecticide. Our research will decrease insect damage to crops using existing genetic machinery of plants as opposed to inserting 'nove ....To move or not to move: are insect movement strategies driven by plant-induced defences? Plants change chemically when damaged by insects. By showing how movement and feeding is related to these induced defences we can manipulate plant defences to resist insect attack in a more focused way. Our target insects are major pests against which we use large amounts of insecticide. Our research will decrease insect damage to crops using existing genetic machinery of plants as opposed to inserting 'novel' toxin-expressing genes. This project builds on Australia's strong record of achievement in agricultural and natural resource research by increasing understanding of the interplay between plant traits and insects. We will build cross-disciplinary research capacity training a new generation of biologists in an exciting area of science.Read moreRead less
Does the origin of Helicoverpa punctigera populations explain their susceptibility to agricultural insecticides? By establishing the geographic origin, and migration pattens of H. punctigera populations (by gene-flow), and directly relating it to the occurrence and persistence of insecticide resistance in Australia (by describing the movement of insects with known insecticide susceptible/resistant status), this research will greatly advance our understanding of how insecticide resistance develop ....Does the origin of Helicoverpa punctigera populations explain their susceptibility to agricultural insecticides? By establishing the geographic origin, and migration pattens of H. punctigera populations (by gene-flow), and directly relating it to the occurrence and persistence of insecticide resistance in Australia (by describing the movement of insects with known insecticide susceptible/resistant status), this research will greatly advance our understanding of how insecticide resistance develops and how it spreads. This knowledge will enable the agricultural industry to use insecticides so as to reduce the frequency of insecticide spray failures, and reduce crop losses caused by insecticide resistant pest outbreaks.Read moreRead less
Enhancement of plant proteinase inhibitors for the protection of crop plants against insect attack. The aim of this project is to characterise the interactions between various known plant proteinase inhibitors and the major digestive enzymes of insects by structural and dynamic studies and to utilise mutational studies to design new inhibitors that more effectively bind to target proteinases. The outcomes will be the knowledge to design specific inhibitors to give optimal inhibition of specific ....Enhancement of plant proteinase inhibitors for the protection of crop plants against insect attack. The aim of this project is to characterise the interactions between various known plant proteinase inhibitors and the major digestive enzymes of insects by structural and dynamic studies and to utilise mutational studies to design new inhibitors that more effectively bind to target proteinases. The outcomes will be the knowledge to design specific inhibitors to give optimal inhibition of specific insect proteinases. This knowledge will lead to novel approaches to protect economically important crops, such as cotton, from insect pests in Australia - potentially saving tens of millions of dollars per annum in chemical pesticide use and enhancing crop production in Australia and internationally.Read moreRead less
Eco-friendly pesticides for crop protection. The aims of the project are to develop robust methods for measuring bioactive pesticidal molecules in butterfly pea cultivars, characterise their modes of action, determine the exposure and persistence of these molecules in field runoff and waterways and, in the longer term, develop butterfly pea cultivars with optimised bioactivity and safety. The major outcome of the project is the generation of new knowledge that will contribute to the development ....Eco-friendly pesticides for crop protection. The aims of the project are to develop robust methods for measuring bioactive pesticidal molecules in butterfly pea cultivars, characterise their modes of action, determine the exposure and persistence of these molecules in field runoff and waterways and, in the longer term, develop butterfly pea cultivars with optimised bioactivity and safety. The major outcome of the project is the generation of new knowledge that will contribute to the development of novel antifungal and insecticidal agents. This outcome is significant as there is a huge need for new pesticidal agents that exhibit wide safety margins, reduce problems associated with resistance to existing treatments, and that are safe for the environment.Read moreRead less
Plant cyclotides as novel sustainable tools for crop protection . This project between the University of Queensland and Syngenta, a top-tier agricultural biotech company, aims at developing new crop protection technologies based on peptides. Insecticides are essential to meet the 60% increase in food production goal set by the UN but long-term exposure to traditional insecticides can harm beneficial pollinating insect populations. Expected outcomes include an exciting new insecticide technology ....Plant cyclotides as novel sustainable tools for crop protection . This project between the University of Queensland and Syngenta, a top-tier agricultural biotech company, aims at developing new crop protection technologies based on peptides. Insecticides are essential to meet the 60% increase in food production goal set by the UN but long-term exposure to traditional insecticides can harm beneficial pollinating insect populations. Expected outcomes include an exciting new insecticide technology based on natural plant defense peptides, the cyclotides, which has potential to revolutionise crop protection, leading to safer products for the environment. Benefits from the technology include a reduction in toxic insecticide residues, precision targetted applications and agrichemicals that degrade without trace.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH190100022
Funder
Australian Research Council
Funding Amount
$4,787,259.00
Summary
ARC Research Hub for Sustainable Crop Protection. The Hub aims to develop and commercialise an innovative biological alternative to chemical fungicides targeting economically significant diseases of broadacre and horticultural crops. It addresses industry challenges of fungicide resistance, chemical residues in food, off-target effects and environmental harm. It builds on ground-breaking ‘BioClay’ platform to deliver pathogen targeting RNA using clay particles as non-genetically modified crop pr ....ARC Research Hub for Sustainable Crop Protection. The Hub aims to develop and commercialise an innovative biological alternative to chemical fungicides targeting economically significant diseases of broadacre and horticultural crops. It addresses industry challenges of fungicide resistance, chemical residues in food, off-target effects and environmental harm. It builds on ground-breaking ‘BioClay’ platform to deliver pathogen targeting RNA using clay particles as non-genetically modified crop protection. An expert multidisciplinary team uniting science, commercial and social licence pathways ensures industry and consumer uptake advancing $60B Australian Agriculture. The Hub translates to increased productivity, market access and enhanced environmental credentials of Australian food.
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Be(e) friendly venomous spiders! Novel biopesticides from arachnid venoms. The overall aim of this project is to improve global honeybee health by developing novel bee-friendly bioinsecticides as well as treatments against honeybee parasites such as varroa mites and small hive beetles. This project seeks to significantly improve existing insecticidal lead peptides from spider venoms to increase their oral toxicity and make them more pest-specific. Expected outcomes of this project include a pane ....Be(e) friendly venomous spiders! Novel biopesticides from arachnid venoms. The overall aim of this project is to improve global honeybee health by developing novel bee-friendly bioinsecticides as well as treatments against honeybee parasites such as varroa mites and small hive beetles. This project seeks to significantly improve existing insecticidal lead peptides from spider venoms to increase their oral toxicity and make them more pest-specific. Expected outcomes of this project include a panel of biologically degradable venom peptides that are active against selected pest and parasite species and that can be economically produced in large scale. This would not only provide significant environmental, social and economical benefits on a global scale, but also boost the Australian agrochemical research sector.Read moreRead less
A novel approach for controlling insect vectors of human disease. Insects are responsible for transmitting a wide variety of debilitating human diseases such as malaria, dengue and yellow fever. Unfortunately, there are very few options available for controlling these insect pests. This project will develop a novel, eco-friendly approach for control of mosquitoes and other important disease vectors.