Rethinking and revitalising herbicides to counter resistance. Weeds and increasingly herbicide resistant weeds are the major yield penalty for agriculture. This project aims to develop innovative ways to overcome resistance. This project expects to (i) make herbicides work more efficiently, (ii) reveal a new mode of action for an under-used herbicide and (iii) assign breakdown pathways to herbicides. Expected outcomes of this project are to (i) to find rare, but truly synergistic herbicide combi ....Rethinking and revitalising herbicides to counter resistance. Weeds and increasingly herbicide resistant weeds are the major yield penalty for agriculture. This project aims to develop innovative ways to overcome resistance. This project expects to (i) make herbicides work more efficiently, (ii) reveal a new mode of action for an under-used herbicide and (iii) assign breakdown pathways to herbicides. Expected outcomes of this project are to (i) to find rare, but truly synergistic herbicide combinations; (ii) reveal a herbicide against which weeds outside of Japan have not evolved resistance to; and (iii) establish how best to make breakdown blockers. A benefit of using existing herbicides is the approaches are close to market, so with partner Nexgen Plants, its outcomes can be commercialised.Read moreRead less
Investigating insect neuronal plasticity under genetic and chemical stress. This project aims to study receptors that translate chemical signals into electrical signals in animal brains. These receptors are targeted by insecticides used to control the major pests that afflict agriculture and domestic pets. The project aims to establish the functions of nicotinic acetylcholine receptors in several behaviours and in insecticide responsiveness in the model insect, Drosophila melanogaster, using mut ....Investigating insect neuronal plasticity under genetic and chemical stress. This project aims to study receptors that translate chemical signals into electrical signals in animal brains. These receptors are targeted by insecticides used to control the major pests that afflict agriculture and domestic pets. The project aims to establish the functions of nicotinic acetylcholine receptors in several behaviours and in insecticide responsiveness in the model insect, Drosophila melanogaster, using mutations that knock out the function of receptor subunits. Prior research has pointed to plasticity in the expression and transport of these receptors in response to genetic and environmental change. This project aims to identify the underlying mechanisms that provide the insect with resilience, to provide better options for pest control.Read moreRead less
Developing a paradigm shift in new pharmaceutical and agrochemical design. This project will provide a paradigm shift in the design of new medicines and farming chemicals. The outcome of this research will be the efficient generation of diverse chemicals having real possibilities to improve global health and food security in the future.
Mechanisms of antifungal resistance in blackleg disease of canola. This project aims to determine how fungicide resistance evolves in the fungus Leptosphaeria maculans, the major pathogen of the oilseed crop canola. Global food production has become more reliant on the use of antifungal agents to protect crops, however these advances are now threatened by the emergence of drug-resistant microbes. The knowledge generated by this project will be used to reduce the risk of resistance evolving in po ....Mechanisms of antifungal resistance in blackleg disease of canola. This project aims to determine how fungicide resistance evolves in the fungus Leptosphaeria maculans, the major pathogen of the oilseed crop canola. Global food production has become more reliant on the use of antifungal agents to protect crops, however these advances are now threatened by the emergence of drug-resistant microbes. The knowledge generated by this project will be used to reduce the risk of resistance evolving in populations of the blackleg fungus. This will have economic benefits through ensuring increased canola yields, while providing health and environmental benefits through minimisation of use of fungicides.Read moreRead less
Using chemistry to illuminate sulfoglycolysis, a major organosulfur pathway. This project aims to develop a detailed molecular description of the sulfoglycolysis pathway, a major pathway involved in cycling an abundant sulfolipid. The project will use an integrated chemical, biochemical and structural approach to illuminate how sulfoglycolysis degrades sulfolipid to access its elemental and energy constituents. Expected outcomes include an advanced understanding of the biosulfur cycle, the devel ....Using chemistry to illuminate sulfoglycolysis, a major organosulfur pathway. This project aims to develop a detailed molecular description of the sulfoglycolysis pathway, a major pathway involved in cycling an abundant sulfolipid. The project will use an integrated chemical, biochemical and structural approach to illuminate how sulfoglycolysis degrades sulfolipid to access its elemental and energy constituents. Expected outcomes include an advanced understanding of the biosulfur cycle, the development of new chemical approaches to manipulate sulfur cycling for agricultural and biotechnology applications, and deepened ties to leading international researchers. Potential benefits include new strategies to reduce dependence on agricultural fertilisers, promote gut wellbeing, and control insect pests.Read moreRead less
Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expe ....Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expected outcomes include better understanding of plant-microbe interactions, disease management strategies, technologies for identifying biosynthetic pathways in other fungi, and enzyme technology for synthesising molecules. This could lead to new herbicides, biopesticides and drugs.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100047
Funder
Australian Research Council
Funding Amount
$380,000.00
Summary
Distributed facility for fragment based drug discovery. Distributed facility for fragment based drug discovery:
The facility aims to provide researchers with the ability to generate small molecules that modulate therapeutically and biologically important protein targets. Fragment-based drug design (FBDD) provides a rational approach to generate such biologically active compounds. The facility is designed to allow researchers throughout Australia to access the necessary infrastructure to underta ....Distributed facility for fragment based drug discovery. Distributed facility for fragment based drug discovery:
The facility aims to provide researchers with the ability to generate small molecules that modulate therapeutically and biologically important protein targets. Fragment-based drug design (FBDD) provides a rational approach to generate such biologically active compounds. The facility is designed to allow researchers throughout Australia to access the necessary infrastructure to undertake FBDD projects against a range of biologically important targets. The facility aims to enable access to high-throughput nuclear magnetic resonance spectroscopy and surface plasmon resonance, and to generate the capacity for automation in chemical synthesis and sample preparation to expedite the development of novel bioactive molecules. The development of better approaches to hit development may benefit many researchers in Australia employing FBDD.Read moreRead less
Fungal Ribosomally Synthesised and Post-translationally Modified Peptides. Fungi produce an array of molecules called secondary metabolites (SMs) that impact on everyday life (e.g. penicillin). This project aims to investigate a new class of fungal peptide SMs called RiPPs which are structurally unique from existing molecules and offer the exciting prospect of harbouring new and novel biological activities. This project expects to discover the mechanisms of RiPP synthesis and their biological ro ....Fungal Ribosomally Synthesised and Post-translationally Modified Peptides. Fungi produce an array of molecules called secondary metabolites (SMs) that impact on everyday life (e.g. penicillin). This project aims to investigate a new class of fungal peptide SMs called RiPPs which are structurally unique from existing molecules and offer the exciting prospect of harbouring new and novel biological activities. This project expects to discover the mechanisms of RiPP synthesis and their biological roles in plant pathogenic fungi, and uncover and engineer novel RiPPs with desired bioactivities. The expected outcome from this project will be a seminal advance in fungal SM biology which should provide significant benefits through the generation of exciting new lead molecules for the agricultural and medical industries.Read moreRead less
CRISPR-based pathway activation for bioactive molecule discovery in fungi. Fungi produce an incredible array of unique bioactive molecules, many of which have contributed greatly to humanity (e.g. the antibiotic penicillin, which has saved millions of lives since its discovery). DNA sequencing has revealed many fungi contain the genetic instructions to produce new molecules that have not been seen previously. However, these genes are “switched off" by default and cannot be accessed. This project ....CRISPR-based pathway activation for bioactive molecule discovery in fungi. Fungi produce an incredible array of unique bioactive molecules, many of which have contributed greatly to humanity (e.g. the antibiotic penicillin, which has saved millions of lives since its discovery). DNA sequencing has revealed many fungi contain the genetic instructions to produce new molecules that have not been seen previously. However, these genes are “switched off" by default and cannot be accessed. This project will develop innovative new methods to "hot-wire" these genes, allowing them to turn on and produce a treasure trove of new bioactive molecules. The outcomes of this project will transform our abilities to tap into the hidden potential of fungi to generate new lead molecules for the agricultural and medical industries.Read moreRead less
Next Generation Polymeric Scaffolds For Dual Agent Delivery. This project aims to provide a novel suite of degradable polymeric scaffolds for releasing multiple active agents with tailored release profiles by utilising both polymer and small molecule synthesis techniques. The project expects to generate new copolymers and polymer networks that exploit molecular architecture to regulate the release profile of the active agents incorporated. The expected outcome is the establishment of design crit ....Next Generation Polymeric Scaffolds For Dual Agent Delivery. This project aims to provide a novel suite of degradable polymeric scaffolds for releasing multiple active agents with tailored release profiles by utilising both polymer and small molecule synthesis techniques. The project expects to generate new copolymers and polymer networks that exploit molecular architecture to regulate the release profile of the active agents incorporated. The expected outcome is the establishment of design criteria for tailoring the release of active agent from the polymer scaffold. This should provide significant benefits by developing a new technology platform that could be readily adapted to applications in agriculture, pharmaceutical science and veterinary medicine where controlled release is required.
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