Discovery Early Career Researcher Award - Grant ID: DE200101560
Funder
Australian Research Council
Funding Amount
$419,589.00
Summary
Towards understanding the molecular details of canola-infection by Fusarium. This project aims at improving our understanding of how canola plants are infected by the pathogenic fungus Fusarium oxysporum. Canola is the primary oilseed crop, and the overall third most important crop in Australia, accounting for a 3 billion AUS$ industry. Fusarium is a relatively new fungal disease to Australian canola, but projected to become a serious threat in the future. The project will provide insights into ....Towards understanding the molecular details of canola-infection by Fusarium. This project aims at improving our understanding of how canola plants are infected by the pathogenic fungus Fusarium oxysporum. Canola is the primary oilseed crop, and the overall third most important crop in Australia, accounting for a 3 billion AUS$ industry. Fusarium is a relatively new fungal disease to Australian canola, but projected to become a serious threat in the future. The project will provide insights into the earliest stages of plant-infection by the fungus on a cellular level, using molecular biology, genetics and microscopic tools. Expected outcomes of this research include the identification of key components to improve plant defense against Fusarium, and the development of strategies to improve the plant's resilience.Read moreRead less
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
Molecular mechanisms of signalling by plant immune receptors. This project aims to understand how resistance proteins function and to find new sources of these proteins. Plant diseases account for 15% loss of global crop production, representing a threat to food security. Fungicides, one key form of protection, represent environmental concerns. The other key form of protection corresponds to resistance gene breeding, which is limited by lengthy breeding processes, restricted choice of genes from ....Molecular mechanisms of signalling by plant immune receptors. This project aims to understand how resistance proteins function and to find new sources of these proteins. Plant diseases account for 15% loss of global crop production, representing a threat to food security. Fungicides, one key form of protection, represent environmental concerns. The other key form of protection corresponds to resistance gene breeding, which is limited by lengthy breeding processes, restricted choice of genes from sexually compatible species and short effective time spans in the field. Building on previous research, this project aims to characterise the molecular basis of the Toll/interleukin-1 receptor domain-mediated nicotinamide adenine dinucleotide (NAD+) cleavage and the structural architecture of plant NLR complexes. This knowledge will support the long-term objective of protecting crops from pathogens.Read moreRead less
Structural basis of plant immune receptor signaling. Plants detect invading pathogens and trigger immune responses in a process called “effector-triggered immunity”, in which pathogen effector (avirulence) proteins are recognized by plant resistance proteins, typically so-called “plant NLRs”. Ongoing work in the applicants’ laboratories has shown that oligomerization into “resistosomes” and NAD+ (nicotinamide adenine dinucleotide) cleavage play central roles in the process. Building on these dat ....Structural basis of plant immune receptor signaling. Plants detect invading pathogens and trigger immune responses in a process called “effector-triggered immunity”, in which pathogen effector (avirulence) proteins are recognized by plant resistance proteins, typically so-called “plant NLRs”. Ongoing work in the applicants’ laboratories has shown that oligomerization into “resistosomes” and NAD+ (nicotinamide adenine dinucleotide) cleavage play central roles in the process. Building on these data, the project aims to characterize the structures of the signaling molecules resulting from TIR (Toll/interleukin-1 receptor) domain-mediated NAD+ cleavage and the structural architecture of plant NLR resistosomes. This knowledge will support the long-term objective of protecting crops from pathogens.Read moreRead less
Enhanced natural insecticidal activity against a pest of national priority . This project aims to deliver environmentally friendly, non-genetically modified crop protection tools against a catastrophic pest, the fall armyworm. This project expects to generate new knowledge of natural plant protection strategies and their application in targeted crop protection using a combination of unconventional, but cleverly integrated, cutting-edge technologies and approaches. Expected outcomes include compr ....Enhanced natural insecticidal activity against a pest of national priority . This project aims to deliver environmentally friendly, non-genetically modified crop protection tools against a catastrophic pest, the fall armyworm. This project expects to generate new knowledge of natural plant protection strategies and their application in targeted crop protection using a combination of unconventional, but cleverly integrated, cutting-edge technologies and approaches. Expected outcomes include comprehensive new technologies to fight against the most damaging global crop pest, improved Australian agritech capacity and strengthened international collaborations. This should provide significant benefits, such as added security for Australia’s most important agricultural crops and regions, and global food production.Read moreRead less
The roles of pathogen effectors in promoting rust diseases of plants. Rust diseases threaten global food security. This cross-institutional project aims to discover how proteins secreted by rust fungi promote disease following their translocation into plant cells. It will use the interaction between flax and the flax rust fungus as a powerful model system to test the hypothesis that manipulation of host RNA metabolism is a fundamental mechanism underpinning rust pathogenesis. This research is in ....The roles of pathogen effectors in promoting rust diseases of plants. Rust diseases threaten global food security. This cross-institutional project aims to discover how proteins secreted by rust fungi promote disease following their translocation into plant cells. It will use the interaction between flax and the flax rust fungus as a powerful model system to test the hypothesis that manipulation of host RNA metabolism is a fundamental mechanism underpinning rust pathogenesis. This research is intended to dramatically improve our understanding of the molecular mechanisms used by rust fungi to establish infection. The knowledge gained is expected to facilitate the development of new strategies for rust disease management in food crops by identifying pathogenic processes that can be targeted for intervention.Read moreRead less
Re-purposing shelved 'antibiotics' in the search for new herbicides. This project aims to identify target-specific herbicidal compounds that inhibit amino acid biosynthesis pathways to tackle herbicide resistance. This project expects to validate a novel herbicide discovery strategy by exploiting the similarity between bacterial and plant enzymes in these pathways to re-purpose failed 'antibiotics'. Expected outcomes include advances in our knowledge of the structure, function and inhibition of ....Re-purposing shelved 'antibiotics' in the search for new herbicides. This project aims to identify target-specific herbicidal compounds that inhibit amino acid biosynthesis pathways to tackle herbicide resistance. This project expects to validate a novel herbicide discovery strategy by exploiting the similarity between bacterial and plant enzymes in these pathways to re-purpose failed 'antibiotics'. Expected outcomes include advances in our knowledge of the structure, function and inhibition of novel herbicide targets, and the identification of compounds with herbicidal activity. This should lay the foundations for long-term benefits related to improving the quantity and quality of Australia’s crops to ensure our food security.Read moreRead less
Clay nanoparticle-facilitated RNAi for non-transgenic modification of crops. This project aims to define the most effective spray formulations, consisting of clay nanoparticles and induced RNA interference (RNAi) to manipulate gene expression in plants. Topical application of double-stranded RNA (dsRNA) for RNAi represents an attractive alternative to genetically engineered crops. However, naked dsRNA is unstable and is not efficiently taken up by plants. For these reasons, topical application o ....Clay nanoparticle-facilitated RNAi for non-transgenic modification of crops. This project aims to define the most effective spray formulations, consisting of clay nanoparticles and induced RNA interference (RNAi) to manipulate gene expression in plants. Topical application of double-stranded RNA (dsRNA) for RNAi represents an attractive alternative to genetically engineered crops. However, naked dsRNA is unstable and is not efficiently taken up by plants. For these reasons, topical application of dsRNA has thus far produced only modest induction of RNAi in plants. Nanoparticle-facilitated manipulation of gene expression in plants will enable sustainable clean green strategies for protecting crops from diseases. This project will result in improved crop protection and productivity and boost the export potential of Australian crops.Read moreRead less
Molecular basis for susceptibility and immunity to Fusarium wilt disease. Fusarium wilt is a devastating disease of many important crop plants, including banana, cotton and tomato. There are significant gaps in our understanding of this disease that need to be addressed to enable better disease management. This project aims to identify and analyse tomato proteins targeted by Fusarium effector proteins (virulence factors), determine how corresponding tomato receptors (resistance proteins) recogni ....Molecular basis for susceptibility and immunity to Fusarium wilt disease. Fusarium wilt is a devastating disease of many important crop plants, including banana, cotton and tomato. There are significant gaps in our understanding of this disease that need to be addressed to enable better disease management. This project aims to identify and analyse tomato proteins targeted by Fusarium effector proteins (virulence factors), determine how corresponding tomato receptors (resistance proteins) recognise these effectors, and identify the signalling pathways and critical defence responses activated by these receptors. The intention is to close the gaps in our understanding and use the knowledge gained to develop new strategies for disease control by interfering with fungal pathogenicity and enhancing plant resistance.Read moreRead less
Elucidating the molecular basis of plant potyvirus resistance . Plant viruses are responsible for a large proportion of crop losses, and genetic resistance is currently the most effective means to control viral spread. This project investigates, on a molecular and structural level, host factors that plant viruses hijack during infection, and in particular, the mutations in these factors that confer resistance. We further aim to elucidate the mechanisms by which plant viruses overcome resistance ....Elucidating the molecular basis of plant potyvirus resistance . Plant viruses are responsible for a large proportion of crop losses, and genetic resistance is currently the most effective means to control viral spread. This project investigates, on a molecular and structural level, host factors that plant viruses hijack during infection, and in particular, the mutations in these factors that confer resistance. We further aim to elucidate the mechanisms by which plant viruses overcome resistance mediated by these host factors. A detailed understanding of the molecular interactions between plant viruses and their host will enable new, robust and more effective forms of resistance to be engineered. This work therefore has economic and environmental implications for agricultural productivity in Australia. Read moreRead less