Discovery Early Career Researcher Award - Grant ID: DE170101165
Funder
Australian Research Council
Funding Amount
$370,808.00
Summary
Molecular interaction between tomato and Fusarium oxysporum. This project aims to develop fungus-resistant crops. Fungal pathogens of crop plants threaten food production food security. The fungus Fusarium oxysporum is the fifth most notorious fungal pathogens of crop plants. This project will use the tomato–Fusarium oxysporum pathosystem to discover how Fusarium manipulates plants to infect them and how plants can resist Fusarium infection. Anticipated outcomes include reduced yield loss in tom ....Molecular interaction between tomato and Fusarium oxysporum. This project aims to develop fungus-resistant crops. Fungal pathogens of crop plants threaten food production food security. The fungus Fusarium oxysporum is the fifth most notorious fungal pathogens of crop plants. This project will use the tomato–Fusarium oxysporum pathosystem to discover how Fusarium manipulates plants to infect them and how plants can resist Fusarium infection. Anticipated outcomes include reduced yield loss in tomato and other crop plants by using genome-editing techniques to develop Fusarium-resistant cultivars.Read moreRead less
Transcriptome profiling of Phytophthora pathogenicity genes: regulation of cell wall degrading enzyme synthesis during plant infection. This project will catalogue the repertoire of enzymes produced by plant pathogens to break down plant cell walls during initial penetration and later establishment of disease. This project will determine how production of these enzymes is regulated and how their function is optimised to achieve successful plant infection.
Transcriptome analysis of Phytophthora–plant interactions: characterisation of plant inhibitor proteins targeting Phytophthora extracellular effectors. A critical aspect of plant defence is protection of plant cell walls against pathogen penetration. Plants achieve this through the activity of inhibitors that specifically target pathogen cell wall degrading enzymes. These inhibitor proteins have great potential in engineering improved plant resistance to disease but their use is hampered by limi ....Transcriptome analysis of Phytophthora–plant interactions: characterisation of plant inhibitor proteins targeting Phytophthora extracellular effectors. A critical aspect of plant defence is protection of plant cell walls against pathogen penetration. Plants achieve this through the activity of inhibitors that specifically target pathogen cell wall degrading enzymes. These inhibitor proteins have great potential in engineering improved plant resistance to disease but their use is hampered by limited knowledge of their deployment and specificity. This project will produce an in-depth understanding of the identity, regulation and role of plant inhibitors that combat attack by destructive pathogens in the genus Phytophthora. It will not only address the serious problem of Phytophthora diseases in Australia but will also apply to plant defence against other pathogens.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100066
Funder
Australian Research Council
Funding Amount
$362,000.00
Summary
Uncovering how rust fungi cause devastating plant diseases. This project aims to generate a new understanding of how rust fungi infect plant cells using single-cell sequencing technologies and data-driven investigations. This project expects to discover conserved rust infection strategies and the first characterisations of mechanisms that transfer virulence proteins from the fungus to the plant. Innovations and new knowledge from this project will be of high-impact and of benefit to the Australi ....Uncovering how rust fungi cause devastating plant diseases. This project aims to generate a new understanding of how rust fungi infect plant cells using single-cell sequencing technologies and data-driven investigations. This project expects to discover conserved rust infection strategies and the first characterisations of mechanisms that transfer virulence proteins from the fungus to the plant. Innovations and new knowledge from this project will be of high-impact and of benefit to the Australian and international community through knowledge discovery about conserved rust infection mechanisms. This project expects to deliver strategies for effective rust disease management that will in the future lessen the impact of rust diseases on agriculture and natural ecosystems in Australia.Read moreRead less
Protecting tomato crops from Fusarium wilt through the efficient application of new genetic resources. The tomato industry is a major horticultural industry in Australia, and Queensland is the major producer of tomatoes for the fresh food market. In Queensland, the tomato industry has expanded in the face of the threat that Fusarium wilt could re-emerge as a major disease problem. This research will ensure that measures can be taken quickly and efficiently to protect existing genetic resources u ....Protecting tomato crops from Fusarium wilt through the efficient application of new genetic resources. The tomato industry is a major horticultural industry in Australia, and Queensland is the major producer of tomatoes for the fresh food market. In Queensland, the tomato industry has expanded in the face of the threat that Fusarium wilt could re-emerge as a major disease problem. This research will ensure that measures can be taken quickly and efficiently to protect existing genetic resources used to control Fusarium wilt. It will also improve our knowledge about the mechanisms plants use to defend themselves against Fusarium wilt diseases.Read moreRead less
New functions for bioactive flavonoids in plants and mammals. We have discovered natural products with biological activity in plants and mammals. These molecules affect plant shape and development and the process of mammalian blood vessel formation. We seek to understand how these molecules work. More understanding is required before one can begin to utilise these molecules for possible beneficial agriculture or human health outcomes. Plant shape influences such things as yield or more drought-r ....New functions for bioactive flavonoids in plants and mammals. We have discovered natural products with biological activity in plants and mammals. These molecules affect plant shape and development and the process of mammalian blood vessel formation. We seek to understand how these molecules work. More understanding is required before one can begin to utilise these molecules for possible beneficial agriculture or human health outcomes. Plant shape influences such things as yield or more drought-resilient root systems. Importantly, we have discovered specific molecules that either promote or inhibit blood vessel formation. A better understanding of how these molecules work could lead to novel treatments for cancer or cardiovascular disease.Read moreRead less
Targeting of lipid transfer proteins and other secreted plant defence proteins by pathogen effectors. Australia depends on plant products for much of its export income and plant diseases are a continual threat to these earnings. New insights into plant disease resistance mechanisms will provide new opportunities to find solutions to disease problems. Often this involves transfer of knowledge gained in simple model plant systems to more complicated crop plant systems. Work on the role of lipid tr ....Targeting of lipid transfer proteins and other secreted plant defence proteins by pathogen effectors. Australia depends on plant products for much of its export income and plant diseases are a continual threat to these earnings. New insights into plant disease resistance mechanisms will provide new opportunities to find solutions to disease problems. Often this involves transfer of knowledge gained in simple model plant systems to more complicated crop plant systems. Work on the role of lipid transfer proteins in the tomato model system will advance our knowledge of fundamental disease and disease resistance processes and ultimately enable technological innovations to improve disease resistance, reduce pesticide usage and lower crop production costs.Read moreRead less
Factors causing wheat stripe rust epidemics. This project aims to tackle wheat stripe rust, one of the most important fungal diseases of wheat in Australia, causing losses of up to $125 million a year. This project expects to gain insights into the fungal evolution and the molecular mechanism that causes hyper-virulent pathogen isolates. The expected outcome is to identify and characterise multiple genetic factors in the pathogen that contribute to wheat stripe rust epidemics in Australia. This ....Factors causing wheat stripe rust epidemics. This project aims to tackle wheat stripe rust, one of the most important fungal diseases of wheat in Australia, causing losses of up to $125 million a year. This project expects to gain insights into the fungal evolution and the molecular mechanism that causes hyper-virulent pathogen isolates. The expected outcome is to identify and characterise multiple genetic factors in the pathogen that contribute to wheat stripe rust epidemics in Australia. This project will contribute to improved disease management strategies to contain wheat stripe rust, resulting in higher wheat yields, reduced application of fungicides and increased revenue for Australian wheat farmers.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
In touch with the environment: dissecting early tactile responses in plants. This project aims to identify the regulatory mechanisms that control touch-responses in plants. Although plants cannot relocate in the face of danger, they are able to sense mechanical manipulations from the environment. These could be caused by pathogens, herbivores, rain or even wind. This touch-responsiveness of plants is essential for pathogen resistance and for triggering architectural changes to overcome obstacles ....In touch with the environment: dissecting early tactile responses in plants. This project aims to identify the regulatory mechanisms that control touch-responses in plants. Although plants cannot relocate in the face of danger, they are able to sense mechanical manipulations from the environment. These could be caused by pathogens, herbivores, rain or even wind. This touch-responsiveness of plants is essential for pathogen resistance and for triggering architectural changes to overcome obstacles and prevent mechanical damage. Using a comprehensive tool set of genetics, genomics and proteomics, this project aims to identify the upstream regulators that control touch responses. Furthermore, it is expected to expand our understanding of the physiological impacts of touch-responses on growth and stress tolerance.Read moreRead less