Biogenesis of secretory organelles and the function of adhesins secreted during the establishment of plant disease. Many agriculturally important crops and Australian native plants are susceptible to diseases caused by species of Phytophthora, a fungus-like organism that lives in the soil. Economic losses due to Phytophthora diseases are estimated to exceed $200 million per annum and the scale of environmental damage in natural ecosystems is huge. Currently, control of Phytophthora diseases la ....Biogenesis of secretory organelles and the function of adhesins secreted during the establishment of plant disease. Many agriculturally important crops and Australian native plants are susceptible to diseases caused by species of Phytophthora, a fungus-like organism that lives in the soil. Economic losses due to Phytophthora diseases are estimated to exceed $200 million per annum and the scale of environmental damage in natural ecosystems is huge. Currently, control of Phytophthora diseases largely depends on a very small number of effective chemicals and there is an imminent risk of the development of pathogen resistance. This research will increase our understanding of how Phytophthora spores infect host plants and will identify suitable targets for the development of novel, environmentally safe chemicals that inhibit disease development.Read moreRead less
Selective secretion: a novel mechanism of protein trafficking and its role in Phytophthora pathogenicity. Agriculturally important crops and over 3,000 Australian native plants are susceptible to diseases caused by Phytophthora, fungus-like pathogens that live in the soil. Economic losses exceed $200m pa and natural ecosystems are being destroyed on a vast scale. Phytophthora control depends upon a limited number of chemical inhibitors to which resistance has already emerged. New control stra ....Selective secretion: a novel mechanism of protein trafficking and its role in Phytophthora pathogenicity. Agriculturally important crops and over 3,000 Australian native plants are susceptible to diseases caused by Phytophthora, fungus-like pathogens that live in the soil. Economic losses exceed $200m pa and natural ecosystems are being destroyed on a vast scale. Phytophthora control depends upon a limited number of chemical inhibitors to which resistance has already emerged. New control strategies are urgently needed. This research will investigate a novel mechanism for release of infection material recently discovered in Phytophthora cells, and will increase our understanding of how Phytophthora infects host plants, providing vital information required for the development of new, environmentally-safe inhibitors. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101897
Funder
Australian Research Council
Funding Amount
$341,000.00
Summary
The Evolution of stripe rust virulence. Fungal crop pathogen epidemics lead to severe yield losses worldwide, impact national economies and individual human lives. Wheat stripe rust fungal epidemics caused by new virulent races can lead to 80 per cent reduction in yield. This project aims to investigate the molecular mechanisms leading to newly virulent races by whole genome, epigenome and transcriptome comparison of several wheat stripe rust races. This project aims to fundamentally advance our ....The Evolution of stripe rust virulence. Fungal crop pathogen epidemics lead to severe yield losses worldwide, impact national economies and individual human lives. Wheat stripe rust fungal epidemics caused by new virulent races can lead to 80 per cent reduction in yield. This project aims to investigate the molecular mechanisms leading to newly virulent races by whole genome, epigenome and transcriptome comparison of several wheat stripe rust races. This project aims to fundamentally advance our understanding of evolutionary forces driving virulence and specification at the whole (epi-)genome level in important fungal crop pathogens. This will promote new crop protection strategies important for local and global food security in an ever-changing environment.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