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
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
The Potential of the Fungicide Phosphite to Control the Autonomous Spread of Phytophthora cinnamomi in Natural and Rehabilitated Ecosystems. Phytophthora cinnamomi is recognised by the Federal Government as a key threatening process to Australia's biodiversity. This project will enhance the existing methodologies and protocols to improve the effectiveness and persistence of phosphite to reduce or contain the autonomous spread of this pathogen through susceptible and threatened plant communities. ....The Potential of the Fungicide Phosphite to Control the Autonomous Spread of Phytophthora cinnamomi in Natural and Rehabilitated Ecosystems. Phytophthora cinnamomi is recognised by the Federal Government as a key threatening process to Australia's biodiversity. This project will enhance the existing methodologies and protocols to improve the effectiveness and persistence of phosphite to reduce or contain the autonomous spread of this pathogen through susceptible and threatened plant communities. It will provide environmental, mining and land-care organisations with improved techniques to control P. cinnamomi in a range of plant communities and environments associated with mining and natural ecosystems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100946
Funder
Australian Research Council
Funding Amount
$394,561.00
Summary
410 million years of stomatal evolution: key innovations in the transition from passive valves to active pores. Central to the supremacy of seed plants was the evolution of active, metabolic control of the stomata; the pores that regulate both plant productivity and water loss. However, little is known about the transition from passive control of stomata in seedless plants to active stomatal control in seed plants. This project will identify the key physiological and genetic innovations that und ....410 million years of stomatal evolution: key innovations in the transition from passive valves to active pores. Central to the supremacy of seed plants was the evolution of active, metabolic control of the stomata; the pores that regulate both plant productivity and water loss. However, little is known about the transition from passive control of stomata in seedless plants to active stomatal control in seed plants. This project will identify the key physiological and genetic innovations that underpinned the evolution of stomatal control over the past 410 million years. Understanding these evolutionary innovations will offer important insights into stomatal function in seed plants, as well as informing models of global productivity and water use through time, with benefits for Australian agriculture and natural resource management.Read moreRead less
Beyond the gene: Linking herbivore behaviour to plant defense gene expression. This collaborative project investigates insect herbivore avoidance of plant defence mechanisms. Our project is novel because it integrates changes in the plant at a number of different levels and links them to insect foraging behaviour. Researchers assume that insects respond to plant defences by changing their foraging behaviour. This has not been tested directly. We use the genetically well characterised plant Arabi ....Beyond the gene: Linking herbivore behaviour to plant defense gene expression. This collaborative project investigates insect herbivore avoidance of plant defence mechanisms. Our project is novel because it integrates changes in the plant at a number of different levels and links them to insect foraging behaviour. Researchers assume that insects respond to plant defences by changing their foraging behaviour. This has not been tested directly. We use the genetically well characterised plant Arabidopsis and the world-wide pest Helicoverpa (heliothis) as a model system. Damage caused to crops by insect herbivores is a direct function of behaviour. Understanding this behaviour will lead to improved pest management and reduced economic losses.Read moreRead less
How plants open up: revealing the evolution of stomatal opening mechanisms. This project aims to identify novel and conserved mechanisms that drive the opening of stomata – plant pores that enable CO2 acquisition for photosynthesis. Stomatal movements strongly affect plant productivity and water use efficiency and have profoundly influenced the earth’s climate and terrestrial ecology. This project will address critical gaps in our understanding of how plants open stomata in response to their env ....How plants open up: revealing the evolution of stomatal opening mechanisms. This project aims to identify novel and conserved mechanisms that drive the opening of stomata – plant pores that enable CO2 acquisition for photosynthesis. Stomatal movements strongly affect plant productivity and water use efficiency and have profoundly influenced the earth’s climate and terrestrial ecology. This project will address critical gaps in our understanding of how plants open stomata in response to their environment and the evolutionary history of the genes controlling this fundamental process. A major expected outcome is knowledge of the diversity of stomatal opening pathways, which should ultimately lead to improved predictions of plant responses to environmental change and assist future targeted modification of plant growth.Read moreRead less
Regulation of photosynthesis by phosphorus in Australia’s C3 and C4 tropical grasses. Tropical grasses with distinctly different photosynthetic biochemistry (C3 and C4) dominate Australia's vast tropical grasslands. The soils of this ancient landscape are chronically low in the mineral nutrient phosphorus that plays a crucial role in regulating photosynthesis. The project will use an integrated experimental approach and novel techniques such as metabolomics to unravel and define the intricate ....Regulation of photosynthesis by phosphorus in Australia’s C3 and C4 tropical grasses. Tropical grasses with distinctly different photosynthetic biochemistry (C3 and C4) dominate Australia's vast tropical grasslands. The soils of this ancient landscape are chronically low in the mineral nutrient phosphorus that plays a crucial role in regulating photosynthesis. The project will use an integrated experimental approach and novel techniques such as metabolomics to unravel and define the intricate mechanisms by which phosphorus regulates the complex photosynthetic biochemistry of C4 grasses. The new scientific knowledge generated by the project will be used for pasture management models to ensure that successful strategies are implemented to reduce soil loss from our fragile grasslands.Read moreRead less
A novel signalling pathway in plant cells: the phospholipase-microtubule link. Plant development is closely linked to a dynamic network of microtubules and associated proteins. The network responds to a variety of hormonal and environmental signals, although the details of the signalling mechanism are unclear. Recently we made an outstanding discovery - a unique phospholipase D, a key signal-transducing enzyme that links the plasma membrane to the microtubule network. This project aims to def ....A novel signalling pathway in plant cells: the phospholipase-microtubule link. Plant development is closely linked to a dynamic network of microtubules and associated proteins. The network responds to a variety of hormonal and environmental signals, although the details of the signalling mechanism are unclear. Recently we made an outstanding discovery - a unique phospholipase D, a key signal-transducing enzyme that links the plasma membrane to the microtubule network. This project aims to define the molecular details of this novel signal-transduction pathway and establish how external signals modulate developmental events or initiate protective responses such as resistance to drought or pathogen attack.Read moreRead less
Root aquaporins as sensors and regulators of plant water transport. The knowledge we will gain will benefit Australia by allowing better management of plant water use. Because such large quantities of water move through aquaporins in membranes, our understanding of the pores could enable us to manipulate plants to conserve or use water depending on predicted climatic conditions. Molecular aspects of the project will reveal potential novel ways of controlling root water uptake by shoot and root m ....Root aquaporins as sensors and regulators of plant water transport. The knowledge we will gain will benefit Australia by allowing better management of plant water use. Because such large quantities of water move through aquaporins in membranes, our understanding of the pores could enable us to manipulate plants to conserve or use water depending on predicted climatic conditions. Molecular aspects of the project will reveal potential novel ways of controlling root water uptake by shoot and root manipulation. High calibre PhD and Honours students will also be educated to maintain the momentum of international excellence within Australia in the field of plant water relations.Read moreRead less
Root-to-shoot: modeling the salt stress response of a plant vascular system. Salt and drought are the two major abiotic stresses affecting crop plant health, growth and development. We aim to understand salt and water transport in plants and the physiological effects of soil salinity. Using biophysical models, we will quantify the movement of salt through plant organs, tissues and cells, from root to leaf. We aim to answer the question of how salt moves across the different tissues and major org ....Root-to-shoot: modeling the salt stress response of a plant vascular system. Salt and drought are the two major abiotic stresses affecting crop plant health, growth and development. We aim to understand salt and water transport in plants and the physiological effects of soil salinity. Using biophysical models, we will quantify the movement of salt through plant organs, tissues and cells, from root to leaf. We aim to answer the question of how salt moves across the different tissues and major organs, how salt accumulates in root, leaf and shoot cells, and how movement and accumulation is controlled by the diversity of transport mechanisms operating in plants. We aim to quantify tissue tolerance, osmotic tolerance and ionic tolerance and discover new mechanisms by which plants can stave off the effect of salt stress.Read moreRead less