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Australian rushes: unearthing the function of root clusters and sand-binding roots. Unearthing the functioning of highly specialised root structures provides fundamental insights into the role of native rush plants in south-western Australian ecosystems and addresses a major issue with Australia's biodiversity, currently a Priority area for the ARC. Native rushes form a prominent but inconspicuous component of the Australian 'grass-like' flora, accounting for more than half the plant biomass on ....Australian rushes: unearthing the function of root clusters and sand-binding roots. Unearthing the functioning of highly specialised root structures provides fundamental insights into the role of native rush plants in south-western Australian ecosystems and addresses a major issue with Australia's biodiversity, currently a Priority area for the ARC. Native rushes form a prominent but inconspicuous component of the Australian 'grass-like' flora, accounting for more than half the plant biomass on some landscapes. Rushes are also highly sensitive to small increments in nutrients in disturbed environments and thus form a management priority relating to their use in rehabilitation of degraded landscapes, such as mine sites and wetland margins. Read moreRead less
A new signalling component in shoot architecture: trehalose 6-phosphate. This project aims to investigate the role of a new signalling pathway involved in shoot branching. New knowledge is expected on how plants regulate shoot branching via sugar or hormone levels and/or signalling. The aims to build on recent finding that trehalose 6-phosphate (Tre6P) promotes shoot branching and to investigate whether sucrose acts via Tre6P and what role sucrose and Tre6P have compared with plant hormones. S ....A new signalling component in shoot architecture: trehalose 6-phosphate. This project aims to investigate the role of a new signalling pathway involved in shoot branching. New knowledge is expected on how plants regulate shoot branching via sugar or hormone levels and/or signalling. The aims to build on recent finding that trehalose 6-phosphate (Tre6P) promotes shoot branching and to investigate whether sucrose acts via Tre6P and what role sucrose and Tre6P have compared with plant hormones. Significant benefits may include new genetic or management strategies to modify shoot architecture.Read moreRead less
Re-balancing global resources: Manipulating toxic prussic acid (dhurrin) to improve nitrogen use efficiency in forage sorghum in a changing climate. Sorghum is grown widely is Australia and world-wide for forage, grain (mostly for animal feed) and biofuels. It grows well in dry areas. The problem is that the leaves contain a toxin that releases prussic acid (cyanide) that can reduce animal production or even kill stock feeding on it, especially when water stressed. The problem will get worse wit ....Re-balancing global resources: Manipulating toxic prussic acid (dhurrin) to improve nitrogen use efficiency in forage sorghum in a changing climate. Sorghum is grown widely is Australia and world-wide for forage, grain (mostly for animal feed) and biofuels. It grows well in dry areas. The problem is that the leaves contain a toxin that releases prussic acid (cyanide) that can reduce animal production or even kill stock feeding on it, especially when water stressed. The problem will get worse with climate change. Low-cyanide plants developed by us using non-GM methods grow fast, but accumulate nitrate instead which is also toxic. This is a waste of expensive fertiliser too. We aim to develop plants that divert resources to growth instead of toxins in order to reduce fertiliser use and help prepare for the future. The fast growing plants may also be useful as a biofuel crop.Read moreRead less
Biosynthetic and evolutionary pathways of red-shifted chlorophylls. This project will provide vital information for the roles of chlorophyll modification. Red-shifted chlorophylls have the potential to increase the efficiency of photosynthesis by extending the spectral limits. The switchable biosynthetic pathway of chlorophyll f will open up a new opportunity for developing new technologies.
The impact of water logging on mitochondrial metabolism in leaves and roots of Grey poplar. Water logging and flooding are seasonal occurrences in a variety of environments. These events cause various damage to environments, including damage to plants. The damage to plants has traditionally been associated with annuals, such as various crop species. However larger plants, i.e. trees, are also very susceptible to water-logging and flooding. As it can take from several years to decades for tress t ....The impact of water logging on mitochondrial metabolism in leaves and roots of Grey poplar. Water logging and flooding are seasonal occurrences in a variety of environments. These events cause various damage to environments, including damage to plants. The damage to plants has traditionally been associated with annuals, such as various crop species. However larger plants, i.e. trees, are also very susceptible to water-logging and flooding. As it can take from several years to decades for tress to be established it is important to understand how trees can withstand water-logging and flooding. As tree plantation are uses for commercial and environmental purposes this knowledge will be useful to a broad spectrum of users in the community.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101562
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Quantifying the contribution of leaf vein networks to the leaf economics spectrum in native and agricultural species. Using a combination of eco-physiological and geometric measures this project will evaluate the influence of leaf vein networks on leaf economics. It is expected that this work will identify vein investment and network design as major sources of variability underlying species adaptive strategies, and the global leaf economics spectrum as a whole.
Unravelling the links between plant transpiration, soil water and nitrate movement: impact of high atmospheric CO2 and irrigation strategy. Australia's serious environmental problems, soil salinity and acidity, may be greatly affected by rising atmospheric CO2 and irrigation strategies. This will occur if the movement of soil water and nitrate changes with transpiration. We will generate different transpiration rates by varying atmospheric CO2 above pastures and irrigation strategies in vineya ....Unravelling the links between plant transpiration, soil water and nitrate movement: impact of high atmospheric CO2 and irrigation strategy. Australia's serious environmental problems, soil salinity and acidity, may be greatly affected by rising atmospheric CO2 and irrigation strategies. This will occur if the movement of soil water and nitrate changes with transpiration. We will generate different transpiration rates by varying atmospheric CO2 above pastures and irrigation strategies in vineyards. The commercial partner's newly developed soil sensors allow, for the first time, simultaneous 3-D measurement of soil water and nitrate in real-time. The results will answer long-standing questions about impacts of transpiration rates on plant nitrogen uptake and generate valuable new knowledge for sustainable management of pastures and horticultural crops. Read moreRead less
Functional genomics of light stress resistance in the model organism Chlamydomonas: combining molecular genetics, transcriptome and proteome analysis. This project aims at combining molecular genetics, transcriptome and proteome analysis to identify genes and pathways underlying high light stress tolerance in previously isolated mutants of the chlorophyte Chlamydomonas reinhardtii. Comprehensive profiles of transcriptome-proteome linkage will be constructed without the complications of multicel ....Functional genomics of light stress resistance in the model organism Chlamydomonas: combining molecular genetics, transcriptome and proteome analysis. This project aims at combining molecular genetics, transcriptome and proteome analysis to identify genes and pathways underlying high light stress tolerance in previously isolated mutants of the chlorophyte Chlamydomonas reinhardtii. Comprehensive profiles of transcriptome-proteome linkage will be constructed without the complications of multicellularity for this unicellular photosynthetic model organism. We will establish a public proteome reference database and provide new microarrays and molecular markers beneficial for research in Chlamydomonas. We expect to advance understanding of high light resistance mechanisms so that it will eventually be applicable to improve productivity in crop plants growing under various environmental stress conditions.Read moreRead less
Novel photoprotective mechanisms and functional biodiversity of high light tolerance in the model alga Chlamydomonas. Most plants have limited capacity to avoid high light (HL) stress which commonly accompanies drought and high temperature stress. We will identify novel genes and proteins that underlie diverse mechanisms of photoprotection in unique very high light resistant (VHLR) mutants in the alga Chlamydomonas and develop new tools to screen other plants for these attributes. Depending on p ....Novel photoprotective mechanisms and functional biodiversity of high light tolerance in the model alga Chlamydomonas. Most plants have limited capacity to avoid high light (HL) stress which commonly accompanies drought and high temperature stress. We will identify novel genes and proteins that underlie diverse mechanisms of photoprotection in unique very high light resistant (VHLR) mutants in the alga Chlamydomonas and develop new tools to screen other plants for these attributes. Depending on progress, we expect to express them in the higher plant Arabidopsis as a first step towards utilization of VHLR genes for crop improvement. Understanding the mechanisms conferring HL photoprotection is a research priority in plant sciences and will further strengthen Australia's innovative contributions to the internationally networked Chlamydomonas Genome Project.Read moreRead less
Functional analysis of novel mitochondrial outer membrane proteins in Arabidopsis. Mitochondria play central roles in the life and death of cells. This project will characterise the functions of proteins on the mitochondrial surface, which mediate signals that define mitochondrial function, providing novel approaches to modify mitochondrial function and plant growth.