The molecular basis of self-incompatibility in solanaceous plants. This study will examine plant reproduction, the processes that ultimately lead to seeds being formed. Seeds are a major source of food for human societies. Benefits likely to arise from this study include an improved knowledge of plant reproduction which could lead to the production of better crops and more sustainable agricultural systems. By examining reproduction in a native plant, this study will also improve our understan ....The molecular basis of self-incompatibility in solanaceous plants. This study will examine plant reproduction, the processes that ultimately lead to seeds being formed. Seeds are a major source of food for human societies. Benefits likely to arise from this study include an improved knowledge of plant reproduction which could lead to the production of better crops and more sustainable agricultural systems. By examining reproduction in a native plant, this study will also improve our understanding of Australia's flora and could help improve management strategies for rare and endagered species. Through the training of students and researchers, this study will contribute highly skilled individuals to the Australian economy.Read moreRead less
Identifying novel salinity tolerance mechanisms by spatial and temporal analysis of lipids in barley. Agrifood production faces the dual challenges of an increasing world population and the threats of abiotic stresses arising from climate change and the erosion of arable land. Cereals, the major food crops, are poorly adapted to tolerate most abiotic stresses, including salinity. This project applies new technologies investigating spatial and temporal biochemical mechanisms a model cereal, Horde ....Identifying novel salinity tolerance mechanisms by spatial and temporal analysis of lipids in barley. Agrifood production faces the dual challenges of an increasing world population and the threats of abiotic stresses arising from climate change and the erosion of arable land. Cereals, the major food crops, are poorly adapted to tolerate most abiotic stresses, including salinity. This project applies new technologies investigating spatial and temporal biochemical mechanisms a model cereal, Hordeum vulgare (barley), utilises to adapt and tolerate salinity. The aims are to investigate the role of specifically plasma membrane lipids modulating either signalling pathways or membrane fluidity that impacts on adaptation during salinity. The results will provide new leads for the development of cereal germplasm with increased salt tolerance.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100181
Funder
Australian Research Council
Funding Amount
$1,050,000.00
Summary
Crossing the biology meso-nanoscale divide by scanning electron microscopy. This project aims to establish complementary scanning electron microscope (SEM) facilities at The University of Melbourne and LaTrobe University to advance research into crops, disease, neurosciences and coral reefs. SEMs are rapidly evolving instruments that permit high resolution imaging of visible size samples such as parts of plants and animals. The potential innovations, applications and benefits to society are far ....Crossing the biology meso-nanoscale divide by scanning electron microscopy. This project aims to establish complementary scanning electron microscope (SEM) facilities at The University of Melbourne and LaTrobe University to advance research into crops, disease, neurosciences and coral reefs. SEMs are rapidly evolving instruments that permit high resolution imaging of visible size samples such as parts of plants and animals. The potential innovations, applications and benefits to society are far reaching, with the facility expected to impact the development of drought and salinity tolerance in crops, production of fibres by plants, resilience of Great Barrier Reef corals to warming, advances in medicinal agriculture, control of important diseases of livestock and humans, and sensory processing and ocular disease.Read moreRead less
The genes and pathways regulated by the AMYB80 network are involved in Arabidopsis pollen development. Tapetum is the inner layer of an anther essential for pollen formation. The project will study tapetal AtMYB80 network regulating pollen development. Knowledge of the network will be important in developing means to protect crop yields against cold and drought. Regulation of AtMYB80 activity is being used to create hybrid crops of high productivity.
ARC Centre of Excellence in Plant Cell Wall Biology. The ARC Centre for Plant Cell Wall Biology will define the regulatory mechanisms that control molecular, enzymic and cellular processes involved in the synthesis, deposition, re-modelling and depolymerisation of cell wall polysaccharides of cereals and grasses. Plant cell walls represent the world's largest renewable carbon resource, but the regulatory mechanisms responsible for their synthesis and assembly are not understood. Key distinguishi ....ARC Centre of Excellence in Plant Cell Wall Biology. The ARC Centre for Plant Cell Wall Biology will define the regulatory mechanisms that control molecular, enzymic and cellular processes involved in the synthesis, deposition, re-modelling and depolymerisation of cell wall polysaccharides of cereals and grasses. Plant cell walls represent the world's largest renewable carbon resource, but the regulatory mechanisms responsible for their synthesis and assembly are not understood. Key distinguishing features of the Centre will be the international, integrative, and multidisciplinary approach towards addressing major questions in plant biology, its strategy to leverage ARC funding, and its linkages with potential national and international end-users of the fundamental scientific discoveries.Read moreRead less
Molecular and cellular mechanisms of action of novel plant guanylyl cyclase enzymes - a new class of overlapping dual-domain molecules. A group of highly unusual catalytic molecules in plants has been identified. The mechanisms of action of these molecules will be studied in this project to learn their role in regulating plant growth in changing climates. The results will reveal how these molecules function and also provide new insights for the development of multi-functional artificial molecule ....Molecular and cellular mechanisms of action of novel plant guanylyl cyclase enzymes - a new class of overlapping dual-domain molecules. A group of highly unusual catalytic molecules in plants has been identified. The mechanisms of action of these molecules will be studied in this project to learn their role in regulating plant growth in changing climates. The results will reveal how these molecules function and also provide new insights for the development of multi-functional artificial molecules.Read moreRead less
ARC Centre of Excellence in Plant Energy Biology. We propose a novel approach to improve sustainable yield by optimising the overall efficiency of energy capture, conversion and use by plants. Efficiency gains in metabolism, transport, and development will be more effective than optimising single nutrient inputs or product outputs. Improving multiple parameters simultaneously is a necessary solution to the increasing demand for more crop yield from finite land, water, and nutrient resources. Unp ....ARC Centre of Excellence in Plant Energy Biology. We propose a novel approach to improve sustainable yield by optimising the overall efficiency of energy capture, conversion and use by plants. Efficiency gains in metabolism, transport, and development will be more effective than optimising single nutrient inputs or product outputs. Improving multiple parameters simultaneously is a necessary solution to the increasing demand for more crop yield from finite land, water, and nutrient resources. Unpredictable environmental challenges adversely affect plant growth and further perturb plant energy balance, limiting yield. The epigenetic controls, gene variants and signals discovered will provide a new basis for sustainable productivity of crops and will future-proof plants in changing climates.Read moreRead less
Evolution and specificity of alternative splicing in plants. This project aims to elucidate fundamental principles of alternative splicing, a basic mechanism that plays a vital role in several biological processes across all organisms. Plants are highly effective in adapting to varied environmental, seasonal and climatic conditions and this project aims to uncover how alternative splicing contributes to regulation of gene expression in response to developmental and environmental cues. Uncovering ....Evolution and specificity of alternative splicing in plants. This project aims to elucidate fundamental principles of alternative splicing, a basic mechanism that plays a vital role in several biological processes across all organisms. Plants are highly effective in adapting to varied environmental, seasonal and climatic conditions and this project aims to uncover how alternative splicing contributes to regulation of gene expression in response to developmental and environmental cues. Uncovering the underlying mechanisms of alternative splicing will not only advance fundamental knowledge, but also has the potential to provide tools and technologies through which sensitivities of plants to environmental stress can be potentially manipulated to benefit agriculture.Read moreRead less
How is the plant genome reactivated and controlled during seed germination? This project aims to determine the mechanisms by which plant genomes are regulated during seed germination. The genomes of cells in mature, inactive seeds are repressed, but later must be rapidly reactivated to allow the gene expression that drives early seedling growth and development. This project will study proteins that turn genes on and off, and how these interact with the structure of DNA, in order to understand ho ....How is the plant genome reactivated and controlled during seed germination? This project aims to determine the mechanisms by which plant genomes are regulated during seed germination. The genomes of cells in mature, inactive seeds are repressed, but later must be rapidly reactivated to allow the gene expression that drives early seedling growth and development. This project will study proteins that turn genes on and off, and how these interact with the structure of DNA, in order to understand how spatial and temporal patterns of gene expression are controlled. It will advance our understanding of genome regulatory programs controlling germination and growth, and how they vary between Arabidopsis and barley. This can improve our ability to manipulate seed behaviour which would benefit growers and producers. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101200
Funder
Australian Research Council
Funding Amount
$453,675.00
Summary
Deciphering how nutrient status impacts plant defence. This project aims to transform our understanding of the relationship between nutrient availability and plant defence. Plant defences are activated by responses to cell wall damage, caused by pathogens. My preliminary data uncovered that the response to cell wall damage depends on the nitrogen status of the plant; providing a direct link between nutrients and defence. The research will use new mutants that disengage this link to uncover molec ....Deciphering how nutrient status impacts plant defence. This project aims to transform our understanding of the relationship between nutrient availability and plant defence. Plant defences are activated by responses to cell wall damage, caused by pathogens. My preliminary data uncovered that the response to cell wall damage depends on the nitrogen status of the plant; providing a direct link between nutrients and defence. The research will use new mutants that disengage this link to uncover molecular mechanisms underlying this process. The outcomes will provide new approaches to breed crop plants with improved nitrogen use efficiency and disease resistance. It will benefit agriculture by reducing the use of costly fertilisers and pesticides and mitigate the huge environmental damage they cause.Read moreRead less