Buried treasure: bioactive plant seed proteins evolving inside hosts. This project aims to examine how evolution in plants shortcuts the creation of new proteins by burying one within another. Scientists now realise that new genes and proteins appear frequently. A recent discovery in plant seeds involves DNA sequence insertions in a gene that makes two proteins instead of one. This project will reveal a new family of buried seed proteins, determine the rules for burying them and search plants fo ....Buried treasure: bioactive plant seed proteins evolving inside hosts. This project aims to examine how evolution in plants shortcuts the creation of new proteins by burying one within another. Scientists now realise that new genes and proteins appear frequently. A recent discovery in plant seeds involves DNA sequence insertions in a gene that makes two proteins instead of one. This project will reveal a new family of buried seed proteins, determine the rules for burying them and search plants for new examples. The first examples from plants create strongly bioactive products so the ability to dig for similar plant events will reveal new and bioactive natural products with biomedical and biotechnology applications.Read moreRead less
Co-evolution of the host pathogen interaction between Leptosphaeria maculans and Brassica species. Brassica canola is Australia's third largest export crop, producing 13% of the world's canola oil. However, blackleg disease, caused by the fungus Leptospheria maculans leads to annual yield losses of 15%, with 100% loss associated with breakdown of resistance. International investment has provided novel genome resources for Brassica and L. maculans. Applying these resources to understand the co-ev ....Co-evolution of the host pathogen interaction between Leptosphaeria maculans and Brassica species. Brassica canola is Australia's third largest export crop, producing 13% of the world's canola oil. However, blackleg disease, caused by the fungus Leptospheria maculans leads to annual yield losses of 15%, with 100% loss associated with breakdown of resistance. International investment has provided novel genome resources for Brassica and L. maculans. Applying these resources to understand the co-evolution of this plant-fungal interaction could prevent the current boom-bust cycle of canola production in Australia. This study will also provide a model and knowledge base for applications in other species, leading to enhanced crops with increased plant protection and robust, reliable productivity.Read moreRead less
Pathogenicity genes of the blackleg fungal pathogen of canola. Blackleg disease, caused by the fungus, Leptosphaeria maculans, is the most serious disease of canola (Brassica napus) Australia and worldwide. Control strategies require knowledge of mechanisms of both plant defence (resistance) and fungal pathogenicity; little is known about such processes for blackleg. I will make pathogenicity mutants of L.maculans (unable to attack canola) and characterise the mutated genes. This project will ....Pathogenicity genes of the blackleg fungal pathogen of canola. Blackleg disease, caused by the fungus, Leptosphaeria maculans, is the most serious disease of canola (Brassica napus) Australia and worldwide. Control strategies require knowledge of mechanisms of both plant defence (resistance) and fungal pathogenicity; little is known about such processes for blackleg. I will make pathogenicity mutants of L.maculans (unable to attack canola) and characterise the mutated genes. This project will develop a better understanding of the disease process for blackleg, identify novel disease control targets in this important fungus and lead to disease resistant canola.Read moreRead less
Characterisation of Genes involved in Secondary Metabolism in the Blackleg Pathogen of Canola. Blackleg caused by the fungus Leptosphaeria maculans is the major disease of canola. In spite of the economic importance of this fungus, little is known about its metabolic pathways, its genes and how they are organised. We have sequenced a large piece of L. maculans DNA comprising eight genes, including a regulatory gene and one that may be may be involved in producing secondary metabolites such as ....Characterisation of Genes involved in Secondary Metabolism in the Blackleg Pathogen of Canola. Blackleg caused by the fungus Leptosphaeria maculans is the major disease of canola. In spite of the economic importance of this fungus, little is known about its metabolic pathways, its genes and how they are organised. We have sequenced a large piece of L. maculans DNA comprising eight genes, including a regulatory gene and one that may be may be involved in producing secondary metabolites such as phytotoxins. We will determine the role of these genes in metabolism and the disease process, thus providing insights into secondary metabolism and gene regulation in this important plant pathogen.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
Spatio-temporal analysis of molecular changes during leaf senescence in arabidopsis and wheat and their response to the environment. Innovative agricultural solutions in Australia can be gained by changing the abundance of proteins and metabolites to influence plant performance and provide more robust plants and plant products. The aging and dying of leaves (leaf senescence) is a key factor in our understanding of plant development and the recovery of nutrients from dying tissues. Leaf senescenc ....Spatio-temporal analysis of molecular changes during leaf senescence in arabidopsis and wheat and their response to the environment. Innovative agricultural solutions in Australia can be gained by changing the abundance of proteins and metabolites to influence plant performance and provide more robust plants and plant products. The aging and dying of leaves (leaf senescence) is a key factor in our understanding of plant development and the recovery of nutrients from dying tissues. Leaf senescence is also important for pre-harvest impacts on seed and grain quality as leaves represent the major nitrogen store remobilised to feed these plant products. This work will support the generation of intellectual property to be applied within Australia's plant-based industries and at the same time provides a strong environment for the training of students and researchers.Read moreRead less
Revealing Enigma of Salt Bladders to Help Crops Cope with Salinity. In this project, the key transport systems mediating salt sequestration in halophytes are planned to be characterised and linked with cell genetic and metabolic profiles. Salinity is a major environmental hurdle affecting crop production around the world. Halophytes (naturally salt-loving plants) use specialised structures, called salt bladders, to sequester excessive salt outside their metabolically active parts. This feature i ....Revealing Enigma of Salt Bladders to Help Crops Cope with Salinity. In this project, the key transport systems mediating salt sequestration in halophytes are planned to be characterised and linked with cell genetic and metabolic profiles. Salinity is a major environmental hurdle affecting crop production around the world. Halophytes (naturally salt-loving plants) use specialised structures, called salt bladders, to sequester excessive salt outside their metabolically active parts. This feature is not utilised by crops however, and no information is available about the molecular mechanisms by which salt is pumped into bladder cells. This knowledge will allow breeders to utilise this, previously unexplored, trait to improve crop performance under conditions of salinity.Read moreRead less
Protein Complexes and Supercomplexes of Plant Organelles. Ample parts of plant primary metabolism occur in subcellular structures called mitochondria, plastids and peroxisomes. They are vital for plant growth and development and are central to the early success of germinating and growing seedlings. This project intends to analyze the protein complexes and supercomplexes within these organelles using state of the art instrumentation and technologies. Findings from this research have the potential ....Protein Complexes and Supercomplexes of Plant Organelles. Ample parts of plant primary metabolism occur in subcellular structures called mitochondria, plastids and peroxisomes. They are vital for plant growth and development and are central to the early success of germinating and growing seedlings. This project intends to analyze the protein complexes and supercomplexes within these organelles using state of the art instrumentation and technologies. Findings from this research have the potential to directly flow into the plant biotechnology industry and could assist the future development of Australian agriculture through genetic improvements. The expertise developed by this work will ensure that Australia is well placed to meet future needs and to generally improve agricultural technology. Read moreRead less
Harnessing peptide hormone outputs to improve root nodulation’s efficacy. This project aims to transform our understanding of symbiotic nitrogen fixation in legume root nodules. Root nodulation sustainably fixes sizeable amounts of nitrogen to boost crop production worldwide yet its utilisation is waning in favour of using nitrogen fertilisers. The project applies cutting-edge tools to define how two hormone systems boost and limit nitrogen fixation, respectively. The project expects to reveal w ....Harnessing peptide hormone outputs to improve root nodulation’s efficacy. This project aims to transform our understanding of symbiotic nitrogen fixation in legume root nodules. Root nodulation sustainably fixes sizeable amounts of nitrogen to boost crop production worldwide yet its utilisation is waning in favour of using nitrogen fertilisers. The project applies cutting-edge tools to define how two hormone systems boost and limit nitrogen fixation, respectively. The project expects to reveal ways to reconfigure these hormone outputs to improve nodule number and the efficacy of nitrogen fixation. The findings will benefit agriculture by reducing the reliance on costly nitrogen fertilisers, thus mitigating the huge environmental damage they cause, and will provide more sustainable ways to ensure food security.Read moreRead less
A new route to controlling root system architecture and drought tolerance. This project aims to transform our understanding of the relationship between root architecture and water and nitrogen acquisition, factors critical to determining yield. We have discovered that mutants affected in a peptide hormone receptor have unique root architectural features relevant to acquiring water and nitrogen. The mutants are drought tolerant and their roots are nitrate insensitive. The project aims to define t ....A new route to controlling root system architecture and drought tolerance. This project aims to transform our understanding of the relationship between root architecture and water and nitrogen acquisition, factors critical to determining yield. We have discovered that mutants affected in a peptide hormone receptor have unique root architectural features relevant to acquiring water and nitrogen. The mutants are drought tolerant and their roots are nitrate insensitive. The project aims to define the receptor’s genetic outputs and expects to uncover new ways to improve water and nitrate acquisition and determine if our findings apply to crops. The application of these findings will reduce the severe environmental damage caused by poor nitrogen fertiliser uptake and provide sustainable ways to ensure food security.Read moreRead less