Comparative toxicology of a fumigant and gasotransmitters: Testing a new model of fumigant toxicity in Caenorhabditis elegans. Fumigants share physical, chemical and functional properties with a medically important class of signalling molecules called gasotransmitters. This project proposes that the toxicity of fumigants is directly caused by their ability to mimic and disrupt gasotransmitter signalling. This project will test this hypothesis using the fumigant phosphine, a chemical that protect ....Comparative toxicology of a fumigant and gasotransmitters: Testing a new model of fumigant toxicity in Caenorhabditis elegans. Fumigants share physical, chemical and functional properties with a medically important class of signalling molecules called gasotransmitters. This project proposes that the toxicity of fumigants is directly caused by their ability to mimic and disrupt gasotransmitter signalling. This project will test this hypothesis using the fumigant phosphine, a chemical that protects the vast majority of the world grain supply from insect pests. This work will show us what makes a fumigant toxic. This knowledge will facilitate the discovery and effective deployment of new fumigants.Read moreRead less
New biotech methods for crop quality assurance. Quality assurance of crop products is a key for Australia to be competitive in the world marketplace. The power of molecular diagnostics has not been applied to this important but neglected part of the produce handling chain. In this project research will be undertaken that will lead to low cost on site assays to test for variety preservation, contamination, and presence of pests and diseases. It employs the tools of genomics and proteomics to p ....New biotech methods for crop quality assurance. Quality assurance of crop products is a key for Australia to be competitive in the world marketplace. The power of molecular diagnostics has not been applied to this important but neglected part of the produce handling chain. In this project research will be undertaken that will lead to low cost on site assays to test for variety preservation, contamination, and presence of pests and diseases. It employs the tools of genomics and proteomics to provide basic understanding of processes which can be developed into cost effective analyses for practical use by industry to ensure quality assurance.Read moreRead less
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
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
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
Crop genome complexity: sulphur metabolism and mustard pungency. This project aims to explain the molecular basis of crop plant plasticity in the context of a complex crop genome. It will determine how epigenetic mechanisms contribute to regulating the yield of a secondary metabolite harvested from mustard plants in response to variation in environmental factors. Specifically it will explore the relationship between sulphur metabolism and small RNA regulation of glucosinolates. The project shoul ....Crop genome complexity: sulphur metabolism and mustard pungency. This project aims to explain the molecular basis of crop plant plasticity in the context of a complex crop genome. It will determine how epigenetic mechanisms contribute to regulating the yield of a secondary metabolite harvested from mustard plants in response to variation in environmental factors. Specifically it will explore the relationship between sulphur metabolism and small RNA regulation of glucosinolates. The project should uncover the role that duplicated genetic loci and epigenetic marks play in regulating tissue-specific gene networks, particularly in field-grown environments. The project will explore how duplication of genes enables a crop such as mustard to respond to application of sulphur fertiliser and regulate the stockpiling of the 'hot' volatile oil in mustard seed, a valuable export commodity.Read moreRead less
Understanding and implications of formation of lipid nanostructures in milk. This project aims to deliver new understanding of the processes of milk digestion. Milk is the most important food for human survival, providing all the essential nutrition to newborn infants and constituting a major part of the adult diet. The recent discovery that nanostructure is formed during the digestion of both cow and breast milk, but not of vegetable 'milk', has opened a large number of questions to answer in t ....Understanding and implications of formation of lipid nanostructures in milk. This project aims to deliver new understanding of the processes of milk digestion. Milk is the most important food for human survival, providing all the essential nutrition to newborn infants and constituting a major part of the adult diet. The recent discovery that nanostructure is formed during the digestion of both cow and breast milk, but not of vegetable 'milk', has opened a large number of questions to answer in this project. Specifically, the project plans to link nanostructure formation in milk with composition during digestion, and the subsequent delivery of nutrients. The project plans to use synchrotron and microscopy techniques to address these questions. Project outcomes may improve our understanding of digestion and drive innovation in products delivering nutrients to infants.Read moreRead less
Ultrasonic production of skim milk. Milk will be skimmed using ultrasonic waves and tiny bubbles that separate the fat droplets from whole milk, saving energy and cleaning costs. It will also be possible to precisely select different nutritional compounds from the rich resource that is whole milk, enabling future health products.
Why is the peribacteroid membrane transcription factor SAT1 required for legume nitrogen fixation and what is its role in other symbiotic systems? This project will investigate the functional activity of the plant membrane bound basic helix-loop-helix (bHLH) transcription factor SAT1 in both nitrogen fixing (Rhizobia) and phosphorus acquiring (Arbuscular Mycorrhizal) symbioses found in plants. The project will identify its regulation and downstream activities across both symbiosis using selected ....Why is the peribacteroid membrane transcription factor SAT1 required for legume nitrogen fixation and what is its role in other symbiotic systems? This project will investigate the functional activity of the plant membrane bound basic helix-loop-helix (bHLH) transcription factor SAT1 in both nitrogen fixing (Rhizobia) and phosphorus acquiring (Arbuscular Mycorrhizal) symbioses found in plants. The project will identify its regulation and downstream activities across both symbiosis using selected legumes and or cereals.Read moreRead less
Stomata functioning in halophytes for improved plant stress tolerance. This project aims to determine how halophytes balance photosynthesis and water loss under extreme soil conditions. Salinity and drought affect crop production. Plants’ ability to balance carbon dioxide uptake and water loss through stomata determines how they cope with stressors. Halophytes can achieve this balance at conditions that normally kill 99% of crops, but how they do so is unknown. This project will characterise the ....Stomata functioning in halophytes for improved plant stress tolerance. This project aims to determine how halophytes balance photosynthesis and water loss under extreme soil conditions. Salinity and drought affect crop production. Plants’ ability to balance carbon dioxide uptake and water loss through stomata determines how they cope with stressors. Halophytes can achieve this balance at conditions that normally kill 99% of crops, but how they do so is unknown. This project will characterise the transport systems mediating stomata function in halophytes and contribute to understanding the molecular and physiological basis of their operation. This should allow breeders to use this trait to improve crop performance under conditions of extreme salinity and drought.Read moreRead less