Discovery Early Career Researcher Award - Grant ID: DE160100893
Funder
Australian Research Council
Funding Amount
$364,000.00
Summary
How do effector proteins from necrotrophic fungi cause disease in plants? This project aims to develop new knowledge to support the development of strategies to protect wheat from necrotrophic fungi. Crop losses caused by plant diseases are a significant economic, environmental and social challenge in a world facing increased demands on food, fibre and biofuels. Parastagonospora nodorum is an economically important necrotrophic fungal pathogen of wheat. During infection, P. nodorum uses effector ....How do effector proteins from necrotrophic fungi cause disease in plants? This project aims to develop new knowledge to support the development of strategies to protect wheat from necrotrophic fungi. Crop losses caused by plant diseases are a significant economic, environmental and social challenge in a world facing increased demands on food, fibre and biofuels. Parastagonospora nodorum is an economically important necrotrophic fungal pathogen of wheat. During infection, P. nodorum uses effector proteins to target sensitivity gene products in wheat. This process, known as necrotrophic effector-triggered susceptibility, results in plant cell death and disease. This project aims to investigate the structural basis of necrotrophic effector-triggered susceptibility in the P. nodorum – wheat pathosystem.Read moreRead less
The natural function and evolution of an essential parasite transporter. This project aims to resolve the natural function and evolution of a transporter essential to the survival of malaria and other parasites. Malaria and its sibling Apicomplexan parasites cause devastating diseases in humans and livestock across the world. Much remains to be understood about these parasites, and options for controlling them are diminishing. The project will interrogate the functions of the transporter protein ....The natural function and evolution of an essential parasite transporter. This project aims to resolve the natural function and evolution of a transporter essential to the survival of malaria and other parasites. Malaria and its sibling Apicomplexan parasites cause devastating diseases in humans and livestock across the world. Much remains to be understood about these parasites, and options for controlling them are diminishing. The project will interrogate the functions of the transporter proteins. The knowledge gained might help to combat Apicomplexan parasites by targeting these transporters’ native functions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100323
Funder
Australian Research Council
Funding Amount
$431,000.00
Summary
Synthetic biology to engineer novel disease resistance in cereal crops. This project aims to engineer disease resistance in crops to dangerous fungal pathogens. The strategy is to exploit our knowledge of the plant immune system using structural biology and directed evolution of natural resistance genes, improving their ability to recognise and respond to fungal attack. Fungal pathogens cause some of the most harmful crop diseases in Australia and worldwide. The rapid evolution of fungi overcome ....Synthetic biology to engineer novel disease resistance in cereal crops. This project aims to engineer disease resistance in crops to dangerous fungal pathogens. The strategy is to exploit our knowledge of the plant immune system using structural biology and directed evolution of natural resistance genes, improving their ability to recognise and respond to fungal attack. Fungal pathogens cause some of the most harmful crop diseases in Australia and worldwide. The rapid evolution of fungi overcomes natural plant resistance and management of these diseases is a major challenge to agriculture. Expected outcomes of the project include engineered wheat plants with more effective disease resistance, reducing fungicide usage. This project intends to accelerate crop breeding and contribute to world food security.Read moreRead less
Protein biosensors for detecting smoke exposure of grapes. Bush fires and controlled burns that take place in the vicinity of vineyards can lead to grape contamination with tasteless phenolic glucosides. Their hydrolysis during wine making leads to “smoke taint” – an unpleasant medicinal taste that can render wine undrinkable. We will apply a combination of organic synthesis, protein engineering and directed evolution to develop protein-based biosensors of phenolic glucosides. These biosensors w ....Protein biosensors for detecting smoke exposure of grapes. Bush fires and controlled burns that take place in the vicinity of vineyards can lead to grape contamination with tasteless phenolic glucosides. Their hydrolysis during wine making leads to “smoke taint” – an unpleasant medicinal taste that can render wine undrinkable. We will apply a combination of organic synthesis, protein engineering and directed evolution to develop protein-based biosensors of phenolic glucosides. These biosensors will be used to devise a simple portable colorimetric test that can be performed in the vineyard or the winery. The ability to rapidly determine the level of grape contamination with phenolic glucosides would give Australian wine growers and wine makers a powerful tool to mitigate the effects of bushfires.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100078
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Multiphoton confocal microscope. Recent developments in light microscopy have revolutionised modern molecular and cellular biology. Dramatic improvements in microscope hardware and software and in the range of fluorescent markers used to tag selected cellular components now provide new and exciting opportunities to localise and determine the function of ions and molecules not only in preserved samples but also, most excitingly, in living cells. The proposed multiphoton confocal microscope will ....Multiphoton confocal microscope. Recent developments in light microscopy have revolutionised modern molecular and cellular biology. Dramatic improvements in microscope hardware and software and in the range of fluorescent markers used to tag selected cellular components now provide new and exciting opportunities to localise and determine the function of ions and molecules not only in preserved samples but also, most excitingly, in living cells. The proposed multiphoton confocal microscope will allow researchers in Canberra to obtain high quality images of static and moving components in living cells and tissues and will facilitate the discovery of new knowledge that contributes to our understanding and control of development and disease in both plants and animals.Read moreRead less
Understanding the molecular basis of fungal rust diseases in plants. This project aims to utilise structural biology, biochemistry and molecular biology approaches to substantially deepen our understanding of rust fungi-plant interactions. Fungal rust pathogens cause disease and significant yield losses in our most important food crops. During colonisation, rust fungi utilise secreted effector proteins to cause plant disease. Effectors can also be recognised by plant immunity receptors, leading ....Understanding the molecular basis of fungal rust diseases in plants. This project aims to utilise structural biology, biochemistry and molecular biology approaches to substantially deepen our understanding of rust fungi-plant interactions. Fungal rust pathogens cause disease and significant yield losses in our most important food crops. During colonisation, rust fungi utilise secreted effector proteins to cause plant disease. Effectors can also be recognised by plant immunity receptors, leading to resistance. The intended outcome of this work is to generate knowledge that can be used for the development of disease management and engineering strategies to protect plants from rust fungi. This should provide significant benefits to agricultural productivity and global food security.Read moreRead less
Exploring the catalytic role of the Rubisco small subunit: a new target for improving carbon dioxide-fixation in plants. This project uses new biotechnological tools to improve the performance of the photosynthetic protein Rubisco, the primary carbon dioxide-fixing enzyme in plants. By supercharging photosynthesis, this research will help to boost yield and reduce water and nitrogen use in crops.
Rubisco for all climates: unlocking the enzyme's structure-function relations for more efficient photosynthesis. This projects biotechnological research will identify structural features in the carbon dioxide (CO2)-capturing enzyme from plants that improve its performance, particularly at warmer temperatures. This knowledge is vital for predicting the influence of climate change on crop productivity and paving the way for supercharging photosynthesis to boost crop performance.
Ancestral enzyme engineering for designer fat products. Consumers are increasingly turning to plant-based alternatives of meat and dairy products due to concerns about health, animal welfare and sustainability. Taste, nutritional profile, protein content and limited variety are barriers that continue to challenge food manufacturers. This project aims to develop a process for the fermentation of specialty food oils and fats from agriculture production waste, that can deliver the flavour and nutri ....Ancestral enzyme engineering for designer fat products. Consumers are increasingly turning to plant-based alternatives of meat and dairy products due to concerns about health, animal welfare and sustainability. Taste, nutritional profile, protein content and limited variety are barriers that continue to challenge food manufacturers. This project aims to develop a process for the fermentation of specialty food oils and fats from agriculture production waste, that can deliver the flavour and nutritional benefits of meat and dairy products when added to plant-based alternatives. The outcomes should valorise existing agriculture and food waste, converting waste materials into valuable food ingredients.Read moreRead less
Novel cell wall genes ripe for the picking. This project aims to investigate the role of recently discovered plant cellulose synthase-like CslM genes and to define the polysaccharide product associated with them. Successful identification of the polysaccharide is highly likely to increase our fundamental understanding of how cell walls are made, how cells stick together or fall apart as well as facilitating the training of the next generation of cell wall biologists in challenging molecular and ....Novel cell wall genes ripe for the picking. This project aims to investigate the role of recently discovered plant cellulose synthase-like CslM genes and to define the polysaccharide product associated with them. Successful identification of the polysaccharide is highly likely to increase our fundamental understanding of how cell walls are made, how cells stick together or fall apart as well as facilitating the training of the next generation of cell wall biologists in challenging molecular and biochemical techniques. This new knowledge could increase our understanding of fruit ripening, and how it might be manipulated. This could have significant downstream commercial benefits if applied to breeding programs of economically important fruit such as grapes, tomatoes and strawberries.Read moreRead less