Role of nitrogen and sulphur nutrition in determining quantity and quality of oil in canola seed. Canola is the second most important crop in Australia, with exports worth $1 billion a year. However, competitiveness of Australian canola on the world markets is hampered by low and inconsistent oil content. Nitrogen fertilisation increases seed yield and seed protein content, but decreases oil content. This project will elucidate regulation by nitrogen and sulphur (the other important nutrient in ....Role of nitrogen and sulphur nutrition in determining quantity and quality of oil in canola seed. Canola is the second most important crop in Australia, with exports worth $1 billion a year. However, competitiveness of Australian canola on the world markets is hampered by low and inconsistent oil content. Nitrogen fertilisation increases seed yield and seed protein content, but decreases oil content. This project will elucidate regulation by nitrogen and sulphur (the other important nutrient in canola growth) of protein and oil biosynthesis in developing canola grain. The knowledge generated in this project will allow optimisation of canola agronomy and more effective breeding for increased nitrogen- and sulphur-use efficiency, seed yields and oil content in canola, thus enhancing the competitiveness of Australian canola on the world markets.Read moreRead less
Role of intracellular calcium homeostasis and aluminium transport across the plasma membrane in aluminium toxicity to plants. Aluminium is the most important yield-limiting factor in acid soils throughout the world. The problem of aluminium toxicity is aggravated by continuous acidification of arable land. Mechanisms of aluminium toxicity in plant cells are poorly understood. The present project seeks to elucidate the molecular basis of the interaction between intracellular calcium homeostasis, ....Role of intracellular calcium homeostasis and aluminium transport across the plasma membrane in aluminium toxicity to plants. Aluminium is the most important yield-limiting factor in acid soils throughout the world. The problem of aluminium toxicity is aggravated by continuous acidification of arable land. Mechanisms of aluminium toxicity in plant cells are poorly understood. The present project seeks to elucidate the molecular basis of the interaction between intracellular calcium homeostasis, cytosolic pH and aluminium uptake across the plasma membrane in aluminium toxicity to plants. Knowledge of primary triggers of aluminium toxicity will pay off in a breeding programme aimed at selecting crop genotypes with increased resistance to aluminium toxicity.Read moreRead less
Aluminium uptake across the root-cell plasma membrane. Aluminium toxicity limits crop growth in acid soils that occupy about 24 million hectares of agricultural land in Australia. Liming can increase pH of the surface soil, but is frequently too expensive in the low-input Australian agriculture. Surface-applied lime is poorly effective in ameliorating subsoil acidity, and incorporating lime deep into the profile is prohibitively expensive and technically difficult. Hence, Al-resistant crop culti ....Aluminium uptake across the root-cell plasma membrane. Aluminium toxicity limits crop growth in acid soils that occupy about 24 million hectares of agricultural land in Australia. Liming can increase pH of the surface soil, but is frequently too expensive in the low-input Australian agriculture. Surface-applied lime is poorly effective in ameliorating subsoil acidity, and incorporating lime deep into the profile is prohibitively expensive and technically difficult. Hence, Al-resistant crop cultivars are important part of sustainable farming in Australia. This project will characterise early triggers of Al toxicity in plants, providing a foundation for increasing Al resistance in crop cultivars. Understanding the physiological basis of Al toxicity will lead to improved crop breeding strategies.Read moreRead less
Wheat biomarkers - the effect of nitrogen withdrawal on the proteome and peptidome. Nitrogen is a crucial macroelement for plants. Its importance is highlighted by the wide use of agricultural nitrogen fertilizers in Australia and world wide. This comes at substantial costs for the environment and the economy, due to low nitrogen use efficiency of cereals and environmental impacts. By understanding plant responses to nitrogen we can improve nitrogen efficiency. This project will identify protein ....Wheat biomarkers - the effect of nitrogen withdrawal on the proteome and peptidome. Nitrogen is a crucial macroelement for plants. Its importance is highlighted by the wide use of agricultural nitrogen fertilizers in Australia and world wide. This comes at substantial costs for the environment and the economy, due to low nitrogen use efficiency of cereals and environmental impacts. By understanding plant responses to nitrogen we can improve nitrogen efficiency. This project will identify proteins and peptides as biomarkers of plant responses to nitrogen withdrawal. Such biomarkers can be used in plant breeding and in agricultural prediction of plant nitrogen requirements with the potential to reduce agricultural costs and environmental impacts.Read moreRead less
Molecular analysis of the symbiotic interface of nitrogen-fixing legumes. Some legumes form a symbiosis with soil bacteria (rhizobia) that convert atmospheric nitrogen to ammonia which is then supplied to the plant. This enables legumes to grow without application of nitrogen-based fertilizer, avoiding environmental problems such as run-off and land degradation, thereby contributing to sustainable agriculture practise. We will investigate the interactions between plant and rhizobia, focusing on ....Molecular analysis of the symbiotic interface of nitrogen-fixing legumes. Some legumes form a symbiosis with soil bacteria (rhizobia) that convert atmospheric nitrogen to ammonia which is then supplied to the plant. This enables legumes to grow without application of nitrogen-based fertilizer, avoiding environmental problems such as run-off and land degradation, thereby contributing to sustainable agriculture practise. We will investigate the interactions between plant and rhizobia, focusing on identifying genes and proteins which govern nutrient exchange between the partners and development of the special structures in the roots that house the bacteria. Subsequent manipulation of these genes and proteins may allow us to identify control points and enhance nitrogen fixation.Read moreRead less