Molecular mechanisms governing the role of calcium in aluminium toxicity and tolerance in 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 and plasma membrane potential ....Molecular mechanisms governing the role of calcium in aluminium toxicity and tolerance in 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 and plasma membrane potential 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
The Betaproteobacteria: could they play a key role in nitrogen fixation on infertile soils with legumes adapted to climate change? Microbial biosecurity is often overlooked when introducing agricultural species to Australia. As we research new legume species to make our $44 billion agricultural industries robust in the face of a changing climate, we need to be aware of the implications of the associated introduction of (beneficial) microbes. By exploring the globe for plants from regions that al ....The Betaproteobacteria: could they play a key role in nitrogen fixation on infertile soils with legumes adapted to climate change? Microbial biosecurity is often overlooked when introducing agricultural species to Australia. As we research new legume species to make our $44 billion agricultural industries robust in the face of a changing climate, we need to be aware of the implications of the associated introduction of (beneficial) microbes. By exploring the globe for plants from regions that already have the climate we are transitioning towards, we have discovered new perennial forage legumes from which we can build a robust agriculture in the arid regions of southern Australia. This will have enormous national benefit in rural regions. This project will research the essential microbial inoculants associated with these new plants.Read moreRead less
Role of organic matter and soil biota in optimising crop nutrition in sustainable farming systems. Australian grain producers face increasing competition on the world market from countries with cheap production costs (China, Argentina, Brazil). This project will develop biological farming systems based on improving soil health and enhancing soil microflora and nutrient cycling. Western Australia and other states are currently defining certification guidelines for sustainable farming systems (inc ....Role of organic matter and soil biota in optimising crop nutrition in sustainable farming systems. Australian grain producers face increasing competition on the world market from countries with cheap production costs (China, Argentina, Brazil). This project will develop biological farming systems based on improving soil health and enhancing soil microflora and nutrient cycling. Western Australia and other states are currently defining certification guidelines for sustainable farming systems (including biological ones). Selling grain produced in certified biological farming system will attract market premium, therefore enhancing the position of Australian farmers. This project will produce fertiliser recommendation systems incorporating organic fertilisers, thus decreasing costs of production and maintaining clean and healthy environment.Read moreRead less
Modelling spatial and temporal dynamics of rhizosphere exudation. Existing crop root systems are poorly suited to Australian soils with low nutrient availability. Using a simulation model to develop computer-aided design of 3-D root structure and function, tailored to particular environments, this project will enhance breeding for increased nutrient-use efficiency.
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239218
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Proteomics facility for biotechnology research in WA. The aim of this application is to establish a fully functional proteomics facility to underpin the future research of many groups in four WA institutions. While molecular biological research has thus far concentrated on molecular genetics, it is now vital to directly examine the patterns of proteins expressed by cells to understand their molecular mechanisms. Individual WA researchers have already ventured into proteomics, utilising facilit ....Proteomics facility for biotechnology research in WA. The aim of this application is to establish a fully functional proteomics facility to underpin the future research of many groups in four WA institutions. While molecular biological research has thus far concentrated on molecular genetics, it is now vital to directly examine the patterns of proteins expressed by cells to understand their molecular mechanisms. Individual WA researchers have already ventured into proteomics, utilising facilities located elsewhere in Australia. The reliance on other groups to conduct their proteomics, which are rapidly becoming basic techniques for competitive molecular biological research, is a serious obstacle to biotechnological research in WA.Read moreRead less
Tightening the phosphorus cycle for grain legumes. Using unique core collections of chickpea, soybean and peanut with diverse genetic backgrounds, this project aims to unravel the mechanisms underlying high phosphorus-use efficiency (PUE) at morphological, physiological, biochemical and molecular levels in three major legume crops. Reduced levels of phosphorus and phytate in seeds will improve seed quality for humans and livestock and dramatically reduce phosphorus-fertiliser inputs. The identif ....Tightening the phosphorus cycle for grain legumes. Using unique core collections of chickpea, soybean and peanut with diverse genetic backgrounds, this project aims to unravel the mechanisms underlying high phosphorus-use efficiency (PUE) at morphological, physiological, biochemical and molecular levels in three major legume crops. Reduced levels of phosphorus and phytate in seeds will improve seed quality for humans and livestock and dramatically reduce phosphorus-fertiliser inputs. The identification of traits and genes associated with high PUE will allow transfer of key traits into commercial cultivars using molecular breeding approaches. Cultivars with improved PUE will enable reduced phosphate fertiliser input and loss of phosphate in runoff from agricultural systems.Read moreRead less
Determination of factors responsible for aphid-borne pea seed-borne mosaic virus epidemics in peas and development of effective virus management tools. Aphid-borne virus epidemics threaten Australia’s $64 million per annum field pea industry. Factors affecting aphid survival within and outside growing seasons, time of first arrival in crops, and virus epidemic development will be identified. A forecasting model and Decision Support System will minimise the losses and permit industry expansion to ....Determination of factors responsible for aphid-borne pea seed-borne mosaic virus epidemics in peas and development of effective virus management tools. Aphid-borne virus epidemics threaten Australia’s $64 million per annum field pea industry. Factors affecting aphid survival within and outside growing seasons, time of first arrival in crops, and virus epidemic development will be identified. A forecasting model and Decision Support System will minimise the losses and permit industry expansion to new areas.Read moreRead less