Membrane transporters in oxidative stress signalling and tolerance in plants. Oxidative stress imposed by salinity and drought severely limits agricultural crop production, resulting in multibillion dollar losses to farmers. Australia is one of the driest continents, with a significant proportion of arable land affected by salinity. Thus, developing salt- and drought tolerant species is critical to minimise the impact of these stresses on crop production. This project will reveal specific ionic ....Membrane transporters in oxidative stress signalling and tolerance in plants. Oxidative stress imposed by salinity and drought severely limits agricultural crop production, resulting in multibillion dollar losses to farmers. Australia is one of the driest continents, with a significant proportion of arable land affected by salinity. Thus, developing salt- and drought tolerant species is critical to minimise the impact of these stresses on crop production. This project will reveal specific ionic mechanisms mediating reactive oxygen species signalling and tolerance in plants. This will help achieve the above goal by providing plant breeders with vital information on key genes controlling oxidative stress tolerance in plants. Read moreRead less
Novel laser isotopic techniques to assess the potential for water-use efficiency improvement of Australian crops. This project aims to develop new methods to reduce the water used by grain crops while maintaining productivity by advancing knowledge of the regulation plant carbon gain and water loss. Novel laser-lased measurement systems developed and applied in this project will provide new mechanistic understanding of plant carbon-water dynamics for individual leaves and at the whole crop scal ....Novel laser isotopic techniques to assess the potential for water-use efficiency improvement of Australian crops. This project aims to develop new methods to reduce the water used by grain crops while maintaining productivity by advancing knowledge of the regulation plant carbon gain and water loss. Novel laser-lased measurement systems developed and applied in this project will provide new mechanistic understanding of plant carbon-water dynamics for individual leaves and at the whole crop scale. Water availability is the most pressing environmental issue facing the Australian grain industry, so improvements in the efficiency with which water is used will have profound economic and environmental effects.Read moreRead less
Stomatal function in transgenic plants with altered guard cell metabolism. Guard cells on the surface of leaves control the rate of water loss and CO2 uptake by changing stomatal aperture in response to environmental signals such light, CO2, humidity and water status. Guard cells therefore play a major role in determining plant productivity and water use efficiency. This project aims to examine the contribution of guard cell energy and carbon metabolism in mediating stomatal responses to the env ....Stomatal function in transgenic plants with altered guard cell metabolism. Guard cells on the surface of leaves control the rate of water loss and CO2 uptake by changing stomatal aperture in response to environmental signals such light, CO2, humidity and water status. Guard cells therefore play a major role in determining plant productivity and water use efficiency. This project aims to examine the contribution of guard cell energy and carbon metabolism in mediating stomatal responses to the environment in intact plants through the generation and analysis of transgenic plants with altered guard cell function. This will aid in the development of strategies for direct manipulation of stomatal function.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
Functional characterisation of novel transport protein in plants. The products of plants provide the food we eat, the air we breath and it is recognised that they play an integral role in defining and protecting the environment. Thus it is essential to understand how plant work to allow their use in novel applications and to adapt to changing environments. Many aspects of plant metabolism are unique to plants and thus we cannot guess or estimate importance from studies in animals or fungi. Appro ....Functional characterisation of novel transport protein in plants. The products of plants provide the food we eat, the air we breath and it is recognised that they play an integral role in defining and protecting the environment. Thus it is essential to understand how plant work to allow their use in novel applications and to adapt to changing environments. Many aspects of plant metabolism are unique to plants and thus we cannot guess or estimate importance from studies in animals or fungi. Approximately 4,000 proteins are specific to plants, or contain domains that are unique to plants. This investigation proposes to elucidate the function of some of these novel proteins, transporters, that play a critical role in transport processes in cells.Read moreRead less
Plant Protein Signalling Networks. We will assess the functional role of PNPs (novel plant protein hormones) at a biochemical, molecular and cellular level. Importantly, as stresses from climatic extremes are increasing, this will lead to new insights and critical appreciation of the processes plants use to regulate their water status. Since water and solute status underpins the regulation of plant growth and development, these findings will have a major impact on both agriculture and horticul ....Plant Protein Signalling Networks. We will assess the functional role of PNPs (novel plant protein hormones) at a biochemical, molecular and cellular level. Importantly, as stresses from climatic extremes are increasing, this will lead to new insights and critical appreciation of the processes plants use to regulate their water status. Since water and solute status underpins the regulation of plant growth and development, these findings will have a major impact on both agriculture and horticulture in Australia. The new insights that we gain can be used to directly accelerate progress towards the development of plants with improved drought and salinity tolerance that will lead to better crop and pasture productivity under harsh Australian conditions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989408
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A multiple-ion membrane inlet mass spectrometer. There is a compelling need for a modern isotope-ratio mass spectrometer to facilitate a range of innovative studies of chemical and biochemical processes. Mass spectrometers operated with a thin permeable membrane over a vacuum inlet allow small gas molecules to be continuously monitored inside specific gas or liquid phase sample chambers. The proposed instrumentation will enable simultaneous and highly sensitive measurement of 10 different isot ....A multiple-ion membrane inlet mass spectrometer. There is a compelling need for a modern isotope-ratio mass spectrometer to facilitate a range of innovative studies of chemical and biochemical processes. Mass spectrometers operated with a thin permeable membrane over a vacuum inlet allow small gas molecules to be continuously monitored inside specific gas or liquid phase sample chambers. The proposed instrumentation will enable simultaneous and highly sensitive measurement of 10 different isotopic species and the capability for detection of hydrogen. This equipment will provide the many researchers and students with opportunities to determine isotopic signatures of isolated chemical reactions through to complex biochemical systems of whole living cells.Read moreRead less
Metabolomic and genetic approaches to the discovery of genes that direct carbon partitioning in plants. Plants make starch, sucrose, cell walls (fibre), oil, organic acids, vitamins and other products of great economic and social importance. The partitioning of carbon resources into such products determines crop productivity and quality. This partitioning is strongly influenced by nutrients, water and salinity. The powerful genomics resources of Arabidopsis including the new discipline of metabo ....Metabolomic and genetic approaches to the discovery of genes that direct carbon partitioning in plants. Plants make starch, sucrose, cell walls (fibre), oil, organic acids, vitamins and other products of great economic and social importance. The partitioning of carbon resources into such products determines crop productivity and quality. This partitioning is strongly influenced by nutrients, water and salinity. The powerful genomics resources of Arabidopsis including the new discipline of metabolomics, will be deployed to understand the regulation of carbon partitioning in leaves and to discover genes that direct partitioning. National research capability will be enhanced and new resources will be generated to breed crops with improved yield potential and product quality under varied environmental conditions.Read moreRead less
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
Discovery of the physiological and molecular modes of action of butenolides in promoting seed germination and vigour in plants. The Australian discovery of butenolides opens up a new scientific frontier and new opportunities for land management, plant conservation and agriculture. Butenolides will be used to promote seed germination and plant growth in land reclamation, in conservation of species, to break dormancy in weeds so that they can be eradicated, and to promote germination and vigour in ....Discovery of the physiological and molecular modes of action of butenolides in promoting seed germination and vigour in plants. The Australian discovery of butenolides opens up a new scientific frontier and new opportunities for land management, plant conservation and agriculture. Butenolides will be used to promote seed germination and plant growth in land reclamation, in conservation of species, to break dormancy in weeds so that they can be eradicated, and to promote germination and vigour in crops. Realising the full potential of butenolides demands that we understand how they work so that creative approaches can be developed that may not even require use of the chemical. Crucially by achieving these aims ahead of international competitors we can ensure that Australia gains maximum benefit.Read moreRead less