Translocated signals regulating stem cell (meristem) activity in legumes. Translocation channels of phloem and xylem allocate nutrients to growing plant organs. They also mediate communication between organs through transport of signals that elicit responses to developmental and environmental cues. The most important sites for signal transduction are the stem cells of root and shoot apical meristems. This project will discover and identify these signals using a metabolomic/proteomic approach an ....Translocated signals regulating stem cell (meristem) activity in legumes. Translocation channels of phloem and xylem allocate nutrients to growing plant organs. They also mediate communication between organs through transport of signals that elicit responses to developmental and environmental cues. The most important sites for signal transduction are the stem cells of root and shoot apical meristems. This project will discover and identify these signals using a metabolomic/proteomic approach and relying on a unique feature of lupin that permits collection of transport fluids. The project will identify ways to modify signal action to enhance performance of legumes.Read moreRead less
What is the function of gamma-aminobutyric acid-gated anion channels in plants? The project will identify the molecular basis of gamma-aminobutyric acid (GABA) signalling in plants. This is significant because GABA regulates proteins that release molecules involved in root-soil interactions, growth, and fertilisation. The project's discoveries will allow improvement of these agronomic traits that ultimately determine crop yield.
Functional network analysis of plant metabolism in response to salinity and temperature through targeted proteomics. This project will measure changes in plant metabolism and provide methods and a pipeline for quantification and modelling. It will assess nitrogen linked metabolism under environmental stress experienced in Australian wheat cropping systems and build fundamental knowledge of changes in networks of nitrogen metabolism in model plants.
Functional genomics approaches to the mechanisms of starch mobilisation in Arabidopsis. Starch is a key carbon and energy reserve that underpins plant growth. This in turn underpins much of Australia's $60 billion agriculture industry. Starch also provides most of the calories in the human diet and is a renewable commodity supporting manufacturing industries. Dependence of society on starch will increase as it becomes used more for novel materials and for bio-ethanol production, which in turn w ....Functional genomics approaches to the mechanisms of starch mobilisation in Arabidopsis. Starch is a key carbon and energy reserve that underpins plant growth. This in turn underpins much of Australia's $60 billion agriculture industry. Starch also provides most of the calories in the human diet and is a renewable commodity supporting manufacturing industries. Dependence of society on starch will increase as it becomes used more for novel materials and for bio-ethanol production, which in turn will create new jobs in the rural economy. A major quality problem in cereal grain is pre-harvest starch breakdown caused by warm wet weather triggering events associated with germination. By understanding starch metabolism in plants we will be better able to manage and enhance growth of crop plants, starch production and seed quality.Read moreRead less
A signalling pathway for future crop improvement. This project aims to decipher a mechanism that controls plant gas exchange – the process that emits oxygen, loses water, absorbs carbon dioxide and is essential for plant growth for food, fibre and fuel production. When plants encounter stressful conditions such as drought, high temperatures or flooding, they adapt their physiology to maintain viability and re-establish growth. This project will manipulate stress-induced gamma-aminobutyric acid’s ....A signalling pathway for future crop improvement. This project aims to decipher a mechanism that controls plant gas exchange – the process that emits oxygen, loses water, absorbs carbon dioxide and is essential for plant growth for food, fibre and fuel production. When plants encounter stressful conditions such as drought, high temperatures or flooding, they adapt their physiology to maintain viability and re-establish growth. This project will manipulate stress-induced gamma-aminobutyric acid’s capacity to control plant gas exchange to help secure future food production, through improving crop tolerance to stresses such as low water availability and high temperatures – conditions associated with a changing Australian climate.Read moreRead less
Dissecting chloride transport in plants to secure an untapped source for improving plant productivity. Chloride and nitrate are central to physiological processes that determine crop yield and food production, but their uptake and transport within the plant body are antagonistic. This project will gain a fundamental understanding of the mechanisms underlying this antagonism. This will provide new tools for improving salinity tolerance and the efficiency of fertiliser use, which can be used for t ....Dissecting chloride transport in plants to secure an untapped source for improving plant productivity. Chloride and nitrate are central to physiological processes that determine crop yield and food production, but their uptake and transport within the plant body are antagonistic. This project will gain a fundamental understanding of the mechanisms underlying this antagonism. This will provide new tools for improving salinity tolerance and the efficiency of fertiliser use, which can be used for the development of new crop varieties. Improving these traits will be essential if we are to successfully address the threats to Australian and global food security posed by salinity, and the rising economic and environmental costs of inefficient fertiliser use.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101117
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding the molecular machines making proteins essential for life: investigating specialisation of plastid ribosome composition and function. Plastid ribosomes are complex molecular machines responsible for the production of proteins required for photosynthesis, a process which underlies global food and oxygen production. By determining if distinct plastid types have ribosomes that differ in both composition and function, the project could benefit biotechnological applications.
Regulation and role of metabolic networks for respiration in plants. This project aims to understand the regulation of respiration in plants which underpins the energy provision that cells need to operate. Understanding respiration and how it responds to the changing environment is a building block needed for rational engineering of our future food from plants.
Characterizing the regulators of mitochondrial biogenesis in Arabidopsis thaliana. The overall aim of this project is to identify and characterise the underlying regulatory factors that control mitochondrial mass and number in plants. The project will exploit a regulatory mechanism that links the mitochondrial import machinery and the respiratory chain. Utilising both forward and reverse genetic approaches, the abundances of protein import translocases will be altered and the changes to mitochon ....Characterizing the regulators of mitochondrial biogenesis in Arabidopsis thaliana. The overall aim of this project is to identify and characterise the underlying regulatory factors that control mitochondrial mass and number in plants. The project will exploit a regulatory mechanism that links the mitochondrial import machinery and the respiratory chain. Utilising both forward and reverse genetic approaches, the abundances of protein import translocases will be altered and the changes to mitochondrial biogenesis will be investigated. This will identify regulatory factors, which can be manipulated and used to alter mitochondrial number and activity.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100044
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
New facilities for multiplex gas-exchange (MGX) measurements of plant performance during climate-controlled growth. Precise study of oxygen and carbon dioxide gas exchange can quantify the underlying factors responsible for plant growth. This dedicated facility will increase the scope and accuracy of Australian research into plant productivity thereby allowing improved understanding of factors affecting plants' adaptability to environmental change and plant competition or pathogen effects.