Functional characterisation of the necrotrophic effector proteins Tox1 and Tox3 from the wheat pathogen Stagonospora nodorum. Fungal pathogens cost the Australian agricultural industry over one billion dollars per year. This project will build upon recent key advances to provide a fundamental basis on how fungal pathogens cause disease. The results from this study will promote future advances in disease management with the aim of securing Australian wheat supplies.
Discovery Early Career Researcher Award - Grant ID: DE210100466
Funder
Australian Research Council
Funding Amount
$427,623.00
Summary
Decrypting chloroplast signalling in C4 photosynthesis under heat stress. This project aims to fill a critical knowledge gap in how photosynthesis, chloroplast signals, metabolism and cell specialisation are coordinated for stress acclimation in plants. It aims to dissect the complex interactions between a) cellular distress signals produced by chloroplasts with b) reactive radicals and c) plant metabolism during heat stress. It expects to provide the first insights into chloroplast signalling c ....Decrypting chloroplast signalling in C4 photosynthesis under heat stress. This project aims to fill a critical knowledge gap in how photosynthesis, chloroplast signals, metabolism and cell specialisation are coordinated for stress acclimation in plants. It aims to dissect the complex interactions between a) cellular distress signals produced by chloroplasts with b) reactive radicals and c) plant metabolism during heat stress. It expects to provide the first insights into chloroplast signalling critical for heat-tolerant C4 photosynthesis which is active in two specialised leaf cell types in cereals such as maize and sorghum. Expected outcomes include an unprecedented cell-level resolution map of chloroplast signalling, which will benefit the engineering of improved photosynthesis into crops. Read moreRead less
Can altered sugar sensing improve crop productivity? This project aims at genetically manipulating sugar sensing pathways in the model C4 grass Setaria viridis, and at replacing sugar sensors in the model C3 crop Oryza sativa (rice) with those from S. viridis. This project expects to elucidate the impact of altered sugar perception on crop photosynthesis and yield. Expected outcomes includes advancing a novel “pull” approach to improve yield in C3 crops by using C4-like sugar sensors to reduce f ....Can altered sugar sensing improve crop productivity? This project aims at genetically manipulating sugar sensing pathways in the model C4 grass Setaria viridis, and at replacing sugar sensors in the model C3 crop Oryza sativa (rice) with those from S. viridis. This project expects to elucidate the impact of altered sugar perception on crop photosynthesis and yield. Expected outcomes includes advancing a novel “pull” approach to improve yield in C3 crops by using C4-like sugar sensors to reduce feedback regulation of photosynthesis which in turn limits productivity. This is in contrast to previous ‘push’ approaches aimed at directly increasing photosynthesis. Hence, this project provides significant benefits by contributing to the next green revolution needed to lift agricultural yields.Read moreRead less
Enhancing and manipulating C4 photosynthesis. To meet the challenge of increasing crop yield for a burgeoning world population, it has become apparent that photosynthetic capacity must be increased per unit leaf area to improve yield potential. Plants with the C4 photosynthetic pathway are major contributors to world food production and bioenergy supply. The aim of this study is to explore ways of enhancing C4 photosynthesis using directed molecular modifications of Setaria viridis, the model mo ....Enhancing and manipulating C4 photosynthesis. To meet the challenge of increasing crop yield for a burgeoning world population, it has become apparent that photosynthetic capacity must be increased per unit leaf area to improve yield potential. Plants with the C4 photosynthetic pathway are major contributors to world food production and bioenergy supply. The aim of this study is to explore ways of enhancing C4 photosynthesis using directed molecular modifications of Setaria viridis, the model monocot C4 species, and through high throughput fluorescence imaging of photosynthesis in Setaria italica accessions. This will provide new insights into rate limiting steps of C4 photosynthesis needed for C4 crop improvement.Read moreRead less
ARC Centre of Excellence in Plant Energy Biology. We propose a novel approach to improve sustainable yield by optimising the overall efficiency of energy capture, conversion and use by plants. Efficiency gains in metabolism, transport, and development will be more effective than optimising single nutrient inputs or product outputs. Improving multiple parameters simultaneously is a necessary solution to the increasing demand for more crop yield from finite land, water, and nutrient resources. Unp ....ARC Centre of Excellence in Plant Energy Biology. We propose a novel approach to improve sustainable yield by optimising the overall efficiency of energy capture, conversion and use by plants. Efficiency gains in metabolism, transport, and development will be more effective than optimising single nutrient inputs or product outputs. Improving multiple parameters simultaneously is a necessary solution to the increasing demand for more crop yield from finite land, water, and nutrient resources. Unpredictable environmental challenges adversely affect plant growth and further perturb plant energy balance, limiting yield. The epigenetic controls, gene variants and signals discovered will provide a new basis for sustainable productivity of crops and will future-proof plants in changing climates.Read moreRead less
Improving plant reproductive success under heat stress: A sweet approach. This project aims to determine how genetic manipulation of cell wall invertase (CWIN) activity could regulate pollen germination, elongation and fruit set under heat stress using tomato as a model. Plant reproductive processes are highly susceptible to heat stress, which often leads to pollination failure and fruit and seed abortion, hence irreversible yield loss. Research has established that CWIN-mediated sugar metabolis ....Improving plant reproductive success under heat stress: A sweet approach. This project aims to determine how genetic manipulation of cell wall invertase (CWIN) activity could regulate pollen germination, elongation and fruit set under heat stress using tomato as a model. Plant reproductive processes are highly susceptible to heat stress, which often leads to pollination failure and fruit and seed abortion, hence irreversible yield loss. Research has established that CWIN-mediated sugar metabolism and signaling may play crucial roles in pollen growth and fruit set under heat stress. The intended outcome is the generation of critical knowledge that will advance understanding on reproductive development under heat stress, thereby providing significant benefits, such as novel ideas and solutions for improving crop yield.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.
Oxygen isotope discrimination during C4 photosynthesis. Plants with the C4 photosynthetic pathway, like sugarcane and pasture grasses, are vital to Australian agriculture and natural ecosystems. This project will use novel laser spectroscopy to measure oxygen isotope discrimination during photosynthesis and quantify the influence of C4 plants on isotopic signatures of atmospheric CO2.
Discovery Early Career Researcher Award - Grant ID: DE140101143
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
An electrophysiological insight into the role of chloroplasts in stomatal drought signalling. Drought implies a range of stresses with which plants have to cope. Drought is not only a domestic issue for Australian people who live in this dry continent but also significantly affects global food supply and drives climate change. Stomata guard cells exert major controls on global water and carbon cycles. Although the total stomatal pore area may be five per cent of a leaf surface, transpirational w ....An electrophysiological insight into the role of chloroplasts in stomatal drought signalling. Drought implies a range of stresses with which plants have to cope. Drought is not only a domestic issue for Australian people who live in this dry continent but also significantly affects global food supply and drives climate change. Stomata guard cells exert major controls on global water and carbon cycles. Although the total stomatal pore area may be five per cent of a leaf surface, transpirational water loss through the stomata contributes to 70 per cent of total agricultural water usage. As an environmental signal, drought regulates stomatal movements. This project seeks to understand the mechanisms of drought induced molecular retrograde signals and their regulation over stomata. The outcomes will aid the development of strategies for reducing water loss from crops.Read moreRead less