The metabolic footprint of plants. Plant roots "leak" 5-10% of the C fixed in photosynthesis. Surprisingly, we have a limited understanding of which compounds leak from roots.This project will identify the compounds leaking from roots and explore their function in tolerance of biotic and abiotic stress and implications for soil respiration.
ARC Centre of Excellence for Plant Success in Nature and Agriculture. The ARC CoE for Plant Success in Nature and Agriculture will discover the adaptive strategies underpinning productivity and resilience in diverse plants and deepen knowledge of the genetic and physiological networks driving key traits. Using novel quantitative and computational approaches, the Centre will link gene networks with traits across biological levels, giving breeders an unparalleled predictive capacity. The Centre wi ....ARC Centre of Excellence for Plant Success in Nature and Agriculture. The ARC CoE for Plant Success in Nature and Agriculture will discover the adaptive strategies underpinning productivity and resilience in diverse plants and deepen knowledge of the genetic and physiological networks driving key traits. Using novel quantitative and computational approaches, the Centre will link gene networks with traits across biological levels, giving breeders an unparalleled predictive capacity. The Centre will accelerate technologies to transfer successful networks into crops and build legal frameworks to secure this knowledge. With a uniquely multidisciplinary team, the Centre will deliver new strategies to address the problems of food security and climate change, establishing Australia as a global leader in these areas.Read moreRead less
Molecular adaptation of photosynthesis powered by long-wavelength light. Some photosynthetic organisms have a remarkable ability to accumulate long-wavelength absorbing photopigments, such as chlorophyll f, in response to the changed light and nutrient environments. The project aims to demonstrate that the structure and function of undefined chlorophyll f-binding proteins can be changed and controlled in desired light and nutrient conditions. The optimised photosynthesis strengthens their adapta ....Molecular adaptation of photosynthesis powered by long-wavelength light. Some photosynthetic organisms have a remarkable ability to accumulate long-wavelength absorbing photopigments, such as chlorophyll f, in response to the changed light and nutrient environments. The project aims to demonstrate that the structure and function of undefined chlorophyll f-binding proteins can be changed and controlled in desired light and nutrient conditions. The optimised photosynthesis strengthens their adaptation capability and challenges the long wavelength limits of photosynthesis. The research outcome will provide tools and a molecular blueprint for the adaptation of photosynthesis with optimised energy transfer pathway and efficiency for potential future molecular applications. Read moreRead less
Wall ingrowth formation in plant transfer cells - discovering regulatory transcription factor cascades. This project will discover how specialised plant 'transfer cells', designed for optimum transport of nutrients, develop complex wall ingrowths. Discovering the genes which regulate wall ingrowth deposition in these cells will generate opportunities to improve crop yield and therefore contribute to addressing global food security.
Targeting chloroplasts to enhance crop salt tolerance. Yield losses in crop plants due to increasingly saline soils are linked to the effects of salt on chloroplasts. By comparing chloroplast water- and salt-transport mechanisms of closely related salt-loving and salt-sensitive plants, this Fellowships aims to discover how chloroplasts maintain function in saline conditions. Novel biophysics and molecular techniques will be used to characterise transporters in model plants, and proof-of-concept ....Targeting chloroplasts to enhance crop salt tolerance. Yield losses in crop plants due to increasingly saline soils are linked to the effects of salt on chloroplasts. By comparing chloroplast water- and salt-transport mechanisms of closely related salt-loving and salt-sensitive plants, this Fellowships aims to discover how chloroplasts maintain function in saline conditions. Novel biophysics and molecular techniques will be used to characterise transporters in model plants, and proof-of-concept complementation experiments aim to confer salt tolerance on sensitive plants. These fundamental insights are likely to lead to rapid, step-change improvements in salt tolerance, especially in agriculturally relevant crops, to benefit Australia’s agri-industry and ensure food security in the future.Read moreRead less
Advanced cryobanking for recalcitrant-seeded Australian rainforest plants. This project aims to develop an interdisciplinary research alliance to enhance the efficiency of ecological restoration for recalcitrant Australian rainforest plant species. The project expects to provide fundamental knowledge to target two major impediments to cryostorage of recalcitrant-seeded native species: desiccation sensitivity with relatively large size, and active metabolism and precocious germination. These attr ....Advanced cryobanking for recalcitrant-seeded Australian rainforest plants. This project aims to develop an interdisciplinary research alliance to enhance the efficiency of ecological restoration for recalcitrant Australian rainforest plant species. The project expects to provide fundamental knowledge to target two major impediments to cryostorage of recalcitrant-seeded native species: desiccation sensitivity with relatively large size, and active metabolism and precocious germination. These attributes severely limit the time available for effective use of collected germplasm for long-term storage. A combination of biochemical, biophysical and molecular simulation approaches will be used to optimise cryopreservation of a wide range of endangered Australian rainforest species. This should provide significant benefits such as enabling conservation agencies to greatly enhance their ability to preserve the unique Australian rainforest flora, particularly given current threats due to habitat loss and global warming.Read moreRead less
Limits to the resilience of Australian forests and woodlands to drought. Water availability is a primary determinant of plant growth and the distribution of plant species and communities throughout the world. In Australia, climate change is predicted to result in increasing temperatures and shifting precipitation patterns, leading to more intense droughts in some areas. This project will examine the resilience of Australian forests and woodlands to drought under both current and future climate s ....Limits to the resilience of Australian forests and woodlands to drought. Water availability is a primary determinant of plant growth and the distribution of plant species and communities throughout the world. In Australia, climate change is predicted to result in increasing temperatures and shifting precipitation patterns, leading to more intense droughts in some areas. This project will examine the resilience of Australian forests and woodlands to drought under both current and future climate scenarios. The results of this work will feed into the new generation of dynamic global vegetation models, allowing for robust prediction of changes in the structure and productivity of Australian vegetation communities in the face of rapid climate change.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
Identification of novel plant transporters responsible for sucrose efflux. This project aims to clone and functionally characterise previously unknown membrane proteins that facilitate high rates of sucrose efflux from cells located at key transport bottlenecks regulating sucrose transport throughout the plant body and hence plant productivity. These aims will be realised through employing systems specifically designed to clone and functionally characterise sucrose efflux proteins encoded in pla ....Identification of novel plant transporters responsible for sucrose efflux. This project aims to clone and functionally characterise previously unknown membrane proteins that facilitate high rates of sucrose efflux from cells located at key transport bottlenecks regulating sucrose transport throughout the plant body and hence plant productivity. These aims will be realised through employing systems specifically designed to clone and functionally characterise sucrose efflux proteins encoded in plant genomes. Expected outcomes will be an understanding of sucrose transport throughout the plant body, build a valuable international partnership and open up new biotechnological opportunities to improve crop yield.Read moreRead less
Plant transfer cells: discovering regulatory mechanisms directing assembly of their ingrowth walls. Specialised transfer cells facilitate nutrient transport within plants which is essential for their growth. This project will explore how structural and functional changes are regulated to form a transfer cell. The results of this research will contribute to scientific knowledge applicable to increasing crop yield.