Improving production of essential oils from Australian trees. Production of essential oils from eucalypts and tea tree is an important rural industry in Australia but we are only a minor producer worldwide. Using new genetic discoveries about how plants make oils, this project will help the industry improve the yield and profitability from both eucalypts and tea tree and contribute new technologies to rural industry.
Re-evaluating the nature, origins and roles of terpenes in Eucalyptus. Terpenes give eucalypts their characteristic smell and mediate many interactions between trees and the environment. Studies of the genome show that eucalypts have more genes to make terpenes than any other plant. Our knowledge of the chemistry and roles of these terpenes is confined to leaves but almost half of the genes occur in roots, wood and bark and there is little idea what their roles are. This project will conduct the ....Re-evaluating the nature, origins and roles of terpenes in Eucalyptus. Terpenes give eucalypts their characteristic smell and mediate many interactions between trees and the environment. Studies of the genome show that eucalypts have more genes to make terpenes than any other plant. Our knowledge of the chemistry and roles of these terpenes is confined to leaves but almost half of the genes occur in roots, wood and bark and there is little idea what their roles are. This project will conduct the first comprehensive study of terpenes in Eucalyptus to identify where and how they are made in the plant, how the major compounds evolved and how terpenes contribute to defence against insects, atmospheric emissions and the composition of soil.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100180
Funder
Australian Research Council
Funding Amount
$299,105.00
Summary
Gas chromatography: separating inseparables, identifiying unidentifiables. This project aims to provide researchers with an integrated capability for separation, isolation, and precise structural identification of volatile compounds. It expects to deliver a systematic solution using unprecedented, automated multidimensional gas chromatographic separation, isolating pure compounds for off-line characterisation using appropriate spectroscopic tools, for example nuclear magnetic resonance. This wi ....Gas chromatography: separating inseparables, identifiying unidentifiables. This project aims to provide researchers with an integrated capability for separation, isolation, and precise structural identification of volatile compounds. It expects to deliver a systematic solution using unprecedented, automated multidimensional gas chromatographic separation, isolating pure compounds for off-line characterisation using appropriate spectroscopic tools, for example nuclear magnetic resonance. This will provide significant benefits, such as permitting traceability of (bio)-synthetic pathways, better characterise chemical signalling in plants, accelerate identification of advanced intermediates required for total synthesis of alkaloids, improve detection of metabolites, and determine interactions between small allergens and proteins.Read moreRead less
Combating myrtle rust, a new disease threatening Australia’s unique flora. This project aims to reduce the impact of myrtle rust, an invasive plant disease. Myrtle rust is a globally significant biodiversity threat that is rapidly spreading to new regions. It affects many iconic native species as well as impacting commercial industries. The expected project outcomes are; a comprehensive understanding of the host genes involved in successful plant defence, and of the pathogen genes involved in th ....Combating myrtle rust, a new disease threatening Australia’s unique flora. This project aims to reduce the impact of myrtle rust, an invasive plant disease. Myrtle rust is a globally significant biodiversity threat that is rapidly spreading to new regions. It affects many iconic native species as well as impacting commercial industries. The expected project outcomes are; a comprehensive understanding of the host genes involved in successful plant defence, and of the pathogen genes involved in the establishment of parasitism. The project will employ new approaches that enhance the application of biotechnology to Australian biosecurity. Key expected benefits are; gene-specific tools for plant breeders and conservation land managers, and improved preparedness for the threat posed by new rust strains.Read moreRead less
Boosting C4 photosynthesis to climate proof crop yields. Building next generation C4 crops, such as maize, sugarcane and sorghum, to cope with drought and heat stress is requisite to ensure the supply of food and fodder. Here we will increase the content and / or catalytic efficiency of the primary carboxylase of C4 photosynthesis (PEPC) that supplies CO2 to the carbon concentrating mechanism and ensures high photosynthetic rates. We will develop new SynBio tools to create and test novel PEPC is ....Boosting C4 photosynthesis to climate proof crop yields. Building next generation C4 crops, such as maize, sugarcane and sorghum, to cope with drought and heat stress is requisite to ensure the supply of food and fodder. Here we will increase the content and / or catalytic efficiency of the primary carboxylase of C4 photosynthesis (PEPC) that supplies CO2 to the carbon concentrating mechanism and ensures high photosynthetic rates. We will develop new SynBio tools to create and test novel PEPC isoforms with desirable properties. Ultimately, the project aims to identify isoforms that improve plant fitness under stress conditions. Optimising PEPC activity will provide next generation solutions to improve water balance and carbon assimilation to keep C4 crops productive under future climates.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100046
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Capturing highly beneficial and persistent legume symbionts. This project aims to investigate impacts of climate change on the survival of symbiotic soil bacteria and the nutritional benefits they provide plants, using molecular technology. This project will generate new knowledge about the process of adaptation in symbiotic bacteria, by measuring genomic changes. Expected outcomes of this project include enhanced capacity to design ecological or genetic manipulations of soil bacteria to augment ....Capturing highly beneficial and persistent legume symbionts. This project aims to investigate impacts of climate change on the survival of symbiotic soil bacteria and the nutritional benefits they provide plants, using molecular technology. This project will generate new knowledge about the process of adaptation in symbiotic bacteria, by measuring genomic changes. Expected outcomes of this project include enhanced capacity to design ecological or genetic manipulations of soil bacteria to augment plant survival and health. Anticipated benefits include enhanced woodland restoration in a biodiversity hotspot, options to mitigate habitat damage from climate change, and strategies to increase agricultural productivity with less fertiliser.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.
Discovery Early Career Researcher Award - Grant ID: DE190100326
Funder
Australian Research Council
Funding Amount
$419,406.00
Summary
Genomics of drought adaptation in endangered Eucalyptus woodlands. This project aims to investigate divergence in drought response strategies among foundation Eucalyptus species, using the latest genomic advances. The project expects to contribute new knowledge of drought adaptation in trees, specifically identifying above and below ground interactions that may constrain evolutionary responses to climate change by assessing genotype-trait associations in an integrated, whole plant research model ....Genomics of drought adaptation in endangered Eucalyptus woodlands. This project aims to investigate divergence in drought response strategies among foundation Eucalyptus species, using the latest genomic advances. The project expects to contribute new knowledge of drought adaptation in trees, specifically identifying above and below ground interactions that may constrain evolutionary responses to climate change by assessing genotype-trait associations in an integrated, whole plant research model. Expected outcomes include enhanced capacity to design agroforestry and restoration breeding programs to increase tree productivity and resilience under increasing aridity. This will benefit the conservation of endangered Australian woodlands, restoration of degraded landscapes, and production forestry.Read moreRead less
Combining new synthetic biology tools to boost crop CO2 capture and growth. A solution for improving crop yield is to enhance the carbon dioxide fixation properties of the enzyme Rubisco whose inefficient activity often limits plant growth. This project makes use of new synthetic biology capabilities to artificially evolve Rubisco in the laboratory and select for new versions with improved performance. These beneficial changes will be introduced into crop Rubisco using targeted gene editing appr ....Combining new synthetic biology tools to boost crop CO2 capture and growth. A solution for improving crop yield is to enhance the carbon dioxide fixation properties of the enzyme Rubisco whose inefficient activity often limits plant growth. This project makes use of new synthetic biology capabilities to artificially evolve Rubisco in the laboratory and select for new versions with improved performance. These beneficial changes will be introduced into crop Rubisco using targeted gene editing approaches and the improvements in photosynthesis, growth and yield evaluated. This information will aid complimentary biotechnological efforts seeking to supercharge photosynthesis and help deliver the second Green Revolution needed to meet the improvement required in future agriculture productivity and resource use.Read moreRead less