Bacterial polycyclic aromatic hydrocarbon transport and degradation. This project aims to investigate the molecular processes underpinning the degradation of polycyclic aromatic hydrocarbons (PAHs) by bacteria. PAHs are persistent environmental contaminants linked to several human diseases, including cancer. Bacteria capable of degrading PAHs could be used to naturally and effectively reduce environmental PAH loads to below safe levels. The project will apply techniques in functional genomics an ....Bacterial polycyclic aromatic hydrocarbon transport and degradation. This project aims to investigate the molecular processes underpinning the degradation of polycyclic aromatic hydrocarbons (PAHs) by bacteria. PAHs are persistent environmental contaminants linked to several human diseases, including cancer. Bacteria capable of degrading PAHs could be used to naturally and effectively reduce environmental PAH loads to below safe levels. The project will apply techniques in functional genomics and biochemistry to help define the ways that PAHs are taken up from the environment by bacteria, their fate within bacterial cells, and the ways that bacteria overcome the inherent toxicity of PAHs. The knowledge generated is expected to enhance our capacity to rationally deploy bacteria for PAH degradation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100130
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Specialised greenhouse space for new initiatives. This greenhouse facility will enable fundamental research of nutrient transport in fruits, seeds and fibre and will underpin biotechnological advances to improve crop yield and quality. The development of drought tolerant Sorghum as a dedicated bio-energy crop will reduce dependence on fossil fuels, building towards an environmentally sustainable Australia.
Modelling of neural plasticity for enhanced performance of brain-machine interfaces. Plasticity of the brain is one of the great scientific challenges of neuroscience. The aim of this project is to model the synaptic changes that occur with reward-modulated spike-timing-dependent plasticity and apply the model to developing plasticity targeted brain-machine interfaces. The significance of this approach is that such plasticity targeted techniques provide the prospect of taking advantage of the un ....Modelling of neural plasticity for enhanced performance of brain-machine interfaces. Plasticity of the brain is one of the great scientific challenges of neuroscience. The aim of this project is to model the synaptic changes that occur with reward-modulated spike-timing-dependent plasticity and apply the model to developing plasticity targeted brain-machine interfaces. The significance of this approach is that such plasticity targeted techniques provide the prospect of taking advantage of the underlying neural plasticity to optimise the form of the neural recording and electrical stimulation. The outcomes will be to greatly improve the performance of brain-machine interface in terms of measures such as the number and sensitivity of channels, as well as robustness and reliability.Read moreRead less
In situ bioremediation solutions for Australia's organochlorine contaminated aquifers. This project will develop biological technologies to accelerate chlorinated solvent degradation in contaminated groundwater. Bacterial cultures developed in Australia will be injected into groundwater to enhance solvent degradation resulting in environmentally friendly and cost effective environmental restoration.
Testing the importance of large-scale climate factors to plant community assembly following land-use change. This project will examine the native plant species and functional diversity of Australia's rain forest communities to create a predictive framework of how plant communities recover following deforestation. Such a framework is key to focusing conservation efforts in degraded and multi-use landscapes.
The energetic basis to seed longevity and storage. The energetic basis to seed longevity and storage. This project aims to quantify patterns of metabolic rate in Australian native seeds to research seed ecology, dormancy, germination, longevity and persistence in natural and artificial seed banks. The project aims to optimise and refine current respirometry technology for use with native seeds, understand the allometric relationship and patterns with seed diversity, and apply this knowledge to b ....The energetic basis to seed longevity and storage. The energetic basis to seed longevity and storage. This project aims to quantify patterns of metabolic rate in Australian native seeds to research seed ecology, dormancy, germination, longevity and persistence in natural and artificial seed banks. The project aims to optimise and refine current respirometry technology for use with native seeds, understand the allometric relationship and patterns with seed diversity, and apply this knowledge to benefit restoration and conservation seed banks. By interpreting the energetics of seeds in a phylogenetic context, this project will develop an experimental protocol to predict the physiology and longevity, and test the viability of seeds in storage. Anticipated outcomes are improved efficiency of seed bank storage, conservation and restoration efforts.Read moreRead less
Accelerating species richness gains and carbon sequestration in secondary regrowth in north Queensland. Tropical abandoned lands offer important opportunities to increase carbon storage and conserve biodiversity. However, natural forest regeneration is slow and frequently inhibited by woody weeds. The project will involve a collaboration between eminent tropical biologists and the carbon-industry to devise innovative strategies to accelerate restoration of degraded land.
Discovery Early Career Researcher Award - Grant ID: DE160100429
Funder
Australian Research Council
Funding Amount
$367,000.00
Summary
Unravelling nickel biopathways in tropical hyperaccumulator plants. This project aims to unravel the ways in which hyperaccumulators work. Hyperaccumulators are plants that have the remarkable ability to concentrate up to six per cent nickel in their leaves and up to 25 per cent in their sap. These plants can be used in phytomining – a new technology to recover nickel from mining waste or contaminated land by growing and harvesting these plants and extracting nickel from their biomass. This proj ....Unravelling nickel biopathways in tropical hyperaccumulator plants. This project aims to unravel the ways in which hyperaccumulators work. Hyperaccumulators are plants that have the remarkable ability to concentrate up to six per cent nickel in their leaves and up to 25 per cent in their sap. These plants can be used in phytomining – a new technology to recover nickel from mining waste or contaminated land by growing and harvesting these plants and extracting nickel from their biomass. This project seeks to understand how the plants accumulate nickel by using tracers and synchrotron techniques to follow the pathways of nickel from the soil into the plants. This knowledge may help us to optimise agronomic processes affecting nickel uptake to enable successful phytomining.Read moreRead less
Understanding the biological functions of the karrikin-responsive signaling system of plants in growth, development and responses to the environment. A new signalling system in plants, related to that of strigolactone hormones but evolutionarily more ancient and functionally distinct, has been discovered. It is defined by the Karrkin-Insensitive-2 (KAI2) protein discovered by its ability to confer responsiveness to karrikins from bushfires. The KAI2 system influences seed germination, and develo ....Understanding the biological functions of the karrikin-responsive signaling system of plants in growth, development and responses to the environment. A new signalling system in plants, related to that of strigolactone hormones but evolutionarily more ancient and functionally distinct, has been discovered. It is defined by the Karrkin-Insensitive-2 (KAI2) protein discovered by its ability to confer responsiveness to karrikins from bushfires. The KAI2 system influences seed germination, and development of seedlings, leaves and potentially roots. This project will use KAI2 mutants and transgenic plants to define the biological functions of KAI2 signalling, and its interactions with other signalling systems. New genes central to KAI2 signalling and responses will be identified for functional analysis. The research will reveal the significance of this new signalling system in plant biology. Read moreRead less
Landscape restoration genomics for climate adaptation in eucalyptus foundation species. Understanding the genetic basis of adaptation in foundation species will allow selection of pre-adapted seeds to establish resilient ecosystems which support the broad range of life supporting services. This project will apply genomics to solve real environmental challenges in restoration management and be a model for other foundation species.