Development and implementation of biodiversity information for sustainable management of South Australian groundwater. Clean potable water is one of the most important resources for human health and a successful economy. Increasingly, subterranean aquifers are used for storage and recovery of water. These aquifers contain dynamic ecosystems, but little is known about species composition or about the importance of the presence of various species for water quality. We will use the latest laborator ....Development and implementation of biodiversity information for sustainable management of South Australian groundwater. Clean potable water is one of the most important resources for human health and a successful economy. Increasingly, subterranean aquifers are used for storage and recovery of water. These aquifers contain dynamic ecosystems, but little is known about species composition or about the importance of the presence of various species for water quality. We will use the latest laboratory techniques and DNA identification methods to provide a template for determining ground water diversity and food web dynamics throughout Australia. This project will lead to a better understanding of how to manage ground water in a sustainable manner.Read moreRead less
Revealing the evolutionary and ecological dynamics of avian influenza virus. This project aims to understand how avian influenza virus (AIV) emerges, evolves and spreads in wild birds. AIV has the potential to devastate the poultry industry and cause human pandemics, but the factors that shape the genetic diversity of AIV in its wild bird reservoir are poorly understood. The project plans to combine genomic, ecological and phylogenetic approaches to reveal key aspects of AIV evolution, as well a ....Revealing the evolutionary and ecological dynamics of avian influenza virus. This project aims to understand how avian influenza virus (AIV) emerges, evolves and spreads in wild birds. AIV has the potential to devastate the poultry industry and cause human pandemics, but the factors that shape the genetic diversity of AIV in its wild bird reservoir are poorly understood. The project plans to combine genomic, ecological and phylogenetic approaches to reveal key aspects of AIV evolution, as well as the risk for future viral emergence. Using sampling sites in Australia and Antarctica, it plans to investigate AIV diversity, the evolutionary dynamics of AIV in wild birds and poultry, and the role played by environmental transmission in AIV ecology.Read moreRead less
Discovery Indigenous Researchers Development - Grant ID: DI0668388
Funder
Australian Research Council
Funding Amount
$87,458.00
Summary
The genetic basis for bioactivity in the traditional medicine plants of Australia. A plant species that produces a bioactive compound usually produce the compound in very small amounts. To allow for marketable levels of production of the bioactive compound, numerous amounts of plants would need to be removed from the environment. This not only removes the limited supply of possibly rare types of plants from the environment but also denies the use of this plant by traditional people. Locating and ....The genetic basis for bioactivity in the traditional medicine plants of Australia. A plant species that produces a bioactive compound usually produce the compound in very small amounts. To allow for marketable levels of production of the bioactive compound, numerous amounts of plants would need to be removed from the environment. This not only removes the limited supply of possibly rare types of plants from the environment but also denies the use of this plant by traditional people. Locating and using the genes responsible for producing these bioactive compounds will allow their sustainable biosynthesis.Read moreRead less
A functional genomic approach for understanding metal ion adaptation in marine cyanobacteria. Unicellular marine cyanobacteria constitute 20-40% of total marine chlorophyll biomass and carbon fixation, and hence significantly impact the global carbon cycle and are very relevant to combating global warming. This research will reveal some of the major mechanisms by which marine cyanobacteria have adapted to metal levels in coastal and oligotrophic environments. Thus these results will help us und ....A functional genomic approach for understanding metal ion adaptation in marine cyanobacteria. Unicellular marine cyanobacteria constitute 20-40% of total marine chlorophyll biomass and carbon fixation, and hence significantly impact the global carbon cycle and are very relevant to combating global warming. This research will reveal some of the major mechanisms by which marine cyanobacteria have adapted to metal levels in coastal and oligotrophic environments. Thus these results will help us understand the distribution and diversity of these organisms in relation to global primary productivity. They will also lead to the development of more robust biomarkers for metal stress and pollution in coastal environments.Read moreRead less
Microbial sulphatises in the rhizosphere and their control by interactions with plants. Plant-microbe interactions are critical in mobilizing soil sulphur for crop growth. This project will identify the microbes responsible for delivering sulphur to two major Australian crops, and will examine how the plants stimulate this activity in their root zone. The results have potential application for sustainable agriculture in Australia.
Uncovering the microbial ecology of Australia's coasts: Friends next-door or enemies at the gate? The health and function of coastal habitats is mediated by an abundant community of marine microbes, which perform essential ecosystem services. However, some microbes can periodically disrupt the biogeochemical balance of coastal habitats, while others are dangerous pathogens that cause human illness. Anthropogenic impacts may underpin episodic shifts in the balance of ‘good’ and ‘bad’ coastal micr ....Uncovering the microbial ecology of Australia's coasts: Friends next-door or enemies at the gate? The health and function of coastal habitats is mediated by an abundant community of marine microbes, which perform essential ecosystem services. However, some microbes can periodically disrupt the biogeochemical balance of coastal habitats, while others are dangerous pathogens that cause human illness. Anthropogenic impacts may underpin episodic shifts in the balance of ‘good’ and ‘bad’ coastal microbes, but the mechanisms and dynamics of these shifts are undefined. This project will unite cutting-edge analytical tools, including microfluidics and ecogenomics, to redefine our understanding of the microbiology of the Australian coast, providing transformative new insights for preserving our aquatic backyard and protecting our health.Read moreRead less
Pelagic symbioses: teasing apart phytoplankton-bacteria relationships. This project aims to decode the intricate relationships between populations of phytoplankton and marine bacteria and interpret their influence on ocean productivity and chemical cycling. While oceanographers typically consider the ecology of phytoplankton and bacteria in isolation, this project suggests that the lives of these organisms are inherently entwined in symbiosis. This project is anticipated to aid in management of ....Pelagic symbioses: teasing apart phytoplankton-bacteria relationships. This project aims to decode the intricate relationships between populations of phytoplankton and marine bacteria and interpret their influence on ocean productivity and chemical cycling. While oceanographers typically consider the ecology of phytoplankton and bacteria in isolation, this project suggests that the lives of these organisms are inherently entwined in symbiosis. This project is anticipated to aid in management of Australia’s valuable marine estate and the ecosystem services and food security it provides.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100615
Funder
Australian Research Council
Funding Amount
$348,200.00
Summary
Harnessing chain-forming diatoms for improved lipid biofuel production. The aim of this project is to unlock the molecular secrets of highly productive chain-forming diatom microalgae that allow them to produce high levels of biofuel lipids. The formation of multicellular chains appears key to the success of some of the most widespread and productive diatom species. Through a combination of systems biology, bioinformatics, and genetics experiments, this project aims to investigate the relationsh ....Harnessing chain-forming diatoms for improved lipid biofuel production. The aim of this project is to unlock the molecular secrets of highly productive chain-forming diatom microalgae that allow them to produce high levels of biofuel lipids. The formation of multicellular chains appears key to the success of some of the most widespread and productive diatom species. Through a combination of systems biology, bioinformatics, and genetics experiments, this project aims to investigate the relationship between chain formation and biofuel lipid productivity in Chaetoceros diatoms, and to discover genes and molecules that encode and influence these traits. The knowledge and technology generated as a result may improve biofuel yields, increase the robustness of species growing in open pond systems, and reduce processing costs such as de-watering.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100032
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
A ToF-SIMS facility for elemental and isotopic imaging of ultra-fine features for researchers in east Australia. A time of flight secondary ion mass spectrometer facility for elemental and isotopic imaging of ultra-fine features: Microbiology has long been an area of strength in Australian science. With recent technological advances microbiology has entered a new golden age unveiling an extraordinary level of diversity and the central role of microbes in global biogeochemistry. The 'omics' era i ....A ToF-SIMS facility for elemental and isotopic imaging of ultra-fine features for researchers in east Australia. A time of flight secondary ion mass spectrometer facility for elemental and isotopic imaging of ultra-fine features: Microbiology has long been an area of strength in Australian science. With recent technological advances microbiology has entered a new golden age unveiling an extraordinary level of diversity and the central role of microbes in global biogeochemistry. The 'omics' era is generating endless hypotheses regarding geochemical processes carried out by microbes and this necessitates the application of advanced technologies to generate empirical support. Time of flight secondary ion mass spectrometry has emerged as a key tool to unravel elemental cycling carried out by microorganisms in mixed species communities in contexts ranging from terrestrial to marine ecology and from groundwater bioremediation to biogas production biotechnologies.Read moreRead less
Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create ....Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create new, artificial interactions between bacteria and eukaryotes. This project will provide fundamental knowledge on the evolution and function of newly discovered ELPs found in both beneficial and pathogenic bacteria and paves the way to control symbiosis for biotechnological applications.Read moreRead less