Modes of speciation in subterranean diving beetles from calcrete aquifers of central Western Australia. Understanding speciation is a fundamental biological problem and our analyses of the diving beetles will broaden our understanding of modes of speciation and how an extraordinary biodiversity of subterranean animals (stygofauna) evolved in the limestone aquifers of central WA. The aquifers are an important source of water for pastoralists and mining companies and the limestone is also a valuab ....Modes of speciation in subterranean diving beetles from calcrete aquifers of central Western Australia. Understanding speciation is a fundamental biological problem and our analyses of the diving beetles will broaden our understanding of modes of speciation and how an extraordinary biodiversity of subterranean animals (stygofauna) evolved in the limestone aquifers of central WA. The aquifers are an important source of water for pastoralists and mining companies and the limestone is also a valuable resource, so there is a need for further research on the impacts of these uses. We will generate further knowledge of the diversity and biological significance of the stygofauna, information that is critical for the environmentally sustainable management of the aquifers and their ecosystems. Read moreRead less
Development of Australian model systems for speciation research. Our project will contribute to an understanding of the process of speciation, a fundamental biological problem, for which there are few well-developed model systems in the world. We will further our understanding of how Australia's extraordinary diversity of animal species have evolved, knowledge which is valuable for understanding the future impact of climatic and environmental changes on species. Our research will generate furthe ....Development of Australian model systems for speciation research. Our project will contribute to an understanding of the process of speciation, a fundamental biological problem, for which there are few well-developed model systems in the world. We will further our understanding of how Australia's extraordinary diversity of animal species have evolved, knowledge which is valuable for understanding the future impact of climatic and environmental changes on species. Our research will generate further knowledge of the diversity and biological significance of subterranean fauna in the arid zone of Australia, providing important background data for assessing the impacts of mining activities on groundwater-dependent-ecosystems and improved strategies for their sustainable management. Read moreRead less
Bacterial innovation and evolution: Molecular prospecting by targeting integrons and gene cassettes. Bacteria can respond rapidly to environmental change by acquiring new genes via lateral gene transfer. A DNA element called the integron can capture, mobilise and express genes, thereby playing a role in the transfer process. We have discovered that integrons are surprisingly abundant in the environment and are associated with a hitherto unsuspected diversity of novel genes. In this study we will ....Bacterial innovation and evolution: Molecular prospecting by targeting integrons and gene cassettes. Bacteria can respond rapidly to environmental change by acquiring new genes via lateral gene transfer. A DNA element called the integron can capture, mobilise and express genes, thereby playing a role in the transfer process. We have discovered that integrons are surprisingly abundant in the environment and are associated with a hitherto unsuspected diversity of novel genes. In this study we will assess the diversity of environmental integrons and examine their contribution to bacterial evolution. Further, we aim to use integron systems to prospect for novel genes and contract new enzyme pathways by directed evolution.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0452650
Funder
Australian Research Council
Funding Amount
$696,005.00
Summary
South Australian Virtual Reality Centre (SAVRC). It is proposed to install a fully immersive three dimensional visualisation facility in Adelaide, at a cost of $5.3 million including requested ARC contribution of $696,005. Applicant Institutions (Adelaide, Flinders, UniSA and Curtin universities) and Industry will provide the remainder.
The facility will support South Australia's leading scientific researchers in the sciences, engineering, business management, carbon dioxide sequestration, p ....South Australian Virtual Reality Centre (SAVRC). It is proposed to install a fully immersive three dimensional visualisation facility in Adelaide, at a cost of $5.3 million including requested ARC contribution of $696,005. Applicant Institutions (Adelaide, Flinders, UniSA and Curtin universities) and Industry will provide the remainder.
The facility will support South Australia's leading scientific researchers in the sciences, engineering, business management, carbon dioxide sequestration, petroleum exploration and production, space environment, bioinformatics, architecture, surgery, dentistry, archaeology and arts.
The facility will enable researchers and industry to significantly leverage other projects leading to much improved research outcomes and efficiency, potentially worth a hundred million dollars or more.
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Organophosphate pesticide degradation: evolved enzymes and biomimetics for bioremediation and medicine. Organophosphate (OP) pesticides are an indispensable part of modern agriculture - their use results in dramatically increased crop yields. However, they are toxic and can damage the environment and cause significant health problems. Enzymes are currently being used to treat runoff water that is contaminated with OPs. The same enzymes also have the potential to aid in the treatment of OP poison ....Organophosphate pesticide degradation: evolved enzymes and biomimetics for bioremediation and medicine. Organophosphate (OP) pesticides are an indispensable part of modern agriculture - their use results in dramatically increased crop yields. However, they are toxic and can damage the environment and cause significant health problems. Enzymes are currently being used to treat runoff water that is contaminated with OPs. The same enzymes also have the potential to aid in the treatment of OP poisoning. However, OP degrading enzymes could be improved in many ways - we will evolve these enzymes to enhance their catalytic properties - to enable them to act more efficiently on an increased number of OPs. Read moreRead less
Improving the sustainability of Australia's water resources: an effective approach for diagnosing and treating foulants on water recycling membrane filters. By determining ways to diagnose and treat fouling problems we will have effectively solved a critical problem in the water recycling industry. By creating more efficient and sustainable ways of using water, we will transform the effectiveness of a wealth of Australian industries that increasingly rely on the efficient use of water (e.g. mini ....Improving the sustainability of Australia's water resources: an effective approach for diagnosing and treating foulants on water recycling membrane filters. By determining ways to diagnose and treat fouling problems we will have effectively solved a critical problem in the water recycling industry. By creating more efficient and sustainable ways of using water, we will transform the effectiveness of a wealth of Australian industries that increasingly rely on the efficient use of water (e.g. mining, agriculture, textiles, energy). By reducing the demand for water (by effectively recycling it), and the energy requirements (by efficiently recycling it), we will increase national wealth and provide significant social and environmental benefits to all Australians.Read moreRead less
The molecular biology and biochemistry of bacterial manganese oxidation. This project will further the understanding of bacterial manganese (Mn2+) oxidation. A multi-disciplinary approach will be used to further investigate the genetics and biochemistry of the Mn2+-oxidising systems of Pseudomonas putida, Leptothrix sp. and Pedomicrobium sp. This work will focus in particular on comparing the Mn2+-oxidising systems from unrelated bacteria. A combination of molecular biology, protein biochemis ....The molecular biology and biochemistry of bacterial manganese oxidation. This project will further the understanding of bacterial manganese (Mn2+) oxidation. A multi-disciplinary approach will be used to further investigate the genetics and biochemistry of the Mn2+-oxidising systems of Pseudomonas putida, Leptothrix sp. and Pedomicrobium sp. This work will focus in particular on comparing the Mn2+-oxidising systems from unrelated bacteria. A combination of molecular biology, protein biochemistry and spectroscopy will be used. This will be the first time that the enzymes of bacterial Mn2+-oxidation will have been characterised in such detail and will lead to a greater understanding of the process of bacterial manganese oxidation.Read moreRead less
Directed evolution of enzymes for bioremediation: structure function studies of bimetalloenzymes. We will evolve enzymes that degrade organophosphate pesticides (OPs) that are used in Australian agriculture. Although these OPs were designed to kill insects they are closely related to chemical warfare agents and are known to be toxic to humans. Bacteria have acquired a number of enzymes that degrade some OPs. One such enzyme has been used in field trials demonstrating its potential to degrade OP ....Directed evolution of enzymes for bioremediation: structure function studies of bimetalloenzymes. We will evolve enzymes that degrade organophosphate pesticides (OPs) that are used in Australian agriculture. Although these OPs were designed to kill insects they are closely related to chemical warfare agents and are known to be toxic to humans. Bacteria have acquired a number of enzymes that degrade some OPs. One such enzyme has been used in field trials demonstrating its potential to degrade OP residues. However, many pesticides are not removed rapidly and OP-degrading enzymes require modification(s) if they are to be useful environmental reagents - this can be achieved with directed evolution. Read moreRead less
Ecological significance of coral disease on the Great Barrier Reef. Coral disease has contributed significantly to the accelerating deterioration of coral reefs globally, but its impact on the Great Barrier Reef is unknown. This project will determine the prevalence of coral disease on the GBR and evaluate the potential threat it poses to reef health. It will build Australian capacity in the ecology and pathology of coral disease, an emergent global research priority, and provide an important ....Ecological significance of coral disease on the Great Barrier Reef. Coral disease has contributed significantly to the accelerating deterioration of coral reefs globally, but its impact on the Great Barrier Reef is unknown. This project will determine the prevalence of coral disease on the GBR and evaluate the potential threat it poses to reef health. It will build Australian capacity in the ecology and pathology of coral disease, an emergent global research priority, and provide an important benchmark for determining whether disease incidence is increasing. It will provide insights into potential links between environmental / anthropogenic stressors and disease incidence, and identify potential threats to coral reef health.Read moreRead less
Directed evolution used to probe protein structure and function; new enzymes for bio-remediation and industry. The aim of the research is to generate new and useful enzymes for bio-remediation and other practical applications. For example, we are evolving enzymes to better degrade organophosphate pesticides that are environmental pollutants. Apart from producing useful enzymes, the proposed research aims at gaining a better understanding of how enzymes work and how they evolve. We intend to dete ....Directed evolution used to probe protein structure and function; new enzymes for bio-remediation and industry. The aim of the research is to generate new and useful enzymes for bio-remediation and other practical applications. For example, we are evolving enzymes to better degrade organophosphate pesticides that are environmental pollutants. Apart from producing useful enzymes, the proposed research aims at gaining a better understanding of how enzymes work and how they evolve. We intend to determine the structure of many related enzymes that have been evolved to have enhanced activities. This data will be used to analyze the intricate relationship between sequence, structure and enzyme activity.Read moreRead less