A microscopic and analytical study of extreme thermophile bacteria in simulated environments compared to organic matter in early Earth hydrothermal systems. The study will examine microbial cells and organic residues of cultured thermophilic archaea from simulated extreme environments in terms of temperature, pressure and mineral concentrations. These will be compared, applying observational and geochemical techniques to organic material in geologically earliest ecosystems. A novel approach will ....A microscopic and analytical study of extreme thermophile bacteria in simulated environments compared to organic matter in early Earth hydrothermal systems. The study will examine microbial cells and organic residues of cultured thermophilic archaea from simulated extreme environments in terms of temperature, pressure and mineral concentrations. These will be compared, applying observational and geochemical techniques to organic material in geologically earliest ecosystems. A novel approach will be adopted, of 'backtracking' changes occurring to cultured microbial cells towards their breakdown and disintegration (in contrast to the more common approach of simulating synthesis of organic compounds as a starting point towards structured functioning organisms), and their viability limits. The results of the study will be tested within the currently available theoretical models for the origin of life.Read moreRead less
Microbial genomics of the southern ocean: monitoring environmental health. This program will derive an integrated understanding of microbial ecology which is essential for determining ways of preserving the health of the World's ecosystems. Through the development of a unique microbial genomics program, Australia will remain a world leader in Antarctic biology, strengthening Australia's reputation in technologically innovative scientific programs of global significance, training local scientists ....Microbial genomics of the southern ocean: monitoring environmental health. This program will derive an integrated understanding of microbial ecology which is essential for determining ways of preserving the health of the World's ecosystems. Through the development of a unique microbial genomics program, Australia will remain a world leader in Antarctic biology, strengthening Australia's reputation in technologically innovative scientific programs of global significance, training local scientists in cutting edge genomic biology and fostering the interests of the international community in sciences ranging from microbial ecology to climate change.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
Chemical Defenses Against Microbial Colonisation of Living Marine Surfaces. Microorganisms have a major impact on all ecosystems. Many of these effects are due to the formation of biofilms - cell clusters and their slime matrix - on living and non-living surfaces. Biofilm formation is often regulated by chemical signals. The aim of this project is to understand how naturally produced chemical signals mediate the formation of biofilms on surfaces of marine macroalgae (seaweeds) at both the eco ....Chemical Defenses Against Microbial Colonisation of Living Marine Surfaces. Microorganisms have a major impact on all ecosystems. Many of these effects are due to the formation of biofilms - cell clusters and their slime matrix - on living and non-living surfaces. Biofilm formation is often regulated by chemical signals. The aim of this project is to understand how naturally produced chemical signals mediate the formation of biofilms on surfaces of marine macroalgae (seaweeds) at both the ecological and molecular levels. By understanding colonisation of natural living surfaces, this project will lead directly to significant advances in control of microorganisms in a variety of applied areas (water treatment, biomaterials, antifouling).Read moreRead less
Diatom frustules: nanostructures at the base of ocean food webs. Molecules interacting with surfaces are fundamental to biological, chemical and physical processes, including desalinization membrane design, lab-on-a-chip systems, industrial catalysis, bioremediation, neurophysiology and uptake of nutrients for incorporation into food webs. Here, we use diatoms as models for molecule-surface interactions to find basic principles that underlay all of these interactions. This research will train st ....Diatom frustules: nanostructures at the base of ocean food webs. Molecules interacting with surfaces are fundamental to biological, chemical and physical processes, including desalinization membrane design, lab-on-a-chip systems, industrial catalysis, bioremediation, neurophysiology and uptake of nutrients for incorporation into food webs. Here, we use diatoms as models for molecule-surface interactions to find basic principles that underlay all of these interactions. This research will train students and scientists and establish collaborations with leading international scientists in the field.Read moreRead less
Physical and Ecological Structure at the Base of Ocean Food Webs. The coastal ocean is a crucial resource to Australia. In founding a research area on coastal food web function we provide international scientific leadership, train scientists in a cutting edge area, and lay the foundation for improved management of fisheries, aquaculture and species invasions. This work boosts Australia's participation in the International Polar Year, and knowledge about Antarctic Territorial waters. Infrastructu ....Physical and Ecological Structure at the Base of Ocean Food Webs. The coastal ocean is a crucial resource to Australia. In founding a research area on coastal food web function we provide international scientific leadership, train scientists in a cutting edge area, and lay the foundation for improved management of fisheries, aquaculture and species invasions. This work boosts Australia's participation in the International Polar Year, and knowledge about Antarctic Territorial waters. Infrastructure benefit comes from the French government paying for an outstanding French scientist to come to Australia 6 months/yr for 5 yrs. This grant acts as the base for larger projects that import EU and American funds.Read moreRead less
Dispersal and colonisation in eukaryotes and prokaryotes. The problem of pest or disease organisms for humanity is fundamentally a problem of unwanted colonisation. For example, colonisation of the surfaces of human tissues by bacterial biofilms is responsible for up to 70% of bacterial infections; colonisation of the surfaces of boat hulls by marine organisms costs the marine shipping industry > $5 billion per year. This proposal will generate fundamental information on the ability of both bac ....Dispersal and colonisation in eukaryotes and prokaryotes. The problem of pest or disease organisms for humanity is fundamentally a problem of unwanted colonisation. For example, colonisation of the surfaces of human tissues by bacterial biofilms is responsible for up to 70% of bacterial infections; colonisation of the surfaces of boat hulls by marine organisms costs the marine shipping industry > $5 billion per year. This proposal will generate fundamental information on the ability of both bacteria and higher organisms to disperse and colonise surfaces, allowing for the development of novel technologies for the prevention of unwanted colonisation of surfaces. Read moreRead less