Future climate change: consequences for decomposition and pathways of carbon flow through rhizosphere fungal communities. The proposed collaboration will provide novel insights into likely consequences of global climate change on decomposition and pathways of carbon flow through forest soils. This will refine predictive models of future climate change and its impacts on the sustainability of Australia's forests. It will also enhance the protection of our valued habitats and their important soil ....Future climate change: consequences for decomposition and pathways of carbon flow through rhizosphere fungal communities. The proposed collaboration will provide novel insights into likely consequences of global climate change on decomposition and pathways of carbon flow through forest soils. This will refine predictive models of future climate change and its impacts on the sustainability of Australia's forests. It will also enhance the protection of our valued habitats and their important soil biodiversity. The knowledge gained will help land managers to adapt current practices to meet the demands of future climate change. This will maximize the opportunities for sequestering carbon in Australia's forests and so contribute to meeting Australia's global responsibility for mitigation of climate change.Read moreRead less
Molecular fossils, environmental genomics and the natural history of an Australian salt lake. Increasing salinity of lakes is a critical problem for sustainable water supply in Australia. To comprehend the consequences of human-induced salinization, it is crucial to understand salt lakes at their most fundamental level. This project develops pioneering technologies to elucidate the microbial ecology and geochemistry of salt lakes in unprecedented detail. It will open new pathways to unravel how ....Molecular fossils, environmental genomics and the natural history of an Australian salt lake. Increasing salinity of lakes is a critical problem for sustainable water supply in Australia. To comprehend the consequences of human-induced salinization, it is crucial to understand salt lakes at their most fundamental level. This project develops pioneering technologies to elucidate the microbial ecology and geochemistry of salt lakes in unprecedented detail. It will open new pathways to unravel how microbial ecosystems adapt to increasing salinization, and how they reacted to climate fluctuations in the past. Students will gain multidisciplinary skills in environmental genomics, proteomics and geochemistry, a unique combination that will become decisive for understanding and preserving ecosystems on our continent.Read moreRead less
EXTRACELLULAR ELECTRON TRANSFER IN BIO-ELECTROCHEMICAL SYSTEMS. Water quality and supply are critical issues in Australia. This project investigates the role of bacteria in maintaining a good freshwater quality, and the influence of environmental parameters on this. It will enable us to assess the role of bacteria on greenhouse gas emissions in a variety of environments. As a result, processes can be developed to alleviate high emissions while simultaneously producing green energy. The proteomic ....EXTRACELLULAR ELECTRON TRANSFER IN BIO-ELECTROCHEMICAL SYSTEMS. Water quality and supply are critical issues in Australia. This project investigates the role of bacteria in maintaining a good freshwater quality, and the influence of environmental parameters on this. It will enable us to assess the role of bacteria on greenhouse gas emissions in a variety of environments. As a result, processes can be developed to alleviate high emissions while simultaneously producing green energy. The proteomics study will deliver, aside from knowledge, redox proteins which find their way to diagnostics and fuel cells. This project substantiates Australia based research at the forefront and enables international anchoring of our expertise.Read moreRead less
Interdisciplinary greenhouse gas assessment - nitrous oxide emissions from marine wastewater disposal. Data generated during this research will resolve ongoing uncertainties surrounding a blind spot in national greenhouse gas (GHG) abatement policy and methodology. Current national and international GHG emission estimates are unable to account for N2O emissions resulting from the downstream disposal phase of the wastewater management cycle, and as a result, actual GHG emissions may be far greate ....Interdisciplinary greenhouse gas assessment - nitrous oxide emissions from marine wastewater disposal. Data generated during this research will resolve ongoing uncertainties surrounding a blind spot in national greenhouse gas (GHG) abatement policy and methodology. Current national and international GHG emission estimates are unable to account for N2O emissions resulting from the downstream disposal phase of the wastewater management cycle, and as a result, actual GHG emissions may be far greater than currently estimated. This research will provide primary data on the magnitude of downstream N2O emissions coming from the near-shore marine disposal of primary-level municipal wastewater in Australia. Results from this research will help quantify the carbon footprint associated with marine disposal of poorly treated effluents worldwide.Read moreRead less
Towards a predictive model for coastal marine microbial assemblages. Coastal regions are overwhelmingly the most intense point of interaction between human activity and oceanic provinces. At this interface, the marine biological ecosystem provides critical services that are required to maintain industrial, economic and social well-being. Our work will identify how these marine systems respond to anthropogenic and climatic variability, National Research Priority 1, and in turn, how this response ....Towards a predictive model for coastal marine microbial assemblages. Coastal regions are overwhelmingly the most intense point of interaction between human activity and oceanic provinces. At this interface, the marine biological ecosystem provides critical services that are required to maintain industrial, economic and social well-being. Our work will identify how these marine systems respond to anthropogenic and climatic variability, National Research Priority 1, and in turn, how this response affects ocean services. This knowledge will inform management efforts in resource and biodiversity conservation, and identify novel areas for future resource exploration.Read moreRead less
The connectivity of pore theory - does it influence microbial community composition and function? Climate change scenarios indicate that Australia will be directly affected by an increase in greenhouse gas emissions. Soil microbial activity is responsible for a large proportion of such emissions; therefore it is important that we understand how such changing climate patterns are likely to influence key microbial populations in soil, particularly those involved in the production of greenhouse ga ....The connectivity of pore theory - does it influence microbial community composition and function? Climate change scenarios indicate that Australia will be directly affected by an increase in greenhouse gas emissions. Soil microbial activity is responsible for a large proportion of such emissions; therefore it is important that we understand how such changing climate patterns are likely to influence key microbial populations in soil, particularly those involved in the production of greenhouse gases. This research interfaces two disciplines, earth and biological sciences, and will establish a new international collaboration that will ensure Australia is at the forefront of a rapidly developing research field.Read moreRead less
Stress, virulence and bacterial disease in temperate seaweeds: the rise of the microbes. Climate change is predicted to increase the spread and virulence of pathogens, and decrease the resistance to disease via temperature stress on the hosts. Combined with other human impacts (higher nutrients, pollution), we may be facing a major rise in the effect of disease on natural communities. However, these effects are largely unstudied. We will investigate the impact of marine pathogens on kelps and ....Stress, virulence and bacterial disease in temperate seaweeds: the rise of the microbes. Climate change is predicted to increase the spread and virulence of pathogens, and decrease the resistance to disease via temperature stress on the hosts. Combined with other human impacts (higher nutrients, pollution), we may be facing a major rise in the effect of disease on natural communities. However, these effects are largely unstudied. We will investigate the impact of marine pathogens on kelps and other seaweeds when they are stressed by temperature, elevated nutrients or other anthropogenic stressors. Kelp are the 'trees of the oceans', the organisms responsible for creating much of the habitat that fishes and other organisms live in. The loss of kelp forests due to disease would radically change these environments.Read moreRead less
Ecology, physiology and molecular microbiology of coral disease on the Great Barrier Reef. Ecological, physiological, molecular and micro-biological techniques will be used to examine the disease of corals of the Great Barrier Reef (GBR). Molecular techniques include the development of diagnostic techniques for disease identification, using Fluorescent In Situ hybridisation (FISH) and DNA microarrays (CHIPS); physiological experiments include examining the effects of temperature and sediment o ....Ecology, physiology and molecular microbiology of coral disease on the Great Barrier Reef. Ecological, physiological, molecular and micro-biological techniques will be used to examine the disease of corals of the Great Barrier Reef (GBR). Molecular techniques include the development of diagnostic techniques for disease identification, using Fluorescent In Situ hybridisation (FISH) and DNA microarrays (CHIPS); physiological experiments include examining the effects of temperature and sediment on virulence and host susceptibility to disease infection; ecological surveys will examine the extent and seasonality of disease in northern and southern parts of the GBR and on isolated reefs in the central GBR. Management implications of the current coral-disease status of the GBR will be targeted.Read moreRead less
Bacterial disease and bleaching of chemically defended marine algae. Disease has emerged as a major factor in the ecology and management of natural marine communities. Moreover, the impact of disease in marine ecosystems is linked to environmental changes such as global warming. Much of the research in this area has focused on tropical systems (coral reefs). However, in temperate reef systems seaweeds are the major habitat formers. This proposal investigates how environmental factors (temperat ....Bacterial disease and bleaching of chemically defended marine algae. Disease has emerged as a major factor in the ecology and management of natural marine communities. Moreover, the impact of disease in marine ecosystems is linked to environmental changes such as global warming. Much of the research in this area has focused on tropical systems (coral reefs). However, in temperate reef systems seaweeds are the major habitat formers. This proposal investigates how environmental factors (temperature, UV) mediate bacterial disease of seaweeds, key temperate organisms. The proposal thus adresses National Research Priority 1: An Environmentally Sustainable Australia, and in particular the Priority Goals 'Sustainable use of Australia's biodiversity' and 'Responding to climate change and variability'. 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