The costs and consequences of resistance to stress in microbial systems. The coexistence of antibiotic resistant and sensitive bacteria in microbial communities represents a paradox. Combining novel ecological models and competition experiments, this project aims to investigate how the pulsing of antibiotics and resources affects the coexistence of resistant and sensitive bacteria. This project expects to generate new knowledge into how the complex non-equilibrium dynamics of natural systems fee ....The costs and consequences of resistance to stress in microbial systems. The coexistence of antibiotic resistant and sensitive bacteria in microbial communities represents a paradox. Combining novel ecological models and competition experiments, this project aims to investigate how the pulsing of antibiotics and resources affects the coexistence of resistant and sensitive bacteria. This project expects to generate new knowledge into how the complex non-equilibrium dynamics of natural systems feeds back to regulate the spread of antibiotic resistance in microbial communities. This should advance our fundamental understanding of microbial competition, and provide a foundation for the development of new ecologically-aware strategies for managing resistance.Read moreRead less
Can ecological theory help to unravel microbial regulation of soil functions? Much attention has been paid to relationships between ecosystem health and biodiversity in above-ground communities, yet little notice is taken of the vast below-ground soil microbial communities. This project will reveal if soil microbial diversity is similarly important for ecosystem function in the face of future environmental challenges.
Discovery Early Career Researcher Award - Grant ID: DE220100479
Funder
Australian Research Council
Funding Amount
$453,582.00
Summary
Delivering defences: using fungi to enhance plant resistance to herbivory. This project will identify how the diversity of beneficial fungi in the soil is affected by agricultural management, and will reveal how these fungi govern the ability of plants to defend themselves from insect herbivores. Through innovative field surveys and experimentation, this project will generate new knowledge in the key areas of soil ecology and plant defence. This will allow us to exploit these soil fungi to enhan ....Delivering defences: using fungi to enhance plant resistance to herbivory. This project will identify how the diversity of beneficial fungi in the soil is affected by agricultural management, and will reveal how these fungi govern the ability of plants to defend themselves from insect herbivores. Through innovative field surveys and experimentation, this project will generate new knowledge in the key areas of soil ecology and plant defence. This will allow us to exploit these soil fungi to enhance crop protection while simultaneously conserving soil ecosystems. Effectively boosting plant defence in this way will reduce reliance on ecologically damaging pesticides, promote soil biodiversity, and ensure the sustainability of crop production into the future. Read moreRead less
Chemical warfare at small scales: does eukaryotic chemical defense theory fit biofilms? The ecology of bacteria has long been treated separately from the ecology of higher organisms. Thus we do not know whether the ecology of bacteria operates by the same general rules as those of plants and animals. This significantly diminishes our understanding of the natural world, and our capacity to manage our environment. In this project we will systematically test ecological defense theories in bacterial ....Chemical warfare at small scales: does eukaryotic chemical defense theory fit biofilms? The ecology of bacteria has long been treated separately from the ecology of higher organisms. Thus we do not know whether the ecology of bacteria operates by the same general rules as those of plants and animals. This significantly diminishes our understanding of the natural world, and our capacity to manage our environment. In this project we will systematically test ecological defense theories in bacterial systems. Our aim is to merge our understanding of the ecology of these very different organisms. This integration of plant and animal ecology and environmental microbiology is new for both fields, and thus studies such as this one have the potential to put Australia at the forefront of this exciting new approach to our environment.Read moreRead less
Plant : fungal symbioses in Australian forests - new perspectives using laser microdissection. Ericaceae are important components of the Australian flora in many habitats, including forests and fragile alpine regions that are significant to Australia's cultural and natural heritage, and several species are considered threatened. This project addresses the fundamental question of whether networks of symbiotic fungal mycelia act as below-ground bridges between Ericaceae plants and tree roots. If d ....Plant : fungal symbioses in Australian forests - new perspectives using laser microdissection. Ericaceae are important components of the Australian flora in many habitats, including forests and fragile alpine regions that are significant to Australia's cultural and natural heritage, and several species are considered threatened. This project addresses the fundamental question of whether networks of symbiotic fungal mycelia act as below-ground bridges between Ericaceae plants and tree roots. If demonstrated, this would alter current views of carbon and nutrient cycling in Australian forests and provide the basis for better informed decisions for the sustainable management of Australian forest resources. This is particularly important in the context of carbon sequestration and future climate change.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
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
Reserving nitrogen in soils through microbial nitrate reduction to ammonium. This project aims to identify those microbes able to transform nitrate to ammonium and thus increase soil nitrogen conservation. More than 50 per cent of the nitrogen in fertilisers applied to soils is lost into the environment, which is both a financial loss to farmers and a main anthropogenic source of nitrogen pollution. Some microbes can transform nitrate into ammonium through dissimilatory reduction (DNRA) and thus ....Reserving nitrogen in soils through microbial nitrate reduction to ammonium. This project aims to identify those microbes able to transform nitrate to ammonium and thus increase soil nitrogen conservation. More than 50 per cent of the nitrogen in fertilisers applied to soils is lost into the environment, which is both a financial loss to farmers and a main anthropogenic source of nitrogen pollution. Some microbes can transform nitrate into ammonium through dissimilatory reduction (DNRA) and thus increase soil nitrogen retention. However, the DNRA process and the responsible microbial groups remain largely unknown. This project plans to use isotope tracing and biomolecular approaches to identify those DNRA microbial groups and elucidate the DNRA reaction process. The findings may support the use of DNRA to improve soil nitrogen.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