A network perspective for ecosystem responses to plant invasion. Invasive species are key drivers of global change, yet, our understanding of their negative impacts on ecosystems is limited within many contexts. This project will provide the first large-scale test for interactions between plants and microbes, via network analyses, as yardsticks for invasive species impacts on ecosystems. Using innovative approaches that link interactions network properties with ecosystem functioning, the fundame ....A network perspective for ecosystem responses to plant invasion. Invasive species are key drivers of global change, yet, our understanding of their negative impacts on ecosystems is limited within many contexts. This project will provide the first large-scale test for interactions between plants and microbes, via network analyses, as yardsticks for invasive species impacts on ecosystems. Using innovative approaches that link interactions network properties with ecosystem functioning, the fundamental data generated in this study will answer unsolved theoretical questions, providing evidence for the use of networks to predict and mitigate invader impacts. These benefits are not only crucial for biodiversity managers but also for those responsible for sustainable crop development under future climates.Read moreRead less
Predatory protists: natural weapons for soil-borne pathogen control. This project aims to understand the mechanistic interactions of predatory protists and fungal pathogens and develop innovative biotechnologies using the protists to suppress soil-borne pathogens. By directly preying on fungal pathogens or activating plant-beneficial bacteria to combat them, the soil predatory protists will be identified, cultivated and utilised to improve disease management. Expected outcomes of this project wi ....Predatory protists: natural weapons for soil-borne pathogen control. This project aims to understand the mechanistic interactions of predatory protists and fungal pathogens and develop innovative biotechnologies using the protists to suppress soil-borne pathogens. By directly preying on fungal pathogens or activating plant-beneficial bacteria to combat them, the soil predatory protists will be identified, cultivated and utilised to improve disease management. Expected outcomes of this project will include a mechanistic understanding of the contribution of protists to pathogen suppression and an innovative, protist-based disease management tool. The novel technologies developed in this project have potentials to benefit Australian agriculture and land management.Read moreRead less
Unlocking Viral Contribution to Terrestrial Nitrogen Cycling. This project aims to investigate how soil viruses steer key nitrogen cycling microorganisms and processes, by utilising emerging approaches of viromes, DNA-stable-isotope probing, and Raman-spectroscopy-based single-cell-sorting technology. This project expects to generate new knowledge in harnessing the potential of soil viruses to improve fertiliser nitrogen use efficiency through manipulating the biological pathways of nitrogen los ....Unlocking Viral Contribution to Terrestrial Nitrogen Cycling. This project aims to investigate how soil viruses steer key nitrogen cycling microorganisms and processes, by utilising emerging approaches of viromes, DNA-stable-isotope probing, and Raman-spectroscopy-based single-cell-sorting technology. This project expects to generate new knowledge in harnessing the potential of soil viruses to improve fertiliser nitrogen use efficiency through manipulating the biological pathways of nitrogen losses from agricultural ecosystems. Expected outcomes of this project include novel and comprehensive evidence for the roles of soil viruses in controlling terrestrial nitrogen cycling processes. This should provide significant benefits to Australian agriculture and environmental management.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101226
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Plant community responses to fire regime: the role of plant–soil feedbacks. We need to know how different prescribed burning regimes set the stage for long-term changes in plant community composition, diversity, and flammability. This project aims to reveal how plant community dynamics under different fire scenarios can be predicted based on contemporary interactions between plants and soil micro-organisms. This innovative approach to fire ecology integrates soil biology and plant ecophysiology ....Plant community responses to fire regime: the role of plant–soil feedbacks. We need to know how different prescribed burning regimes set the stage for long-term changes in plant community composition, diversity, and flammability. This project aims to reveal how plant community dynamics under different fire scenarios can be predicted based on contemporary interactions between plants and soil micro-organisms. This innovative approach to fire ecology integrates soil biology and plant ecophysiology with sophisticated experiments and novel modelling techniques. Expected outcomes include a much-needed mechanistic framework for early detection of major ecological changes under novel fire regimes, with direct benefits for land managers and the long-term conservation of Australia’s iconic vegetation.Read moreRead less
Can eco-evolutionary theories explain outcomes of microbiome coalescence . Environmental microbial communities are among the most abundant and diverse natural communities, responsible for many ecologically and economically important ecosystem functions, including primary productivity and climate regulation. This project aims to identify the biotic and abiotic factors that regulate community and functional outcomes of microbiome coalescence (the mixing of two different communities) caused by natu ....Can eco-evolutionary theories explain outcomes of microbiome coalescence . Environmental microbial communities are among the most abundant and diverse natural communities, responsible for many ecologically and economically important ecosystem functions, including primary productivity and climate regulation. This project aims to identify the biotic and abiotic factors that regulate community and functional outcomes of microbiome coalescence (the mixing of two different communities) caused by natural and anthropogenic activities. The outcomes will provide a unifying ecological framework to predict variation in microbiomes across different scales, ecosystem types and disturbances, and will generate critical knowledge for the development of effective microbiome products, a rapidly growing industryRead moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100822
Funder
Australian Research Council
Funding Amount
$383,887.00
Summary
Haloalkaliphilic sulphur oxidising bacteria in dealkalising bauxite residue. This project aims to establish breakthrough technology for neutralising bauxite refinery wastes by creating new knowledge about the taxonomic composition and molecular metabolism of sulphur oxidising bacteria capable of oxidising low-cost element sulphur in extremely haloalkaline niches. The findings will be translated into field feasible ecological engineering technology in partnership with industry partners. This DECR ....Haloalkaliphilic sulphur oxidising bacteria in dealkalising bauxite residue. This project aims to establish breakthrough technology for neutralising bauxite refinery wastes by creating new knowledge about the taxonomic composition and molecular metabolism of sulphur oxidising bacteria capable of oxidising low-cost element sulphur in extremely haloalkaline niches. The findings will be translated into field feasible ecological engineering technology in partnership with industry partners. This DECRA project will also contribute to the net zero waste strategy in Australia and could significantly contribute to global problems of mining waste, carbon emission, and soil depletion if implemented. The commercialisation of the technology package will increase economic advantages and employment in Australia.Read moreRead less
Understanding the risk of microplastics in Australian agricultural soils. Biosolids following wastewater treatment are a significant source of microplastics (MPs) that are contaminants of concern. MPs in biosolids pose potential unknown risks to agriculture, food security and ecosystem health through their application to farmlands. Currently, the lack of knowledge on the MPs contamination of agricultural soils is a significant knowledge gap. This project aims to generate new knowledge of MPs' fa ....Understanding the risk of microplastics in Australian agricultural soils. Biosolids following wastewater treatment are a significant source of microplastics (MPs) that are contaminants of concern. MPs in biosolids pose potential unknown risks to agriculture, food security and ecosystem health through their application to farmlands. Currently, the lack of knowledge on the MPs contamination of agricultural soils is a significant knowledge gap. This project aims to generate new knowledge of MPs' fate, behaviour, risk and associated contaminants in biosolids and sludge-amended agricultural soils. The new knowledge generated in this project is expected to help devise better management options to minimise the MP associated risks in agricultural soils, thereby safeguarding the food security and soil health.Read moreRead less
Mineral Biosequestration of Organic Carbon in Early Pedogenesis of Tailings. Upcycling tailings into soil (technosols developed from technogenic parent materials) offers a sustainable approach to overcome severe topsoil shortage that limits the progress of ecological rehabilitation of tailings across mine sites. This project aims to establish new knowledge on mineral bioweathering, organic carbon (OC) sequestration in rapidly formed mineral phases, and OC turnover driven by colonising microbes a ....Mineral Biosequestration of Organic Carbon in Early Pedogenesis of Tailings. Upcycling tailings into soil (technosols developed from technogenic parent materials) offers a sustainable approach to overcome severe topsoil shortage that limits the progress of ecological rehabilitation of tailings across mine sites. This project aims to establish new knowledge on mineral bioweathering, organic carbon (OC) sequestration in rapidly formed mineral phases, and OC turnover driven by colonising microbes and plant roots, in the early pedogenesis of tailings initiated by inputs of organic and inorganic materials. This new knowledge is required for developing eco-engineering technology adaptable to a wide range of tailings of diverse mineralogy, to achieve sustainable tailings rehabilitation and organic carbon sequestration.Read moreRead less