Bioplastics in the environment: lifetimes and toxicology. Globally, governments are implementing policies to drive a move to a circular economy. In the process, new materials are being introduced whose potential impacts need to be understood before they are widely used. This project pioneers investigations into the rate and extent of biodegradation of biodegradable plastics in aquatic and soil environments and the associated ecotoxicology of this process. In particular, it aims to quantify the e ....Bioplastics in the environment: lifetimes and toxicology. Globally, governments are implementing policies to drive a move to a circular economy. In the process, new materials are being introduced whose potential impacts need to be understood before they are widely used. This project pioneers investigations into the rate and extent of biodegradation of biodegradable plastics in aquatic and soil environments and the associated ecotoxicology of this process. In particular, it aims to quantify the extent to which the surfaces of these materials accumulate environmental pollutants via adsorption and other mechanisms. The outcomes will include conceptual models of biodegradation across environments, including lifetimes and likely impacts, critical information for framing a sustainable plastics industry.Read moreRead less
Is mass commercialisation of silver-based nanotechnology undermining its biomedical antibacterial potential? Silver nanoparticles have demonstrated broad spectrum antibacterial potential and are increasingly used in biomedical applications to limit infection. They are also found in a growing range of everyday products such as shampoos and socks. This situation is analogous to the previous use of antibiotics for nonmedical purposes and the subsequent spread of antibiotic resistant bacteria. This ....Is mass commercialisation of silver-based nanotechnology undermining its biomedical antibacterial potential? Silver nanoparticles have demonstrated broad spectrum antibacterial potential and are increasingly used in biomedical applications to limit infection. They are also found in a growing range of everyday products such as shampoos and socks. This situation is analogous to the previous use of antibiotics for nonmedical purposes and the subsequent spread of antibiotic resistant bacteria. This project will measure silver resistance selection pressure in key microbial communities. Novel monitoring devices, a multi-technique chemistry approach, and correlative synchrotron spectroscopy and molecular biology techniques will be used to decipher the environmental silver resistome and its likely significance.Read moreRead less
Revealing the microbial process of iron-driven anaerobic ammonium oxidation. This project aims to gain fundamental understanding of the recently discovered microbially-facilitated process of anaerobic ammonium oxidation that is coupled to iron reduction. This process (called Feammox) is suggested to be responsible for significant nitrogen loss from soil and sediment ecosystems, resulting in pollution of the atmosphere and our water systems. In the project, the Feammox microorganisms will be enri ....Revealing the microbial process of iron-driven anaerobic ammonium oxidation. This project aims to gain fundamental understanding of the recently discovered microbially-facilitated process of anaerobic ammonium oxidation that is coupled to iron reduction. This process (called Feammox) is suggested to be responsible for significant nitrogen loss from soil and sediment ecosystems, resulting in pollution of the atmosphere and our water systems. In the project, the Feammox microorganisms will be enriched and characterised to reveal the metabolic details of the iron reduction and ammonium oxidation pathways. This will improve understanding of ecosystem nitrogen flux and benefit the management of nitrogen fertilizers used to meet the food and energy requirements of the world’s growing populations.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101310
Funder
Australian Research Council
Funding Amount
$434,582.00
Summary
A unique and overlooked microbial process scavenging two greenhouse gases. This project aims to perform the first-ever systematic investigation of a novel microbial process, in which two potent gases (methane and nitric oxide) responsible for the climate change are metabolized simultaneously. This process is suggested to be universal in early and modern Earth's aquatic systems, which is a potential but overlooked microbial sink for methane and nitric oxide. By identifying the responsible organis ....A unique and overlooked microbial process scavenging two greenhouse gases. This project aims to perform the first-ever systematic investigation of a novel microbial process, in which two potent gases (methane and nitric oxide) responsible for the climate change are metabolized simultaneously. This process is suggested to be universal in early and modern Earth's aquatic systems, which is a potential but overlooked microbial sink for methane and nitric oxide. By identifying the responsible organisms and their metabolic pathway, this project represents a critical step towards a full understanding of their roles in affecting the greenhouse gas emission. This understanding will also enable us to more reliably predict the global climate change, which is one of the most significant challenges in the 21st Century.Read moreRead less
Iron-dependent anaerobic oxidation of methane process. This project aims to investigate the microbial process of iron-dependent anaerobic oxidation of methane. This process may be pervasive in Earth's aquatic systems, and possibly a major methane sink. This project will identify the organisms mediating this reaction, elucidate their metabolic pathways and characterise their ecophysiological properties. This project is expected to understand how this process regulates the atmospheric concentratio ....Iron-dependent anaerobic oxidation of methane process. This project aims to investigate the microbial process of iron-dependent anaerobic oxidation of methane. This process may be pervasive in Earth's aquatic systems, and possibly a major methane sink. This project will identify the organisms mediating this reaction, elucidate their metabolic pathways and characterise their ecophysiological properties. This project is expected to understand how this process regulates the atmospheric concentration of methane and more reliably predict global methane emissions in a changing climate. By addressing this key knowledge gap, this project will enhance our ability to predict global methane emissions in a changing climate.Read moreRead less
Identifying limitations to the establishment of microbial communities and sustainable nutrient cycling in bauxite residue sand under rehabilitation. Australia is the world's largest producer of bauxite. The process of refining bauxite to aluminium generates 2 t of residue for every 3 t of bauxite, creating a major residue management issue. Rehabilitation of residue disposal areas is critical for reducing impacts on the environment and surrounding community and ultimately aims to create a sustain ....Identifying limitations to the establishment of microbial communities and sustainable nutrient cycling in bauxite residue sand under rehabilitation. Australia is the world's largest producer of bauxite. The process of refining bauxite to aluminium generates 2 t of residue for every 3 t of bauxite, creating a major residue management issue. Rehabilitation of residue disposal areas is critical for reducing impacts on the environment and surrounding community and ultimately aims to create a sustainable ecosystem following closure of the facility. This research will provide a detailed understanding of the establishment of microbial communities and the factors controlling the survival and functioning of microorganisms in bauxite residue sand. The outcomes will aid the development of improved protocols and strategies for bauxite residue rehabilitation in Australia and internationally.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100009
Funder
Australian Research Council
Funding Amount
$389,476.00
Summary
Toxic Oceans: How do anthropogenic pollutants impact vital marine microbes? Environmental pollution threatens the sustainability of the world's oceans. However, we still do not understand how pollution affects primary producers at the base of oceanic food chains. This project aims to provide the first account of how common chemical pollutants (herbicides, plastic leachates and crude oil) affect key groups of marine photosynthetic bacteria. As these microbes underpin entire marine food webs, unde ....Toxic Oceans: How do anthropogenic pollutants impact vital marine microbes? Environmental pollution threatens the sustainability of the world's oceans. However, we still do not understand how pollution affects primary producers at the base of oceanic food chains. This project aims to provide the first account of how common chemical pollutants (herbicides, plastic leachates and crude oil) affect key groups of marine photosynthetic bacteria. As these microbes underpin entire marine food webs, understanding their responses is crucial to monitoring and mitigating the impact of pollutants on ocean ecosystems. The aim is to design and validate novel, rapid environmental stress assays, based on gene expression profiling. This represents a pioneering new application of gene monitoring techniques to ocean conservation.Read moreRead less
Synthetic Biology Derived Electroactive Whole Cell Microbial Biosensors. The aim of this project is to develop, using synthetic biology, electrically integrated microbial biosensors for the detection of heavy metals in the environment. Building on our existing technology, this project aims to produce novel ‘biobricks’ capable of electrically integrating electric microbes into real time environmental monitors for heavy metal contaminants. This expansion of synthetic biology, and integration of el ....Synthetic Biology Derived Electroactive Whole Cell Microbial Biosensors. The aim of this project is to develop, using synthetic biology, electrically integrated microbial biosensors for the detection of heavy metals in the environment. Building on our existing technology, this project aims to produce novel ‘biobricks’ capable of electrically integrating electric microbes into real time environmental monitors for heavy metal contaminants. This expansion of synthetic biology, and integration of electric bacteria into sensor systems, will result in a new platform technology that expands our abilities to protect the ecology, agriculture and health of terrestrial, marine and agricultural at risk areas from economic and environmental damage.Read moreRead less
Microbiology of a tropical creek impacted by sewage effluent: novel assessment using N-cycle functional markers and changes in community composition. Although most of Darwin Harbour has good water quality, there is much concern about local 'hot spots' where sewage has degraded ecosystem processes and values. As no bio-indicators of tropical marine water and sediment quality are known, the project will identify functional markers and microbial indicators of stress for integrated environmental mo ....Microbiology of a tropical creek impacted by sewage effluent: novel assessment using N-cycle functional markers and changes in community composition. Although most of Darwin Harbour has good water quality, there is much concern about local 'hot spots' where sewage has degraded ecosystem processes and values. As no bio-indicators of tropical marine water and sediment quality are known, the project will identify functional markers and microbial indicators of stress for integrated environmental monitoring.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101401
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel autotrophic biological nitrogen removal process driven by ammonia-oxidising archaea and anammox bacteria. This project will provide fundamental support to the development of more sustainable nitrogen removal processes. This would bring considerable benefits to the Australian wastewater industry and could potentially influence the way that biological nutrient removal plants are designed and operated.