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
Australian Laureate Fellowships - Grant ID: FL180100036
Funder
Australian Research Council
Funding Amount
$3,011,916.00
Summary
Engineering microbes that increase coral climate resilience. This project aims to develop microbes which are able to enhance the climate resilience of corals. Coral reefs around the world are being lost at an alarming rate. Developing microbial symbionts to enhance coral climate resilience will give Australian and other coral reef ecosystems an increased chance of surviving the impact of climate change. The project will also enhance understanding of the functional roles of microbial symbionts of ....Engineering microbes that increase coral climate resilience. This project aims to develop microbes which are able to enhance the climate resilience of corals. Coral reefs around the world are being lost at an alarming rate. Developing microbial symbionts to enhance coral climate resilience will give Australian and other coral reef ecosystems an increased chance of surviving the impact of climate change. The project will also enhance understanding of the functional roles of microbial symbionts of corals, and advance the microbial symbiosis discipline globally. Expected outcomes include healthier coral reefs through the use of more climate resilient coral stock in reef conservation and restoration initiatives.Read moreRead less
Developing and testing a novel biological reduction cell to remediate heavy metal and acid-containing industrial and mine leachates. Echo Remediation Ltd. has a new reduction cell that uses sulfur and bacteria to remove heavy metals and acidity from mine leachates, but development is now required to make it viable. The project aims to optimise the process using molecular approaches to study the effects of operating conditions on the bacterial communities. As part of the investigation, active iro ....Developing and testing a novel biological reduction cell to remediate heavy metal and acid-containing industrial and mine leachates. Echo Remediation Ltd. has a new reduction cell that uses sulfur and bacteria to remove heavy metals and acidity from mine leachates, but development is now required to make it viable. The project aims to optimise the process using molecular approaches to study the effects of operating conditions on the bacterial communities. As part of the investigation, active iron reducers will be selected and introduced to the cell (in conjunction with chemical amendments) and their colonization monitored. The new technology once developed has the potential to be used at mine sites in Australia and overseas and its employment offers a sustainable, biological "green" approach to mine waste remediation.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.
Microbial infestation of pre-painted steel building materials: chemical and microbial characterization, model development and control strategies. Coated steel building materials are a multi-billion dollar Australian industry. Microorganisms form slime layers on those materials, which are unsightly and reduce their energy benefits. The project will identify the problem organisms, the factors that facilitate their growth and will develop novel biofilm resistant, functional building materials.
Biogeochemical remediation approaches for PFAS contaminated environments. This project aims to identify and harvest microorganisms capable of directly or indirectly affecting PFOS or PFOA degradation in the environment. Fluorinated compounds such as PFOS and PFOA in firefighting foams are contaminants of concern now routinely detected in contaminated groundwater and soil globally. Understanding the role of microorganisms, and the biogeochemical processes they perform in relation to fluorinated c ....Biogeochemical remediation approaches for PFAS contaminated environments. This project aims to identify and harvest microorganisms capable of directly or indirectly affecting PFOS or PFOA degradation in the environment. Fluorinated compounds such as PFOS and PFOA in firefighting foams are contaminants of concern now routinely detected in contaminated groundwater and soil globally. Understanding the role of microorganisms, and the biogeochemical processes they perform in relation to fluorinated compounds, will inform handling of contaminated sites and lead to development of cost effective and sustainable remediation technologies. 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
Discovery Early Career Researcher Award - Grant ID: DE160100615
Funder
Australian Research Council
Funding Amount
$348,200.00
Summary
Harnessing chain-forming diatoms for improved lipid biofuel production. The aim of this project is to unlock the molecular secrets of highly productive chain-forming diatom microalgae that allow them to produce high levels of biofuel lipids. The formation of multicellular chains appears key to the success of some of the most widespread and productive diatom species. Through a combination of systems biology, bioinformatics, and genetics experiments, this project aims to investigate the relationsh ....Harnessing chain-forming diatoms for improved lipid biofuel production. The aim of this project is to unlock the molecular secrets of highly productive chain-forming diatom microalgae that allow them to produce high levels of biofuel lipids. The formation of multicellular chains appears key to the success of some of the most widespread and productive diatom species. Through a combination of systems biology, bioinformatics, and genetics experiments, this project aims to investigate the relationship between chain formation and biofuel lipid productivity in Chaetoceros diatoms, and to discover genes and molecules that encode and influence these traits. The knowledge and technology generated as a result may improve biofuel yields, increase the robustness of species growing in open pond systems, and reduce processing costs such as de-watering.Read moreRead less
The toxins of water-borne cyanobacteria: regulation and exploitation of their biosynthesis. Water quality is a major concern in Australia, as is the global need for new natural products with antibiotic activity. The mechanisms by which cyanobacteria produce toxins that reduce the quality of water may very well be the answer to the lack of novel medicinal compounds currently being discovered in nature. Encompassed in this one program are the aims of ameliorating the effects of toxic algal blooms ....The toxins of water-borne cyanobacteria: regulation and exploitation of their biosynthesis. Water quality is a major concern in Australia, as is the global need for new natural products with antibiotic activity. The mechanisms by which cyanobacteria produce toxins that reduce the quality of water may very well be the answer to the lack of novel medicinal compounds currently being discovered in nature. Encompassed in this one program are the aims of ameliorating the effects of toxic algal blooms as well as introducing the means for the design and synthesis of a range of novel bioactive products. The benefits include better water quality and biosafety management options, a new generation of drug design and discovery, and the associated transformation of environmental and medical research and education in Australia.Read moreRead less
Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create ....Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create new, artificial interactions between bacteria and eukaryotes. This project will provide fundamental knowledge on the evolution and function of newly discovered ELPs found in both beneficial and pathogenic bacteria and paves the way to control symbiosis for biotechnological applications.Read moreRead less