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
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
Discovery Early Career Researcher Award - Grant ID: DE120101213
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Microbial buffering: protecting the Great Barrier Reef against anthropogenic impacts. Coral reefs are hotspots of diversity, but are susceptible to human activities such as agriculture and tourism. Novel molecular approaches will be used to characterise what microorganisms are found at polluted and non-polluted sites of the Great Barrier Reef lagoon and what metabolic pathways they use to protect it against human impacts.
Australia's ocean microbiome: how the diversity and functionality of microbes influence key oceanographic provinces. Every millilitre of seawater contains millions of microbes that maintain the health of our planet, but their identity and function in Australian waters is undefined. This project will identify the microbes inhabiting Australian marine systems, elucidate the services they provide, and predict how they will be affected by future environmental changes
Defining how inter-bacterial symbioses regulate aquatic ecosystem health. This project will determine how ecological relationships among aquatic bacteria govern the health of Australia’s marine and freshwater environments. Cyanobacteria support aquatic ecosystem productivity, but can have detrimental effects when they form harmful blooms, although the factors governing the balance of these contrasting impacts are largely undefined. By coupling sophisticated approaches including genomics, phenomi ....Defining how inter-bacterial symbioses regulate aquatic ecosystem health. This project will determine how ecological relationships among aquatic bacteria govern the health of Australia’s marine and freshwater environments. Cyanobacteria support aquatic ecosystem productivity, but can have detrimental effects when they form harmful blooms, although the factors governing the balance of these contrasting impacts are largely undefined. By coupling sophisticated approaches including genomics, phenomics, and microfluidics to examine how symbioses with other bacteria influence the growth and function of important species of cyanobacteria, this research will elucidate the importance of an over-looked factor in controlling the productivity, health and value of Australia’s aquatic estate.Read moreRead less
The effect of microbial diversity vs function on marine holobionts. This project aims to integrate a central theme of modern ecology - the relationship between biodiversity and functioning of communities - with the new biological paradigm of holobionts, where organisms are the entirety of the host plus its associated microbiome. This project blends marine and microbial ecology, aiming to experimentally decouple effects of microbial diversity versus function on the performance of dominant marine ....The effect of microbial diversity vs function on marine holobionts. This project aims to integrate a central theme of modern ecology - the relationship between biodiversity and functioning of communities - with the new biological paradigm of holobionts, where organisms are the entirety of the host plus its associated microbiome. This project blends marine and microbial ecology, aiming to experimentally decouple effects of microbial diversity versus function on the performance of dominant marine holobionts, habitat-forming seaweeds. Expected outcomes are to characterise key microbial taxa and functions and their effects on seaweed performance, and how this is affected by environmental stress. This will provide significant benefits, such as providing critical information and new tools for understanding and managing a major Australian ecosystem.Read moreRead less
Do marine heat waves cause pathogen outbreaks in Australian coastal waters? This project aims to identify links between increasingly frequent Marine Heat Wave (MHW) events and outbreaks of microbes that cause disease in marine animals, reduced aquaculture yields and human health hazards. Pathogenic bacteria from the Vibrio genus exhibit a preference for elevated seawater temperature and this project will test the hypothesis that episodic MHWs will trigger blooms of dangerous species. Using innov ....Do marine heat waves cause pathogen outbreaks in Australian coastal waters? This project aims to identify links between increasingly frequent Marine Heat Wave (MHW) events and outbreaks of microbes that cause disease in marine animals, reduced aquaculture yields and human health hazards. Pathogenic bacteria from the Vibrio genus exhibit a preference for elevated seawater temperature and this project will test the hypothesis that episodic MHWs will trigger blooms of dangerous species. Using innovative ecogenomic tools, this project will track the impact of MHWs on the dynamics of pathogenic Vibrio within coastal habitats, oyster farming facilities and coral reefs. The benefit of this project will be essential new knowledge on an emerging threat to Australia’s valuable marine estate, food security and public health.Read moreRead less
Can cyanobacteria use organic nutrients to thrive in future oceans? Marine cyanobacteria are central to regulating the global climate and underpin entire marine food webs. Though they possess genes necessary to uptake diverse organic nutrients, we know very little about whether and how organic nutrients shape the physiology and ecology of cyanobacteria. Using our innovative high-throughput approach, this project aims to systematically characterise organic nutrient uptake in picocyanobacteria. O ....Can cyanobacteria use organic nutrients to thrive in future oceans? Marine cyanobacteria are central to regulating the global climate and underpin entire marine food webs. Though they possess genes necessary to uptake diverse organic nutrients, we know very little about whether and how organic nutrients shape the physiology and ecology of cyanobacteria. Using our innovative high-throughput approach, this project aims to systematically characterise organic nutrient uptake in picocyanobacteria. Our molecules-to-ecosystems approach expects to transform our understanding of alternate nutrient acquisition in cyanobacteria and how it may shape populations of these important photosynthetic organisms in a rapidly-changing ocean landscape. Read moreRead less
Australian Laureate Fellowships - Grant ID: FL140100021
Funder
Australian Research Council
Funding Amount
$2,700,000.00
Summary
Building virtual cyanobacteria: moving beyond the genomics era. Building virtual cyanobacteria: moving beyond the genomics era. This project aims to establish a new understanding of complex biological systems through the development of computational models of single cells and global ecosystems. The project will focus on globally important photosynthetic bacteria that underlie the entire marine food web. This project aims to characterise the diversity and abundance of photosynthetic bacteria acro ....Building virtual cyanobacteria: moving beyond the genomics era. Building virtual cyanobacteria: moving beyond the genomics era. This project aims to establish a new understanding of complex biological systems through the development of computational models of single cells and global ecosystems. The project will focus on globally important photosynthetic bacteria that underlie the entire marine food web. This project aims to characterise the diversity and abundance of photosynthetic bacteria across Australia's marine habitats and unravel the genetic basis for their adaptation to different environments. This data will be integrated with biochemical and physiological studies to create quantitative models at the cellular and global ecosystem scales. This project aims to develop new biomonitoring technologies, which combined with these models, will enable assessment of the health of Australia's marine ecosystems.Read moreRead less
Do binding proteins allow cyanobacteria to scavenge diverse nutrients? Marine cyanobacteria are abundant primary producers that underlie the entire marine food web. They encode a diverse range of predicted nutrient uptake systems that are highly conserved, suggesting these transporters play critical roles in their success in diverse marine ecosystems. However, there is very limited data regarding their function, specificity and ecological importance. Using our pioneering combinatorial approach, ....Do binding proteins allow cyanobacteria to scavenge diverse nutrients? Marine cyanobacteria are abundant primary producers that underlie the entire marine food web. They encode a diverse range of predicted nutrient uptake systems that are highly conserved, suggesting these transporters play critical roles in their success in diverse marine ecosystems. However, there is very limited data regarding their function, specificity and ecological importance. Using our pioneering combinatorial approach, we will undertake systematic functional characterisation of these nutrient uptake systems and determine their physiological and ecological importance. Our integrative science will provide a molecules-to-ecosystems understanding of cyanobacterial nutrient acquisition.Read moreRead less