Microbe-produced repellents and their roles in marine pathogen behaviours. Economic losses caused by disease outbreaks in marine fisheries and aquaculture exceed US$6 billion per year globally. Decades of research in human and plant pathogens have revealed that the ability of pathogens to infect their host is governed by behaviours; however our understanding of the chemical cues affecting the behaviour of marine pathogens is very poor. This research program aims to combine new approaches in micr ....Microbe-produced repellents and their roles in marine pathogen behaviours. Economic losses caused by disease outbreaks in marine fisheries and aquaculture exceed US$6 billion per year globally. Decades of research in human and plant pathogens have revealed that the ability of pathogens to infect their host is governed by behaviours; however our understanding of the chemical cues affecting the behaviour of marine pathogens is very poor. This research program aims to combine new approaches in microfluidics and chemical imaging to identify the cues that govern the behaviour of marine pathogens. Expected outcomes include an improved capacity to predict, monitor and manage marine diseases, as well as novel strategies to prevent disease outbreaks, helping to protect Australia’s valuable marine estate.Read moreRead less
Understanding evolution of dominant bacteria inhabiting the rodent gut . The gut microbiome is central to animal health and immune function, however we have an incomplete understanding of how this important symbiotic ecosystem evolved. By approaching this knowledge gap from a historical perspective and using real-time observation, this project will address how the gut community evolved with the rodent host and how members of that community respond to new selective pressures. The significance of ....Understanding evolution of dominant bacteria inhabiting the rodent gut . The gut microbiome is central to animal health and immune function, however we have an incomplete understanding of how this important symbiotic ecosystem evolved. By approaching this knowledge gap from a historical perspective and using real-time observation, this project will address how the gut community evolved with the rodent host and how members of that community respond to new selective pressures. The significance of these findings is in their capacity to inform our understanding of the relationship between host and microbe, not only within a key model system, but by extrapolation to other host-microbe systems. Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE200100884
Funder
Australian Research Council
Funding Amount
$426,691.00
Summary
Do novel diets reshape wildlife microbiomes and resilience to stressors? This project aims to investigate how bacteria can assist wildlife in adapting to the accelerating threat of environmental change. Using an innovative, interdisciplinary approach this project expects to identify interactions between environmental change and the diet, microbial communities and stress resilience of wildlife, using the threatened Grey-headed flying fox as a model system. Expected outcomes include detailed under ....Do novel diets reshape wildlife microbiomes and resilience to stressors? This project aims to investigate how bacteria can assist wildlife in adapting to the accelerating threat of environmental change. Using an innovative, interdisciplinary approach this project expects to identify interactions between environmental change and the diet, microbial communities and stress resilience of wildlife, using the threatened Grey-headed flying fox as a model system. Expected outcomes include detailed understanding of the role of microbial communities in shaping wildlife adaptations and development of ecological interventions to enhance wildlife resilience in Australia and globally. Such outcomes may reveal opportunities for management strategies that safeguard threatened species and reduce human-wildlife conflicts.Read moreRead less
Structural Characterisation of the Type IX Secretion System. The Type IX Secretion System present in diverse bacteria of veterinary, agricultural, environmental and industrial importance enables effector proteins to be secreted and attached to the cell surface where they contribute to disease pathogenesis or degrade biopolymers of commercial interest. This project aims to determine the structure and assembly mechanism of this complex secretion nanomachine comprising 15 different proteins using s ....Structural Characterisation of the Type IX Secretion System. The Type IX Secretion System present in diverse bacteria of veterinary, agricultural, environmental and industrial importance enables effector proteins to be secreted and attached to the cell surface where they contribute to disease pathogenesis or degrade biopolymers of commercial interest. This project aims to determine the structure and assembly mechanism of this complex secretion nanomachine comprising 15 different proteins using state of the art microscopy. Knowledge of the structure will greatly enhance our understanding of secretion mechanisms and our ability to both inhibit the system to treat disease in animals or manipulate the system for industrial applications providing future economic and environmental benefits to our nation.Read moreRead less
Microbial community stability dynamics to environmental triggers. This project aims to advance our knowledge of the structural/functional dynamics of complex microbial communities by defining stability in response to environmental influences such as nutrient stress, pathogen invasion and antibiotics/chemicals. Using innovative microbial consortia modelling, to identify communities at risk of homeostatic disruption, we will develop and test pre-emptive microbial manipulation strategies for restor ....Microbial community stability dynamics to environmental triggers. This project aims to advance our knowledge of the structural/functional dynamics of complex microbial communities by defining stability in response to environmental influences such as nutrient stress, pathogen invasion and antibiotics/chemicals. Using innovative microbial consortia modelling, to identify communities at risk of homeostatic disruption, we will develop and test pre-emptive microbial manipulation strategies for restoring community stability. This project will yield significant global impact and economic/health benefit for humans and animals.Read moreRead less
Skin Microbes and Animal Health: Understanding the Ecological Context. This project aims to understand the fundamental ecological relationships between animal hosts (frogs, geckos) and bacteria on their skin by separating host effects from environmental factors that determine skin microbiome composition. The research is significant because it will generate new knowledge needed to understand how skin microbes function in providing protection against disease. Expected outcomes include the provisio ....Skin Microbes and Animal Health: Understanding the Ecological Context. This project aims to understand the fundamental ecological relationships between animal hosts (frogs, geckos) and bacteria on their skin by separating host effects from environmental factors that determine skin microbiome composition. The research is significant because it will generate new knowledge needed to understand how skin microbes function in providing protection against disease. Expected outcomes include the provision of essential information that will guide future research efforts on the factors that determine a healthy skin microbial community (which is needed before skin diseases can be combated). The research will provide significant benefits, including more targeted conservation efforts to combat wildlife skin diseases.Read moreRead less
Defining the Microbial-scale Processes Governing Ocean Health . This project aims to resolve the foundations of healthy ocean function by employing innovative approaches to uncover the links between marine chemistry and microbiology. While the importance of microbes in governing ocean health is unquestionable, they are often studied over inappropriately large-scales, leading to inaccurate interpretation of the oceanic processes that ultimately influence fishery production and climate control. W ....Defining the Microbial-scale Processes Governing Ocean Health . This project aims to resolve the foundations of healthy ocean function by employing innovative approaches to uncover the links between marine chemistry and microbiology. While the importance of microbes in governing ocean health is unquestionable, they are often studied over inappropriately large-scales, leading to inaccurate interpretation of the oceanic processes that ultimately influence fishery production and climate control. We will develop new oceanographic tools and analytical techniques to provide a unique "microbes-eye-view" of the sea. The project's outcomes are anticipated to deliver transformative new knowledge on the controls of ocean productivity and sustainability, helping to safeguard Australia’s valuable marine estate.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100008
Funder
Australian Research Council
Funding Amount
$387,103.00
Summary
Exploring the evolution and ecology of non-photosynthetic Cyanobacteria. This project aims to contribute and expand our rudimentary understanding of non-photosynthetic Cyanobacteria by obtaining representative genome sequences using metagenomics. The dogma that all Cyanobacteria are photosynthetic has recently been challenged by the discovery of non-photosynthetic lineages. This project expects to obtain representative genome sequences using metagenomics to predict surface structures. The expect ....Exploring the evolution and ecology of non-photosynthetic Cyanobacteria. This project aims to contribute and expand our rudimentary understanding of non-photosynthetic Cyanobacteria by obtaining representative genome sequences using metagenomics. The dogma that all Cyanobacteria are photosynthetic has recently been challenged by the discovery of non-photosynthetic lineages. This project expects to obtain representative genome sequences using metagenomics to predict surface structures. The expected outcomes from this project includes providing insights into the function and evolution of non-photosynthetic Cyanobacteria and their viruses, and pure or enriched cultures to enable future studies.Read moreRead less
Unlocking the secrets of metabolic variation in a highly diverse bacterium. This project aims to explore metabolic diversity of Klebsiella pneumoniae, a bacterium relevant to the agricultural, veterinary, medical and biotechnology industries. It is expected to reveal significant insights into the biology of this diverse organism via an innovative combination of DNA sequence analyses and metabolic modelling. Expected outcomes include 4500 novel metabolic models and a novel population metabolic fr ....Unlocking the secrets of metabolic variation in a highly diverse bacterium. This project aims to explore metabolic diversity of Klebsiella pneumoniae, a bacterium relevant to the agricultural, veterinary, medical and biotechnology industries. It is expected to reveal significant insights into the biology of this diverse organism via an innovative combination of DNA sequence analyses and metabolic modelling. Expected outcomes include 4500 novel metabolic models and a novel population metabolic framework. This should provide major benefits for understanding bacterial ecology and evolution, and for future studies seeking to optimise industrial processes or prevent disease. It will also directly contribute to building Australia’s capacity in computational biology- a key driver of biotechnology innovation.Read moreRead less