Novel link between bacterial sugar metabolism and cell-to-cell signalling. This project aims to understand the role and function of the bacterial communication system that enables bacteria to form complex communities and alter phenotypic traits, essential for survival in their environment. Bacteria survive in their environmental niches by developing complex multicellular communities. Cell to cell communication, termed quorum sensing (QS), is critical for this process and is linked to their capac ....Novel link between bacterial sugar metabolism and cell-to-cell signalling. This project aims to understand the role and function of the bacterial communication system that enables bacteria to form complex communities and alter phenotypic traits, essential for survival in their environment. Bacteria survive in their environmental niches by developing complex multicellular communities. Cell to cell communication, termed quorum sensing (QS), is critical for this process and is linked to their capacity to detect and secrete small signalling molecules, autoinducers. This project will provide a new paradigm in bacterial adaptation through comprehensive characterisation of the Autoinducer-2 QS system. This knowledge will provide future opportunities for intervention in microbial infestation with broad potential benefits.Read moreRead less
The role of central carbon metabolism in cell cycle control in bacteria. Bacteria are simple organisms, yet we still do not understand how they coordinate their growth with their reproduction so faithfully, generation after generation, to produce viable newborn cells. The new discovery of a link between the food bacteria eat and the first stage of their cell division now provides the opportunity to elucidate how bacteria 'measure' their energy production to control their proliferation. This proj ....The role of central carbon metabolism in cell cycle control in bacteria. Bacteria are simple organisms, yet we still do not understand how they coordinate their growth with their reproduction so faithfully, generation after generation, to produce viable newborn cells. The new discovery of a link between the food bacteria eat and the first stage of their cell division now provides the opportunity to elucidate how bacteria 'measure' their energy production to control their proliferation. This project combines the latest technology with complementary expertise in bacterial cell division and metabolism. This should identify the mechanism that integrates these fundamental pathways in bacteria, crucial to both their survival and ability to cause infection.Read moreRead less
Identifying how bacterial cells find their middle: a new perspective. This project will reveal new information about how bacterial cells divide with high precision to ensure that each newborn cell contains the correct genetic material. The research uses frontier techniques, provides innovative training to young Australian researchers, and will identify new ways to treat infections caused by bacteria.
Engineer enzyme nanoparticles as antibiotic alternatives for agriculture. Antibiotic usage in agriculture contributes to spread of resistant bacteria. Existing antibiotic alternatives to minimize such usage are focused on growth promotion of animals and infection prevention, but lack efficient treatment. This project aims to engineer enzyme nanoparticles, with synergy from multiple enzymes, to confer better antibacterial abilities against livestock pathogens. It will combine protein engineering, ....Engineer enzyme nanoparticles as antibiotic alternatives for agriculture. Antibiotic usage in agriculture contributes to spread of resistant bacteria. Existing antibiotic alternatives to minimize such usage are focused on growth promotion of animals and infection prevention, but lack efficient treatment. This project aims to engineer enzyme nanoparticles, with synergy from multiple enzymes, to confer better antibacterial abilities against livestock pathogens. It will combine protein engineering, nanotechnology and biophysics to develop new enzyme nanoparticles that can be manufactured at low-cost through self-assembly process. The intended outcome is knowledge on molecular engineering of enzyme nanoparticles and innovative agriculture biotechnology for treatment of bacterial infectious diseases in livestock.Read moreRead less
Autotransporter folding: insights advancing recombinant protein production. Imagine a world in which any protein could be produced using a single production platform. This project aims to make this a reality by reengineering autotransporters, a large family of bacterial virulence factors with a modular structure that makes them amenable to rational design. The project plans to examine the structures and folding behaviour of autotransporters and reengineered derivatives fused to target heterologo ....Autotransporter folding: insights advancing recombinant protein production. Imagine a world in which any protein could be produced using a single production platform. This project aims to make this a reality by reengineering autotransporters, a large family of bacterial virulence factors with a modular structure that makes them amenable to rational design. The project plans to examine the structures and folding behaviour of autotransporters and reengineered derivatives fused to target heterologous proteins using biochemical, biophysical, and structural methods. It is expected that this project will provide fundamental insights into factors that dictate autotransporter folding and stability, which may enhance recombinant protein production and drive discovery of strategies to prevent autotransporter-mediated infection.Read moreRead less
Autotransporter assembly: new insights and biotechnological potential. The objective of this project is to improve our understanding of a fundamental biological problem: how autotransporters are assembled into cellular membranes. Autotransporters are a large family of bacterial proteins that play key roles in the pathogenesis of several infectious diseases. Currently, the precise mechanism by which disease-causing molecules are assembled into the outer membranes of bacteria and mitochondria is p ....Autotransporter assembly: new insights and biotechnological potential. The objective of this project is to improve our understanding of a fundamental biological problem: how autotransporters are assembled into cellular membranes. Autotransporters are a large family of bacterial proteins that play key roles in the pathogenesis of several infectious diseases. Currently, the precise mechanism by which disease-causing molecules are assembled into the outer membranes of bacteria and mitochondria is poorly understood. The knowledge that the project develops may inform future strategies aimed at the rational treatment of bacterial and mitochondrial diseases.Read moreRead less
Molecular insights into bacterial metal ion homeostasis and toxicity. This project aims to measure bacterial cellular metal concentrations, elucidate mechanisms cells use to adapt to changing extracellular metal concentrations, and reveal the molecular targets of metal toxicity. Metal ions are essential to all forms of life, and half of all proteins use metal ions for cellular chemical processes. However, how cells precisely balance sufficient metal ions for essential cellular chemistry without ....Molecular insights into bacterial metal ion homeostasis and toxicity. This project aims to measure bacterial cellular metal concentrations, elucidate mechanisms cells use to adapt to changing extracellular metal concentrations, and reveal the molecular targets of metal toxicity. Metal ions are essential to all forms of life, and half of all proteins use metal ions for cellular chemical processes. However, how cells precisely balance sufficient metal ions for essential cellular chemistry without accumulating a toxic excess (metal homeostasis) is poorly understood. Discovering the roles of metal ions in bacterial cells will be key to defining the chemical biology of living systems and will provide information essential to understanding how microbes adapt to changing environments.Read moreRead less
New molecular tools to study the mechanisms of bacterial metal homeostasis. This project aims to provide new insight into how metal ion uptake is regulated. It will precisely measure the cellular concentrations of metal ions, reveal the roles of metal ions in essential cellular processes, and identify the molecular targets of metal toxicity. Metal ions are essential to all forms of life and are used by up to half of all proteins to facilitate cellular chemical processes. The intended outcome of ....New molecular tools to study the mechanisms of bacterial metal homeostasis. This project aims to provide new insight into how metal ion uptake is regulated. It will precisely measure the cellular concentrations of metal ions, reveal the roles of metal ions in essential cellular processes, and identify the molecular targets of metal toxicity. Metal ions are essential to all forms of life and are used by up to half of all proteins to facilitate cellular chemical processes. The intended outcome of the research is to provide new fundamental knowledge of the roles of metal ions in bacterial cells; knowledge that will be key to defining the chemical biology of living systems and will provide information essential to understanding how microbes adapt to changing environments.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101666
Funder
Australian Research Council
Funding Amount
$395,588.00
Summary
Engineering nanoparticles with enhanced adhesion at the nano-bio interfaces. This project aims to develop a next-generation adhesive nanoparticle platform through in-depth understandings of nanoparticle interactions with bio-interfaces. This project expects to generate new knowledge in the multidisciplinary research field at nano-bio-interfaces by using a recently developed nano-colloidal probe technology, instructing the rational design of nanoparticles with enhanced interface adhesive properti ....Engineering nanoparticles with enhanced adhesion at the nano-bio interfaces. This project aims to develop a next-generation adhesive nanoparticle platform through in-depth understandings of nanoparticle interactions with bio-interfaces. This project expects to generate new knowledge in the multidisciplinary research field at nano-bio-interfaces by using a recently developed nano-colloidal probe technology, instructing the rational design of nanoparticles with enhanced interface adhesive properties. Expected outcomes include a family of adhesive nanoparticles designed for nanopesticide and animal feed applications, with the potential to deliver valuable intellectual property of commercial interest and economic benefit through technology advancement.Read moreRead less
Developing an integrated device for on-farm detection of sugarcane diseases. Pathogenic organisms cause yield losses of more than $150M pa to the Australian sugarcane industry and many millions more worldwide. Partnering with Sugar Research Australia, this project aims to develop a novel on-farm diagnostic device, comprising new nanotechnology and magnetism-induced microfluidics with naked eye observation and electrochemical detection. This device is expected to enable improved disease managemen ....Developing an integrated device for on-farm detection of sugarcane diseases. Pathogenic organisms cause yield losses of more than $150M pa to the Australian sugarcane industry and many millions more worldwide. Partnering with Sugar Research Australia, this project aims to develop a novel on-farm diagnostic device, comprising new nanotechnology and magnetism-induced microfluidics with naked eye observation and electrochemical detection. This device is expected to enable improved disease management strategies through the prediction of potential risks and rapid and effective actions to mitigate impending yield loss. In turn productivity and sustainability of Australia’s sugar industry will be enhanced. The new platform device has great potential for improved disease management in other crops in Australia and globally.Read moreRead less