Unlocking the potential of bacterial polymers by defining key determinants. Sugary structures that coat the surface of some bacteria, known as capsules, can be modified by bacterial viruses (bacteriophage) in the environment. For the bacterial genus Acinetobacter, this influences their use as naturally renewable 'green' biopolymers for remediating environments contaminated with petroleum hydrocarbons. This project aims to characterise crucial capsule polymerase enzymes using a combination of bio ....Unlocking the potential of bacterial polymers by defining key determinants. Sugary structures that coat the surface of some bacteria, known as capsules, can be modified by bacterial viruses (bacteriophage) in the environment. For the bacterial genus Acinetobacter, this influences their use as naturally renewable 'green' biopolymers for remediating environments contaminated with petroleum hydrocarbons. This project aims to characterise crucial capsule polymerase enzymes using a combination of bioinformatics and experimental methodologies to establish how bacteriophage influence Acinetobacter capsules. Outcomes include the development of an innovative genomics pipeline to detect capsule change, improving the use of living bacteria for bioremediation and sustainable rehabilitation of natural ecosystems.Read moreRead less
How Bacteria Fold Virulence Factors to Cause Disease. Bacteria use folding enzymes to assemble proteins essential for cell integrity and pathogenicity. These foldases include the Disulphide bridge proteins, which catalyse the introduction of disulfide bonds. This project will study two important human pathogens, Salmonella Typhimurium and uropathogenic Escherichia coli, to address the fundamental and poorly understood questions of diversity of Dsb networks across bacterial pathogens and the role ....How Bacteria Fold Virulence Factors to Cause Disease. Bacteria use folding enzymes to assemble proteins essential for cell integrity and pathogenicity. These foldases include the Disulphide bridge proteins, which catalyse the introduction of disulfide bonds. This project will study two important human pathogens, Salmonella Typhimurium and uropathogenic Escherichia coli, to address the fundamental and poorly understood questions of diversity of Dsb networks across bacterial pathogens and the role of these foldases in virulence. The research will reveal how bacterial virulence factors are folded, identify novel targets for therapeutic intervention and provide the basis for structure-based design on new antimicrobials in the future. Read moreRead less
Chemical warfare in the marine environment: the role of surface-associated bacteria and their antibiotics. Antibiotics from natural sources are an essential part of modern medicine, however their function in the environment is poorly understood. This project aims to define how antibiotic-producing bacteria from marine macroalgae determine ecological interactions on the micro- and macro-biological level. This work will combine innovative approaches in microbial and chemical analysis to provide in ....Chemical warfare in the marine environment: the role of surface-associated bacteria and their antibiotics. Antibiotics from natural sources are an essential part of modern medicine, however their function in the environment is poorly understood. This project aims to define how antibiotic-producing bacteria from marine macroalgae determine ecological interactions on the micro- and macro-biological level. This work will combine innovative approaches in microbial and chemical analysis to provide insights into how antibiotics influence microbial communities and how this impacts on macroalgal health. The outcomes of this project will answer the fundamental question of the impact of antibiotics in natural systems and the role of antibiotic-producing bacteria in safeguarding important habitat-forming macroalgae against environmental stress.Read moreRead less
Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others a ....Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others are used in biotechnology for biosynthetic chemical production or bioremediation. This project expects to help the future development of new antibiotics and assist in the design of strains to be used in biotechnological applications.Read moreRead less
Unlocking bacterial shapeshifting and its role in antimicrobial resistance. This project aims to combine advanced imaging with innovative microfluidics to identify how microbial shapeshifting can be exploited as a target for new antimicrobials. Infections that are hard to treat due to increasing antimicrobial resistance not only have an enormous, global impact on mammalian health, including livestock and humans, but also carry a growing economic burden. Advanced understanding of microbial life c ....Unlocking bacterial shapeshifting and its role in antimicrobial resistance. This project aims to combine advanced imaging with innovative microfluidics to identify how microbial shapeshifting can be exploited as a target for new antimicrobials. Infections that are hard to treat due to increasing antimicrobial resistance not only have an enormous, global impact on mammalian health, including livestock and humans, but also carry a growing economic burden. Advanced understanding of microbial life can propel urgently needed progress this area. Specifically, the project outcomes are expected to aid the development of next generation antibiotics. The new fundamental knowledge should also benefit translational prevention, identification and management efforts of a rising national and global health threat.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
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 characterisation of hypervirulence and the infectious cycle in Clostridium difficile. Gut diseases caused by the bacterium Clostridium difficile are a significant animal and public health problem in Australia and many other countries. This project will allow us to understand how this bacterium causes disease, leading to the development of much needed preventative and treatment strategies for animals and human patients.
Molecular evolution of a model oligomeric enzyme from bacterial extremophiles. The national benefits of this research program include insight into the sustainability of marine microorganisms that play an important role in Australia's diverse ecosystem, the development and applications of frontier technologies including high-performance computing on the world's largest supercomputer facility for life science research, and knowledge impacting on the discovery of novel antibiotics that target patho ....Molecular evolution of a model oligomeric enzyme from bacterial extremophiles. The national benefits of this research program include insight into the sustainability of marine microorganisms that play an important role in Australia's diverse ecosystem, the development and applications of frontier technologies including high-performance computing on the world's largest supercomputer facility for life science research, and knowledge impacting on the discovery of novel antibiotics that target pathogenic bacteria, like Golden Staph. This program will also train several young Australians in highly sought after skills, including bacteriology, biophysics, enzymology, molecular biology, molecular modelling, protein chemistry and structural biology. Read moreRead less
How does glycosylation shape protein function within Burkholderia? Protein glycosylation, the chemical addition of sugars to proteins, is an important but poorly understood aspect of bacterial physiology. This project aims to build on our recent discovery of the conservation of O-linked glycosylation across the Burkholderia genus to understand the function of this modification. Using cutting-edge proteomics, novel expression systems and molecular approaches this project will reveal the role of g ....How does glycosylation shape protein function within Burkholderia? Protein glycosylation, the chemical addition of sugars to proteins, is an important but poorly understood aspect of bacterial physiology. This project aims to build on our recent discovery of the conservation of O-linked glycosylation across the Burkholderia genus to understand the function of this modification. Using cutting-edge proteomics, novel expression systems and molecular approaches this project will reveal the role of glycosylation in Burkholderia species. This innovative project will provide a comprehensive understanding of how glycosylation contributes to Burkholderia protein function and how these systems can be harnessed for the creation of bespoke glycoconjugatesRead moreRead less