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
The development of tools to study carbohydrate-processing enzymes implicated in human disease. Diseases caused by improper function of carbohydrate-processing enzymes are a major health burden. This research aims to find ways to restore the function of these enzymes bringing a better quality of life to people suffering from these diseases.
Mitochondrial proteases and their contribution to protein homeostasis. This research will examine how a critically important cellular organelle known as the mitochondrion maintains its functional integrity by sensing and signalling protein perturbations. As mitochondrial dysfunction is central to a number of neurodegenerative diseases understanding the molecular biology of this fundamentally important cellular process could, in the future, provide for better health outcomes for an aging Australi ....Mitochondrial proteases and their contribution to protein homeostasis. This research will examine how a critically important cellular organelle known as the mitochondrion maintains its functional integrity by sensing and signalling protein perturbations. As mitochondrial dysfunction is central to a number of neurodegenerative diseases understanding the molecular biology of this fundamentally important cellular process could, in the future, provide for better health outcomes for an aging Australian population. The training of post-graduate students is an integral component of this study and thus will contribute to building national research capacity. International collaborations and new discoveries will also contribute to the recognition of Australian research.Read moreRead less
Deciphering Electron Transfer Pathways in Bacteria. Enzyme catalysed oxidation reactions are key players in the production of naturally occurring biologically active molecules. These processes are tightly regulated by their electron transfer partners. This project aims to characterise new electron transfer ferredoxin proteins from a metabolically diverse bacterium. These ferredoxins, important in many bacteria, contain different non-cysteine amino acids in their iron-sulfur cluster binding motif ....Deciphering Electron Transfer Pathways in Bacteria. Enzyme catalysed oxidation reactions are key players in the production of naturally occurring biologically active molecules. These processes are tightly regulated by their electron transfer partners. This project aims to characterise new electron transfer ferredoxin proteins from a metabolically diverse bacterium. These ferredoxins, important in many bacteria, contain different non-cysteine amino acids in their iron-sulfur cluster binding motifs and are poorly defined. The outcomes will advance understandings of electron transfer, a fundamental process. This will allow strategies to combat human and plant pathogens and unlock the potential of these systems as biocatalysts for the green chemical synthesis of complex and valuable chemicals.Read moreRead less
The regulation of anti-viral immunity by host and viral proteins. Anti-viral immunity is initially triggered when specific immune sensors detect viral components within the cell. This project will use a combined functional/structural approach to investigate the specifics of immune activation by a pivotal immune sensor and use this information to understand how influenza A sabotages this specific immune response.
A new Src, PKCdelta and Akt regulated protease activated receptor system in metastasis. In contrast with localised cancer which can often be cured, curative treatment is generally not possible for cancer that has spread. This project will characterise a protein that drives the spread of cancer and to develop new approaches to treat patients at risk of developing these aggressive tumours that spread to other organs.
MOLECULAR APPROACHES TO OVERCOME SCABIES AND ASSOCIATED DISEASE. Scabies causes childhood pyoderma predisposing to severe disease in later life. It is a major increasing health burden in Indigenous people of Northern Australia. Drug resistance is developing in mites and bacteria. The lack of clinical material has hampered molecular research and this work will use comparative genomics of parasitic and free living mites and microbiome analysis to understand fundamental aspects of mite biology and ....MOLECULAR APPROACHES TO OVERCOME SCABIES AND ASSOCIATED DISEASE. Scabies causes childhood pyoderma predisposing to severe disease in later life. It is a major increasing health burden in Indigenous people of Northern Australia. Drug resistance is developing in mites and bacteria. The lack of clinical material has hampered molecular research and this work will use comparative genomics of parasitic and free living mites and microbiome analysis to understand fundamental aspects of mite biology and pathogenesis. The understanding of proteins that are essential for mite survival and interfere with host defences will allow the informed design of peptide inhibitors as a new strategy to develop alternative treatment options.Read moreRead less
Fragment Based Screening for new Antibiotics by Protein X-Ray Crystallography. Due in part to rising levels of antibiotic resistance, the death toll from pathogenic bacteria is expected to skyrocket over the next 15 years. There is therefore a pressing need for new antibiotics to treat bacterial infection. This project will use a relatively new discovery tool called fragment based screening to discover a new generation of antibacterial agents. This tool will allow for the rapid economical discov ....Fragment Based Screening for new Antibiotics by Protein X-Ray Crystallography. Due in part to rising levels of antibiotic resistance, the death toll from pathogenic bacteria is expected to skyrocket over the next 15 years. There is therefore a pressing need for new antibiotics to treat bacterial infection. This project will use a relatively new discovery tool called fragment based screening to discover a new generation of antibacterial agents. This tool will allow for the rapid economical discovery of new drugs, and will complement other investments in Australian biotechnology infrastructure.Read moreRead less
Inhibiting pathological signalling in haematopoietic disease. Certain leukaemias and other blood diseases are caused by the mutation of one particular molecule, called Janus Kinase (JAK), inside our bodies. This project aims to understand the biochemical details of these diseases by studying this mutated molecule in detail. The project will aim to provide the information for developing effective therapeutics against these diseases.
Characterisation of a powerful molecular motor, the FtsK DNA translocase. The FtsK protein is a fast and powerful molecular motor, a pump that can, and does, move an entire bacterial chromosome. This project will uncover the detail of the mechanism used by this motor to convert the cell's chemical energy source Adenosine Triphosphate (ATP) into movement of DNA; revealing the molecular detail of a fast and powerful motor.