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.
Roles of the kynurenine pathway in physiological and pathological brain function. This project will aim to study the metabolism of the essential amino acid tryptophan in the brain and its involvement in diseases including multiple sclerosis and brain tumours.
Dissecting key steps of the miRNA-mediated gene regulation and its implication in immune response and cancer. This project will characterise in detail one of the most important ways that genes are turned off in humans. This process is involved in many diseases including cancer and infections. The result will provide potential novel drug targets to prevent and treat such diseases.
Lipidomics of vision. Presbyopia and cataract are the major causes of visual impairment worldwide. Nevertheless, our understanding of lens ageing at both a cellular and molecular level is limited. This project will gain new insight into the effect of age on lens membrane lipids and their role in the development of presbyopia and cataract.
Small heat shock proteins: front-line defenders and therapeutic targets. Small heat-shock chaperone proteins play a key role as front line defenders against protein aggregation, a process linked to ageing and disease. This project spans fields from protein chemistry to cell biology to generate an unprecedented insight into the links between the structure, function and therapeutic potential of these chaperone proteins.
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
3D Structure determination of biomacromolecular assemblies from sparse data. This project has direct impact on pharmaceutical research: Biomacromolecular interactions are key points for pharmaceutical intervention and detailed structural knowledge of dynamic protein interactions can significantly accelerate drug development. Australia has invested in expensive instrumentation that can be used with new laboratory methods to obtain information on delicately balanced biomacromolecular interactions, ....3D Structure determination of biomacromolecular assemblies from sparse data. This project has direct impact on pharmaceutical research: Biomacromolecular interactions are key points for pharmaceutical intervention and detailed structural knowledge of dynamic protein interactions can significantly accelerate drug development. Australia has invested in expensive instrumentation that can be used with new laboratory methods to obtain information on delicately balanced biomacromolecular interactions, and how they malfunction in disease. This project will provide a computational framework to increase the impact of this investment by integrating measurements from a range of novel technologies and developing understanding of changes in structure of large protein complexes in different functional states.Read moreRead less
Nuclear and chromatin architecture in the replication stress response. DNA replication is an essential biological activity required for the transmittance of genomic material across cell divisions. If errors occur during DNA replication, this results in dangerous outcomes including mutation, genome instability, and cell death. Cells cope with challenges to DNA replication through a process called the replication stress response. This fellowship explores a newly discovered pathway in the replicati ....Nuclear and chromatin architecture in the replication stress response. DNA replication is an essential biological activity required for the transmittance of genomic material across cell divisions. If errors occur during DNA replication, this results in dangerous outcomes including mutation, genome instability, and cell death. Cells cope with challenges to DNA replication through a process called the replication stress response. This fellowship explores a newly discovered pathway in the replication stress response where changes to the architecture of a cell nucleus, and movement of the genomic material inside, promotes repair of genomic damage that occurs during replication. The result of this project will be an understanding of fundamental biological processes that protect human genomes.Read moreRead less
The cellular dynamics of lipid droplets: implications for obesity and biodiesel production. Obesity is a pandemic that if not stopped, will lead to huge social and economic problems in Australia. In essence, the hallmark of human obesity is the accumulation of cellular lipid droplets. This research will benefit Australia by providing a fundamental understanding of how lipid droplets are formed. This will have immediate international impact at the scientific level and will also identify novel com ....The cellular dynamics of lipid droplets: implications for obesity and biodiesel production. Obesity is a pandemic that if not stopped, will lead to huge social and economic problems in Australia. In essence, the hallmark of human obesity is the accumulation of cellular lipid droplets. This research will benefit Australia by providing a fundamental understanding of how lipid droplets are formed. This will have immediate international impact at the scientific level and will also identify novel compounds and strategies for treating obesity. The proposed study will also benefit Australian agriculture and energy industry by providing strategies to improve the production of plant oil and biodiesel. Read moreRead less
Single-molecule optofluidics: streamlining high-throughput engineering and analysis of proteins and protein assemblies. This project aims at creating novel technologies for high-throughput engineering and analysis of proteins with single-molecule sensitivity. The platform will considerably accelerate the generation of protein-based diagnostics, new vaccines and therapeutics; it will foster collaborations with industry putting Australia at the forefront of protein research.