Development of small molecule primary sulfonamides as new drugs for malaria. Malaria is a major global health threat, causing approximately 800,000 deaths annually. Lives can be saved if patients are treated. The use of current antimalarial drugs is limited by drug resistance, low activity and poor safety. This project investigates the effectiveness of a new class of molecule as a safe drug treatment option to kill malaria parasites.
Development of effective peptide-based drugs. There is huge interest in the development of bioactive peptides and proteins for the treatment of a wide range of diseases. The aim of this research project is to develop potent and effective peptide-based drugs that are able to resist the body's natural degradation pathways so that they can reach their biological target and act as effective drugs.
Towards the sustainable discovery and development of new antibiotics. This project aims to define how to access silent biosynthetic genes within microbial genome to facilitate access to new chemical diversity hidden within microbial genomes. Using interdisciplinary approaches in genome mining and metabolomics technologies, the project expects to inspire and enable the future design of more effective antibiotics. Expected outcomes from this program include define new microbial defence molecules, ....Towards the sustainable discovery and development of new antibiotics. This project aims to define how to access silent biosynthetic genes within microbial genome to facilitate access to new chemical diversity hidden within microbial genomes. Using interdisciplinary approaches in genome mining and metabolomics technologies, the project expects to inspire and enable the future design of more effective antibiotics. Expected outcomes from this program include define new microbial defence molecules, to meet future demands in agrochemical and environmental sciences. It will also train future scientists and develop international collaborations. This should provide significant benefit, including a higher-quality workforce for research and innovation, positioning Australia at the forefront of drug discovery. Read moreRead less
The potential of membranes – peptide engineering to modulate ion channels. This project aims to develop a platform technology to identify new and selective sodium channel inhibitors based on ultra-stable venom peptides that can interact with and cross membranes. Sodium channels are involved in almost all aspects of human physiology. The ability to selectively inhibit individual sodium channel subtypes and to understand what drives peptides' ability to cross membranes would be a major achievement ....The potential of membranes – peptide engineering to modulate ion channels. This project aims to develop a platform technology to identify new and selective sodium channel inhibitors based on ultra-stable venom peptides that can interact with and cross membranes. Sodium channels are involved in almost all aspects of human physiology. The ability to selectively inhibit individual sodium channel subtypes and to understand what drives peptides' ability to cross membranes would be a major achievement and lead to new neuroscience research tools and technologies. This project’s proposed technology could be translated into new knowledge relevant to the biotechnology industry.Read moreRead less
Metals in biocatalysis. Metals and enzymes are essential for the chemistry of life. This project will aim to garner the potential of metal-dependent enzymes to develop new drugs against osteoporosis, combat the spread of antibiotics resistance and optimise some of these enzymes to detoxify pesticide-polluted environments, thus contributing to global health and food security.
Genetic dissection of cardiac morphogenesis. The human heart is critical for survival and yet, despite its importance, we still lack a basic understanding of how it forms. This project aims to discover new genes involved in cardiac development so we can understand how to build a heart. Armed with this information, this research will assist in devising strategies for the repair of congenital and acquired heart disease.
The mechanochemical basis of cell polarity. This project aims to study how epithelial cells initiate polarisation, a major question in biology that conventional biochemical, cell biological and genetic approaches have not answered. This project will investigate the mechanochemical basis of symmetry breaking in the cellular cortex, a thin layer of actomyosin filaments underneath the plasma membrane, and how this forms signalling zones. Understanding polarity is expected to improve epithelia manip ....The mechanochemical basis of cell polarity. This project aims to study how epithelial cells initiate polarisation, a major question in biology that conventional biochemical, cell biological and genetic approaches have not answered. This project will investigate the mechanochemical basis of symmetry breaking in the cellular cortex, a thin layer of actomyosin filaments underneath the plasma membrane, and how this forms signalling zones. Understanding polarity is expected to improve epithelia manipulation in disciplines from tissue engineering to regenerative biology and reveal how epithelial architecture and physiology are generated.Read moreRead less
Developing a paradigm shift in new pharmaceutical and agrochemical design. This project will provide a paradigm shift in the design of new medicines and farming chemicals. The outcome of this research will be the efficient generation of diverse chemicals having real possibilities to improve global health and food security in the future.
Overcoming antibiotic resistance: rapid discovery of new antibacterial drug targets using chemical proteomics. The prevalence of multidrug-resistant bacteria in the community is a critical public health issue and there is an urgent and compelling need for new antibiotics with novel modes of action to combat these deadly superbugs. While antibiotics from nature have long been a mainstay of the pharmaceutical industry, their development as drugs can be challenging as their cellular targets and mod ....Overcoming antibiotic resistance: rapid discovery of new antibacterial drug targets using chemical proteomics. The prevalence of multidrug-resistant bacteria in the community is a critical public health issue and there is an urgent and compelling need for new antibiotics with novel modes of action to combat these deadly superbugs. While antibiotics from nature have long been a mainstay of the pharmaceutical industry, their development as drugs can be challenging as their cellular targets and modes of action are frequently unknown. In this project, innovative chemical proteomics approaches will be used to rapidly identify and characterise the cellular targets and modes of action of both newly discovered and historic antibiotic natural products, thereby overcoming this bottleneck and accelerating the development of next-generation antibiotics.Read moreRead less
Regulation of 3D Cell Migration by Microtubule-Dependent Processes. The overarching aim of this research is to elucidate the molecular mechanisms that cells use to move in 3D environments: a basic biological function essential to development and homeostasis. During these processes, cells interact with their surroundings where they translate biophysical forces into biochemical signals to adapt their shape to move. This requires distinct signalling, controlled in space and time, to regulate the cr ....Regulation of 3D Cell Migration by Microtubule-Dependent Processes. The overarching aim of this research is to elucidate the molecular mechanisms that cells use to move in 3D environments: a basic biological function essential to development and homeostasis. During these processes, cells interact with their surroundings where they translate biophysical forces into biochemical signals to adapt their shape to move. This requires distinct signalling, controlled in space and time, to regulate the crosstalk between organelles and the cytoskeleton. To date, the role of microtubules remains elusive. Using interdisciplinary approaches combining advanced imaging technology with novel cell biology methods, the project aims to uncover fundamental knowledge about how cells interact with their environment.Read moreRead less