Nettles & toxic toupees: the molecular weaponry of venomous caterpillars. This project aims to investigate the structure, function and evolution of peptide toxins in venoms made by caterpillars in superfamily Zygaenoidea. Caterpillars in this group are covered in spines that inject pain-causing venoms, and this protects them from vertebrate and invertebrate predators. This project will test if peptides in this venom cause pain by pharmacological modulation of mammalian ion channels and signallin ....Nettles & toxic toupees: the molecular weaponry of venomous caterpillars. This project aims to investigate the structure, function and evolution of peptide toxins in venoms made by caterpillars in superfamily Zygaenoidea. Caterpillars in this group are covered in spines that inject pain-causing venoms, and this protects them from vertebrate and invertebrate predators. This project will test if peptides in this venom cause pain by pharmacological modulation of mammalian ion channels and signalling receptors, and if they have insecticidal properties. The first three-dimensional structures of caterpillar venom peptides will also be solved. Genomes of representatives of two different zygaenoid families will be produced, and genomic techniques will be used to elucidate how venom use evolved at the molecular level.Read moreRead less
A new class of sodium channel toxin from ant venoms . Ants are diverse and ubiquitous and the ability of certain species to sting is familiar to many of us. Yet we know remarkably little about the chemistry underlying these stings. We recently discovered that the venoms of ants, including common Australian species, harbour a novel and unique class of sodium channel toxins. Building on this discovery, the aim of this project will be to perform an in-depth characterisation of the effects of these ....A new class of sodium channel toxin from ant venoms . Ants are diverse and ubiquitous and the ability of certain species to sting is familiar to many of us. Yet we know remarkably little about the chemistry underlying these stings. We recently discovered that the venoms of ants, including common Australian species, harbour a novel and unique class of sodium channel toxins. Building on this discovery, the aim of this project will be to perform an in-depth characterisation of the effects of these toxins on sodium channels and to uncover the diversity and breadth of this toxin class in ant venoms. The outcome of this project will be novel insights into the chemistry of ant venoms and new insights into sodium channel function.Read moreRead less
Developing a multicomponent platform for targeted gene delivery. Gene delivery systems are important tools in biological research and offer many exciting future prospects. Delivering gene material is very difficult in practice: rapid deterioration, poor cell uptake, and reaching the right tissue and cell types are major obstacles. Ways to overcome each barrier individually have been suggested in existing research but these components have not yet been combined in a single solution, which this pr ....Developing a multicomponent platform for targeted gene delivery. Gene delivery systems are important tools in biological research and offer many exciting future prospects. Delivering gene material is very difficult in practice: rapid deterioration, poor cell uptake, and reaching the right tissue and cell types are major obstacles. Ways to overcome each barrier individually have been suggested in existing research but these components have not yet been combined in a single solution, which this project will tackle. This proposal aims to create a technology to stabilise and deliver active gene material to target cells. The gene delivery tool developed in this project will advance biological research greatly with many potential future applications.Read moreRead less
Venom-derived blood-brain-barrier shuttles. This project aims to discover new venom peptides capable of crossing the blood-brain barrier and to develop non-toxic peptide-based brain delivery systems. It addresses long-standing challenges and knowledge gaps in the delivery of macromolecules across biological barriers. Expected outcomes include an improved understanding of the strategies nature exploits to reach targets in the brain, mechanistic pathways to cross biological membranes, and innovati ....Venom-derived blood-brain-barrier shuttles. This project aims to discover new venom peptides capable of crossing the blood-brain barrier and to develop non-toxic peptide-based brain delivery systems. It addresses long-standing challenges and knowledge gaps in the delivery of macromolecules across biological barriers. Expected outcomes include an improved understanding of the strategies nature exploits to reach targets in the brain, mechanistic pathways to cross biological membranes, and innovative discovery and chemistry strategies to advance fundamental research across the chemical and biological sciences. Anticipated benefits include technological innovations relevant to Australia’s biotechnology sector and enhanced capacity for cross-disciplinary collaboration.Read moreRead less
Autocyclases: A new class of self-cyclising proteins. The biotechnology sector is emerging as an important economic strength in Australia. While the improved efficacy and selectivity of biomolecules has seen them emerge as alternatives to existing chemicals in health and agriculture, the stability of biomolecules remains a major limiting factor. A general strategy for improving protein stability is by joining the ends of the peptide chain in a cyclisation reaction. While a wide range of cyclic p ....Autocyclases: A new class of self-cyclising proteins. The biotechnology sector is emerging as an important economic strength in Australia. While the improved efficacy and selectivity of biomolecules has seen them emerge as alternatives to existing chemicals in health and agriculture, the stability of biomolecules remains a major limiting factor. A general strategy for improving protein stability is by joining the ends of the peptide chain in a cyclisation reaction. While a wide range of cyclic peptides and proteins are being developed in Australia and around the world, the cyclisation reaction presents a significant challenge. In this proposal we detail a novel method for protein cyclisation as a general, low-cost and green production method for making a diverse range of biomolecules. Read moreRead less
Expanding access to modified proteins via a novel semi-synthetic platform. This project aims to address a critical knowledge gap in understanding how post-translational modifications modulate the structure and activity of proteins. By developing an innovative semi-synthetic platform to produce pure proteins inaccessible by existing methods, the project will reveal how natural protein modifications influence structure and function. Expected outcomes include the delivery of breakthrough technologi ....Expanding access to modified proteins via a novel semi-synthetic platform. This project aims to address a critical knowledge gap in understanding how post-translational modifications modulate the structure and activity of proteins. By developing an innovative semi-synthetic platform to produce pure proteins inaccessible by existing methods, the project will reveal how natural protein modifications influence structure and function. Expected outcomes include the delivery of breakthrough technologies for accessing modified proteins for a range of applications in academia and industry, as well as the generation of new knowledge in the fields of chemistry and biology. The project will lead to the training of interdisciplinary early career researchers and has the potential to benefit Australia’s biotechnology sector.Read moreRead less
Conotoxin diversification and evolution of venom peptides in cone snails. The marine snails of the genus Conus have evolved one of the most complex venoms that has emerged as a rich source of novel bioactive peptides. However, < 0.1% of their true potential has been characterised to-date. Using advanced genomic, proteomic, structural and pharmacological approaches pioneered in our laboratory, this study will decipher how conotoxin diversification from ancestral worm hunters facilitated the shift ....Conotoxin diversification and evolution of venom peptides in cone snails. The marine snails of the genus Conus have evolved one of the most complex venoms that has emerged as a rich source of novel bioactive peptides. However, < 0.1% of their true potential has been characterised to-date. Using advanced genomic, proteomic, structural and pharmacological approaches pioneered in our laboratory, this study will decipher how conotoxin diversification from ancestral worm hunters facilitated the shift in diet to modern fish and mollusc hunting species by determining the evolutionary trajectories of positively selected conotoxins. Investigation of the structure and function of these highly optimised venom peptides will provide new research tools and potential leads to new pharmaceuticals and agrochemicals.Read moreRead less
Genetic code expansion of a eukaryotic in vitro translation system. The genetic code programs biosynthesis of polypeptides with efficiency vastly superior to chemical engineering. As the chemical diversity of natural amino acids in proteins is limited, finding ways to include “unnatural” amino acids can supercharge biology with a range of new protein activities. While the genetic code can be expanded to make space for unnatural amino acids, the rarity of free codons and reliance on prokaryotic ....Genetic code expansion of a eukaryotic in vitro translation system. The genetic code programs biosynthesis of polypeptides with efficiency vastly superior to chemical engineering. As the chemical diversity of natural amino acids in proteins is limited, finding ways to include “unnatural” amino acids can supercharge biology with a range of new protein activities. While the genetic code can be expanded to make space for unnatural amino acids, the rarity of free codons and reliance on prokaryotic organisms limit the applicability of this approach. We will develop a new higher-organism cell-free protein production system that can incorporate multiple unnatural amino acids into defined points of proteins. This, enabling and broadly applicable technology, will be tested by constructing opioid biosensors.Read moreRead less
Harnessing molecular strain for drug discovery and bioconjugation. Peptides and proteins are increasingly important therapies for the treatment of disease. Nevertheless, the synthesis and optimisation of these high-value compounds still relies primarily on technologies developed decades ago. There is a desperate need for modern strategies to unlock the full potential of peptides and proteins for diverse applications in drug discovery. This interdisciplinary research aims to develop new tools for ....Harnessing molecular strain for drug discovery and bioconjugation. Peptides and proteins are increasingly important therapies for the treatment of disease. Nevertheless, the synthesis and optimisation of these high-value compounds still relies primarily on technologies developed decades ago. There is a desperate need for modern strategies to unlock the full potential of peptides and proteins for diverse applications in drug discovery. This interdisciplinary research aims to develop new tools for the construction and modification of peptides and proteins by harnessing the energy in a unique class of strained molecules. A focus on peptide-based inhibitors of the proteasome, a critical target for modern cancer treatments, should provide future health and economic benefits for the Australian community.Read moreRead less
Advances in Peptide Synthesis: Exploiting Underutilised Functional Groups. The translation of therapeutically-relevant classes of peptides to the clinic is often limited by chemists' ability to synthesise these complex biomolecules efficiently and sustainably. This project aims to develop new tools for the preparation of designer peptides that are broadly inspired by an underutilised reactive group found in naturally-occurring peptide sequences. Expected outcomes encompass health and economic be ....Advances in Peptide Synthesis: Exploiting Underutilised Functional Groups. The translation of therapeutically-relevant classes of peptides to the clinic is often limited by chemists' ability to synthesise these complex biomolecules efficiently and sustainably. This project aims to develop new tools for the preparation of designer peptides that are broadly inspired by an underutilised reactive group found in naturally-occurring peptide sequences. Expected outcomes encompass health and economic benefits for the Australian community, including: the first approach to a class of promising antibiotic peptide natural product analogues, the development of a mild electrochemical approach to peptide modification, and the production of a library of novel amino acids for incorporation into potential antibiotic leads.Read moreRead less