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
Discovery and characterisation of novel spider-venom peptides targeting the human sodium ion channel Nav1.7. Drugs that selectively block the human sodium ion channel Nav1.7 are likely to be powerful analgesics for treating a wide variety of pain conditions. However, it has proved difficult to obtain selective blockers of this channel. The aim of this project is to determine whether spider-venoms might provide a source of highly selective Nav1.7 blockers.
Innovations in peptide-based drug design. This project will aim to develop new types of drugs that fill a gap between existing small molecule drugs, which are relatively inexpensive and stable, but often have side-effects, and biologics which are very expensive and require injection. Our new generation of peptide-based drugs promise to be applicable to diseases that are not treatable by current drugs.
Structure and function of predatory and defensive venoms in cone snails. This project aims to investigate newly-discovered cone snail venoms to accelerate the search for novel bioactive peptides. It was recently discovered that cone snails can rapidly and reversibly switch between distinct venoms in response to predatory or defensive stimuli, implying that defensive and predatory venoms have evolved under separate selection pressures. The project plans to obtain separate predatory and defensive ....Structure and function of predatory and defensive venoms in cone snails. This project aims to investigate newly-discovered cone snail venoms to accelerate the search for novel bioactive peptides. It was recently discovered that cone snails can rapidly and reversibly switch between distinct venoms in response to predatory or defensive stimuli, implying that defensive and predatory venoms have evolved under separate selection pressures. The project plans to obtain separate predatory and defensive venoms and venom duct tissue from individual cone snails to compare and contrast the structure and function of conotoxins evolved for predation versus those evolved for defence, to elucidate the structure and function of these important classes of bioactive peptides.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
Unravelling the molecular diversity and evolution of centipede venoms. The project intends to improve understanding of venom evolution in centipedes. Venoms have emerged as a rich source of pharmacological tools with potential for development into therapeutics and bioinsecticides. However, venoms-based discovery has been limited by the narrow taxonomical range of animals studied, with many groups of venomous animals overlooked. One such group is centipedes, whose venoms contain diverse toxins th ....Unravelling the molecular diversity and evolution of centipede venoms. The project intends to improve understanding of venom evolution in centipedes. Venoms have emerged as a rich source of pharmacological tools with potential for development into therapeutics and bioinsecticides. However, venoms-based discovery has been limited by the narrow taxonomical range of animals studied, with many groups of venomous animals overlooked. One such group is centipedes, whose venoms contain diverse toxins that differ between taxa. This project aims to provide an insight into centipede venom evolution, and how it might be constrained by venom-gland morphology. This study seeks to contribute to our understanding of protein evolution and direct biodiscovery efforts around centipede venom.Read moreRead less
Gain from pain: new tools from venomous animals for exploring pain pathways. This project aims to explore animal venoms for new pain-causing toxins, to determine their structure and mechanism of action. Many venomous animals use their venom defensively and envenomation is frequently associated with rapid and often excruciating pain. In most cases the molecular mechanisms by which they achieve this is unknown. Using biochemical, pharmacological and biophysical techniques, this project expects to ....Gain from pain: new tools from venomous animals for exploring pain pathways. This project aims to explore animal venoms for new pain-causing toxins, to determine their structure and mechanism of action. Many venomous animals use their venom defensively and envenomation is frequently associated with rapid and often excruciating pain. In most cases the molecular mechanisms by which they achieve this is unknown. Using biochemical, pharmacological and biophysical techniques, this project expects to uncover toxins that employ new mechanisms of pain signalling, leading to new insights into pain physiology.Read moreRead less
Engineering peptides into superglues selective for target proteins. This project aims to discover how to create long-acting peptides for future research tools, drugs, biosensors and diagnostics. Peptides are currently viewed by the general community as injectable performance-enhancing drugs which are difficult to detect because they don't last very long. However, peptides have many potential benefits that are difficult to obtain because of their short durations of action. This project aims to de ....Engineering peptides into superglues selective for target proteins. This project aims to discover how to create long-acting peptides for future research tools, drugs, biosensors and diagnostics. Peptides are currently viewed by the general community as injectable performance-enhancing drugs which are difficult to detect because they don't last very long. However, peptides have many potential benefits that are difficult to obtain because of their short durations of action. This project aims to develop ways of engineering peptide shapes into nanoscale superglues that stick more tightly but selectively to their target proteins, thereby extending their durations of action. Technology for engineering superglues would produce proof of concept and prototypes for future research tools, drugs, diagnostics and biosensors.Read moreRead less