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
Australian Sea Anemone Venoms: Bioprospecting & Evolution. Australian sea anemones are a highly promising and largely unexplored source of peptides and proteins with potential therapeutic and diagnostic applications. This project aims to evaluate this potential by undertaking transcriptomic analyses of a number species of anemones from Australian waters and identifying peptides and proteins in their venoms by mass spectrometry. It will also demonstrate the value of transcriptomics in informing t ....Australian Sea Anemone Venoms: Bioprospecting & Evolution. Australian sea anemones are a highly promising and largely unexplored source of peptides and proteins with potential therapeutic and diagnostic applications. This project aims to evaluate this potential by undertaking transcriptomic analyses of a number species of anemones from Australian waters and identifying peptides and proteins in their venoms by mass spectrometry. It will also demonstrate the value of transcriptomics in informing taxonomic classification of anemones. In addition this project will assess toxin diversity within and between species based on nematocyst function from specific tissue sources and provide a clearer understanding of the evolution of venoms in Australian Actiniaria.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101481
Funder
Australian Research Council
Funding Amount
$373,000.00
Summary
Aquatic invasion of venomous snakes. Animal venoms target multiple physiological pathways to rapidly disrupt homeostasis and cause paralysis and death of prey animals. Physiological protein-encoding genes are recruited into the envenoming function, which then evolve to be highly effective on their molecular targets. The expansion of venom complexity due to the predator-prey chemical 'arms race' has given rise to a plethora of toxin types. While examples of venoms that have become subsequently st ....Aquatic invasion of venomous snakes. Animal venoms target multiple physiological pathways to rapidly disrupt homeostasis and cause paralysis and death of prey animals. Physiological protein-encoding genes are recruited into the envenoming function, which then evolve to be highly effective on their molecular targets. The expansion of venom complexity due to the predator-prey chemical 'arms race' has given rise to a plethora of toxin types. While examples of venoms that have become subsequently streamlined and/or simplified in response to a change in environment and/or specialisation of diet are plenty, the underlying mechanisms remain elusive. This project aims to unravel how animal venoms become streamlined and uncover the underexplored vast pharmacopeia of aquatic venoms.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100192
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Deep Protein Sequencing, Structure and Quantification Facility. This project aims to establish state-of-the-art complementary mass spectrometers to help research into molecular structure and interactions, post-translational modifications, compound stability and availability within complex biological samples. The facility’s complementary mass spectrometers combine high specificity with high sensitivity and ultrafast scanning, and are expected to rapidly discover, identify and characterise biomole ....Deep Protein Sequencing, Structure and Quantification Facility. This project aims to establish state-of-the-art complementary mass spectrometers to help research into molecular structure and interactions, post-translational modifications, compound stability and availability within complex biological samples. The facility’s complementary mass spectrometers combine high specificity with high sensitivity and ultrafast scanning, and are expected to rapidly discover, identify and characterise biomolecules including peptides, proteins and small molecules. The discovery of unknown compounds is expected to improve fundamental understanding of molecular structure and function, provide opportunities for new bio-industries in health and the environment, and generate commercial opportunities through spin-off companies, patents and licensing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100015
Funder
Australian Research Council
Funding Amount
$630,000.00
Summary
High-resolution and high-throughput Nuclear Magnetic Resonance (NMR) facility. This facility will provide researchers at James Cook University and The University of Queensland with a nuclear magnetic resonance spectroscope with a cryogenically cooled probe which will enable the structures of novel biomolecules from spiders, hookworms, plants and synthetic drugs to be revealed. These studies have the potential to lead to new drugs for cancer, pain, inflammatory and tropical diseases.
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
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
Discovery Early Career Researcher Award - Grant ID: DE210100422
Funder
Australian Research Council
Funding Amount
$447,346.00
Summary
Using toxins to manipulate the gating of voltage-gated sodium channels. The project aims to investigate how sodium channel subtypes contribute to the excitability of sensory neurons by utilising venom-derived peptides that specifically target and alter the function of these channels. This project expects to generate new knowledge in the area of neuroscience using an interdisciplinary approach including synthetic peptide chemistry, pharmacology and electrophysiology. Expected outcomes of this pro ....Using toxins to manipulate the gating of voltage-gated sodium channels. The project aims to investigate how sodium channel subtypes contribute to the excitability of sensory neurons by utilising venom-derived peptides that specifically target and alter the function of these channels. This project expects to generate new knowledge in the area of neuroscience using an interdisciplinary approach including synthetic peptide chemistry, pharmacology and electrophysiology. Expected outcomes of this project include the development of new venom-based research tools and improved techniques for studying sodium channel function. This will provide significant benefits, including advancement of fundamental knowledge in physiology and the development of novel analgesics. Read moreRead less
Understanding sub-cellular systems at the atomic level. By extending the range of biomolecular systems that can be modelled computationally at the atomic level the project will enable important biomedical processes such as how bacterial toxins penetrate cell membranes and how protein hormones transmit signals into cells to be understood in unprecedented detail.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100186
Funder
Australian Research Council
Funding Amount
$550,000.00
Summary
High-throughput, high resolution protein-peptide sequencing and quantification facility. This facility will enhance the research capability of scientists at The University of Queensland who are using mass spectrometry to elucidate the structures of novel toxins which have the potential to be developed as drugs.