The molecular basis for efficacy at G protein coupled receptors. This project aims to investigate the molecular steps underlying the relationship between sensing by signal-transmitting proteins on the cell surface called G protein-coupled receptors and cellular response. The project aims to build on studies that have sought to understand the primary, molecular basis for this cellular volume control. This project seeks to use these novel approaches to fill this knowledge gap, providing a deeper u ....The molecular basis for efficacy at G protein coupled receptors. This project aims to investigate the molecular steps underlying the relationship between sensing by signal-transmitting proteins on the cell surface called G protein-coupled receptors and cellular response. The project aims to build on studies that have sought to understand the primary, molecular basis for this cellular volume control. This project seeks to use these novel approaches to fill this knowledge gap, providing a deeper understanding of how physiology and medicines work. The project expects to expand fundamental understanding of signal transmission at this receptor class. This project will deliver benefits including expanded basic knowledge and a contribution to future improvements in drug development.Read moreRead less
Discovering novel allosteric probes of muscarinic acetylcholine receptors. This project aims at fostering novel approaches to selectively target vital receptors in the human body, the muscarinic acetylcholine receptors (mAChRs). By harnessing the design of receptor mutations, compounds synthesis and fluorescent imaging, the project expects to develop new pharmacological tools for a family of receptors essential for the life of all vertebrates. By enriching our understanding of this family of rec ....Discovering novel allosteric probes of muscarinic acetylcholine receptors. This project aims at fostering novel approaches to selectively target vital receptors in the human body, the muscarinic acetylcholine receptors (mAChRs). By harnessing the design of receptor mutations, compounds synthesis and fluorescent imaging, the project expects to develop new pharmacological tools for a family of receptors essential for the life of all vertebrates. By enriching our understanding of this family of receptor, the project expects to provide significant benefits to the research field by impacting on future drug discovery efforts, not only at mAChRs, but at other structurally related receptors.Read moreRead less
Alpha-Conotoxins: Selective Probes For Nicotinic Receptor Subtype Structure And Function. Marine snails from the waters off the Australian coast produce an amazing variety of mini-proteins in their venoms called conotoxins that they use to capture prey. These conotoxins bind very specifically to receptors in our body associated with the transmission of nerve signals. We will use natural and synthetically modified conotoxins to selectively block particular types of neuronal 'receptors' to gain a ....Alpha-Conotoxins: Selective Probes For Nicotinic Receptor Subtype Structure And Function. Marine snails from the waters off the Australian coast produce an amazing variety of mini-proteins in their venoms called conotoxins that they use to capture prey. These conotoxins bind very specifically to receptors in our body associated with the transmission of nerve signals. We will use natural and synthetically modified conotoxins to selectively block particular types of neuronal 'receptors' to gain a greater understanding of how the nervous system functions. This knowledge will help in the design of new drugs to treat a variety of diseases and disorders. Essentially we will use a chemical armoury developed by the cone snail to design state-of-the-art mini-protein drugs.Read moreRead less
New modulators of voltage-gated sodium channel subtypes from Australian Tarantula venoms. The venoms of Australian tarantula spiders provide a unique and untapped source of bioactive molecules. From a large stock of venom, and in collaboration with Australian pharmaceutical company Xenome, we will develop a comprehensive library of venom components suitable for drug screening. Potential national benefits from this work include a huge reduction in the healthcare bill deriving from a new treatmen ....New modulators of voltage-gated sodium channel subtypes from Australian Tarantula venoms. The venoms of Australian tarantula spiders provide a unique and untapped source of bioactive molecules. From a large stock of venom, and in collaboration with Australian pharmaceutical company Xenome, we will develop a comprehensive library of venom components suitable for drug screening. Potential national benefits from this work include a huge reduction in the healthcare bill deriving from a new treatment for pain, as well as substantial royalty returns from drugs sales. Discoveries from the program are also likely to lead to an enhancement in Australia's reputation in the neurosciences and to the development of new diagnostic research tools. The major community benefit will be a reduction in the suffering of chronic pain patients.Read moreRead less
Defining mechanisms of action of novel alpha-conotoxins at nicotinic receptor-channels. Marine snails from the waters off the Australian coast produce an amazing variety of mini-proteins in their venoms called conotoxins that they use to capture prey. These conotoxins bind very specifically to receptors in our body associated with the transmission of nerve signals. We will use natural and synthetically modified conotoxins to selectively block particular types of neuronal 'receptors' to gain a gr ....Defining mechanisms of action of novel alpha-conotoxins at nicotinic receptor-channels. Marine snails from the waters off the Australian coast produce an amazing variety of mini-proteins in their venoms called conotoxins that they use to capture prey. These conotoxins bind very specifically to receptors in our body associated with the transmission of nerve signals. We will use natural and synthetically modified conotoxins to selectively block particular types of neuronal 'receptors' to gain a greater understanding of how the nervous system functions. This knowledge will help in the design of new drugs to treat a variety of diseases and disorders. Essentially we will use a chemical armoury developed by the cone snail to design state-of-the-art mini-protein drugs.Read moreRead less
Understanding endogenous allosteric modulators of G protein-coupled receptors. Major life science challenges include how chemicals outside cells signal to proteins inside, how this results in physiological responses, and how dysfunction of these processes leads to pathophysiology. Despite the critical importance of G protein-coupled receptors (GPCRs), much remains to be learned about their regulation by endogenous and synthetic molecules. This project aims to address this gap, by building on rec ....Understanding endogenous allosteric modulators of G protein-coupled receptors. Major life science challenges include how chemicals outside cells signal to proteins inside, how this results in physiological responses, and how dysfunction of these processes leads to pathophysiology. Despite the critical importance of G protein-coupled receptors (GPCRs), much remains to be learned about their regulation by endogenous and synthetic molecules. This project aims to address this gap, by building on recent ground-breaking studies that have been performed, by focusing on alternative binding sites of GPCRs called allosteric sites. The major hypothesis is that these allosteric sites are widespread across GPCRs because the body produces endogenous allosteric ligands that remain largely unidentified, but which can play vital roles in biology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100117
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Allosteric fingerprinting of G protein-coupled receptor monomers and oligomers. Allosteric modulation describes interactions between distinct, but conformationally linked, binding sites. Research will develop enabling technology using the unique profile, or 'fingerprint', of allosteric modulation at interacting and non-interacting G protein-coupled receptors to probe for receptor complexes within healthy and diseased tissue.
Stabilising biased allosteric G protein-coupled receptor conformations. This project aims to develop and identify molecules that can stabilise distinct calcium sensing receptor (CaSR) conformations. The CaSR is a G protein-coupled receptor (GPCR) vertebrates need to live. GPCRs are responsible for virtually all (patho)physiological processes. They are structurally very flexible, but this has hindered their structural determination. Developing and validating the proposed molecules should help fut ....Stabilising biased allosteric G protein-coupled receptor conformations. This project aims to develop and identify molecules that can stabilise distinct calcium sensing receptor (CaSR) conformations. The CaSR is a G protein-coupled receptor (GPCR) vertebrates need to live. GPCRs are responsible for virtually all (patho)physiological processes. They are structurally very flexible, but this has hindered their structural determination. Developing and validating the proposed molecules should help future structural studies of an important GPCR. The project expects to enhance understanding of the structure and function of the CaSR and ultimately of the GPCR superfamily, which will ultimately lead to opportunities to discover new drugs.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC200100052
Funder
Australian Research Council
Funding Amount
$4,789,838.00
Summary
ARC Training Centre for Cryo-Electron Microscopy of Membrane Proteins for Drug Discovery. This Centre aims to train industry-ready, world class graduates in cryo-electron microscopy of membrane proteins. The Centre’s graduates and research results would enable tomorrow’s industrial expansion in structure-enhanced drug design. Expected outcomes are world-first structural biology knowledge and techniques, and the entrepreneurial and technical skills desired by industry. This should provide signifi ....ARC Training Centre for Cryo-Electron Microscopy of Membrane Proteins for Drug Discovery. This Centre aims to train industry-ready, world class graduates in cryo-electron microscopy of membrane proteins. The Centre’s graduates and research results would enable tomorrow’s industrial expansion in structure-enhanced drug design. Expected outcomes are world-first structural biology knowledge and techniques, and the entrepreneurial and technical skills desired by industry. This should provide significant benefits including advancing Australian biotechnological capacity and improved linkages with major pharmaceutical partners. It should also provide a substantive competitive advantage to nascent Australian biotechnology companies that also links into new National investment into drug discovery and development infrastructure.Read moreRead less
Probing the role of dynamics in protein modulation of GPCR phenotype . Life relies upon the fundamental ability to convert external stimuli into an appropriate biological response. Such stimuli are transmitted by cell surface proteins (receptors), which convert this stimulus into an intracellular signal. The largest group of cell surface receptors is the G protein-coupled receptor (GPCR) family. Despite advances in GPCR structure determination, many questions regarding the structural basis of GP ....Probing the role of dynamics in protein modulation of GPCR phenotype . Life relies upon the fundamental ability to convert external stimuli into an appropriate biological response. Such stimuli are transmitted by cell surface proteins (receptors), which convert this stimulus into an intracellular signal. The largest group of cell surface receptors is the G protein-coupled receptor (GPCR) family. Despite advances in GPCR structure determination, many questions regarding the structural basis of GPCR function and signalling remain unanswered. The primary outcome of this project is to provide mechanistic insight into the dynamics of GPCR ligand recognition and activation to advance our understanding of GPCR signal transduction, a fundamental biological process for all living organisms.Read moreRead less