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Understanding and controlling neuropeptide GPCR-transducer coupling. G protein-coupled receptors (GPCRs) are physiologically essential, yet the spatiotemporal complexity of receptor function has limited our understanding of their function and success in drug development. Using a multi-disciplinary approach integrating GPCR signalling, trafficking and drug delivery, this research program aims to understand, and control, the molecular mechanisms that enable a single receptor to respond to differen ....Understanding and controlling neuropeptide GPCR-transducer coupling. G protein-coupled receptors (GPCRs) are physiologically essential, yet the spatiotemporal complexity of receptor function has limited our understanding of their function and success in drug development. Using a multi-disciplinary approach integrating GPCR signalling, trafficking and drug delivery, this research program aims to understand, and control, the molecular mechanisms that enable a single receptor to respond to different ligands to promote unique cellular processes. The anticipated outcomes include an enhanced capacity for understanding fundamental biology, and stronger national and international collaborations. It will provide significant benefits including expanded basic knowledge and advancement of drug delivery technology.Read moreRead less
Defining a new family of sodium channel accessory proteins. Voltage-gated sodium channels are key proteins that function as multi-subunit complexes to regulate neuronal excitability. The project aims to investigate the structure and function of a novel family of accessory subunits by utilizing a class of toxins, derived from the giant Australian stinging tree, that directly binds to these proteins to modulate sodium channel function. The project aims to generate significant new knowledge on the ....Defining a new family of sodium channel accessory proteins. Voltage-gated sodium channels are key proteins that function as multi-subunit complexes to regulate neuronal excitability. The project aims to investigate the structure and function of a novel family of accessory subunits by utilizing a class of toxins, derived from the giant Australian stinging tree, that directly binds to these proteins to modulate sodium channel function. The project aims to generate significant new knowledge on the function of sodium channels as multi-protein complexes. Expected outcomes of this project include development of novel channel-modulating molecules that may have applications as neuroscience tools to address fundamental questions about ion channel function and biology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100931
Funder
Australian Research Council
Funding Amount
$453,237.00
Summary
Molecular insights into the allosteric regulation of opioid receptors. Allosteric regulation is the biological process by which molecules bind to proteins someplace other than their active site, regulating their activity. Proteins on the cell surface called membrane receptors can be allosterically regulated to fine-tune the response of cells to the environment. This project aims to investigate how small molecules regulate receptor activity at a molecular level, using opioid receptors as an exemp ....Molecular insights into the allosteric regulation of opioid receptors. Allosteric regulation is the biological process by which molecules bind to proteins someplace other than their active site, regulating their activity. Proteins on the cell surface called membrane receptors can be allosterically regulated to fine-tune the response of cells to the environment. This project aims to investigate how small molecules regulate receptor activity at a molecular level, using opioid receptors as an exemplar system. I will use an interdisciplinary approach that combines structural biology, medicinal chemistry, analytical pharmacology, and cell biology. The knowledge gained from these studies will advance fundamental understanding of receptor function and can lay the foundation for future drug discovery efforts.Read moreRead less
Beyond structure - solving conformational dynamics for intractable proteins. Proteins perform almost every task that enables the amazing complexity of cellular and whole organism physiology. These molecular machines perform this incredible array of tasks due to their ability to dynamically change shape. For the vast majority of these machines, we can only view a snapshot of the possible shapes they can adopt and can’t monitor how they change from one shape to another, which is critical for their ....Beyond structure - solving conformational dynamics for intractable proteins. Proteins perform almost every task that enables the amazing complexity of cellular and whole organism physiology. These molecular machines perform this incredible array of tasks due to their ability to dynamically change shape. For the vast majority of these machines, we can only view a snapshot of the possible shapes they can adopt and can’t monitor how they change from one shape to another, which is critical for their functioning. This project aims to develop and apply a completely new method to visualise dynamic changes in protein shape which is not possible with current techniques. This will allow us to provide a new description and understanding of the function of proteins, which is fundamental to all biology.Read moreRead less