Aquaporin channels in cell migration. The project aims to determine the role of Aquaporin1 (AQP1) in enhancing rapid cell motility. Cell migration is important for development, repair, and protection in multicellular organisms. AQP1 is increased in some rapidly migrating cell types. Loss of AQP1 impairs migration, which is restored by reintroduction of AQP1 but not AQP4. Expected outcomes include defining the features of AQP1 that confer enhanced cell migration. The project will test the hypothe ....Aquaporin channels in cell migration. The project aims to determine the role of Aquaporin1 (AQP1) in enhancing rapid cell motility. Cell migration is important for development, repair, and protection in multicellular organisms. AQP1 is increased in some rapidly migrating cell types. Loss of AQP1 impairs migration, which is restored by reintroduction of AQP1 but not AQP4. Expected outcomes include defining the features of AQP1 that confer enhanced cell migration. The project will test the hypothesis that dual water and ion channel functions of AQP1 are needed for movement, using migration assays in cells with wild type and mutant AQP1, and selective pharmacological agents developed by the project team to dissect the essential channel properties that enable rapid migration in cancer and stem cells. The project seeks to build knowledge of AQP roles in development, regeneration and surveillance, potentially improving health care by revealing pathways in migration disorders such as metastasis.Read moreRead less
Fundamental roles of aquaporin-1 channels in cell migration and morphology. This project aims to investigate cell migration mechanisms and the roles of aquaporin channels in controlling cell motility and morphology. The ability of cells to move and maintain proper shape is important for development, repair and survival in multicellular organisms. This project will test the role of mammalian aquaporin-1 channels in enabling rapid migration in normal and cancer cells, in repairing barrier layers i ....Fundamental roles of aquaporin-1 channels in cell migration and morphology. This project aims to investigate cell migration mechanisms and the roles of aquaporin channels in controlling cell motility and morphology. The ability of cells to move and maintain proper shape is important for development, repair and survival in multicellular organisms. This project will test the role of mammalian aquaporin-1 channels in enabling rapid migration in normal and cancer cells, in repairing barrier layers in kidney and brain, and in allowing red blood cells to maintain the classic disk-shape needed for optimal transport. Outcomes will define features of aquaporin-1 that provide these functions, using molecular, optical and pharmacological tools. Results will define aquaporin channel properties that enable optimal cellular function.Read moreRead less
Cardiac a1-adrenergic receptors in survival of the fittest. This project aims to determine the role of alpha1A-adrenergic receptor inactivation, a receptor/signalling pathway, in mediating cardiac contraction and survival in response to stressors fight-or-flight response triggers.Higher organisms’ ability to respond to environmental changes is central to the survival of the fittest, and is mediated by the release of catecholamines that stimulate adrenergic receptors. The precise receptor and sig ....Cardiac a1-adrenergic receptors in survival of the fittest. This project aims to determine the role of alpha1A-adrenergic receptor inactivation, a receptor/signalling pathway, in mediating cardiac contraction and survival in response to stressors fight-or-flight response triggers.Higher organisms’ ability to respond to environmental changes is central to the survival of the fittest, and is mediated by the release of catecholamines that stimulate adrenergic receptors. The precise receptor and signalling pathways underlying these adaptive responses remain unclear. This project’s research could improve contractility, reduce cardiomyocyte death and define organismal adaptation to extreme environmental changes.Read moreRead less
Activity-based chemogenetics: a novel approach to modulating brain function. Aim: To unravel the astounding complexity of the vertebrate brain by developing a completely novel method, that enables manipulation of the activity of defined nerve cells to study behaviour. Significance: Such technical advances are essential for understanding the intricate function of the brain. Expected outcomes: We will provide a technical advance of broad scope that will lead to novel neuroscience throughout the wo ....Activity-based chemogenetics: a novel approach to modulating brain function. Aim: To unravel the astounding complexity of the vertebrate brain by developing a completely novel method, that enables manipulation of the activity of defined nerve cells to study behaviour. Significance: Such technical advances are essential for understanding the intricate function of the brain. Expected outcomes: We will provide a technical advance of broad scope that will lead to novel neuroscience throughout the world. We will also increase understanding of body weight control through the experiments planned to validate our tool. Benefit: Our technical advance has the potential to alter experimental protocols, and the information obtained by experimental neuroscience, across all areas attempting to understand brain function.Read moreRead less