Calcium signalling in neurons of the central nervous system. Understanding of the processes of cell-to-cell communication between neurons that comprise the brain and central nervous system is of primary importance to our understanding of fundamental phenomena such as voluntary and reflex movement, sensory responses and learning and memory. We would like to obtain a better understanding of how calcium controls neuronal and synaptic function. These studies will combine high-speed fluorescence ima ....Calcium signalling in neurons of the central nervous system. Understanding of the processes of cell-to-cell communication between neurons that comprise the brain and central nervous system is of primary importance to our understanding of fundamental phenomena such as voluntary and reflex movement, sensory responses and learning and memory. We would like to obtain a better understanding of how calcium controls neuronal and synaptic function. These studies will combine high-speed fluorescence imaging, electrophysiological recording, gene transfer using Adeno- and Sindbis viruses, and genetically designed and targeted biosensors to describe key "descriptors" of the calcium signals generated as neurons of the central nervous system ?talk? to each other.Read moreRead less
Molecular neurobiology of the GABAB receptor: Studies of heteromeric receptor function and signalling. The G protein-coupled receptor (GPCR) for the inhibitory transmitter gamma- aminobutyric acid (GABA) is a unique heterodimer. Molecular analyses will be undertaken to provide insights into its signalling mechanisms and functional regulation. Investigations employing point mutant and chimeric receptors will analyse how ligand binding to the extracellular domain of the GABA-BR1 subunit triggers ....Molecular neurobiology of the GABAB receptor: Studies of heteromeric receptor function and signalling. The G protein-coupled receptor (GPCR) for the inhibitory transmitter gamma- aminobutyric acid (GABA) is a unique heterodimer. Molecular analyses will be undertaken to provide insights into its signalling mechanisms and functional regulation. Investigations employing point mutant and chimeric receptors will analyse how ligand binding to the extracellular domain of the GABA-BR1 subunit triggers G protein-coupling to the intracellular portion of the GABA-BR2 subunit. Focus will be on different modes of GPCR signalling, including constitutive activity and roles for membrane and cytosolic regulatory proteins. Targeted studies of GABAB receptor subunits will provide new information on the mechanistic regulation of GPCR signalling.Read moreRead less
Olfactory signal transduction in Drosophila melanogaster. This project will strengthen Australia's research capabilities in the areas of molecular neurobiology and neurogenetics. The project will equip students with the intellectual and technical skills needed to work in priority areas such as genomics and biotechnology, as well as in medical and agricultural research, and education. The research has possible long term applications in modifying the behaviour of insects of agricultural or medical ....Olfactory signal transduction in Drosophila melanogaster. This project will strengthen Australia's research capabilities in the areas of molecular neurobiology and neurogenetics. The project will equip students with the intellectual and technical skills needed to work in priority areas such as genomics and biotechnology, as well as in medical and agricultural research, and education. The research has possible long term applications in modifying the behaviour of insects of agricultural or medical importance. For example, by inhibiting the ability of insects to perceive specific odours it may ultimately be possible to prevent insects that carry disease from identifying target animals, or plant pests from locating their host plants.Read moreRead less
Olfactory signalling and coding in Drosophila and other insects. Animals rely on olfactory cues to detect food, danger, and others of the same species. The olfactory systems of Drosophila and other insects are simpler than those of mammals, yet complex enough to offer fascinating systems for studying neural information processing. This project aims to investigate the role of the Drosophila odorant receptors in olfactory coding, and to use multiple approaches to isolate components of the poorly u ....Olfactory signalling and coding in Drosophila and other insects. Animals rely on olfactory cues to detect food, danger, and others of the same species. The olfactory systems of Drosophila and other insects are simpler than those of mammals, yet complex enough to offer fascinating systems for studying neural information processing. This project aims to investigate the role of the Drosophila odorant receptors in olfactory coding, and to use multiple approaches to isolate components of the poorly understood insect olfactory signal transduction pathway. In addition, the role of the NO/cGMP pathway in olfactory signalling will be studied using an olfactory mutant that has nitric oxide synthase defects.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668266
Funder
Australian Research Council
Funding Amount
$264,000.00
Summary
High Resolution Cellular and Molecular Imaging System. Understanding where molecules are within cells, and how they interact with each other, is fundamental to significant advances being made in biology. Our research will use advanced imaging techniques to localize proteins within a variety of cells including neurons and germ cells. We will be able to determine how the different molecules within a single cell interact with each other. This information is relevant to many biological mechanisms ....High Resolution Cellular and Molecular Imaging System. Understanding where molecules are within cells, and how they interact with each other, is fundamental to significant advances being made in biology. Our research will use advanced imaging techniques to localize proteins within a variety of cells including neurons and germ cells. We will be able to determine how the different molecules within a single cell interact with each other. This information is relevant to many biological mechanisms and to many human diseases. Furthermore, our research will help maintain Australia's strong international reputation in the fields of neuroscience, protein trafficking and stem cells. Read moreRead less
Functional studies on a novel, brain-specific, Golgi ATP-binding protein in membrane trafficking. In cells specialised for communication such as neurones, protein transport constitutes a large part of total cellular activity. A primary pathway in protein transport is trafficking from the Golgi apparatus to the cell membrane; materials destined for the cell membrane and secretion are sorted, packed and transported from the Golgi apparatus. However, the mechanisms underlying these processes at the ....Functional studies on a novel, brain-specific, Golgi ATP-binding protein in membrane trafficking. In cells specialised for communication such as neurones, protein transport constitutes a large part of total cellular activity. A primary pathway in protein transport is trafficking from the Golgi apparatus to the cell membrane; materials destined for the cell membrane and secretion are sorted, packed and transported from the Golgi apparatus. However, the mechanisms underlying these processes at the Golgi remain largely unknown. We have recently cloned a novel ATP-binding protein specifically expressed at the Golgi apparatus in human brain, and hypothesise that this protein regulates Golgi protein trafficking by interacting with two other molecules, dynamin and calcium, during cell secretion.Read moreRead less
Characterisation of a novel neural-specific ATPase in cholesterol transport. Ageing is determined by both genetic and metabolic factors. To a large part, the detailed mechanisms of ageing remain to be unexplored. Genetically, the timing of cell ageing entails the loss of telomeres (tips of chromosomes). However, the buildup of metabolic wastes resets the timing prematurely. Metabolic products accumulate from excess production or a shortfall of removal activity, which occurs in the various parts ....Characterisation of a novel neural-specific ATPase in cholesterol transport. Ageing is determined by both genetic and metabolic factors. To a large part, the detailed mechanisms of ageing remain to be unexplored. Genetically, the timing of cell ageing entails the loss of telomeres (tips of chromosomes). However, the buildup of metabolic wastes resets the timing prematurely. Metabolic products accumulate from excess production or a shortfall of removal activity, which occurs in the various parts of ageing cells in tissues such as brain. Traffic jams of cholesterol transport in the secretory pathway induce early ageing of the nerve cells. We investigate a novel mechanism controlling cholesterol transport in nerve cell ageing.Read moreRead less
A redox sensor and triple receptor function for guanylyl cyclase. Nitric oxide (NO) protects from blood vessel spasms and clot formation. Conversely, insufficient NO occurs in cardiovascular disease. Life-saving drugs like glycerol trinitrate supply more NO to blood vessels, however these drugs are limited in their action when their target protein (NOGC) is decreased or defective, eg. in hypertension or arteriosclerosis. We have elucidated the reason for this defect and simultaneously discovered ....A redox sensor and triple receptor function for guanylyl cyclase. Nitric oxide (NO) protects from blood vessel spasms and clot formation. Conversely, insufficient NO occurs in cardiovascular disease. Life-saving drugs like glycerol trinitrate supply more NO to blood vessels, however these drugs are limited in their action when their target protein (NOGC) is decreased or defective, eg. in hypertension or arteriosclerosis. We have elucidated the reason for this defect and simultaneously discovered an entirely novel group of drugs which activate NOGC without NO. Impressively, these drugs are most effective in diseased blood vessels. The aim is the development of novel blood pressure lowering/anti-anginal drugs with higher effectiveness and less side-effects because they work in an entirely new way.Read moreRead less
Gene Discovery and Functional Analysis of Copper Homeostasis Genes in Drosophila. Copper is a vital nutrient required for the formation and maintenance of bones, blood vessels and the central nervous system, but copper is also potentially toxic when in excess. Homeostatic mechanisms are needed to maintain safe levels of copper in the body and disruptions to these mechanisms are associated with disorders such as Alzheimer's disease, heart disease and osteoporosis. We are investigating the regulat ....Gene Discovery and Functional Analysis of Copper Homeostasis Genes in Drosophila. Copper is a vital nutrient required for the formation and maintenance of bones, blood vessels and the central nervous system, but copper is also potentially toxic when in excess. Homeostatic mechanisms are needed to maintain safe levels of copper in the body and disruptions to these mechanisms are associated with disorders such as Alzheimer's disease, heart disease and osteoporosis. We are investigating the regulation of a key copper pump, the Menkes protein, which helps control copper levels in the body and we are using the genetic advantages of the fruit fly Drosophila to discover new genes that regulate Menkes activity and therefore copper levels. These studies could lead to novel therapies for a range of copper-related disorders.Read moreRead less
Novel modes of signalling of serotonin 5-HT2c receptors. This project focuses on a special family of receptor proteins that mediate the actions of the neurochemical, serotonin (5HT), in the human brain. These serotonin receptors are major targets for antidepressant and antipsychotic medications, and also play a role in anxiety, migraine and control of appetite. Despite the important role of serotonin receptors in health and disease, the mechanism of action of many drugs acting on these receptors ....Novel modes of signalling of serotonin 5-HT2c receptors. This project focuses on a special family of receptor proteins that mediate the actions of the neurochemical, serotonin (5HT), in the human brain. These serotonin receptors are major targets for antidepressant and antipsychotic medications, and also play a role in anxiety, migraine and control of appetite. Despite the important role of serotonin receptors in health and disease, the mechanism of action of many drugs acting on these receptors remains unknown. Our project will specifically investigate novel molecular mechanisms associated with serotonin receptor activity that may prove vital in understanding mechanisms of psychiatric illnesses, and how many psychiatric medicines actually work.Read moreRead less