Specialized glial cells within the hippocampus of the brain regulate important morphological events in embryonic development. Memories of past experiences, and our ability to learn new information, is processed in a region of the brain called the hippocampus. In order for this to occur, the cells that make up the hippocampus must form correctly during embryonic development. This proposal investigates the cellular and molecular mechanisms regulating hippocampal formation. The national benefit of ....Specialized glial cells within the hippocampus of the brain regulate important morphological events in embryonic development. Memories of past experiences, and our ability to learn new information, is processed in a region of the brain called the hippocampus. In order for this to occur, the cells that make up the hippocampus must form correctly during embryonic development. This proposal investigates the cellular and molecular mechanisms regulating hippocampal formation. The national benefit of this work is to provide basic knowledge about the processes that underlie correct brain formation and function, and to understand what processes are disrupted when the brain fails to function correctly. Such disruptions lead to mental retardation and learning difficulties, and in the aged, an inability to form and store new memories, as occurs in dementia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347278
Funder
Australian Research Council
Funding Amount
$383,000.00
Summary
Brain Slice Macroscopic Imaging and Electrophysiology Recording System. Electrical signals are the primary mode of communication between excitable cells, in particular, the cells (neurons) that comprise the brain and central nervous system. Understanding of the processes of cell-to-cell communication between neurons is of primary importance to our understanding of fundamental phenomena such as voluntary and reflex movement, sensory responses and learning and memory, as well as providing fundamen ....Brain Slice Macroscopic Imaging and Electrophysiology Recording System. Electrical signals are the primary mode of communication between excitable cells, in particular, the cells (neurons) that comprise the brain and central nervous system. Understanding of the processes of cell-to-cell communication between neurons is of primary importance to our understanding of fundamental phenomena such as voluntary and reflex movement, sensory responses and learning and memory, as well as providing fundamental knowledge of numerous disease states. We are applying for equipment to monitor electrical signals (both visually and electrically) of small groups of cells (neurons) or large groups of interconnected cells (macroscopic complexes) within the brain. Facilities of this type for the visual and electrical recording of cell communication and brain activity will be unique to these Universities in Australia and extremely rare in the scientific world.Read moreRead less
Investigating the mechanisms of flavonoid actions on glycine receptors. The research to be conducted in this project will use state-of-the-art electrophysiological and molecular biological approaches to carefully characterise the actions of certain flavonoid compounds on the glycine-receptor channel. These compounds have recently been reported to act as modulators of ligand-gated ion channels, proteins integral to brain function and disease. However, no-one has studied in any detail the mechan ....Investigating the mechanisms of flavonoid actions on glycine receptors. The research to be conducted in this project will use state-of-the-art electrophysiological and molecular biological approaches to carefully characterise the actions of certain flavonoid compounds on the glycine-receptor channel. These compounds have recently been reported to act as modulators of ligand-gated ion channels, proteins integral to brain function and disease. However, no-one has studied in any detail the mechanisms by which these compounds act. By discovering their site and mechanisms of action we will further our understanding of these important proteins and their modulation, maintain Australia's significant expertise in this field and provide leads for future development of drugs with potential therapeutic value.Read moreRead less
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
Inhibitory control of retinal sensitivity. We will determine how the nerve cells that carry information from the eye to the brain are always able to provide signals despite very different environments; daylight, fog and night. Knowledge of how nerve cells achieve this rapid learning is important for any understanding of brain function; it is fundamental if we are to develop machines that see or that help restore vision in humans. The project will provide the world's first look at the synaptic ph ....Inhibitory control of retinal sensitivity. We will determine how the nerve cells that carry information from the eye to the brain are always able to provide signals despite very different environments; daylight, fog and night. Knowledge of how nerve cells achieve this rapid learning is important for any understanding of brain function; it is fundamental if we are to develop machines that see or that help restore vision in humans. The project will provide the world's first look at the synaptic physiology that underpins all visual perception, helping to bring Australia back to the forefront of research in this field. This new collaboration between two successful researchers will attract top quality students and researchers from Australia and abroad and be published in major journals.Read moreRead less
Understanding how the brain uses sensory information to guide reaching and grasping movements. Reaching, grasping and manipulating objects are crucial aspects of our daily lives, which are performed so effortlessly that they tend to be taken for granted. We know however that these functions take a relatively long time to mature (think of a baby learning how to get an object), and that they can be impaired by brain lesions involving a region called the posterior parietal cortex. We also know that ....Understanding how the brain uses sensory information to guide reaching and grasping movements. Reaching, grasping and manipulating objects are crucial aspects of our daily lives, which are performed so effortlessly that they tend to be taken for granted. We know however that these functions take a relatively long time to mature (think of a baby learning how to get an object), and that they can be impaired by brain lesions involving a region called the posterior parietal cortex. We also know that this region has multiple subdivisions, but how exactly these interact in allowing the sensory information to guide arm and hand muscles is unknown. Discovering how this happens in terms of cellular interaction can have profound implications for the creation of new technologies such as artificial limbs and autonomous robots, and result in health benefits.Read moreRead less
Identifying novel roles of disease-related proteins in the regulation of exocytosis and nervous communication. This research aims to identify new molecules involved in regulating nerve communication and hormone secretion and which are relevent to human diseases and conditions including Type 2 Diabetes, Down Syndrome, Alzheimer's Disease and Huntington's Disease. The findings may provide new targets in the treatments of such conditions. This research is therefore of special relevance to National ....Identifying novel roles of disease-related proteins in the regulation of exocytosis and nervous communication. This research aims to identify new molecules involved in regulating nerve communication and hormone secretion and which are relevent to human diseases and conditions including Type 2 Diabetes, Down Syndrome, Alzheimer's Disease and Huntington's Disease. The findings may provide new targets in the treatments of such conditions. This research is therefore of special relevance to National Research Priority 2: Promoting and Maintaining Good Health and especially to the sub-areas of this Research Priority 2: Ageing well, ageing productively and Preventative healthcare.Read moreRead less
Microparticles as effectors of microvascular alterations in brain inflammation. Cerebral malaria (CM) kills many children worldwide, but we do not understand why their small blood vessels in the brain become obstructed. We found that tiny elements detached from cell membranes, called microparticles (MP), are dramatically elevated in the blood during CM. Our results strongly suggest that these MP are important in CM development. We have found that some drugs block the release of MP and the stick ....Microparticles as effectors of microvascular alterations in brain inflammation. Cerebral malaria (CM) kills many children worldwide, but we do not understand why their small blood vessels in the brain become obstructed. We found that tiny elements detached from cell membranes, called microparticles (MP), are dramatically elevated in the blood during CM. Our results strongly suggest that these MP are important in CM development. We have found that some drugs block the release of MP and the stickiness of malaria parasites to blood vessels. Our project will tackle the conditions of MP production and define new drugs to prevent it. It also will explain how the brain becomes affected by high numbers of MP. Our results will cast new light on why the brain functions abnormally when its blood vessels become modified.Read moreRead less
Central command neurons integrating cardiorespiratory drive in exercise. The ability to perform exercise is fundamental to human health and welfare. This ability depends upon the co-ordination by the brain of respiratory and cardiovascular function, such that the delivery of oxygen to exercising muscles is maximised. This project will test the idea that there is a specific group of neurons in the brain that drive both the respiratory and cardiovascular changes that occur during exercise, and w ....Central command neurons integrating cardiorespiratory drive in exercise. The ability to perform exercise is fundamental to human health and welfare. This ability depends upon the co-ordination by the brain of respiratory and cardiovascular function, such that the delivery of oxygen to exercising muscles is maximised. This project will test the idea that there is a specific group of neurons in the brain that drive both the respiratory and cardiovascular changes that occur during exercise, and will determine the location and functions of such neurons. Such new knowledge will help us understand how the brain optimises the ability of the body to perform exercise. This is of fundamental importance in sports science, a field in which Australia excels.Read moreRead less
Transduction of neuronal signals by brain macroglial cells: implications for neuronal function. Study of mechanisms regulating brain cell (neuron and glial) communication is essential for understanding of normal brain function and transformations that occur in neurodegenerative states and age-related disorders. Mechanisms underlying neuron-glia communication are not well understood. By combining cell physiology, digital imaging technologies, and genetically designed and delivered molecules we w ....Transduction of neuronal signals by brain macroglial cells: implications for neuronal function. Study of mechanisms regulating brain cell (neuron and glial) communication is essential for understanding of normal brain function and transformations that occur in neurodegenerative states and age-related disorders. Mechanisms underlying neuron-glia communication are not well understood. By combining cell physiology, digital imaging technologies, and genetically designed and delivered molecules we will enhance our understanding of this brain cell communication and critical roles played by intracellular calcium. This will enhance international competitiveness of Australian biological research and provide novel insight of glial function in neurodegeneration and potential for specific therapeutic intervention in disease.Read moreRead less