Developmental Plasticity In The Nonhuman Primate Visual Cortex
Funder
National Health and Medical Research Council
Funding Amount
$464,417.00
Summary
A phenomenon that has puzzled many for a number of years is why damage to the visual brain during infancy has far less of an impact on visual capacity than the same lesion suffered later in life. This project hopes to uncover this mystery and see how brain 'wiring' is altered to compensate.
Much of the human brain is devoted to vision, which requires the integrated activity of many interconnected areas of the cerebral cortex. Damage to these areas is a relatively common complication of preterm delivery and- or perinatal conditions including trauma and infection. The severity of both the short- and long-term effects of these lesions appears to be related to the time of the damage. The aim of this project is to investigate the way in which the multiple visual areas of the brain devel ....Much of the human brain is devoted to vision, which requires the integrated activity of many interconnected areas of the cerebral cortex. Damage to these areas is a relatively common complication of preterm delivery and- or perinatal conditions including trauma and infection. The severity of both the short- and long-term effects of these lesions appears to be related to the time of the damage. The aim of this project is to investigate the way in which the multiple visual areas of the brain develop and become 'wired' together in the period following birth. We will also determine if there are mechanisms which allow alternate routes to be found for processing visual information while the brain is still establishing connections between its multiple areas. This will allow us to understand the anatomical and physiological bases of the deficits caused by early damage to the visual areas of the brain, and perhaps point to strategies that will lead to improved recovery of visual function.Read moreRead less
Control Of Sympathetic Nerves That Talk To The Immune System
Funder
National Health and Medical Research Council
Funding Amount
$385,958.00
Summary
The two complex systems of the body, the immune system and the nervous system, communicate with each other. This proposal studies one of the major pathways from brain to immune system - sympathetic immuno-efferent nerves. In stroke, these pathways cause profound immunosuppression, causing susceptibility to infection. Their poorly understood central and peripheral pathways will be defined and mapped by this study.
Molecular Investigations Of The Neuroprotective Activity Of Estrogen, Phytoestrogens, And Phytosterols
Funder
National Health and Medical Research Council
Funding Amount
$270,872.00
Summary
Estrogen protects women from heart and brain disease but more women will spend over a third of their lives in the postmenopausal state, which is characterized by reduced estrogen levels. Many studies suggest that estrogen-like compounds produced by plants may provide health benefits and alleviate the symptoms of menopause. We investigate the protective effects of such compounds in nerve cells, to address the unmet need for safe and effective prevention and treatment of neurological diseases.
The Role Of Ten-m3 In Patterning Ipsilateral Retinal Projections
Funder
National Health and Medical Research Council
Funding Amount
$453,042.00
Summary
The normal functioning of the brain depends on connections of billions of nerve cells or neurons. We have found that a protein called Ten_m3 plays a very important role in specifying the way that neurons from the eye connect to the brain. The role of this protein is so important that mice which lack the protein behave as if they are blind. The aim of this project is to understand how this protein controls the development of the visual system.
Wnt-Ryk Signaling In The Establishment Of Major Axon Tracts In The Embryonic Mouse Brain
Funder
National Health and Medical Research Council
Funding Amount
$513,946.00
Summary
The corpus callosum is the major interhemispheric commissure in the human brain, comprising approximately 3 million myelinated fibers which connect homologous regions in the neocortex. To date more than 50 different human congenital syndromes have been described in which the corpus callosum does not form leading to epilepsy and mental retardation. We have identified a new guidance molecule (Ryk) which is crucial for corpus callosum formation. This project aims to dissect that molecular mechanism ....The corpus callosum is the major interhemispheric commissure in the human brain, comprising approximately 3 million myelinated fibers which connect homologous regions in the neocortex. To date more than 50 different human congenital syndromes have been described in which the corpus callosum does not form leading to epilepsy and mental retardation. We have identified a new guidance molecule (Ryk) which is crucial for corpus callosum formation. This project aims to dissect that molecular mechanisms controlling Ryk signaling during corpus callosum development. Our analysis of Ryk function will advance our understanding of the molecular mechanisms underlying the formation of this important commissure.Read moreRead less
Endothelial Cell Membrane Stabilisation: Deciphering Protective Mechanisms Against Cerebral Malaria
Funder
National Health and Medical Research Council
Funding Amount
$358,319.00
Summary
Each year 3.2 billion people are exposed to the threat of malaria, resulting in about 2 million deaths annually. Deaths due to malaria often result from complications that affect the brain; this is called cerebral malaria . We still do not understand enough about the changes that cause cerebral malaria, so this project will investigate some new ideas about how cerebral malaria develops. Our aim is to identify new therapeutic targets that could help people survive this fatal disease.
Gene-environment Interactions And Synaptic Plasticity In The Developing And Dysfunctional Cerebral Cortex
Funder
National Health and Medical Research Council
Funding Amount
$526,026.00
Summary
The cerebral cortex contains many billions of neurons, which are interconnected by trillions of synapses, to form networks underlying our most complex brain functions. It is only after birth, with environmental stimulation, that diverse brain functions begin to emerge. We are interested in the mechanisms whereby the genetic programme regulating maturation of the cerebral cortex is sculpted by interaction with the environment, as well as ongoing gene-environment interactions and mechanisms of pla ....The cerebral cortex contains many billions of neurons, which are interconnected by trillions of synapses, to form networks underlying our most complex brain functions. It is only after birth, with environmental stimulation, that diverse brain functions begin to emerge. We are interested in the mechanisms whereby the genetic programme regulating maturation of the cerebral cortex is sculpted by interaction with the environment, as well as ongoing gene-environment interactions and mechanisms of plasticity in postnatal brain. Many brain disorders, including schizophrenia, autism, epilepsy, Alzheimer's and Huntington's disease, involve abnormal development or function of the cerebral cortex. Our group has recently demonstrated that onset and progression of Huntington's disease, previously considered the epitome of genetic determinism, can be modulated by environmental factors, suggesting that all brain disorders must involve gene-environment interactions. In this project we are focusing on a specific molecular pathway which processes information from the environment and induces experience-dependent changes in the structure and function of neurons in cerebral cortex. We know that the molecular pathway we are examining has been linked to schizophrenia, a disorder of brain development, and we are attempting to understand how disruption of these molecular pathways can lead to the abnormal brain development and plasticity seen in this disease. We hope to discover neurobiological mechanisms which provide integrative understanding at the level of molecules, networks of neurons, and behaviour, in mouse models of brain disorders with disruption of specific genes, receiving different types of environmental stimulation. Analysing normal mice in this project will also provide new information on mechanisms of plasticity in the healthy cerebral cortex, that may underlie higher brain functions such as learning, which occurs throughout postnatal life, and memory.Read moreRead less