The Molecular Basis For Target Selection In The Central Nervous System By Sensory Axons
Funder
National Health and Medical Research Council
Funding Amount
$251,325.00
Summary
The normal function of the brain depends upon the specific connections that nerve cells make with each other. These connections are set up in the developing embryo when nerve cells send out long processes - axons - which grow towards their synaptic targets. How axons select their correct targets from amongst the millions of alternatives in the developing brain is unknown. A better understanding of this problem will help us develop therapies to assist regenerating axons re-establish correct conne ....The normal function of the brain depends upon the specific connections that nerve cells make with each other. These connections are set up in the developing embryo when nerve cells send out long processes - axons - which grow towards their synaptic targets. How axons select their correct targets from amongst the millions of alternatives in the developing brain is unknown. A better understanding of this problem will help us develop therapies to assist regenerating axons re-establish correct connections following injury to the brain or spinal cord. We propose to use a simple model system, the embryo of the fruitfly Drosophila, to find molecules that are involved in this process of neuron target recognition - ' axon targeting' molecules - and to study how they work. Drosophila can be genetically manipulated in ways not possible in higher animals. Furthermore the simplicity of its nervous system means that we can determine the connections of individual nerve cells with a high degree of precision. In the first part of our project, we will examine Drosophila embryos that carry mutations in genes suspected to code for targeting molecules. We will stain individual sensory nerve cells in these embryos with dyes to reveal the anatomy of their axons in the brain. If sensory axons terminate abnormally in the brain of a given mutant, the affected gene is likely to code for an axon targeting molecule. In the second part of the study, we will investigate the functions of candidate axon targeting molecules using two approaches. Firstly, we will seek to determine whether the molecule acts in the sensory axons or in their target cells. Secondly, we will use time-lapse microscopy to study how the homing behaviour of the sensory axons is affected in mutant embryos. The results of these studies will lead us closer to an answer to the question: How do axons recognise their specific target cells in the brain?Read moreRead less
The Role Of Cell Adhesion Molecules In Regulation Of Axon Advance
Funder
National Health and Medical Research Council
Funding Amount
$426,006.00
Summary
All cells contain on their surface a class of molecules, cell adhesion molecules, that enable them to adhere to other cells in tissues. Cell adhesion molecules have long been known to be involved in the guidance of axons to their targets during development. However the molecular mechanisms by which these molecules act are largely unknown. We propose to use the powerful genetic tools available in the fruitfly to dissect the mechanisms by which two cell adhesion molecules promote axon growth.
Quantifying The Role Of Epigenetic Factors In Neurocognitive Outcomes: A Twin Study
Funder
National Health and Medical Research Council
Funding Amount
$1,516,790.00
Summary
We aim to identify the environmental factors in early life that contribute towards an individual brain development using MRI brain scans and related psychological skills measured in late childhood. We are using twins to better understand differences in their early life environments independent of genetics.
Targeting Tau Phosphorylation To Treat And Prevent Acquired Epilepsy, Neurodegeneration And Neuropsychiatric Disease Following A Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$524,820.00
Summary
This project will explore a new approach to the prevention and treatment of epilepsy and the associated mental health disorders following a brain injury. This involves inhibiting pathological forms of the Tau protein, which has been implicated in the development of epilepsy and neurodegeneration. The drug that will be tested in this study has already been demonstrated to be safe and well tolerated in humans, meaning that a positive result from these studies could be expediently translated into c ....This project will explore a new approach to the prevention and treatment of epilepsy and the associated mental health disorders following a brain injury. This involves inhibiting pathological forms of the Tau protein, which has been implicated in the development of epilepsy and neurodegeneration. The drug that will be tested in this study has already been demonstrated to be safe and well tolerated in humans, meaning that a positive result from these studies could be expediently translated into clinical studies.Read moreRead less
A Multi-cohort Investigation Of The Effects Of BDNF Val66Met On Tau, Neurodegeneration And Cognition In Preclinical Alzheimer’s Disease
Funder
National Health and Medical Research Council
Funding Amount
$325,758.00
Summary
There are currently no disease modifying therapies for Alzheimer’s disease. We will elucidate the role of a genetic polymorphism that has previously been shown to exert neuroprotective effects on memory decline and brain volume loss associated with Alzheimer’s disease. By studying the role of this gene in multiple cohorts of individuals with varying degrees of Alzheimer’s disease risk, this study has high potential to uncover novel disease-modifying strategies for the treatment of the disease.
Characterisation Of Eurl, A Novel Gene Implicated In The Etiology Of Abnormal Brain Development And Intellectual Disability
Funder
National Health and Medical Research Council
Funding Amount
$597,541.00
Summary
Intellectual disability affects around one per cent of Australians, and can arise from genetic abnormalities during fetal life, such as through abnormal regulation of gene expression. We have identified a novel gene, known as eurl, which controls brain assembly as well as the ability of neurons to form functional connections within the brain. We will investigate how this novel gene controls brain development, and characterise eurl as a potential therapeutic target for learning and memory.
Enhancing Rehabilitation Services For Aboriginal Australians After Brain Injury: Healing Right Way
Funder
National Health and Medical Research Council
Funding Amount
$906,445.00
Summary
This project involves implementation of the first culturally secure intervention package for Aboriginal survivors of brain impairment in Australia. Stroke and traumatic brain injury occur significantly more frequently in Aboriginal populations, yet Aboriginal people are under-represented in rehabilitation programs. The project will improve accessibility to rehabilitation, improve health outcomes, and establish an economic model contributing to sustainability and planning of future services.
APLP2: A Neuroprotective Receptor For Acute Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$648,739.00
Summary
Traumatic brain injury (TBI) is the major cause of deaths in Australians under 45 years of age. We have shown that the amyloid precursor protein (APP) is protective in models of TBI. To understand how APP is neuroprotective we have isolated APP binding proteins and identified the amyloid precursor-like protein 2 (APLP2) molecule as a strong candidate for the APP-neuroprotective receptor. This grant will investigate the interaction between APP and APLP2 as a novel neuroprotective pathway in TBI.
Mechanisms Guiding Pathfinding And Positioning Of Cortical Interneurons
Funder
National Health and Medical Research Council
Funding Amount
$621,606.00
Summary
Brain disorders place an economic and social burden on Australia and the personal costs of these illnesses are immeasurable. Several brain abnormalities are caused from the failure of neurons to position themselves in the correct location when the brain develops. Our study aims to discover how neurons move and what factors influence this process. It provides an understanding of normal brain development, as well as providing insight into what may go wrong in the formation of brain diseases.