Neourobiology Of Human Epilepsy: Genes, Cellular Mechanisms,network And Whole Brain
Funder
National Health and Medical Research Council
Funding Amount
$17,652,824.00
Summary
The team is comprised of neurologists, molecular geneticists, physiologists and brain imaging specialists and leads the world in the discovery of the genetic causes of epilepsy. They will continue to identify genes underlying epilepsy and study how genetic variations result in development of seizures. Advanced brain imaging will be used to understand the effects of genetic variation on brain structure and function. This study may lead to new diagnostic methods and treatments for epilepsy.
The Incidence And Genetics Of The Infantile Epileptic Encephalopathies
Funder
National Health and Medical Research Council
Funding Amount
$175,224.00
Summary
Severe epilepsies with frequent seizures and cognitive impairments in the first 18 months of life are known as ‘infantile epileptic encephalopathies’ (IEE). The cause of IEE is unknown in many patients, although presumed genetic. This study of patients with IEE in Victoria aims to describe the incidence of IEE, and understand the genetic causes of IEE. Understanding the causes of IEE will be the first step towards development of urgently-needed novel therapies for these devastating conditions.
The Australian Parkinson's Project - Uncovering Genetic Risk Factors For Sporadic PD
Funder
National Health and Medical Research Council
Funding Amount
$768,546.00
Summary
Parkinson s disease (PD) is a progressively disabling movement disorder afflicting many elderly Australians. It is caused by the degeneration of specific nerve cells in the brain that produce certain chemicals and patients suffer from an inability to move fluently (or ultimately at all). At present we do not know what triggers this neurodegeneration, but it is believed that complex interactions between inherited (genetic) and environmental factors contribute significantly to the phenomenon. This ....Parkinson s disease (PD) is a progressively disabling movement disorder afflicting many elderly Australians. It is caused by the degeneration of specific nerve cells in the brain that produce certain chemicals and patients suffer from an inability to move fluently (or ultimately at all). At present we do not know what triggers this neurodegeneration, but it is believed that complex interactions between inherited (genetic) and environmental factors contribute significantly to the phenomenon. This project aims to learn more about these complex interactions and their association with PD. People with PD and unaffected individuals will be recruited from throughout Australia and we will look for specific combinations of genetic, environmental and lifestyle factors that either increase or decrease an individual's risk for PD. This research will identify the most common dominant genetic and environmental influences for PD in Australia, enabling scientists to focus on the most relevant biological pathways to target therapeutically.Read moreRead less
Professor Scheffer and her collaborators lead the world in the discovery of the genetic causes of epilepsy. She will continue to identify new and refine known epilepsy syndromes and develop the classification of the epilepsies. Together with molecular colleagues, she will continue to discover the underlying genes causing this debilitating disorder leading to novel insights into the neurobiology. Her work may lead to new treatments and improve outcomes for people for epilepsy.
Neurodevelopmental Mechanisms And Early Intervention In Psychiatric Illness
Funder
National Health and Medical Research Council
Funding Amount
$652,765.00
Summary
Schizophrenia and depression are devastating mental illnesses and a huge burden to society. Drug treatments can be beneficial, but many patients are either treatment-resistant or show severe side-effects. There is an urgent need for truly novel treatment strategies which should ideally prevent symptoms. The main aim of this project is to elucidate brain mechanisms involved in schizophrenia and depression development to inform clinical research about improved preventative treatment strategies.
Epistatic Genetic Effects On Neuroanatomical Subtypes Of Schizophrenia
Funder
National Health and Medical Research Council
Funding Amount
$410,141.00
Summary
Schizophrenia represents a number of clinically distinct syndromes, with a complex mode of inheritance. The delineation of biologically valid subtypes of schizophrenia is necessary to advance our understanding of the genetic basis of these syndromes. This project uses pattern classification techniques to determine subtypes of schizophrenia on the basis of structural brain abnormality across multiple regions, and will examine genetic interactions and differential gene expression associated with t ....Schizophrenia represents a number of clinically distinct syndromes, with a complex mode of inheritance. The delineation of biologically valid subtypes of schizophrenia is necessary to advance our understanding of the genetic basis of these syndromes. This project uses pattern classification techniques to determine subtypes of schizophrenia on the basis of structural brain abnormality across multiple regions, and will examine genetic interactions and differential gene expression associated with these biologically-derived subtypes.Read moreRead less
Integrated Analysis Of Genome, Epigenome, And Transcriptome Data In Schizophrenia
Funder
National Health and Medical Research Council
Funding Amount
$417,511.00
Summary
Schizophrenia is a severe psychiatric disorder with a diverse range of symptoms. While the cause is unknown, it is thought to develop from a combination of genetic, epigenetic and environmental risk factors. This study will use genome wide approaches to investigate the relationship between genetic/epigenetic modification of DNA and gene expression in schizophrenia. This study could provide an integrated understanding of the neuropathology of schizophrenia and ultimately lead to better treatment.
The Role Of Netrin-DCC In The Development Of The Corpus Callosum
Funder
National Health and Medical Research Council
Funding Amount
$512,065.00
Summary
During embryonic development neurons send out axons that connect to other target neurons within the brain. The proper connectivity of these axons is vital to brain function. The largest axon tract in the brain is called the corpus callosum and connects neurons in the left and right cerebral hemispheres. When the corpus callosum does not form, significant cognitive, motor and sensory deficits occur in patients. This condition, known as agenesis of the corpus callosum (ACC), is associated with ove ....During embryonic development neurons send out axons that connect to other target neurons within the brain. The proper connectivity of these axons is vital to brain function. The largest axon tract in the brain is called the corpus callosum and connects neurons in the left and right cerebral hemispheres. When the corpus callosum does not form, significant cognitive, motor and sensory deficits occur in patients. This condition, known as agenesis of the corpus callosum (ACC), is associated with over 50 different human congenital syndromes. Thus understanding how the genes and molecules involved in the formation of the corpus callosum function in normal development can provide the basis for our understanding of what goes wrong in ACC. In this proposal we will investigate the role of the axon guidance molecule Netrin1, and its receptor DCC, in development of the corpus callosum in both a mouse model and in humans with malformations of the corpus callosum. Although Netrin1-DCC signalling has traditionally been associated with mechanisms of axon guidance, we hypothesize that these molecules may play a different role, specifically in cellular adhesion and ultimately in the fusion of the two cerebral hemispheres, in a manner that allows the corpus callosum to form. A second role for Netrin1-DCC signalling may be in the guidance of these axons once the midline has fused correctly and we investigate this in Aim 2 of the proposal. Finally, we are collaborating with a paediatric neurologist at UCSF, who has identified several mutations in the DCC gene in patients with ACC. In Aim 3 we test whether these mutations disrupt the function of DCC in callosal axon pathfinding. Understanding how these genes function during development of the brain and how their function may be altered in ACC is crucial to providing a proper diagnosis and prognosis for these patients. Ultimately, understanding more about how these genes function could also lead to prevention of these disorders.Read moreRead less
Characterisation And Modelling Of Schizophrenia-associated Dysregulation Of MiR-137 Expression
Funder
National Health and Medical Research Council
Funding Amount
$581,661.00
Summary
We have identified mutation-associated changes in the expression of a non-coding microRNA gene in the cerebral cortex in schizophrenia. This gene, known as MIR137, functions by repressing hundreds of target genes and therefore has major implications for schizophrenia. The project will identify the genetic mechanism affecting the expression of MIR137, and determine the biological and behavioural implications of this change in the context of schizophrenia.
A new theory for retinotectal map formation. How brains become wired up during development is a question of
importance to both biology and computing. In this project we adopt a
novel computational approach to understanding the development of
topographic maps, a wiring pattern that is ubiquitous in biological
nervous systems. This project will build capacity for research in
computational neuroscience in Australia. It may also lead to
technological benefits such as new ideas for the design o ....A new theory for retinotectal map formation. How brains become wired up during development is a question of
importance to both biology and computing. In this project we adopt a
novel computational approach to understanding the development of
topographic maps, a wiring pattern that is ubiquitous in biological
nervous systems. This project will build capacity for research in
computational neuroscience in Australia. It may also lead to
technological benefits such as new ideas for the design of self-wiring
computing devices, and new insights into
the causes of wiring defects both during normal development and
rewiring after injury.
Read moreRead less