Uncovering The Function Of Susceptibility Variants In Alzheimer's Disease: From GWAS To Cell-Type Specific EQTLs And MQTLs
Funder
National Health and Medical Research Council
Funding Amount
$647,804.00
Summary
This project will investigate some of the genetic and epigenetic changes that occur inside certain brain cells that make them selectively vulnerable to Alzheimer's disease, in order to better understand the mechsnisms that give origin to the disease and identify possible targets for precision therapies.
Identification And Characterisation Of Genes Causing Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE) And Related Phenotypes
Funder
National Health and Medical Research Council
Funding Amount
$376,640.00
Summary
Epilepsy affects approximately 2% of the population at some stage of their lives. We have recently identified two new genes involved in the development of a type of epilepsy known as ADNFLE. We aim to identify further epilepsy genes by sequencing ADNFLE patients who do not yet have identified mutations. We also aim to identify the genes interacting with the genes we have identified, increasing our understanding of the cellular networks involved in the development of epilepsy.
Massive Parallel Sequencing In The Genetics Of Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$451,716.00
Summary
Epilepsy is a serious disorder which affects approximately 2% of the population at some stage in their life and around 30% of patients do not gain adequate control of their seizures with medications presently available. Approximately 70% of epilepsy in inherited and so far the majority of the genetic causes are yet to be discovered. My group aims to identify new epilepsy genes. This leads to improved diagnosis, treatment and counseling for patients and increased understanding of the biological m ....Epilepsy is a serious disorder which affects approximately 2% of the population at some stage in their life and around 30% of patients do not gain adequate control of their seizures with medications presently available. Approximately 70% of epilepsy in inherited and so far the majority of the genetic causes are yet to be discovered. My group aims to identify new epilepsy genes. This leads to improved diagnosis, treatment and counseling for patients and increased understanding of the biological mechanisms underlying seizures.Read moreRead less
Reprogramming Of Ataxia Telangiectasia Fibroblasts To Generate IPS Cells
Funder
National Health and Medical Research Council
Funding Amount
$601,386.00
Summary
Ataxia telangiectasia (A-T) is a human genetic disorder characterised by immunodeficiency, cancer predisposition and neurodegeneration. The aim of this project is to generate adult stem cells from A-T patient as a model system to investigate the nature of the nervous system defect in this disorder. These adult stem cells will be employed to produce neuronal cells which will be a resource for screening for therapeutic compounds to treat A-T patients.
Neurologic Effects Of Mutational Load In MELAS Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$505,786.00
Summary
This project will use a new stem cell model to discover what happens to brain cells in patients with the MELAS 3243A>G mutation, a common genetic mutation found in 1-500 Australians. Brain cells will be grown from our stem cell model and used to find out how this mutation causes problems in the affected brain cells. We will find out what happens to the brain when the amount of mutation is reduced in vitro. By understanding what happens, we will be able to design new treatments for this disord ....This project will use a new stem cell model to discover what happens to brain cells in patients with the MELAS 3243A>G mutation, a common genetic mutation found in 1-500 Australians. Brain cells will be grown from our stem cell model and used to find out how this mutation causes problems in the affected brain cells. We will find out what happens to the brain when the amount of mutation is reduced in vitro. By understanding what happens, we will be able to design new treatments for this disorder.Read moreRead less
Molecular Genetics Of Hereditary Motor And Sensory Neuropathy With Pyramidal Signs
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
Summary
This project aims to determine the molecular cause of hereditary motor neuropathies with pyramidal signs by chromosomal linkage studies and to screen suitable families to locate genes with disease causing mutations. We propose to use the resources of the human genome project to locate the defective gene. In previous studies we have used these methods to identify genes of two other hereditary diseases of nerve. Our data suggests that this disorder forms part of the largest group of hereditary neu ....This project aims to determine the molecular cause of hereditary motor neuropathies with pyramidal signs by chromosomal linkage studies and to screen suitable families to locate genes with disease causing mutations. We propose to use the resources of the human genome project to locate the defective gene. In previous studies we have used these methods to identify genes of two other hereditary diseases of nerve. Our data suggests that this disorder forms part of the largest group of hereditary neuropathies yet to be defined. Because this disorder affects long spinal cord neurones, identifying the mutated gene and studying its function may shed light on possible mechanisms involved in other spinal cord diseases. This research is a systematic search and should lead to identifying the abnormal gene causing disease. Once the gene involved is known then an effective diagnostic test will be developed. When a test for the disease is available, it is likely that we will find that the disorder is more common than previously recognised. Knowledge of the function of the gene will lead to an understanding of how the disease develops and will eventually enable development of effective treatments.Read moreRead less
Role of micro-RNAs in learning and memory of insects. This project will investigate how small molecules in the brain, so-called micro RNAs, regulate processes underlying learning and memory formation. The outcomes will provide new knowledge on the specific function of these molecules in the brain, and help us understand their role in cognitive disorders such as autism and schizophrenia.
The role of gene isoforms in human brain development. This project aims to investigate how genes vary their products to control human brain development, by creating new methods to study gene activity in individual brain cells. Using these innovative methods, this project expects to generate fundamental new knowledge of how the human brain forms. Expected outcomes of this project include widely applicable techniques, strengthened international (UK) research collaborations and highly trained perso ....The role of gene isoforms in human brain development. This project aims to investigate how genes vary their products to control human brain development, by creating new methods to study gene activity in individual brain cells. Using these innovative methods, this project expects to generate fundamental new knowledge of how the human brain forms. Expected outcomes of this project include widely applicable techniques, strengthened international (UK) research collaborations and highly trained personnel in genomics and neuroscience. This should deliver many benefits, including a better understanding of how the brain forms, training of higher degree by research students, as well as tools and methods of benefit to the academic research and biotechnology sectors.Read moreRead less
Genetic Bases For Charcot-Marie-Tooth And Hereditary Sensory Type 1 Neuropathies
Funder
National Health and Medical Research Council
Funding Amount
$618,055.00
Summary
This project aims to identify the defective gene in a hereditary disease of peripheral nerve. The hereditary disorders of peripheral nerve form the commonest group of human genetic diseases, collectively called Charcot-Marie-Tooth neuropathy. Although few hereditary nerve diseases are fatal most cause lifelong disability. All cause weakness of the lower legs and later weakness and wasting of the muscles of the arm and hand. Affected individuals have difficulty running, frequent falls with gradua ....This project aims to identify the defective gene in a hereditary disease of peripheral nerve. The hereditary disorders of peripheral nerve form the commonest group of human genetic diseases, collectively called Charcot-Marie-Tooth neuropathy. Although few hereditary nerve diseases are fatal most cause lifelong disability. All cause weakness of the lower legs and later weakness and wasting of the muscles of the arm and hand. Affected individuals have difficulty running, frequent falls with gradually increasing disability eventually requiring splints and other walking aids. We propose to use the newly developed resources of the human genome project to locate the defective gene. In previous studies we have used these methods to locate the defective genes of 2 other hereditary diseases of nerve. In this study we propose to investigate a newly recognised form of CMT called intermediate CMT. Intermediate CMT has characteristics intermediate between the better known forms of CMT affecting the nerve itself (the axon) or the nerve insulation (the surrounding myelin sheath). The disorder may therefore affect both components of nerve. The affected gene may mediate communication between the nerve and its sheath. This research should give valuable insight into the mechanisms responsible for the maintenance of normal nerve. Finding the gene may therefore have relevance to many other diseases of nerve. This research is a systematic search and should lead to the abnormal gene causing the disease. Once the gene involved is known then an effective test will be developed. When we can test for the disease, we probably will find that the disorder is much more common than previously recognised. Knowledge of the function of this gene will lead to an understanding of how the disease develops and will eventually lead to effective treatments.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101033
Funder
Australian Research Council
Funding Amount
$315,220.00
Summary
Genomic Diversity in the Human Brain: the Functional Role of Expandable DNA Repeats. Neuronal cells accumulate genetic changes during development and adult life, and recent evidence suggests that the resulting genomic diversity may underlie neuronal functional diversity. To date only a few types of somatic genetic variation have been characterised in the human brain. Trinucleotide repeats (TNR) are hotspots of genomic instability and TNR expansions at specific loci cause dozens of brain disorder ....Genomic Diversity in the Human Brain: the Functional Role of Expandable DNA Repeats. Neuronal cells accumulate genetic changes during development and adult life, and recent evidence suggests that the resulting genomic diversity may underlie neuronal functional diversity. To date only a few types of somatic genetic variation have been characterised in the human brain. Trinucleotide repeats (TNR) are hotspots of genomic instability and TNR expansions at specific loci cause dozens of brain disorders, suggesting that the human brain is particularly vulnerable to this type of genetic variation. This project aims to investigate, for the first time, TNR somatic instability in the human brain on a genome-wide scale, therefore, addressing the genetic diversity of the brain from a novel and highly relevant angle. Read moreRead less