Genetic And Phenotype Studies Of Partial Epilepsy In Gypsies
Funder
National Health and Medical Research Council
Funding Amount
$646,136.00
Summary
Epilepsy is one of the most common serious neurological disorders, which affects more than 50 million people worldwide. Genetic research, with a major contribution from Australian researchers, has led to the discovery of many rare forms of the disease caused by mutations in single genes of large effect. However, the vast majority of cases worldwide belong to the so-called genetically complex forms, involving multiple interacting genes and environmental factors. The genetically complex epilepsies ....Epilepsy is one of the most common serious neurological disorders, which affects more than 50 million people worldwide. Genetic research, with a major contribution from Australian researchers, has led to the discovery of many rare forms of the disease caused by mutations in single genes of large effect. However, the vast majority of cases worldwide belong to the so-called genetically complex forms, involving multiple interacting genes and environmental factors. The genetically complex epilepsies have proved particularly difficult to understand and the numerous genetic studies conducted so far have failed to produce important and replicable results. It is becoming increasingly clear that enormous genetic heterogeneity, with many rare mutations occurring in different affected subjects, will be a major obstacle to understanding the molecular basis of complex epilepsies. In this context, genetically isolated populations, which stem from a small number of ancestors, can be particularly helpful and revealing, since their limited genetic diversity means that the number of genes involved in causing complex epilepsies may be smaller and shared between individuals and families. In this study, we will analyze affected families, as well as non-familial cases of epilepsy, from a genetically isolated population - the European Roma-Gypsies. We will determine the number of potential susceptibility genes involved in familial forms, the overlap and differences between families, as well as the contribution of the genes identified in families to the development of sporadic epilepsy.Read moreRead less
Identification And Characterisation Of Phenotypic Modifier Genes In Familial Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$413,250.00
Summary
Alzheimer's disease (AD) is the most common cause of dementia the fourth most common cause of death. There are no effective cures for AD and those drugs currently available are of very limited value in delaying the onset and progression of this invariably fatal disease. AD is diagnosed by two key features in the brain, dense plaques composed of the amyloid beta peptide, and tangles composed of the tau protein. The identification of new therapeutic targets, such as the enzymes which produce amylo ....Alzheimer's disease (AD) is the most common cause of dementia the fourth most common cause of death. There are no effective cures for AD and those drugs currently available are of very limited value in delaying the onset and progression of this invariably fatal disease. AD is diagnosed by two key features in the brain, dense plaques composed of the amyloid beta peptide, and tangles composed of the tau protein. The identification of new therapeutic targets, such as the enzymes which produce amyloid beta peptide, and the development of drugs that interact with these targets offers the prospect of developing treatments to delay disease onset, retard or even halt the development of this relentlessly progressive disease. Our research focuses on the genes that are involved in variant forms of AD. One neuropathological variant form we and others have described is characterised by large diffuse (cotton wool) amyloid plaques. Cotton wool plaque pathology is associated with AD causing mutations in the presenilin 1 (PS-1) gene. Another clinical AD variant that we have described is characterised by the presence of spastic paraparesis (SP). SP is associated with PS-1 mutations, but when present delays disease onset. We have identified two potential modifier genes which are likely to be directly involved in the production of cotton wool plaques or modifying the effect of PS-1 mutations and the occurence of SP. For both genes, the goal of this project is to use a range of genetic approaches to clone the modifier genes by and to assess their effects on the clinical and pathological development of AD. By studying the effects of genes which act to modify the effects of the PS-1 mutations in these variant forms of AD we hope to gain a greater understanding of how the plaques and tangles actually lead to the clinical symptoms of the disease and to gain insights into new ways in which AD may be treated.Read moreRead less
Mutation Analysis Of Novel Candidate Genes For X-linked Charcot Marie Tooth (CMTX3) Neuropathy.
Funder
National Health and Medical Research Council
Funding Amount
$191,434.00
Summary
Our goal is to explore how peripheral nerves degenerate by identifying the gene mutation causing an X linked form of Charcot Marie Tooth neuropathy (CMTX3). Using bioinformatic resources and state of the art gene mutation scanning we will complete characterisation and systematic screening of candidate genes and novel transcripts in the region. Discovery of this gene will provide a means to determine mechanisms causing axonal degeneration and lead to targeted therapeutic treatment strategies.
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
Fainting (syncope) is a common disorder leading to blackouts, which can cause injury. Breath-holding is a related problem in younger children also resulting in blackouts. Both of these conditions can run in families but little is known about what causes these events. We will study large families to identify the genes underlying these common phenomena. This will deepen our understanding of patterns of inheritance, improve genetic counseling, and lead to better diagnostic and treatment options.
Cloning And Characterisation Of A Bipolar Disorder Susceptibility Gene On Chromosome 15q
Funder
National Health and Medical Research Council
Funding Amount
$347,621.00
Summary
Bipolar disorder is a severe mood disorder, characterised by aberrant mood swings resulting in periods of mania and depression. We need to define more clearly the biological basis of bipolar disorder to improve diagnosis and treatment. Bipolar disorder is highly heritabile allowing the use of genetics to identify the predisposing genes. Our aim is to identify a bipolar susceptibility gene on chromosome 15 and to understand how this gene contributes to the risk of developing bipolar disorder.