Neuroanatomical Correlates Of Susceptibility In A Model Of Genetic Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$329,275.00
Summary
Genetic generalized epilepsy (GGE) is the most common form of epilepsy, but our understanding of the pathogenesis, in particular anatomical effects of genetic mutations, is incomplete. This project represents the first quantitative study of anatomical changes caused by a human GGE mutation. Pilot data show that the fundamental wiring of the cortex is different in GGE brains with obvious implications for epileptogenesis. This study is expected to inspire improved treatment and diagnosis.
Do Changes In HCN Channels Function Cause Epilepsy?
Funder
National Health and Medical Research Council
Funding Amount
$386,172.00
Summary
About 100 000 people suffer from epilepsy in Australia with about one third poorly controlled with current anti-epileptic drugs. It is important to continue to develop novel modes of treatment for this debilitating disease. This project investigates an ion channel, known as HCN that is thought to be involved in making a brain epileptic. Understanding how changes in HCN channels make nerve cells and nerve networks more excitable will help us develop better strategies for designing drugs.
NPY Suppresses Seizures And Modulates Thalamocortical Activity In Animal Models Of Generalized Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$386,020.00
Summary
Epilepsy is the most common serious chronic neurological disease in the community, affecting up to 3% of the population in a lifetime and 0.5-1% at any one time. Absence epilepsy is one of the most common types of epilepsy, most frequently seen in childhood and teenage years that may persist into adulthood. Anti-epileptic drugs are effective in controlling absence seizures in most patients, however there is an important group (20-40%) of patients in whom the absence seizures remain uncontrolled ....Epilepsy is the most common serious chronic neurological disease in the community, affecting up to 3% of the population in a lifetime and 0.5-1% at any one time. Absence epilepsy is one of the most common types of epilepsy, most frequently seen in childhood and teenage years that may persist into adulthood. Anti-epileptic drugs are effective in controlling absence seizures in most patients, however there is an important group (20-40%) of patients in whom the absence seizures remain uncontrolled with current medications. Recently there has been considerable interest in the role that chemical in the brain, such as neuropeptide Y (NPY), may play in epilepsy. The research proposed will examine the role of NPY in several animal models of absence epilepsy. We have recently shown that NPY suppresses absence seizures in a rat genetic model of generalised epilepsy, and that this appears to be mediated by Y2 receptors. This work will build on these novel findings, and determine the localisation of the effect within the brain, and the underlying mechanism. We will check NPY effects across several models in different species, a genetic rat model with spontaneous seizures, and in mice treated with a chemical to induce seizures. This will determine its broad applicability. We will also determine the effects of removal of NPY or NPY receptors on the effects of NPY on seizure expression. Finally, brain recording techniques will be applied to determine the mechanism and site within the brain underlying the protective actions of NPY. The project has the potential to provide novel insights into the role of NPY in the expression and modulation of absence seizures. NPY related mechanisms might represent targets for the development of a new class of therapeutic agents for the treatment of absence epilepsy. Targets that are identified as being important in the expression of absence seizures may also prove to be relevant in other types of generalised epilepsy syndromes.Read moreRead less
Absence epilepsy is the commonest form of idiopathic generalized epilepsy. It can lead to hundreds of seizures per day, and mainly affects children between the ages of four and eight. Its cause is in most cases unknown. In this study we will use a rat model of absence epilepsy to investigate the cellular basis of this disease. Preliminary work indicates that a particular protein - HCN1 - is reduced in the cortex of rats with absence epilepsy. This protein codes for a pore in the membrane of nerv ....Absence epilepsy is the commonest form of idiopathic generalized epilepsy. It can lead to hundreds of seizures per day, and mainly affects children between the ages of four and eight. Its cause is in most cases unknown. In this study we will use a rat model of absence epilepsy to investigate the cellular basis of this disease. Preliminary work indicates that a particular protein - HCN1 - is reduced in the cortex of rats with absence epilepsy. This protein codes for a pore in the membrane of nerve cells, which acts like a switch. We have preliminary evidence that in rats with absence epilepsy this switch does not work properly. We wish to investigate how this influences the activity of nerve cells in rats with absence epilepsy. Furthermore, as absence epilepsy is an inherited disease, we wish to track down the genetic basis of this disease. This will give us clues as to the cause of the disease in this rat model. This research will shed light on the potentially important role of the HCN1 protein in absence epilepsy, which may represent an potentially new therapeutic target for the development of drugs for the treatment of absence epilepsy.Read moreRead less
Epilepsy is the name of a group of disorders where seizures occur. 5% of people will have at least one seizure. Seizures accompanied by fever (febrile) are common in early childhood. Most forms of epilepsy and febrile seizures have an inherited component. Progress in finding genes for common forms of epilepsy has been slow, probably because they are due to the interaction of a number of genes. Four genes for rare epilepsies with single gene inheritance have been identified. These genes code for ....Epilepsy is the name of a group of disorders where seizures occur. 5% of people will have at least one seizure. Seizures accompanied by fever (febrile) are common in early childhood. Most forms of epilepsy and febrile seizures have an inherited component. Progress in finding genes for common forms of epilepsy has been slow, probably because they are due to the interaction of a number of genes. Four genes for rare epilepsies with single gene inheritance have been identified. These genes code for subunits of ion channels in cells. We study families where many individuals have seizures and carefully diagnose the seizures types. This work has resulted in the description of 5 new inherited epilepsies and led to discovery of 3 of the 4 known genes. The most important new inherited epilepsy is Generalized Epilepsy with Febrile Seizures Plus (GEFS+). GEFS+ accounts for many children with febrile seizures restricted to early childhood, or where seizures continue into mid-childhood. GEFS+ families may contain an individual with severe generalized epilepsy with intellectual disability. In a Tasmanian family with GEFS+, we found a gene defect in the sodium channel of nerve cells in the brain. We plan to study more families with GEFS+. We believe that specific severe childhood epilepsies may occur in families with GEFS+. If so, then the underlying cause of these serious disorders may be gene defects of GEFS+. Finding such genes will help to understand the basis of seizures and ultimately lead to targeted therapies. The second major focus of our work on GEFS+ is to use family studies to understand how different types of seizures are inherited, and to gain insights into the gene interactions underlying common epilepsies. We plan to study isolated cases of GEFS+ for the gene defects found in families. This strategy will reveal whether the same genes are important in the genetics of the common epilepsies.Read moreRead less
Investigating Genetic Determinants Of Absence Epilepsy In A Polygenic Rat Model
Funder
National Health and Medical Research Council
Funding Amount
$458,481.00
Summary
The underlying genetic causes of idiopathic generalised epilepsies (IGE) are still largely unknown. In an animal model of IGE we have discovered novel genetic abnormalities an ion channel. This proposal will build upon these novel findings to examine the role these abnormalities have in determining the absence epilepsy phenotype and this work has the potential to provide vital information regarding the mechanisms by which this gene contributes to an IGE seizure phenotype.
Epilepsy is a common disease in the Australian population affecting 3 percent of individuals. It incurs lifelong medical, social and educational costs, and in some cases can be fatal. It is a large burden on public healthcare in Australia. Focal epilepsies are the most common type of seizure that arise from specific parts of the brain. This study has two aims and a future strategy relevant to gene discovery and clinical testing for focal epilepsy.