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.
Modifying Brain Excitabilty By Upregulating The KCC2 Chloride Transporter
Funder
National Health and Medical Research Council
Funding Amount
$535,662.00
Summary
Brain activity depends upon the fine balance between neuronal excitation and inhibition. When this balance is lost, debilitating seizures can result, such as occurs in epilepsy. We have developed a new gene manipulation approach to enhance neuronal inhibition and prevent seizures in mice. We will examine the physiological mechanisms underlying this effect, and we propose that we can also use this genetic switch to stop the progression into epilepsy that occurs following a brain trauma.
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