NEW MECHANISM FOR FEBRILE SEIZURES IN YOUNG CHILDREN
Febrile seizures are
the most frequent form of childhood epileptic attacks and affect roughly two to
four per cent of all children worldwide. They often occur between the ages of
three months and five years and can even appear upon mild hyperthermia. What is
apparently even more decisive than the fever level, however, is the speed with
which the fever rises. "This explains why children can experience a
febrile seizure even before the parents have noticed that the child is
ill," says Professor Holger Lerche, M.D., Director of the Hertie Institute
for Clinical Brain Research (HIH) and Medical Director of the Department of
Neurology and Epileptology at the University of Tübingen.
Parents naturally
become worried when a small child shows a tendency to fever attacks. However,
the prospects in most cases are good: the attacks subside by the time of school
age, and damaging aftereffects remain present only in rare and exceptional cases.
The factors which
contribute to the development of epilepsy from simple febrile seizures are
still largely unknown. "Genetic predisposition plays an important role.
But up to now there has been an inadequate understanding of which genomic
mutations are involved in detail," says the study's co-initiator,
Professor Yvonne Weber, M.D., Assistant Medical Director of the Department of
Neurology and Epileptology at the University of Tübingen.
The team of
researchers came upon the track of these genetic mutations via exome
sequencing, a special technique for examining a partial section of the genetic
material. Even though the exome makes up only about one per cent of the human
genotype, it also contains most of the pathogenic genetic alterations
(mutations) which have been found to date. Analysis of genetic material first
revealed STX1B mutations in two large families whose
members are prone to both febrile seizures and epileptic attacks. The analysis
was then widened to include further patients, which led to the discovery of
four further mutations. Here too, the affected persons suffered from febrile
seizures and serious epileptic attacks, which had resulted over and above this
in mental disabilities. "In other words, the STX1B mutations gave us an important clue:
they do more than trigger epileptic febrile seizures, which of themselves often
subside in these small patients by the time of the first school year; the
mutations may also be the cause of serious cases of epilepsy, with consequent
impairment of intellectual development," as Lerche explains. The
researchers now hope to turn these insights to practical advantage in the form
of better methods of treatment and even, in the ideal case, to successfully
prevent the development of epilepsy.
Together with
experts in the field of zebrafish research from the University of Leuven,
Belgium and the University of Luxembourg's Centre for Systems Biomedicine
(LCSB), the neuroscientists were able to confirm the impact of the newly
discovered STX1Bmutations with
the aid of a model system. Zebrafish provide an excellent model for the study
of epilepsy. In the zebrafish, the development of organs such as the brain
takes place at the level of molecular mechanisms in much the same way as in
humans. "We were able to show not only that similar patterns of
epileptiform attacks also occur in zebrafish with genetically altered STX1B genes, but also that brainwave changes
appeared which were clearly aggravated by hyperthermia -- as in the case of
fever," says Dr. Camila Esguerra, the principal investigator who led this
part of the study at the University of Leuven and is now in the process of
forming a new research team at the University of Oslo, Norway.
Zebrafish are also
especially well-suited for the development of new avenues of treatment.
Together with Dr. Alexander Crawford (Luxembourg), Dr. Esguerra has already
found a substance which can prevent the most violent form of attacks in
zebrafish. "We hope that from this we will be able to develop a new drug
in a few years which will prevent the development of certain forms of serious
epilepsy in childhood," says Crawford. In addition, a search for new
substances will also be carried out inSTX1B mutations.
The project also
included clinical and genetic experts of the EuroEPINOMICS Consortium, a
European Science Foundation network initiated and directed by scientists in
Tübingen, Kiel and Antwerp and funded in Germany with 2.5 million Euros from
the German Research Foundation. This has brought clinicians together with
scientists in the field of basic research to study both the genetic mechanisms
of epilepsy and avenues for new methods of therapy. Still another network,
"IonNeurONet" is part of this project and is carrying on a search for
the causes of rare forms of epilepsy and other nervous disorders (e.g. rare
forms of migraine as well as retinal and muscular diseases). With the help of
the German Federal Ministry for Education and Research (BMBF), which has
provided support for the network, patients with the corresponding impairments
have been gained as test subjects for the study. Such large-scale networks,
with the corresponding numbers of patients, are essential for the discovery and
confirmation of new genetic defects. They are also a prerequisite for later
clinical trials to confirm research results in patients. The work described
here has brought the scientists and physicians of the present study a step
closer to a discovery of new therapeutic options.
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