SEVERE CHILDHOOD EPILEPSIES : SYNAPSE GENES
Philadelphia, Sept.
25, 2014 – An international research team has identified gene mutations causing
severe, difficult-to-treat forms of childhood epilepsy. Many of the mutations
disrupt functioning in the synapse, the highly dynamic junction at which nerve
cells communicate with one another
This research
represents a paradigm shift in epilepsy research, giving us a new target on
which to focus treatment strategies,” said pediatric neurologist Dennis Dlugos,
M.D., director of the Pediatric Regional Epilepsy Program at The Children’s
Hospital of Philadelphia , and a study co-author. “There is tremendous
potential for new drug development and personalized treatment strategies, which
is our task for the years to come.”
Multiple researchers
from the U.S. and Europe performed the research, the largest collaborative
study to date focused on the genetic roots of severe epilepsies. The scientists
reported their results online today in the American Journal of Human
Genetics (epub ahead of print).
Two international
research consortia collaborated on the study—the Epi4K/EPGP Consortium, funded
by the National Institute of Neurological Disorders and Stroke (NINDS) and the
European EuroEPINOMICS consortium. The genetic analysis was performed at the
NINDS-funded Epi4K Sequencing, Biostatistics, and Bioinformatics Core at Duke
University, led by Drs. David Goldstein, Erin Heinzen and Andrew Allen.
The current study
added to the list of gene mutations previously reported to be associated with
these severe epilepsy syndromes, called epileptic encephalopathies. The
researchers sequenced the exomes (those portions of DNA that code for proteins)
of 356 patients with severe childhood epilepsies, as well as their parents. The
scientists looked for “de novo” mutations—those that arose in affected
children, but not in their parents. In all, they identified 429 such de novo
mutations.
In 12 percent of the
children, these mutations were considered to unequivocally cause the child’s
epilepsy. In addition to several known genes for childhood epilepsies, the
study team found strong evidence for additional novel genes, many of which are
involved in the function of the synapse.
Epilepsies are amongst
the most common disorders of the central nervous system, affecting up to 3
million patients in the U.S. Up to one third of all epilepsies are resistant to
treatment with antiepileptic medication and may be associated with other
disabilities such as intellectual impairment and autism. Severe epilepsies are
particularly devastating in children. In many patients with severe epilepsies,
no cause for the seizures can be identified, but there is increasing evidence
that genetic factors may play a causal role.
The research teams
used a method called family-based exome sequencing, which looks at the part of
the human genome that carries the blueprints for proteins. When comparing the
sequence information in children with epilepsy with that of their parents, the
researchers were able to identify the de novo changes that arose in the genomes
of the affected children. While de novo changes are increasingly recognized as
the genetic cause for severe seizure disorders, not all de novo changes are
necessarily disease-causing.
“Everybody has one or
two de novo mutations and it is our task to find those changes that cause
disease,” said co-author Ingo Helbig, M.D., now at The Children’s Hospital of
Philadelphia. “We pulled out those genes that have more mutations in patients
with epilepsy than you would expect by chance. These genes will hopefully tell
us a bit more about the underlying disease mechanisms and how we can address
them with new treatments.” As a member of the European EuroEPINOMICS
consortium, Helbig was a co-initiator of the transatlantic collaboration that
conducted the study. Helbig is also a member of the Genetics Commission of the
International League Against Epilepsy (ILAE).
The most surprising
finding in the study by the international research group is a gene called DNM1,
which was found to be mutated in five patients. The gene carries the code for
dynamin-1, a structural protein that plays a role in shuttling small vesicles
between the body of the neuron and the synapse. These vesicles are structures
that contain neurotransmitters, chemical signals crucial to communication
between nerve cells. When the researchers looked on a network level, they found
that many of the genes that were found to be mutated in patients had a clear
connection with the function of the synapse.
This research finding,
says Dlugos, provides important information about the functional roles of the
genes that were identified. “We knew that synaptic genes were important but not
to this extent,” he added.
A spokesperson for
Citizens United for Research in Epilepsy (CURE), a non-profit organization
dedicated to finding a cure for epilepsy and increasing awareness of the
disease, applauded this study. Dr. Tracy Dixon-Salazar, Associate Research
Director at CURE and mother of a child with severe genetic epilepsy, added, “It
is exciting to see the big consortia put the genomic data of almost 400
patients together. This clearly highlights that by working together we can find
new genes faster, helping us to explain what causes this often devastating
disease in children.”
Funders of this study
included the National Institute of Neurological Disorders and Stroke (NINDS),
part of the National Institutes of Health (grants NS053998, NS077364, NS077274,
NS077303, and NS077276), The Andrew’s Foundation, Finding a Cure for Epilepsy
and Seizures, the Richard Thalheimer Philanthropic Fund and the European
Science Foundation. In addition to his CHOP position, Dr. Dlugos is on the
faculty of the Perelman School of Medicine at the University of Pennsylvania.
Dr. Helbig has an
additional summary of this research on Beyond the lon Channel “the genetics blog of the International League
Against Epilepsy: http://channelopathist.net
“De Novo Mutations in
Synaptic Transmission Genes Including DNM1 Cause Epileptic Encephalopathies,” American
Journal of Human Genetics, published online Sept. 25, 2014, in Oct. 2, 2014
print issue. http://doi.org/10.1016/j.ajhg.2014.08.013
About The Children’s
Hospital of Philadelphia: The Children’s Hospital of Philadelphia was founded
in 1855 as the nation’s first pediatric hospital. Through its long-standing
commitment to providing exceptional patient care, training new generations of
pediatric healthcare professionals and pioneering major research initiatives,
Children’s Hospital has fostered many discoveries that have benefited children
worldwide. Its pediatric research program receives the highest amount of
National Institutes of Health funding among all U.S. children’s hospitals. In
addition, its unique family-centered care and public service programs have brought
the 535-bed hospital recognition as a leading advocate for children and
adolescents.
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