Share or be shared. During the last two weeks, the RES consortium has approved a new data sharing policy that will allow us to work with increased transparency and accountability within our upcoming projects. This new data sharing policy is a consequent extension of the previous protocols we had in earlier consortia – with one major difference. This time, it’s in writing. While we are getting ready to tackle the large dataset on epileptic encephalopathies released by the Sanger Institute, we took a moment to talk about how things should be running.
Category Archives: Brain malformations
Sturge-Weber syndrome explained – somatic mutations in GNAQ
Phakomatoses. There are a group of disorders that affect both the skin and the central nervous system. These disorders, called neurocutaneous disorders or phakomatoses, may result in epilepsy or intellectual disability, depending on the extent to which the brain is affected. While a genetic basis for some neurocutaneous disorders including Tuberous Sclerosis Complex (TSC) and neurofibromatosis is known, the etiology of other neurocutaneous diseases remains unknown. Now, a recent paper in the New England Journal of Medicine reports on the genetic alterations underlying one of the most common neurocutaneous disorders, Sturge-Weber syndrome. Continue reading
STRADA mutations, mTOR activation and personalized medicine using rapamycin
Rapamycin. The mTOR pathway, known through its role in Tuberous Sclerosis Complex (TSC), becomes increasingly important in epilepsy. A wide range of epilepsies caused by brain malformations are due to mutations in genes involved in this pathway, and several neurodevelopmental disorders associated with macrocephaly, intellectual disability and epilepsy are known, where components of this pathway are altered due to germline mutations. For one of these disorders named PMSE (polyhydramnios, megalencephaly and symptomatic epilepsy), a recent paper in Science Translational Medicine reports the effects of treatment with rapamycin, an mTOR inhibitor. The results demonstrate that personalized medicine might in part be promising, asexisting drugs can be used in rare genetic diseases. Continue reading
Hypermutability of autism genes: lessons from genome sequencing
Pushing past the exome. Family exome sequencing has become a standard technology to identify de novo mutations in neurodevelopmental disorders including autism, schizophrenia, intellectual disability and epilepsy. Despite the many advances in the field, exome data is confusing and difficult to interpret. Accordingly, we were wondering what the increase from exome sequencing to genome sequencing might add other than more data and more questions. Now, a recent paper in Cell reports on family-based whole-genome sequencing in autism. And some of the results are quite surprising. Continue reading
CASK aberrations in Ohtahara syndrome
Suppression-burst. Ohtahara Syndrome is a rare epileptic encephalopathy with onset in the first weeks of life. The typical EEG feature of Ohtahara Syndrome is suppression-burst activity, suggesting a profound disruption of cerebral function. Ohtahara Syndrome can be caused by severe brain malformations and neurometabolic disorders. In addition, mutations in ARX and STXBP1 are known causes of Ohtahara Syndrome. In a recent publication in Epilepsia, genetic alterations in CASK were identified in patients with Ohtahara Syndrome and cerebellar hypoplasia. Given that CASK mutations are the known cause for a complex X-chromosomal disorder, this report provides us with an interesting example of what happens when genes underlying distinct clinical dysmorphology syndromes cross over to the epilepsies. Continue reading
The Hippocampus Conspiracy
Slightly misleading. The green and blue histological staining that has become the EuroEPINOMICS logo features a human hippocampus, a part of the human brain that is particularly important in human epilepsy. Temporal Lobe Epilepsy (TLE) is the most common epilepsy in adults and involves the hippocampal region. Ironically, TLE is the human epilepsy that has always been at odds with genetic research. Let’s review what we know about the genetics of TLE and “hippocampal genetics”. Continue reading
A new twist on an old gene: EFHC1 in epileptic encephalopathy
A peculiar gene. There is one gene in the small world of epilepsy genetics that has always troubled me. A gene that has an unknown function and is not expressed in the postnatal brain, but is well established as one of the few genes for autosomal dominant Juvenile Myoclonic Epilepsy (JME). This gene is EFHC1. Now, a recent paper in Epilepsia reports EFHC1 as a possible candidate gene in autosomal recessive epileptic encephalopathy with neonatal onset. The mystery surrounding this gene continues. Continue reading
Jumping genes in the brain – single neuron sequencing of L1 retrotransposons
The not so static genome. We usually think that our genome is static and that differences between cell types usually arise through mechanisms that do not necessarily involve alterations of the DNA structure. This suggestion has been challenged by initial data suggesting that retrotransposons may be particulary active in neurones. Now, a recent study in Cell investigates the role of jumping genes using single-cell sequencing of neurons.
Genome meets Connectome: gene networks and brain microstructure
Genetic imaging. There are two major fields in epilepsy research – functional imaging and genetics. Both fields live parallel lives and hardly ever interact. When they do, the interaction is usually short-lived and full of disappointments, as nothing has really ever worked. However, a grant application due today has led me to a recent publication in the Journal of Neuroscience, which combines imaging and GWAS. And believe it or not, the ion channels are back. Continue reading
Face to face – atypical face shape and CNVs in epilepsy
Face scan. A large high-tech camera scans your face in 3D and – using more than 30,000 data points – extracts information from your face that you were not aware of including details of your genetic make-up. What sounds like dystopic Gattaca-like science fiction at first is actually an interesting novel technique to learn more about epilepsy-related microdeletions. It seems that some of their effects might be hidden in subtle facial features that might help understand how these genetic variants contribute to disease. Continue reading