The microdeletion landscape of Genetic Generalized Epilepsy

CNV. Structural genomic variations or Copy Number Variations (CNVs) significantly contribute to the genetic architecture of many neurodevelopmental disorders. However, given the enormous variation in the human genome in healthy individuals, the precise contribution of CNVs remains poorly understood. In a recent publication in PLOS Genetics, we were able to assess the microdeletion architecture in more than 1,000 patients with Genetic Generalized Epilepsy (GGE) compared to more than 5,000 controls. We found that microdeletions occur almost twice as often in GGE patients compared to controls, an analysis that revealed both known suspects and interesting candidates. Continue reading

Epi25 – breaking the genetic sound barrier

25,000 genomes. The epilepsy community is currently preparing for the largest sequencing project in the epilepsies so far, responding to a call by the National Human Genome Research Institute (NHGRI). If funded, the Epi25 project will allow us to begin sequencing 25,000 individuals with epilepsy, helping us to achieve the next, necessary level for gene discovery in human epilepsies. Here are some of the reasons why we need Epi25 and why you should be part of it. Continue reading

Switching inhibition on – SLC12A5/KCC2 variants in human epilepsy

Inhibition. We usually like to think of GABA as an inhibitory neurotransmitter, which counteracts the excitatory and potentially epileptogenic effects of glutamate. However, this is not always true during brain development. Initially, GABA is a powerful excitatory neurotransmitter. The excitatory effect of GABA has been shown to be important for brain development and the formation of dendritic spines – and the switch from excitation to inhibition is due to a single ion channel: KCC2, encoded by SLC12A5. Two recent publications in EMBO Reports now implicate genetic variation in SLC12A5 in human epilepsy. Continue reading

An inconvenient truth – segregation of monogenic variants in small families

Climate change. In the era of exome and genome sequencing, it might be worthwhile revisiting the merit of family studies in epilepsy research. Seizure disorders are known to have a highly diverse genetic architecture. When singleton studies identify a single, unique gene finding, this discovery usually does not provide much information about the potential causal role of the variant given the high degree of genomic noise. In contrast, family studies are usually considered more robust, as segregation of variants can be traced. Here is the inconvenient truth: unless the family is very large, segregation of possibly monogenic variants adds little information given the vast amount of variants present in our genomes. Continue reading

Navigating the epilepsiome – live from Tübingen

2D. I am writing this post during our EuroEPINOMICS meeting in Tübingen listening to presentation from CoGIE, the EuroEPINOMICS project working on IGE/GGE and Rolandic Epilepsies and RES, the project on rare epilepsies. At some point during the afternoon, I made my selection for the best graph during the presentations today – an overview of the conservation space of epilepsy genes. Continue reading

Identifying core phenotypes – epilepsy, ID and recurrent microdeletions

Triad. There are three microdeletions in particular that increase the risk for the Idiopathic/Genetic Generalized Epilepsies (IGE/GGE). This triad includes microdeletions at 15q13.3, 16p13.11 and 15q11.2, which are hotspot deletions arising from the particular architecture of the human genome. While the association of these microdeletions with epilepsy and other neurodevelopmental disorders including autism, intellectual disability and schizophrenia is well established, the core phenotype of these variants remains elusive, including the question whether such a core phenotype actually exists. In a recent paper in Neurology, Mullen and collaborators zoom in on a possible core phenotype of these microdeletions. The authors investigate a phenotype in which these microdeletions are particularly enriched: generalized epilepsy with intellectual disability. Continue reading

“Meta-channelopathies” – RBFOX1 deletions and human epilepsy

Man is built to seize. When Hughlings Jackson made this famous comment pertaining to the inherent hyperexcitability of the human brain in response to a wide range of different stimuli, he probably didn’t anticipate the mechanisms of splicing regulation. Our CNS is actively protected from hyperexcitability through directed splicing of ion channel mRNA. Now, a recent study in Epilepsia finds that these mechanisms may be dysfunctional in human epilepsy. Continue reading

NRXN1 deletions and the double hit hypothesis of idiopathic epilepsy

Old friends. Structural genomic variants or Copy Number Variations (CNVs) play an important role in many neurodevelopmental disorders including epilepsy, autism, schizophrenia and intellectual disability. Many of the CNVs representing genetic risk factors overlap between these diseases. Now, a recent study in Epilepsia reports on the exon-disrupting deletions in NRXN1 as genetic risk factors for Idiopathic Generalised Epilepsy. NRNX1 deletions were previously reported in several other neurodevelopmental disorders. However, there is an interesting and unanticipated twist to the story. Continue reading