Publications of the week: genetics of Infantile Spasms, CERS1, DYRK1A, and hyaluronan

This week in epilepsy genetics. The following publications might be relevant for you, as they demonstrate what happened in the field of epilepsy genetics in the last two weeks. The publications range from basic science studies in extracellular space to novel gene discoveries. I have added a brief comment to each of these studies. Continue reading

Living in a post-linkage world, craving knowledge

Genomics meets linkage. This blog post is about family studies in epilepsy genetics. One of my tasks for the next two months is to write the “Trilateral Grant” – we were invited to submit a full proposal for a German-Israeli-Palestinian grant by the German Research Foundation (DFG) on the genetics of familial epilepsies. As keeping up our blogging schedule will be my other big task for the coming months, I thought that I could combine both and explore some topics regarding family studies on this blog. Let’s start with a sobering fact – small dominant families remain difficult to solve, not because of too little but rather too much genetic data. Continue reading

The OMIM epileptic encephalopathy genes – a 2014 review

EIEE1-19. Online Mendelian Inheritance in Man (OMIM) is one of the most frequently accessed online databases for information on genetic disorders. Genes for epileptic encephalopathies are organized within a phenotypic series entitled Early Infantile Epileptic Encephalopathy (EIEE). The EIEE phenotypic series currently lists 19 genes (EIEE1-19). Let’s review the evidence for these genes as of 2014. Continue reading

The final EuroEPINOMICS General Assembly – Impressions from Helsinki

Time flies by. Last week, we have had the final General Assembly of the EuroEPINOMICS project in Tuusula, Finland. All four projects of the EuroEPINOMICS consortium presented the current, ongoing projects and it’s good to hear that there are multiple publications in various stages coming up. Over the three years of the consortium, the diverse groups grew closer together. During this meeting many unpublished results were shown, including extension of studies on genes such as HCN1, CHD2GRIN2A, GRIN2B or RBFOX1 as well as more data on epigenetics in acquired epilepsy.

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SLC25A22, migrating seizures and mitochrondial glutamate deficiency

MPSI. Migrating partial seizures of infancy (MPSI) are a catastrophic form of infantile epilepsy that was entirely unexplained until de novo mutations in KCNT1 were identified in a subset of sporadic cases in 2012. For familial MPSI, however, the genetic basis remained unknown. In a recent publication in Annals of Neurology, Poduri and collaborators identify mutations in SCL25A22 in a family with recessive MPSI. Their study sheds light on the genetic basis of catastrophic epilepsies and the phenotypic range of mitochondrial glutamate starvation. Continue reading

The many faces of PIGA – from paroxysmal nocturnal hemoglobinuria to epileptic encephalopathy

PNH. PIGA codes for a protein involved in the early steps of GPI anchor synthesis, hydrophobic anchors that are attached to a range of proteins, which allows them to be attached to the membrane. This mechanism is important for protein sorting in the endoplasmatic reticulum and the Golgi apparatus. Acquired mutations in PIGA are known to cause paroxysmal nocturnal hemoglobinuria (PNH), an anemia due to destruction of red blood cells. In a recent paper in Neurology, de novo mutations in PIGA are now identified in a complex genetic syndrome, which has early-onset intractable epilepsy as the most prominent feature. Continue reading

Papers of the week – SCN1B, ATP1A3, NGLY1, and ontologies

Filling in. As Dennis is current fully engaged in the Helsinki meeting, I am filling in for him to present the most relevant publications in the field published in the last two weeks. This week’s publications were about functional studies, phenotype delineations, and novel gene findings. Continue reading

The return of the h-current: HCN1 mutations in atypical Dravet Syndrome

Hyperpolarization. More than a quarter of a century ago, physiologists identified an electrical current in neurons and cardiac myocytes that behaved so strangely that it was called the “queer” or “funny” current: it paradoxically caused depolarization upon hyperpolarization. This current was finally named h-current and is mediated by HCN channels. The h-current has been associated with epilepsy through functional studies, but a genetic link has been elusive so far. In a recent publication in Nature Genetics, de novo mutations in HCN1 are identified in patients with early-onset epileptic encephalopathies resembling Dravet Syndrome. Continue reading

Imbalance of a rare second messenger – FIG4 mutations in polymicrogyria

Brain malformations. Various brain malformations are thought to have a genetic basis, and several genes have already been identified. Polymicrogyria is a particular form of congenital brain malformation due to an excessive number of small and sometimes malformed gyri. In a recent publication in Neurology, mutations in FIG4 are described in a familial form of polymicrogyria. However, the FIG4 gene is no stranger in the field of neurogenetics. Continue reading

Popper, Kuhn, and the paradigm shifts of the genomic revolution

Paradigm shifts no more. During our bioinformatics workshop in Leuven, Roland pointed out that I tend to use the phrase “paradigm shift” too liberally. In fact, the concept of paradigm changes in science was made popular by Thomas Kuhn, an American physicist, historian, and philosopher of science. Kuhn believed that scientists work within a given set of paradigms and believes that they don’t really question them – until everything falls apart. Let me take you on a brief journey through the philosophy of genomics starting with Kuhn’s nemesis, Karl Popper. Continue reading