A polygenic trickle of rare disruptive variants in schizophrenia

Polygenic. Schizophrenia is a complex neurodevelopmental disorder that is assumed to be caused by a mixture of genetic and non-genetic factors. The genetic component in schizophrenia is thought to be polygenic, i.e. due to the interaction of multiple genetic factors. Rare variants may play a particular role in this presumable polygenic genetic architecture, but so far this component of the genetic morbidity has been hard to pin down. Now, a recent study in Nature explores the role of rare, disruptive mutations in schizophrenia using large-scale population-based exome sequencing. Let’s find out about a new level of exome-wide honesty and why even a gene with 10 disruptive mutations in cases and none in controls is only mentioned in passing. Continue reading

CACNA2D2, the ducky mouse, and what it takes to be an epilepsy gene

Subunit. Spontaneous mouse mutants help to identify candidate genes for disease mechanisms and have hinted at an important role for ion channels in epilepsy long before the first human channelopathies were identified. The ducky mouse has absence seizures and suffers from ataxia. A truncation mutation in CACNA2D2 could be identified in this phenotype, encoding for an auxiliary calcium channel subunit. This finding emphasizes the role of calcium channels in absence seizures and begs the question whether genetic variation in CACNA2D2 is also involved in human epilepsy. A recent publication in PLOS One now identifies the second recessive CACNA2D2 mutation in a patient with epileptic encephalopathy. But are two independent cases sufficient anymore to claim causality? Continue reading

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