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- Title
Deep sequencing reveals increased DNA methylation in chronic rat epilepsy.
- Authors
Kobow, Katja; Kaspi, Antony; Harikrishnan, K.; Kiese, Katharina; Ziemann, Mark; Khurana, Ishant; Fritzsche, Ina; Hauke, Jan; Hahnen, Eric; Coras, Roland; Mühlebner, Angelika; El-Osta, Assam; Blümcke, Ingmar
- Abstract
Epilepsy is a frequent neurological disorder, although onset and progression of seizures remain difficult to predict in affected patients, irrespective of their epileptogenic condition. Previous studies in animal models as well as human epileptic brain tissue revealed a remarkably diverse pattern of gene expression implicating epigenetic changes to contribute to disease progression. Here we mapped for the first time global DNA methylation patterns in chronic epileptic rats and controls. Using methyl-CpG capture associated with massive parallel sequencing (Methyl-Seq) we report the genomic methylation signature of the chronic epileptic state. We observed a predominant increase, rather than loss of DNA methylation in chronic rat epilepsy. Aberrant methylation patterns were inversely correlated with gene expression changes using mRNA sequencing from same animals and tissue specimens. Administration of a ketogenic, high-fat, low-carbohydrate diet attenuated seizure progression and ameliorated DNA methylation mediated changes in gene expression. This is the first report of unsupervised clustering of an epigenetic mark being used in epilepsy research to separate epileptic from non-epileptic animals as well as from animals receiving anti-convulsive dietary treatment. We further discuss the potential impact of epigenetic changes as a pathogenic mechanism of epileptogenesis.
- Subjects
EPILEPSY research; NUCLEOTIDE sequence; DNA methylation; ANIMAL disease models; GENE expression; EPILEPSY in animals
- Publication
Acta Neuropathologica, 2013, Vol 126, Issue 5, p741
- ISSN
0001-6322
- Publication type
Article
- DOI
10.1007/s00401-013-1168-8