Genomic <scp>DNA</scp> methylation distinguishes subtypes of human focal cortical dysplasia

Kobow, Katja; Ziemann, Mark; Kaipananickal, Harikrishnan; Khurana, Ishant; Mühlebner, Angelika; Feucht, Martha; Hainfellner, Johannes A.; Czech, Thomas; Aronica, Eleonora; Pieper, Tom; Holthausen, Hans; Kudernatsch, Manfred; Hamer, Hajo M.; Kasper, Burkhard S.; Rössler, Karl; Conti, Valerio; Guerrini, Renzo; Coras, Roland; Blümcke, Ingmar; El‐Osta, Assam; Kaspi, Antony

doi:10.1111/epi.14934

Cited by 63 publications

(95 citation statements)

References 52 publications

(108 reference statements)

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“…We performed unsupervised dimensionality reduction and hierarchical cluster analysis. In addition to previously described FCD and TLE specific methylation classes [36], PMG in our analysis formed a novel separate cluster in the UMAP dimensionality reduction (Fig. 1a).…”

Section: Novel Methylation Cluster Defines Pmg Among Other MCDsupporting

confidence: 61%

“…It can further provide certain information on chromosomal imbalances, and inform about molecular pathways underlying disease development. This has been proven to variable extent in brain tumors and major subtypes of focal cortical dysplasia (FCD) [32,36,53,57]. We hypothesized that the determination of DNA methylation signatures might help distinguish PMG from other related hemispheric and focal MCD and identify PMG subtypes with specific molecular and clinical features.…”

Section: Introductionmentioning

confidence: 99%

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Mosaic trisomy of chromosome 1q in human brain tissue associates with unilateral polymicrogyria, very early-onset focal epilepsy, and severe developmental delay

Kobow

Jabari

Pieper

et al. 2020

Preprint

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Polymicrogyria (PMG) is a developmental cortical malformation characterized by an excess of small and frustrane gyration and abnormal cortical lamination. PMG frequently associates with seizures. The molecular pathomechanisms underlying PMG development are not yet understood. About 40 genes have been associated with PMG, and small copy number variations have also been described in selected patients. We recently provided evidence that epilepsy-associated structural brain lesions can be classified based on genomic DNA methylation patterns. Here we analyzed 26 PMG patients employing array-based DNA-methylation profiling on formalin-fixed paraffin-embedded material. A series of 62 well-characterized non-PMG cortical malformations (focal cortical dysplasia type 2a/b and hemimegalencephaly), temporal lobe epilepsy, and non-epilepsy autopsy controls was used as reference cohort. Unsupervised dimensionality reduction and hierarchical cluster analysis of DNA methylation profiles showed that PMG formed a distinct DNA methylation class. Copy number profiling from DNA methylation data identified a uniform duplication spanning the entire long arm of chromosome 1 in 7 out of 26 PMG patients, which was verified by additional fluorescence in situ hybridization analysis. In respective cases about 50% of nuclei in the center of the PMG lesion were 1q triploid. No chromosomal imbalance was seen in adjacent, architecturally normal-appearing tissue indicating mosaicism. Clinically, PMG 1q patients presented with a unilateral frontal or hemispheric PMG without hemimegalencephaly, a severe form of intractable epilepsy with seizure onset in the first months of life, and severe developmental delay. Our results show that PMG can be classified among other structural brain lesions according to their DNA methylation profile. One subset of PMG with distinct clinical features exhibits a duplication of chromosomal arm 1q.

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Section: Novel Methylation Cluster Defines Pmg Among Other MCDsupporting

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Mosaic trisomy of chromosome 1q in human brain tissue associates with unilateral polymicrogyria, very early-onset focal epilepsy, and severe developmental delay

Kobow

Jabari

Pieper

et al. 2020

Preprint

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“…Data-driven (unsupervised) classification techniques are particularly useful for extracting information from unclassified patterns, or during an exploratory phase of pattern recognition. Kobow and colleagues were able to show that major FCD subtypes can be discriminated from each other as well as from non-FCD epilepsy (ie, patients with TLE) and nonepilepsy autopsy controls based on their epigenomic signature, 37 thereby recapitulating previous results obtained in experimental epilepsy models. 29,32 Thus, the approach appears promising with regard to the identification of diagnostic molecular biomarkers.…”

Section: Dna (Sequence) Is Not Destinysupporting

confidence: 60%

“…Thereby, one genome gives rise to several "epigenomes" and consequently phenotypes. 37 The aim was to identify potential molecular biomarkers based on DNA methylation that could help stratify patients according to seizure phenotype and associated pathology. [24][25][26][27][28][29][30][31][32] Massive parallel sequencing and improved molecular and computational analysis allow advanced profiling of the genome, exome, and transcriptome together with all different layers of the epigenome, opening new avenues to decipher complex disease pathomechanisms.…”

Section: Dna (Sequence) Is Not Destinymentioning

confidence: 99%

“…Kobow et al recently performed genome-wide DNA methylation profiling in tissue from patients with focal cortical dysplasia (FCD), patients with TLE, and no-seizure controls. 37 The aim was to identify potential molecular biomarkers based on DNA methylation that could help stratify patients according to seizure phenotype and associated pathology. To aid biomarker identification, they performed multidimensional scaling and hierarchical cluster analysis, to reduce the high dimensionality of the data and identify unbiased subgroups within the data.…”

Section: Dna (Sequence) Is Not Destinymentioning

confidence: 99%

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2017 WONOEP appraisal: Studying epilepsy as a network disease using systems biology approaches

et al. 2019

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The revolution in high‐throughput omics technologies has dramatically expanded our understanding of the epilepsies as complex diseases. It is now clear that further progress in treating the full spectrum of seizure disorders requires a systems‐level framework for analyzing and integrating data from multiple omics technologies that moves beyond the search for single molecular alterations to an understanding of dysregulated pathways in epilepsy. Taking such a pathway‐centered view requires further integrating the tools of systems biology into epilepsy research. In this appraisal, we highlight and summarize systems biology approaches in basic epilepsy studies as they were discussed during the 2017 Workshop on the Neurobiology of Epilepsy (WONOEP). During the 3‐day event, participants exchanged emerging results and thoughts on developing the systems biology of epilepsy, and the promise and limitations of these approaches for the near term.

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Assessing the role of rare genetic variants in drug‐resistant, non‐lesional focal epilepsy

Wolking

Moreau

McCormack

et al. 2021

Ann Clin Transl Neurol

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Objective: Resistance to antiseizure medications (ASMs) is one of the major concerns in the treatment of epilepsy. Despite the increasing number of ASMs available, the proportion of individuals with drug-resistant epilepsy remains unchanged. In this study, we aimed to investigate the role of rare genetic variants in ASM resistance. Methods: We performed exome sequencing of 1,128 individuals with non-familial non-acquired focal epilepsy (NAFE) (762 nonresponders, 366 responders) and were provided with 1,734 healthy controls. We undertook replication in a cohort of 350 individuals with NAFE (165 nonresponders, 185 responders). We performed gene-based and gene-set-based kernel association tests to investigate potential enrichment of rare variants in relation to drug response status and to risk for NAFE. Results: We found no gene or gene set that reached genome-wide significance. Yet, we identified several 1376

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Genomic DNA methylation distinguishes subtypes of human focal cortical dysplasia

Cited by 63 publications

References 52 publications

Mosaic trisomy of chromosome 1q in human brain tissue associates with unilateral polymicrogyria, very early-onset focal epilepsy, and severe developmental delay

Mosaic trisomy of chromosome 1q in human brain tissue associates with unilateral polymicrogyria, very early-onset focal epilepsy, and severe developmental delay

2017 WONOEP appraisal: Studying epilepsy as a network disease using systems biology approaches

Assessing the role of rare genetic variants in drug‐resistant, non‐lesional focal epilepsy

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