BCOR variants are associated with X-linked recessive partial epilepsy.

OBJECTIVE: BCOR gene, encoding a corepressor of BCL6, plays an important role in fetal development. BCOR mutations were previously associated with oculofaciocardiodental syndrome (OFCD or MCOPS2, OMIM# 300166). The BCOR protein is ubiquitously expressed in multiple areas, including the brain. However, the role of BCOR in neurological disorder remains elusive. METHODS: Trios-based whole-exome sequencing was performed in a cohort of 323 cases with partial epilepsy without acquired causes. RESULTS: Seven hemizygous missense BCOR variants, including c 0.103 G>C/p.Asp35His, c.1079 A>G/p.His360Arg, c 0.1097 C>T/p.Thr366Ile, c 0.3301 C>T/p.Pro1101Ser, c 0.3391 C>T/p.Arg1131Trp, c 0.4199 G>A/p.Arg1400Gln, and c 0.5254 G>A/p.Asp1752Asn, were identified in seven cases with partial epilepsy. Two patients presented partial seizures with generalized seizures and/or generalized discharges. One case showed cortical dysplasia in the right temporal-occipital area on MRI. Two cases presented mild developmental delay. However, all patients achieved seizure-free. The frequency of BCOR variants in the present cohort was significantly higher than that in the controls of healthy Chinese volunteers and all populations of Genome Aggregation Database (gnomAD). Computational modeling, including hydrogen bond and prediction of protein stability, implied that the variants lead to structural impairment. Previously, OFCD associated BCOR mutations were mostly destructive mutations in an X-linked dominant (XLD) pattern; in contrast, the BCOR variants identified in this study were all missense variants, which were associated with partial epilepsy in an X-linked recessive (XLR) pattern. The proportion of missense mutations in epilepsy was significantly higher than that in OFCD. CONCLUSIONS: BCOR was potentially a candidate pathogenic gene of partial epilepsy with or without developmental delay. The genotype-phenotype correlation helps understanding the mechanism underlying phenotypic variation.

CHD4 variants are associated with childhood idiopathic epilepsy with sinus arrhythmia.

AIMS: CHD4 gene, encoding chromodomain helicase DNA-binding protein 4, is a vital gene for fetal development. In this study, we aimed to explore the association between CHD4 variants and idiopathic epilepsy. METHODS: Trios-based whole-exome sequencing was performed in a cohort of 482 patients with childhood idiopathic epilepsy. The Clinical Validity Framework of ClinGen and an evaluating method from five clinical-genetic aspects were used to determine the association between CHD4 variants and epilepsy. RESULTS: Four novel heterozygous missense mutations in CHD4, including two de novo mutations (c.1597A>G/p.K533E and c.4936G>A/p.E1646K) and two inherited mutations with co-segregation (c.856C>G/p.P286A and c.4977C>G/p.D1659E), were identified in four unrelated families with eight individuals affected. Seven affected individuals had sinus arrhythmia. From the molecular sub-regional point of view, the missense mutations located in the central regions from SNF2-like region to DUF1087 domain were associated with multisystem developmental disorders, while idiopathic epilepsy-related mutations were outside this region. Strong evidence from ClinGen Clinical Validity Framework and evidences from four of the five clinical-genetic aspects suggested an association between CHD4 variants and epilepsy. CONCLUSIONS: CHD4 was potentially a candidate pathogenic gene of childhood idiopathic epilepsy with arrhythmia. The molecular sub-regional effect of CHD4 mutations helped explaining the mechanisms underlying phenotypic variations.