SHROOM4 Variants Are Associated With X-Linked Epilepsy With Features of Generalized Seizures or Generalized Discharges

CCDC22 variants caused X-linked focal epilepsy and focal cortical dysplasia

BACKGROUND

The CCDC22 gene plays vital roles in regulating the NF-κB pathway, an essential pathway for neuroinflammation, neurodevelopment, and epileptogenesis. Previously, variants in CCDC22 were reported to be associated with intellectual disability. This study aimed to explore the association between CCDC22 and epilepsy.

METHODS

Trios-based whole-exome sequencing (WES) was performed in a cohort of patients with epilepsy of unknown cause recruited from the China Epilepsy Gene 1.0 Project. Damaging effects of variants were analysed using protein modelling.

RESULTS

Hemizygous missense CCDC22 variants were identified in three unrelated cases. These variants had no hemizygous frequencies in controls. All missense variants identified in this study were predicted to be "damaging" by multiple in silico tools and to alter the hydrogen bonds with surrounding residues and/or protein stability. The three patients presented with focal epilepsy of varying severity, including one with refractory seizures and focal cortical dysplasia (FCD) and two with seizures responding to antiseizure medicine. Notably, the variant associated with the severe phenotype was located in the coiled-coil domain and predicted to alter hydrogen bonding and protein stability, whereas the two variants associated with mild epilepsy were located outside functional domains and had moderate molecular alterations. Analysis of spatiotemporal expression indicated that CCDC22 was expressed in brain subregions with three peaks in the fetal stage, infancy, and early adulthood, especially in the fetal stage, explaining the occurrence of developmental abnormities.

SIGNIFICANCE

CCDC22 variants are potentially associated with X-linked focal epilepsy and FCD. The molecular subregional effects supported the occurrence of FCD.

Epilepsy-associated genes: an update

PURPOSE

To provide an updated list of epilepsy-associated genes based on clinical-genetic evidence.

METHODS

Epilepsy-associated genes were systematically searched and cross-checked from the OMIM, HGMD, and PubMed databases up to July 2023. To facilitate the reference for the epilepsy-associated genes that are potentially common in clinical practice, the epilepsy-associated genes were ranked by the mutation number in the HGMD database and by case number in the China Epilepsy Gene 1.0 project, which targeted common epilepsy.

RESULTS

Based on the OMIM database, 1506 genes were identified to be associated with epilepsy and were classified into three categories according to their potential association with epilepsy or other abnormal phenotypes, including 168 epilepsy genes that were associated with epilepsies as pure or core symptoms, 364 genes that were associated with neurodevelopmental disorders as the main symptom and epilepsy, and 974 epilepsy-related genes that were associated with gross physical/systemic abnormalities accompanied by epilepsy/seizures. Among the epilepsy genes, 115 genes (68.5%) were associated with epileptic encephalopathy. After cross-checking with the HGMD and PubMed databases, an additional 1440 genes were listed as potential epilepsy-associated genes, of which 278 genes have been repeatedly identified variants in patients with epilepsy. The top 100 frequently reported/identified epilepsy-associated genes from the HGMD database and the China Epilepsy Gene 1.0 project were listed, among which 40 genes were identical in both sources.

SIGNIFICANCE

Recognition of epilepsy-associated genes will facilitate genetic screening strategies and be helpful for precise molecular diagnosis and treatment of epilepsy in clinical practice.

DLG3 variants caused X-linked epilepsy with/without neurodevelopmental disorders and the genotype-phenotype correlation

Background

The DLG3 gene encodes disks large membrane-associated guanylate kinase scaffold protein 3, which plays essential roles in the clustering of N-methyl-D-aspartate receptors (NMDARs) at excitatory synapses. Previously, DLG3 has been identified as the causative gene of X-linked intellectual developmental disorder-90 (XLID-90; OMIM# 300850). This study aims to explore the phenotypic spectrum of DLG3 and the genotype-phenotype correlation.

Methods

Trios-based whole-exome sequencing was performed in patients with epilepsy of unknown causes. To analyze the genotype-phenotype correlations, previously reported DLG3 variants were systematically reviewed.

Results

DLG3 variants were identified in seven unrelated cases with epilepsy. These variants had no hemizygous frequencies in controls. All variants were predicted to be damaging by silico tools and alter the hydrogen bonds with surrounding residues and/or protein stability. Four cases mainly presented with generalized seizures, including generalized tonic-clonic and myoclonic seizures, and the other three cases exhibited secondary generalized tonic-clonic seizures and focal seizures. Multifocal discharges were recorded in all cases during electroencephalography monitoring, including the four cases with generalized discharges initially but multifocal discharges after drug treating. Protein-protein interaction network analysis revealed that DLG3 interacts with 52 genes with high confidence, in which the majority of disease-causing genes were associated with a wide spectrum of neurodevelopmental disorder (NDD) and epilepsy. Three patients with variants locating outside functional domains all achieved seizure-free, while the four patients with variants locating in functional domains presented poor control of seizures. Analysis of previously reported cases revealed that patients with non-null variants presented higher percentages of epilepsy than those with null variants, suggesting a genotype-phenotype correlation.

Significance

This study suggested that DLG3 variants were associated with epilepsy with/without NDD, expanding the phenotypic spectrum of DLG3. The observed genotype-phenotype correlation potentially contributes to the understanding of the underlying mechanisms driving phenotypic variation.

X-linked variations inSHROOM4are implicated in congenital anomalies of the urinary tract and the anorectal, cardiovascular and central nervous systems

Background

SHROOM4is thought to play an important role in cytoskeletal modification and development of the early nervous system. Previously, single-nucleotide variants (SNVs) or copy number variations (CNVs) inSHROOM4have been associated with the neurodevelopmental disorder Stocco dos Santos syndrome, but not with congenital anomalies of the urinary tract and the visceral or the cardiovascular system.

Methods

Here, exome sequencing and CNV analyses besides expression studies in zebrafish and mouse andknockdown(KD) experiments using a splice blocking morpholino in zebrafish were performed to study the role ofSHROOM4during embryonic development.

Results

In this study, we identified putative disease-causing SNVs and CNVs inSHROOM4in six individuals from four families with congenital anomalies of the urinary tract and the anorectal, cardiovascular and central nervous systems (CNS). Embryonic mouse and zebrafish expression studies showedShroom4expression in the upper and lower urinary tract, the developing cloaca, the heart and the cerebral CNS. KD studies in zebrafish larvae revealed pronephric cysts, anomalies of the cloaca and the heart, decreased eye-to-head ratio and higher mortality compared with controls. These phenotypes could be rescued by co-injection of human wild-typeSHROOM4mRNA and morpholino.

Conclusion

The identified SNVs and CNVs in affected individuals with congenital anomalies of the urinary tract, the anorectal, the cardiovascular and the central nervous systems, and subsequent embryonic mouse and zebrafish studies suggestSHROOM4as a developmental gene for different organ systems.