Aziz Mazarib

X-linked protocadherin 19 mutations cause female-limited epilepsy and cognitive impairment.

Epilepsy and mental retardation limited to females (EFMR) is a disorder with an X-linked mode of inheritance and an unusual expression pattern. Disorders arising from mutations on the X chromosome are typically characterized by affected males and unaffected carrier females. In contrast, EFMR spares transmitting males and affects only carrier females. Aided by systematic resequencing of 737 X chromosome genes, we identified different protocadherin 19 (PCDH19) gene mutations in seven families with EFMR. Five mutations resulted in the introduction of a premature termination codon. Study of two of these demonstrated nonsense-mediated decay of PCDH19 mRNA. The two missense mutations were predicted to affect adhesiveness of PCDH19 through impaired calcium binding. PCDH19 is expressed in developing brains of human and mouse and is the first member of the cadherin superfamily to be directly implicated in epilepsy or mental retardation.

Missense mutations in the sodium-gated potassium channel gene KCNT1 cause severe autosomal dominant nocturnal frontal lobe epilepsy

We performed genomic mapping of a family with autosomal dominant nocturnal frontal lobe epilepsy (ADNFLE) and intellectual and psychiatric problems, identifying a disease-associated region on chromosome 9q34.3. Whole-exome sequencing identified a mutation in KCNT1, encoding a sodium-gated potassium channel subunit. KCNT1 mutations were identified in two additional families and a sporadic case with severe ADNFLE and psychiatric features. These findings implicate the sodium-gated potassium channel complex in ADNFLE and, more broadly, in the pathogenesis of focal epilepsies.

A Homozygous Mutation in Human PRICKLE1 Causes an Autosomal-Recessive Progressive Myoclonus Epilepsy-Ataxia Syndrome

Progressive myoclonus epilepsy (PME) is a syndrome characterized by myoclonic seizures (lightning-like jerks), generalized convulsive seizures, and varying degrees of neurological decline, especially ataxia and dementia. Previously, we characterized three pedigrees of individuals with PME and ataxia, where either clinical features or linkage mapping excluded known PME loci. This report identifies a mutation in PRICKLE1 (also known as RILP for REST/NRSF interacting LIM domain protein) in all three of these pedigrees. The identified PRICKLE1 mutation blocks the PRICKLE1 and REST interaction in vitro and disrupts the normal function of PRICKLE1 in an in vivo zebrafish overexpression system. PRICKLE1 is expressed in brain regions implicated in epilepsy and ataxia in mice and humans, and, to our knowledge, is the first molecule in the noncanonical WNT signaling pathway to be directly implicated in human epilepsy.

Epilepsy and mental retardation limited to females: an under-recognized disorder

Epilepsy and Mental Retardation limited to Females (EFMR) which links to Xq22 has been reported in only one family. We aimed to determine if there was a distinctive phenotype that would enhance recognition of this disorder. We ascertained four unrelated families (two Australian, two Israeli) where seizures in females were transmitted through carrier males. Detailed clinical assessment was performed on 58 individuals, using a validated seizure questionnaire, neurological examination and review of EEG and imaging studies. Gene localization was examined using Xq22 microsatellite markers. Twenty-seven affected females had a mean seizure onset of 14 months (range 6-36) typically presenting with convulsions. All had convulsive attacks at some stage, associated with fever in 17 out of 27 (63%). Multiple seizure types occurred including tonic-clonic (26), tonic (4), partial (11), absence (5), atonic (3) and myoclonic (4). Seizures ceased at mean 12 years. Developmental progress varied from normal (7), to always delayed (4) to normal followed by regression (12). Intellect ranged from normal to severe intellectual disability (ID), with 67% of females having ID or being of borderline intellect. Autistic (6), obsessive (9) and aggressive (7) features were prominent. EEGs showed generalized and focal epileptiform abnormalities. Five obligate male carriers had obsessional tendencies. Linkage to Xq22 was confirmed (maximum lod 3.5 at = 0). We conclude that EFMR is a distinctive, under-recognized familial syndrome where girls present with convulsions in infancy, often associated with intellectual impairment and autistic features. The unique inheritance pattern with transmission by males is perplexing. Clinical recognition is straightforward in multiplex families due to the unique inheritance pattern; however, this disorder should be considered in smaller families where females alone have seizures beginning in infancy, particularly in the setting of developmental delay. In single cases, diagnosis will depend on identification of the molecular basis.

Genetic architecture of idiopathic generalized epilepsy: Clinical genetic analysis of 55 multiplex families

Summary:  Purpose: In families with idiopathic generalized epilepsy (IGE), multiple IGE subsyndromes may occur. We performed a genetic study of IGE families to clarify the genetic relation of the IGE subsyndromes and to improve understanding of the mode(s) of inheritance.

Genetic variation of CACNA1H in idiopathic generalized epilepsy

In a recent report, Chen and colleagues described 12 putative mutations in the T-type calcium channel gene CACNA1H in 14 of 118 patients with childhood absence epilepsy (CAE), and concluded that missense mutations in this gene may predispose to CAE. To investigate variation of CACNA1H in our patient population, we screened exons 9 to 11, in which 75% of the putative mutations described by Chen and colleagues are located, in 192 patients (134 unrelated) with idiopathic generalized epilepsies or generalized epilepsy with febrile seizures plus. This group included 34 CAE and 15 juvenile absence epilepsy patients. The study was approved by the ethics committees of the Women’s and Children’s Hospital and Austin Health. Informed consent was obtained from participants. DNA was amplified by polymerase chain reaction and screened for variation by single-stranded conformation analysis. Sequencing was performed using ABI BigDye v3.0 on the ABI 3700 instrument. Ninety-six control samples were screened for variants identified in patients. When a variant was present in a patient and not in controls, available members of the patient’s family were tested for the variant. Four variants were present only in patients. These were c.1438G3A (A480T); c.1853C3T (P618L); c.18571858del (V621fsX654), and c.2264G3A (G755D). The inheritance of these changes in the families is shown in the Figure. None of these variants was found in CAE or juvenile absence epilepsy patients. None of the four variants segregate with a specific epilepsy phenotype in each family, nor is their presence associated with any one phenotype. There are two instances in which siblings with the same phenotype are discordant for a variant, and all four variants are present in unaffected individuals. Our failure to replicate the findings of Chen and colleagues in absence phenotypes in our patient population suggests that the significance of CACNA1H variants in the cause of human epilepsy remains unclear. Moreover, functional data are required for all CACNA1H variants before their role in epilepsy is established. Generalized epilepsies are likely to be polygenic in origin, with variations in multiple ion-channel subunits or other genes interacting to cause epileptogenesis. For example, a mutation of GABRG2 has been found previously in three members of Family E and it is probable that several genes

LGI1 mutations in temporal lobe epilepsies

Background and Objectives: A number of familial temporal lobe epilepsies (TLE) have been recently recognized. Mutations in LGI1 (leucine-rich, glioma-inactivated 1 gene) have been found in a few families with the syndrome of autosomal dominant partial epilepsy with auditory features (ADPEAF). The authors aimed to determine the spectrum of TLE phenotypes with LGI1 mutations, to study the frequency of mutations in ADPEAF, and to examine the role of LGI1 paralogs in ADPEAF without LGI1 mutations. Methods: The authors performed a clinical and molecular analysis on 75 pedigrees comprising 54 with a variety of familial epilepsies associated with TLE and 21 sporadic TLE cases. All were studied for mutations in LGI1. ADPEAF families negative for LGI1 mutations were screened for mutations in LGI2, LGI3, and LGI4. Results: Four families had ADPEAF, 22 had mesial TLE, 11 had TLE with febrile seizures, two had TLE with developmental abnormalities, and 15 had various other TLE syndromes. LGI1 mutations were found in two of four ADPEAF families, but in none of the other 50 families nor in the 21 individuals with sporadic TLE. The mutations were novel missense mutations in exons 1 (c.124T→G; C42G) and 8 (c.1418C→T; S473L). No mutations in LGI2, LGI3, or LGI4 were found in the other two ADPEAF families. Conclusion: In TLE, mutations in LGI1 are specific for ADPEAF but do not occur in all families. ADPEAF is genetically heterogeneous, but mutations in LGI2, LGI3, or LGI4 did not account for families without LGI1 mutations.

Does a SCN1A gene mutation confer earlier age of onset of febrile seizures in GEFS

SCN1A is the most clinically relevant epilepsy gene and is associated with generalized epilepsy and febrile seizure plus (GEFS+) and Dravet syndrome. We postulated that earlier onset of febrile seizures in the febrile seizure (FS) and febrile seizure plus (FS+) phenotypes may occur in the presence of a SCN1A mutation. This was because of the age‐related onset of Dravet syndrome, which typically begins in the first year of life. We found that patients with FS and FS+ with SCN1A mutations had earlier median onset of febrile seizures compared to the population median. Patients with GABRG2 mutations had a similar early onset in contrast to patients with SCN1B mutations where onset was later. This study is the first to demonstrate that a specific genetic abnormality directly influences the FS and FS+ phenotype in terms of age of onset.

Unverricht–Lundborg disease in a five-generation Arab family: Instability of dodecamer repeats

Background: Unverricht–Lundborg disease (ULD) is the prototypical form of progressive myoclonus epilepsy, and subjects are usually very photosensitive. ULD is caused by mutations in the cystatin B (CSTB) gene; the most common mutation is expansion of a dodecamer repeat near the promoter. The authors studied a five-generation Arab family with ULD lacking photosensitivity. Methods: An Arab family from the Galilee region of Israel with progressive myoclonus epilepsy was clinically evaluated. Blood samples were obtained from three living affected and 16 unaffected individuals. Expansion of dodecamer repeat in the CSTB gene was examined. Results: The three living affected individuals showed spontaneous and action myoclonus, ataxia, and mild dementia. EEG in two individuals showed generalized polyspike-wave without photosensitivity. The family structure with large sibships and multiple consanguineous loops allowed the authors to examine the gene over four generations of adults. The three living affected individuals were homozygous for repeat expansions and 11 of the 16 unaffected family members were heterozygous. Instability was demonstrated by the presence of expansions of different sizes occurring on the same haplotype background in this inbred family. Fragment size variations could be unequivocally detected in two sibships. The expansions were in the 49 to 54 dodecamer repeat range. Changes in one generation were small, 1 to 4 repeat units, consisting of either enlargements or contractions. Conclusions: Instability of the expanded dodecamer repeats in the cystatin B gene is frequent. Almost invariably, a small change is observed in parent–child transmission. The lack of photosensitivity in this family is unexplained.

Multiplex families with epilepsy: Success of clinical and molecular genetic characterization.

Objective: To analyze the clinical syndromes and inheritance patterns of multiplex families with epilepsy toward the ultimate aim of uncovering the underlying molecular genetic basis. Methods: Following the referral of families with 2 or more relatives with epilepsy, individuals were classified into epilepsy syndromes. Families were classified into syndromes where at least 2 family members had a specific diagnosis. Pedigrees were analyzed and molecular genetic studies were performed as appropriate. Results: A total of 211 families were ascertained over an 11-year period in Israel. A total of 169 were classified into broad familial epilepsy syndrome groups: 61 generalized, 22 focal, 24 febrile seizure syndromes, 33 special syndromes, and 29 mixed. A total of 42 families remained unclassified. Pathogenic variants were identified in 49/211 families (23%). The majority were found in established epilepsy genes (e.g., SCN1A, KCNQ2, CSTB), but in 11 families, this cohort contributed to the initial discovery (e.g., KCNT1, PCDH19, TBC1D24). We expand the phenotypic spectrum of established epilepsy genes by reporting a familial LAMC3 homozygous variant, where the predominant phenotype was epilepsy with myoclonic-atonic seizures, and a pathogenic SCN1A variant in a family where in 5 siblings the phenotype was broadly consistent with Dravet syndrome, a disorder that usually occurs sporadically. Conclusion: A total of 80% of families were successfully classified, with pathogenic variants identified in 23%. The successful characterization of familial electroclinical and inheritance patterns has highlighted the value of studying multiplex families and their contribution towards uncovering the genetic basis of the epilepsies.