SCN1A‐related phenotypes: Epilepsy and beyond

SCN1A, encoding the alpha 1 subunit of the sodium channel, is associated with several epilepsy syndromes and a range of other diseases. SCN1A represents the archetypal channelopathy associated with a wide phenotypic spectrum of epilepsies ranging from genetic epilepsy with febrile seizures plus (GEFS+), to developmental and epileptic encephalopathies (DEEs). SCN1A disorders also result in other diseases such as hemiplegic migraine and autism spectrum disorder (ASD). Dravet syndrome (DS) is the prototypic DEE with an early onset of febrile status epilepticus, hemiclonic or generalized tonic‐clonic seizures, and later onset of additional seizure types. Electroencephalography (EEG) and magnetic resonance imaging (MRI) are normal at onset. Development is normal in the first year of life but plateaus rapidly, with most patients ultimately having intellectual disability. Epilepsy is drug‐resistant and necessitates polytherapy. Most pathogenic variants occur de novo in the affected child, but they are inherited from mosaic affected or unaffected parents in rare cases. The molecular finding of haploinsufficiency is consistent with a loss‐of‐function defect in cells and animal models. Although seizures are the most commonly reported symptom in DS, many additional issues critically affect patients’ cognitive and behavioral functioning. Hemiplegic migraine (HM) is a rare form of migraine with aura, characterized by the emergence of hemiparesis as part of the aura phase. All SCN1A mutations reported in sporadic/familial HM3 are missense mutations. Most of the experimental results show that they cause a gain of function of Na_V1.1 as opposed to the loss of function of the epileptogenic Na_V1.1 mutations. SCN1A and SCN2A pathogenic variants have been identified in genetic studies of cohorts of patients with ASD. In addition, ASD features are often reported in patients with Dravet syndrome and other DEEs.     

Partial epilepsy with antecedent febrile seizures and seizure aggravation by antiepileptic drugs: Associated with loss of function of Nav1.1

Purpose: Generalized epilepsy with febrile seizures plus (GEFS+) and severe myoclonic epilepsy in infancy (SMEI) are associated with sodium channel α‐subunit type‐1 gene (SCN1A) mutations. Febrile seizures and partial seizures occur in both GEFS+ and SMEI; sporadic onset and seizure aggravation by antiepileptic drugs (AEDs) are features of SMEI. We thus searched gene mutations in isolated cases of partial epilepsy with antecedent FS (PEFS+) that showed seizure aggravations by AEDs. Methods: Genomic DNA from four patients was screened for mutations in SCN1A, SCN2A, SCN1B, and GABRG2 using denaturing high‐performance liquid chromatography (dHPLC) and sequencing. Whole‐cell patch clamp analysis was used to characterize biophysical properties of two newly defined mutants of Na_v1.1 in tsA201 cells. Results: Two heterozygous de novo mutations of SCN1A (R946H and F1765L) were detected, which were proven to cause loss of function of Na_v1.1. When the functional defects of mutants reported previously are compared, it is found that all mutants from PEFS+ have features of loss of function, whereas GEFS+ shows mild dysfunction excluding loss of function, coincident with mild clinical manifestations. PEFS+ is similar to SMEI clinically with possible AED‐induced seizure aggravation and biophysiologically with features of loss of function, and different from SMEI by missense mutation without changes in hydrophobicity or polarity of the residues. Conclusions: Isolated milder PEFS+ may associate with SCN1A mutations and loss of function of Na_v1.1, which may be the basis of seizure aggravation by sodium channel–blocking AEDs. This study characterized phenotypes biologically, which may be helpful in understanding the pathophysiologic basis, and further in management of the disease.     

An SCN2A mutation in a family with infantile seizures from Madagascar reveals an increased subthreshold Na+ current

Missense mutations in SCN2A, encoding the brain sodium channel Na_V1.2, have been described in benign familial neonatal‐infantile seizures (BFNIS), a self‐limiting disorder, whereas several SCN2A de novo nonsense mutations have been found in patients with more severe phenotypes including epileptic encephalopathy. We report a family with BFNIS originating from Madagascar. Onset extended from 3 to 9 months of age. Interictal EEGs were normal. In two patients, ictal electroencephalography (EEG) studies showed partial seizure patterns with secondary generalization in one. Seizures remitted before 18 months of age, with or without medication. Intellectual development was normal. A novel missense mutation of SCN2A, c.4766A>G/p.Tyr1589Cys, was found in a highly conserved region of Na_V1.2 (D4/S2‐S3). Functional studies using heterologous expression in tsA201 cells and whole‐cell patch clamping revealed a depolarizing shift of steady‐state inactivation, increased persistent Na⁺ current, a slowing of fast inactivation and an acceleration of its recovery, thus a gain‐of‐function. Using an action potential waveform in a voltage‐clamp experiment we indicated an increased inward Na⁺ current at subthreshold voltages, which can explain a neuronal hyperexcitability. Our results suggest that this mutation induces neuronal hyperexcitability, resulting in infantile epilepsy with favorable outcome.     

A sodium channel mutation linked to epilepsy increases ramp and persistent current of Nav1.3 and induces hyperexcitability in hippocampal neurons

Voltage-gated sodium channelopathies underlie many excitability disorders. Genes SCN1A, SCN2A and SCN9A, which encode pore-forming α-subunits Na_V1.1, Na_V1.2 and Na_V1.7, are clustered on human chromosome 2, and mutations in these genes have been shown to underlie epilepsy, migraine, and somatic pain disorders. SCN3A, the gene which encodes Na_V1.3, is part of this cluster, but until recently was not associated with any mutation. A charge-neutralizing mutation, K345Q, in the Na_V1.3 DI/S5-6 linker has recently been identified in a patient with cryptogenic partial epilepsy. Pathogenicity of the Na_V1.3/K354Q mutation has been inferred from the conservation of this residue in all sodium channels and its absence from control alleles, but functional analysis has been limited to the corresponding substitution in the cardiac muscle sodium channel Na_V1.5. Since identical mutations may produce different effects within different sodium channel isoforms, we assessed the K354Q mutation within its native Na_V1.3 channel and studied the effect of the mutant Na_V1.3/K354Q channels on hippocampal neuron excitability. We show here that the K354Q mutation enhances the persistent and ramp currents of Na_V1.3, reduces current threshold and produces spontaneous firing and paroxysmal depolarizing shift-like complexes in hippocampal neurons. Our data provide a pathophysiological basis for the pathogenicity of the first epilepsy-linked mutation within Na_V1.3 channels and hippocampal neurons.     

Pure haploinsufficiency for Dravet syndrome Na(V)1.1 (SCN1A) sodium channel truncating mutations

Purpose: Dravet syndrome (DS), a devastating epileptic encephalopathy, is mostly caused by mutations of the SCN1A gene, coding for the voltage‐gated Na⁺ channel Na_V1.1 α subunit. About 50% of SCN1A DS mutations truncate Na_V1.1, possibly causing complete loss of its function. However, it has not been investigated yet if Na_V1.1 truncated mutants are dominant negative, if they impair expression or function of wild‐type channels, as it has been shown for truncated mutants of other proteins (e.g., Ca_V channels). We studied the effect of two DS truncated Na_V1.1 mutants, R222* and R1234*, on coexpressed wild‐type Na⁺ channels. Methods: We engineered R222* or R1234* in the human cDNA of Na_V1.1 (hNa_V1.1) and studied their effect on coexpressed wild‐type hNa_V1.1, hNa_V1.2 or hNa_V1.3 cotransfecting tsA‐201 cells, and on hNa_V1.6 transfecting an human embryonic kidney (HEK) cell line stably expressing this channel. We also studied hippocampal neurons dissociated from Na_V1.1 knockout (KO) mice, an animal model of DS expressing a truncated Na_V1.1 channel. Key Findings: We found no modifications of current amplitude coexpressing the truncated mutants with hNa_V1.1, hNa_V1.2, or hNa_V1.3, but a 30% reduction coexpressing them with hNa_V1.6. However, we showed that also coexpression of functional full‐length hNa_V1.1 caused a similar reduction. Therefore, this effect should not be involved in the pathomechanism of DS. Some gating properties of hNa_V1.1, hNa_V1.3, and hNa_V1.6 were modified, but recordings of hippocampal neurons dissociated from Na_V1.1 KO mice did not show any significant modifications of these properties. Therefore, Na_V1.1 truncated mutants are not dominant negative, consistent with haploinsufficiency as the cause of DS. Significance: We have better clarified the pathomechanism of DS, pointed out an important difference between pathogenic truncated Ca_V2.1 mutants and hNa_V1.1 ones, and shown that hNa_V1.6 expression can be reduced in physiologic conditions by coexpression of hNa_V1.1. Moreover, our data may provide useful information for the development of therapeutic approaches.     

Confirming an expanded spectrum of SCN2A mutations: a case series

Mutations in sodium channel genes are highly associated with epilepsy. Mutation of SCN1A, the gene encoding the voltage gated sodium channel (VGSC) alpha subunit type 1 (Nav1.1), causes Dravet syndrome spectrum disorders. Mutations in SCN2A have been identified in patients with benign familial neonatal‐infantile epilepsy (BFNIE), generalised epilepsy with febrile seizures plus (GEFS+), and a small number of reported cases of other infantile‐onset severe intractable epilepsy. Here, we report three patients with infantile‐onset severe intractable epilepsy found to have de novo mutations in SCN2A. While a causal role for these mutations cannot be directly established, these findings contribute to growing evidence that mutation of SCN2A is associated with a range of epilepsy phenotypes including severe infantile‐onset epilepsy.     

Somatostatin-Positive Interneurons Contribute to Seizures in SCN8A Epileptic Encephalopathy

SCN8A epileptic encephalopathy is a devastating epilepsy syndrome caused by mutant SCN8A, which encodes the voltage-gated sodium channel Na_V1.6. To date, it is unclear if and how inhibitory interneurons, which express Na_V1.6, influence disease pathology. Using both sexes of a transgenic mouse model of SCN8A epileptic encephalopathy, we found that selective expression of the R1872W SCN8A mutation in somatostatin (SST) interneurons was sufficient to convey susceptibility to audiogenic seizures. Patch-clamp electrophysiology experiments revealed that SST interneurons from mutant mice were hyperexcitable but hypersensitive to action potential failure via depolarization block under normal and seizure-like conditions. Remarkably, GqDREADD-mediated activation of WT SST interneurons resulted in prolonged electrographic seizures and was accompanied by SST hyperexcitability and depolarization block. Aberrantly large persistent sodium currents, a hallmark of SCN8A mutations, were observed and were found to contribute directly to aberrant SST physiology in computational modeling and pharmacological experiments. These novel findings demonstrate a critical and previously unidentified contribution of SST interneurons to seizure generation not only in SCN8A epileptic encephalopathy, but epilepsy in general.SIGNIFICANCE STATEMENT SCN8A epileptic encephalopathy is a devastating neurological disorder that results from de novo mutations in the sodium channel isoform Na_v1.6. Inhibitory neurons express Na_V1.6, yet their contribution to seizure generation in SCN8A epileptic encephalopathy has not been determined. We show that mice expressing a human-derived SCN8A variant (R1872W) selectively in somatostatin (SST) interneurons have audiogenic seizures. Physiological recordings from SST interneurons show that SCN8A mutations lead to an elevated persistent sodium current which drives initial hyperexcitability, followed by premature action potential failure because of depolarization block. Furthermore, chemogenetic activation of WT SST interneurons leads to audiogenic seizure activity. These findings provide new insight into the importance of SST inhibitory interneurons in seizure initiation, not only in SCN8A epileptic encephalopathy, but for epilepsy broadly.     

No mutations in the voltage‐gated NaV1.7 sodium channel α1 subunit gene SCN9A in familial complex regional pain syndrome

Background: Mutations in the voltage‐gated Na_V1.7 Na⁺ channel α1 gene SCN9A have been linked to pain disorders, such as inherited primary erythromelalgia and paroxysmal extreme pain disorder. Both show clinical overlap with complex regional pain syndrome (CRPS), a condition that is characterized by pain in association with combinations of vasomotor, sudomotor, sensory, and motor disturbances. Therefore, we here investigated the involvement of the SCN9A gene in familial CRPS. Methods: We performed a mutation analysis of the SCN9A gene in four index cases of families with CRPS. All 26 coding exons and adjacent sequences of the SCN9A gene were analyzed for mutations using direct sequencing analysis. Results: No causal gene mutations were identified in the SCN9A gene in any of the patients. Conclusions: Despite the fact that the SCN9A gene is an excellent candidate, we did not find evidence that it plays a major role in familial CRPS.     

Painful neuropathies: the emerging role of sodium channelopathies

Pain is a frequent debilitating feature reported in peripheral neuropathies with involvement of small nerve (Aδ and C) fibers. Voltage‐gated sodium channels are responsible for the generation and conduction of action potentials in the peripheral nociceptive neuronal pathway where Na_V1.7, Na_V1.8, and Na_V1.9 sodium channels (encoded by SCN9A, SCN10A, and SCN11A) are preferentially expressed. The human genetic pain conditions inherited erythromelalgia and paroxysmal extreme pain disorder were the first to be linked to gain‐of‐function SCN9A mutations. Recent studies have expanded this spectrum with gain‐of‐function SCN9A mutations in patients with small fiber neuropathy and in a new syndrome of pain, dysautonomia, and small hands and small feet (acromesomelia). In addition, painful neuropathies have been recently linked to SCN10A mutations. Patch‐clamp studies have shown that the effect of SCN9A mutations is dependent upon the cell‐type background. The functional effects of a mutation in dorsal root ganglion (DRG) neurons and sympathetic neuron cells may differ per mutation, reflecting the pattern of expression of autonomic symptoms in patients with painful neuropathies who carry the mutation in question. Peripheral neuropathies may not always be length‐dependent, as demonstrated in patients with initial facial and scalp pain symptoms with SCN9A mutations showing hyperexcitability in both trigeminal ganglion and DRG neurons. There is some evidence suggesting that gain‐of‐function SCN9A mutations can lead to degeneration of peripheral axons. This review will focus on the emerging role of sodium channelopathies in painful peripheral neuropathies, which could serve as a basis for novel therapeutic strategies.     

De novo truncating mutation in SCN1A as a cause of febrile seizures plus (FS+)

SCN1A is one of the most relevant epilepsy genes. In general, de novo severe mutations, such as truncating mutations, lead to a classic form of Dravet syndrome (DS), while missense mutations are associated with both DS and milder phenotypes within the GEFS+ spectrum, however, these phenotype‐genotype correlations are not entirely consistent. Case report. We report an 18‐year‐old woman with a history of recurrent febrile generalized tonic‐clonic seizures (GTCS) starting at age four months and afebrile asymmetric GTCS and episodes of arrest, suggestive of focal impaired awareness seizures, starting at nine months. Her psychomotor development was normal. Sequencing of SCN1A revealed a heterozygous de novo truncating mutation (c.5734C>T, p.Arg1912X) in exon 26. Conclusion. Truncating mutations in SCN1A may be associated with milder phenotypes within the GEFS+ spectrum. Accordingly, SCN1A gene testing should be performed as part of the assessment for sporadic patients with mild phenotypes that fit within the GEFS+ spectrum, since the finding of a mutation has diagnostic, therapeutic and genetic counselling implications.     

De novo SCN1A pathogenic variants in the GEFS+ spectrum: Not always a familial syndrome

Genetic epilepsy with febrile seizures plus (GEFS+) is a familial epilepsy syndrome characterized by heterogeneous phenotypes ranging from mild disorders such as febrile seizures to epileptic encephalopathies (EEs) such as Dravet syndrome (DS). Although DS often occurs with de novo SCN1A pathogenic variants, milder GEFS+ spectrum phenotypes are associated with inherited pathogenic variants. We identified seven cases with non‐EE GEFS+ phenotypes and de novo SCN1A pathogenic variants, including a monozygotic twin pair. Febrile seizures plus (FS+) occurred in six patients, five of whom had additional seizure types. The remaining case had childhood‐onset temporal lobe epilepsy without known febrile seizures. Although early development was normal in all individuals, three later had learning difficulties, and the twin girls had language impairment and working memory deficits. All cases had SCN1A missense pathogenic variants that were not found in either parent. One pathogenic variant had been reported previously in a case of DS, and the remainder were novel. Our finding of de novo pathogenic variants in mild phenotypes within the GEFS+ spectrum shows that mild GEFS+ is not always inherited. SCN1A screening should be considered in patients with GEFS+ phenotypes because identification of pathogenic variants will influence antiepileptic therapy, and prognostic and genetic counseling.     

Clinical spectrum of SCN1A mutations

Mutations in the NaV1.1 neuronal sodium channel alpha-subunit ( SCN1A ) gene have been documented in a spectrum of epilepsy syndromes, ranging from the relatively benign generalized epilepsy with febrile seizures plus (GEFS⁺) to severe myoclonic epilepsy in infancy (SMEI), and rare cases of familial migraine. More than 300 new mutations have been identified to date, with missense mutations being the most common in GEFS⁺ and more deleterious mutations (nonsense, frameshift) representing the majority of SMEI mutations. Microchromosomal abnormalities including SCN1A deletions, amplifications, and duplications are also found in patients with SMEI. Deletions range in size from one single exon to abnormalities extending beyond SCN1A and involving contiguous genes. The majority of SCN1A mutations in SMEI arise de novo. SCN1A mutations are found throughout the protein structure, and some clustering of mutations is observed in the C-terminus and the loops between segments 5 and 6 of the first three domains of the protein. Functional studies so far show no consistent relationship between changes to channel properties and clinical phenotype.     

Exome sequencing identifies a de novo SCN2A mutation in a patient with intractable seizures,severe intellectual disability,optic atrophy,muscular hypotonia,and brain abnormalities

Epilepsy is a phenotypically and genetically highly heterogeneous disorder with >200 genes linked to inherited forms of the disease. To identify the underlying genetic cause in a patient with intractable seizures, optic atrophy, severe intellectual disability (ID), brain abnormalities, and muscular hypotonia, we performed exome sequencing in a 5‐year‐old girl and her unaffected parents. In the patient, we detected a novel, de novo missense mutation in the SCN2A (c.5645G>T; p.R1882L) gene encoding the α_II‐subunit of the voltage‐gated sodium channel Na_v1.2. A literature review revealed 33 different SCN2A mutations in 14 families with benign forms of epilepsy and in 21 cases with severe phenotypes. Although almost all benign mutations were inherited, the majority of severe mutations occurred de novo. Of interest, de novo SCN2A mutations have also been reported in five patients without seizures but with ID (n = 3) and/or autism (n = 3). In the present study, we successfully used exome sequencing to detect a de novo mutation in a genetically heterogeneous disorder with epilepsy and ID. Using this approach, we expand the phenotypic spectrum of SCN2A mutations. Our own and literature data indicate that SCN2A‐linked severe phenotypes are more likely to be caused by de novo mutations. A PowerPoint slide summarizing this article is available for download in the Supporting Information section here .     

Familial hemiplegic migraine

Familial hemiplegic migraine (FHM) is a rare and genetically heterogeneous autosomal dominant subtype of migraine with aura. Mutations in the genes CACNA1A and SCNA1A, encoding the pore-forming α₁ subunits of the neuronal voltage-gated Ca²⁺ channels Ca_v2.1 and Na⁺ channels Na_v1.1, are responsible for FHM1 and FHM3, respectively, whereas mutations in ATP1A2, encoding the α₂ subunit of the Na⁺, K⁺ adenosinetriphosphatase (ATPase), are responsible for FHM2. This review discusses the functional studies of two FHM1 knockin mice and of several FHM mutants in heterologous expression systems (12 FHM1, 8 FHM2, and 1 FHM3). These studies show the following: (1) FHM1 mutations produce gain-of-function of the Ca_v2.1 channel and, as a consequence, increased Ca_v2.1-dependent neurotransmitter release from cortical neurons and facilitation of in vivo induction and propagation of cortical spreading depression (CSD: the phenomenon underlying migraine aura); (2) FHM2 mutations produce loss-of-function of the α₂ Na⁺,K⁺-ATPase; and (3) the FHM3 mutation accelerates recovery from fast inactivation of Na_v1.5 (and presumably Na_v1.1) channels. These findings are consistent with the hypothesis that FHM mutations share the ability of rendering the brain more susceptible to CSD by causing either excessive synaptic glutamate release (FHM1) or decreased removal of K⁺ and glutamate from the synaptic cleft (FHM2) or excessive extracellular K⁺ (FHM3). The FHM data support a key role of CSD in migraine pathogenesis and point to cortical hyperexcitability as the basis for vulnerability to CSD and to migraine attacks. Hence, they support novel therapeutic strategics that consider CSD and cortical hyperexcitability as key targets for preventive migraine treatment.     

Progress in searching for the febrile seizure susceptibility genes

Febrile seizures (FS) represent the most common form of childhood seizures. They affect 2–5% of infants in the Caucasian population and are even more common in the Japanese population, affecting 6–9% of infants. Some familial FS are associated with a wide variety of afebrile seizures. Generalized epilepsy with febrile seizures plus (GEFS+) is a familial epilepsy syndrome with a spectrum of phenotypes including FS, atypical FS (FS+) and afebrile seizures. A significant genetic component exists for susceptibility to FS and GEFS+: extensive genetic studies have shown that at least nine loci are responsible for FS. Furthermore, mutations in the voltage-gated sodium channel subunit genes (SCN1A, SCN2A and SCN1B) and the GABA_A receptor subunit genes (GABRG2 and GABRD) have been identified in GEFS+. However, the causative genes have not been identified in most patients with FS or GEFS+. Common forms of FS are genetically complex disorders believed to be influenced by variations in several susceptibility genes. Recently, several association studies on FS have been reported, but the results vary among different groups and no consistent or convincing FS susceptibility gene has emerged. Herein, we review the genetic data reported in FS, including the linkage analysis, association studies, and genetic abnormalities found in the FS-related disorders such as GEFS+ and severe myoclonic epilepsy in infancy.     

SCN1A mutations in focal epilepsy with auditory features: widening the spectrum of GEFS plus

Aims. Epilepsy with auditory features (EAF) is a focal epilepsy syndrome characterized by prominent auditory ictal manifestations. Two main genes, LGI1 and RELN, have been implicated in EAF, but the genetic aetiology remains unknown in half of families and most sporadic cases. We previously described a pathogenic SCN1A missense variant (p.Thr956Met) segregating in a large family in which the proband and her affected daughter had EAF, thus satisfying the minimum requirement for diagnosis of autosomal dominant EAF (ADEAF). However, the remaining eight affected family members had clinical manifestations typically found in families with genetic epilepsy with febrile seizures plus (GEFS+). We aimed to investigate the role/impact of SCN1A mutations in EAF. Methods. We detailed the phenotype of this family and report on SCN1A screening in a cohort of 29 familial and 52 sporadic LGI1 variant‐negative EAF patients. Results. We identified two possibly pathogenic missense variants (p.Tyr790Phe and p.Thr140Ile) in sporadic patients (3.8%) showing typical EAF and no antecedent febrile seizures. Both p.Thr956Met and p.Tyr790Phe were previously described in unrelated patients with epilepsies within the GEFS+ spectrum. Conclusion. SCN1A mutations may be involved in EAF within the GEFS+ spectrum, however, the role of SCN1A in EAF without features that lead to a suspicion of underlying GEFS+ remains unclear and should be elucidated in future studies.     

SCN2A channelopathies: Mechanisms and models

Variants in the SCN2A gene, encoding the voltage‐gated sodium channel Na_V1.2, cause a variety of neuropsychiatric syndromes with different severity ranging from self‐limiting epilepsies with early onset to developmental and epileptic encephalopathy with early or late onset and intellectual disability (ID), as well as ID or autism without seizures. Functional analysis of channel defects demonstrated a genotype‐phenotype correlation and suggested effective treatment options for one group of affected patients carrying gain‐of‐function variants. Here, we sum up the functional mechanisms underlying different phenotypes of patients with SCN2A channelopathies and present currently available models that can help in understanding SCN2A‐related disorders.     

Phenotypic and genetic spectrum of SCN8A‐related disorders,treatment options,and outcomes

Pathogenic variants in SCN8A have originally been described in patients with developmental and epileptic encephalopathy (DEE). However, recent studies have shown that SCN8A variants can be associated with a broader phenotypic spectrum, including the following: (1) Patients with early onset, severe DEE, developing severe cognitive and motor regression, pyramidal/extrapyramidal signs, and cortical blindness. Severe SCN8A‐DEE is characterized by intractable seizures beginning in the first months of life. The seizures are often prolonged focal hypomotor and occur in clusters, with prominent vegetative symptoms (apnea, cyanosis, mydriasis), evolving to clonic or bilateral tonic‐clonic manifestations. Spasm‐like episodes, cortical myoclonus, and recurrent episodes of status epilepticus are also common. Electroencephalograms (EEGs) show progressive background deterioration and multifocal abnormalities, predominant in the posterior regions. (2) Sporadic and familial patients with mild‐to‐moderate intellectual disability, discrete neurological signs, and treatable epilepsy. EEG is abnormal in half of the cases, showing multifocal or diffuse epileptiform abnormalities. (3) Familial cases with benign infantile seizures, sometimes associated with paroxysmal dyskinesia later in life, with no other neurological deficits, normal cognition, and usually normal interictal EEG. (4) Patients without epilepsy but with cognitive and/or behavioral disturbances, or with movement disorders. Extrapyramidal features, such as dyskinesia, ataxia, and choreoathetosis are common in all groups. Early death has been reported in about 5% of the patients, most often in the subgroup of severe DEE. Premature death occurs during early childhood and often for causes other than sudden unexpected death in epilepsy. All epilepsy subgroups exhibit better seizure control with sodium channel blockers, usually at supratherapeutic doses in the severe cases. In severe SCN8A‐DEE, ketogenic diet often has a good effect, whereas levetiracetam has a negative effect, if any. The familial SCN8A‐related epilepsies show an autosomal dominant pattern of inheritance, whereas the vast majority of SCN8A‐DEEs occur de novo.     

Genetics of migraine: an update with special attention to genetic comorbidity

PURPOSE OF REVIEW: To highlight recent genetic findings in migraine and discuss, new mutations in hemiplegic migraine genes in familial and sporadic cases and relevant candidate gene association studies. Special attention will be given to comorbid diseases of migraine. RECENT FINDINGS: Familial hemiplegic migraine (FHM) is genetically heterogeneous with mutations in the CACNA1A (FHM1), ATP1A2 (FHM2) and SCN1A (FHM3) genes. Nineteen novel ATP1A2 mutations were identified last year, eleven of them in FHM2 families. A systematic genetic analysis of patients with sporadic hemiplegic migraine revealed five mutations in this gene, which has implications for genetic counselling. The identification of a second FHM3 SCN1A mutation definitely established SCN1A as a migraine gene. The identification of TREX1 mutations in families with retinal vasculopathy and associated diseases such as migraine may provide new insights in migraine pathophysiology. SUMMARY: Many novel ATP1A2 mutations were identified in patients with familial and sporadic hemiplegic migraine. In sporadic patients, ATP1A2 screening has the highest chance of finding a causal mutation. A second FHM3 mutation definitely established the epilepsy SCN1A gene as a migraine gene. The discovery of genes in monogenic diseases in which migraine is prominent may lead to new insights in the molecular pathways involved in migraine pathophysiology.