Full Text
KCNQ2 (OMIM 602235) mutations can contribute to benign familial neonatal convulsions (BFNC) (Biervert et al., ; Leppert et al., ; Neubauer et al., ), benign familial neonatal‐infantile seizures (BFNIS), benign familial infantile seizures (BFIS), and neonatal‐onset epileptic encephalopathy (EE) (Kato et al., ; Weckhuysen et al., , ). The mutant gene, KCNQ2, a voltage‐gated potassium‐channel gene at 20q13, is usually inherited with autosomal‐dominant form in a benign epileptic syndrome associated with a KCNQ2 mutation. Patients with BFNC, BFNIS, or BFIS usually have seizures as neonates and infants, but they are predicted to have benign outcomes (Leppert et al., ; Neubauer et al., ; Singh et al., ). Most seizures will spontaneously disappear during an infant's first 12 months of life (Coppola et al., ; Singh et al., ). In KCNQ2 mutation‐associated neonatal‐onset EE, most mutations are de novo or mosaic inherited, and patients present with severe seizures and severe neurological outcomes (Kato et al., ; Weckhuysen et al., ). Electroencephalograms (EEGs) in neonatal‐onset EE patients show interictal burst‐suppression or multiple focal spikes (Kato et al., ; Weckhuysen et al., ). Patients usually have intellectual developmental delays despite seizure remission. A loss (Maljevic et al., ; Maljevic, Wuttke, & Lerche, ; Wuttke et al., ) or gain (Miceli et al., ; Millichap et al., ) of KCNQ2 gene function is presumed to be the major mechanism for KCNQ2‐associated neonatal‐onset EE. Recent analyses of data from genome‐wide association studies (GWASs) of humans and animals indicate that KCNQ2 mutations contribute to schizophrenia susceptibility (Choi et al., ; Lee, Kim, & Song, ). However, outcomes for patients with KCNQ2 mutations cannot be accurately predicted.
The KCNQ2 gene is expressed predominantly in the brain and encodes for voltage‐gated potassium‐channel subunits that underlie the M‐current, a repolarizing current that limits repetitive firing during long‐lasting depolarizing inputs (Cooper, Harrington, Jan, & Jan, ; Cooper & Jan, ; Coppola et al., ; Wang et al., ). Each subunit of KCNQ2 consists of heteromultimeric channels with six transmembrane domains (S1–S6): voltage sensors in S1–S4, a loop between S5 and S6 that builds the ion channel pore domain, and a long C‐terminal region of mostly unknown function (Biervert et al., ; Cooper et al., ; Lerche et al., ). The C‐terminal tail contains two helical domains (A and B) that bind to calmodulin (CaM), a calcium (Ca2+) sensor (Ambrosino et al., ). Helix A contains the consensus CaM binding IQ motif, and helix B mediates Ca2+‐dependent CaM binding (Ambrosino et al., ; Liu & Devaux, ; Zhou et al., ). CaM accounts for trafficking protein to cell‐surface membranes. The mutations in the CaM domain have been reported to impair the interaction with calmodulin molecules, and to impair surface expression of potassium channel, which increased action potential firing and hyperexcitability (Maljevic et al., ; Zhou et al., ).
The precise percentage of neonates and children with KCNQ2‐associated epilepsy is unknown. About 163 (1.9%) of the 8,565 patients in one study (Lindy et al., ) with epilepsy and neurodevelopmental disorders had detectable KCNQ2 mutations. Weckhuysen et al. () reported 11 (13%) KCNQ2‐associated neonatal‐onset seizures in 84 patients with neonatal‐onset EE. Kato et al. () identified 12 (5%) KCNQ2‐associated cases of neonatal‐onset EE in 239 patients. The percentages of KCNQ2‐associated epilepsy were not consistent but depended upon what kinds of patients were enrolled. For neonates, rapidly diagnosing and promptly stopping seizures should improve the patient's outcome (Chen et al., ; Grinton et al., ). The diagnosis can be supported by clinical features, EEG findings, age seizure onset, and family history, and it can be confirmed using a genetic study.
Despite some case‐series reports (Grinton et al., ; Kato et al., ; Weckhuysen et al., , ) and some functional studies (Maljevic et al., , ; Wuttke et al., ), however, the phenotypes and genotypes are still complex and noteworthy. We previously reported (Lee, Yang, Liang, Chang, & Li, ) in a functional study of HEK293 cells that genotype is a major determinant of phenotype. Additional investigations are warranted. In the present study, we investigated a series of cases with KCNQ2 mutation variants from patients with childhood nonlesional epilepsy.
Ethical approval of the study was provided by Chung Shan Medical University Hospital's Internal Review Board (IRB #: CS13036).
One hundred and thirty‐one patients met all three criteria for “childhood epilepsy without an identified cause” ([1] first seizure when <18 years old, [2] age at last visit <18 years old, and [3] at least one magnetic resonance image [MRI] with no detectable seizure‐related lesions) and were enrolled in the study. Seizure onset occurred before 2 months old for 45 (34%) patients, and between 2 months and 18 years old for the other 86 (66%). The KCNQ2 genes were sequenced and screened in all patients. If mutations were detected, we requested to sequence and screen the patients’ relatives. Fifty‐five healthy adults who said that they had never had epileptic seizures were enrolled as controls.
A genomic DNA purification kit (Gentra Systems;
The PCR products were then purified (PCR‐M Clean‐Up System; Viogene‐Biotek Corp., New Taipei City, Taiwan), and their concentrations were measured using a spectrophotometer (Ultrospec 3100 Pro; Amersham Biosciences UK, Little Chalfont, Buckinghamshire, UK). The products were sequenced using an automated DNA sequencer (3100; Applied Biosystems, Foster City, CA). DNA sequencing was done using a kit (ABI PRISM BigDye Terminator Cycle Sequencing Ready Reaction Kit, v3.1; Applied Biosystems) on the ABI PRISM 3730XL DNA analyzer. The sequence data of each patient were checked against the GenBank reference sequence and version number of KCNQ2 gene (NM_172107.3). Each mutation was numbered and described based on the Mutation Database Initiative (MDI)/Human Genome Variation Society (HGVS) Mutation Nomenclature Recommendations (
Seven (5%) of the 131 patients (three boys; four girls) had KCNQ2 mutations: one each for c.1627 G>A c.1627 G>A p.(Val543Met); c.1294 C>T p.(Arg432Cys); c.740 C>T p.(Ser247Leu); c.1741 C>T (p.Arg581*); c.853 C>A p.(Pro285Thr); c.860 C>T p.(Thr287Ile); and a splicing mutation: c.387+1 G>T (Tables and ). None of these seven mutations was found in the control group (Supplemental Table S1). All seven mutations, except one splicing and one nonsense mutation, were missense. Four parents had the same mutations as did their children, but three children had de novo mutations: p.(Ser247Leu), p.(Pro285Thr), and p.(Thr287Ile). Mutation p.(Ser247Leu) was in the S5 transmembrane domain; mutations p.(Pro285Thr) and p.(Thr287Ile) were in the pore domain (Figure ); the mutation in patient 3 was in a splicing site in the S2 domain (Figure ); and mutation p.(Val543Met) was in the C‐terminal CaM domain (Figure ).
Seven of the 131 patients had identified KCNQ2mutatoins. The clinical and familial histories are summarized| Patient number | Patient 1 | Patient 2 | Patient 3 | Patient 4 | Patient 5 | Patient 6 | Patient 7 |
| Genotype | c.1627 G>A | c.1294 C>T | c.387+1 G>T | c.740 C>T | c.1741 C>T | c.853 C>A | c.860 C>T |
| Protein change | p.(Val543Met) | p.(Arg432Cys) | Splicing | p.(Ser247Leu) | (p.Arg581*) | p.(Pro285Thr) | p.(Thr287Ile) |
| Family mutation | Father and two aunts | Father | Mother | De novo | Mother and sister | De novo | De novo |
| Sex | Female | Female | Male | Male | Female | Female | Male |
| Other genetic study | KCNQ3 | Panel | KCNQ3 | Whole exon | Panel | Whole exon | KCNQ3 |
| Family number of seizures other than index patient (n) | 3 | 1 | 1 | 0 | 2 | 0 | 0 |
| Later seizures older than 3 years from familial KCNQ2 mutation (n) | 0 | 2 | 0 | 1 | 1 | 1 | 1 |
| Age at first seizure | Day 14 | 1 year (febrile seizure) | Day 3 | Day 3 | Day 3 | Day 2 | Newborn |
| Seizure type | General tonic | General tonic | General clonic | General tonic | General tonic | General tonic | General tonic |
| Seizure frequency before drug control | + | + | +++ | +++ | +++ | +++ | +++ |
| Drug control | OXC | OXC, TOP | PB, OXC | Intravenous PB, PHT then changed to PB, SAB, CLN | PB | Intravenous PB, PHT then changed to oral PB, SAB, CLN, OXC | TOP, OXC |
| Seizure frequency after 6‐months drugs | ‐ | ‐ | ‐ | ‐ | ‐ | ‐ | + |
| Abnormal MRI | No | No | No | Basal ganglion | No | Thin corpus callosum | No |
| Dev. Del./Int. Dis. | No | Mild(ADHD) | No | Severe | No | Severe | Severe |
The sequence data of each patient were checked against the GenBank reference sequence and version number of KCNQ2 gene (NM_172107.3).
Abbreviations: NA, not available; VOUS, variance of unknown significance; PHT, phenytoin; OXC, oxcarbazepine; VPA, valproic acid; TOP, topiramate; PB, phenobarbital; KEP, levetiracetam; SAB, vigabatrin; CLN, clonazepam; MRI, magnetic resonance imaging; EEG, electroencephalography; +++, daily; ++, weekly; +, less than weekly; ADHD, attention deficit and hyperactivity; Dev. Del./Int. Dis., Developmental delay/intellectual disability.
| Genotype (N) | Phenotype | Severity | NCBI ClinVar | Functional domain | Global MAF | East Asia MAF | Cont. in Taiwan (N = 55) | FATHMM predict | Poly Phen2 | SIFT | ACMG score | |
| c.387+1 G>T | Splicing | BFNC | + | Pathogenic | S2 | 0 | 0 | 0 | PVS1, PM2, PP4 | |||
| c.740C>T p.(Ser247Leu) | Missense | EE | +++ | Pathogenic | S5 | 0 | 0 | 0 | D | D | D | PS2, PM1, PM2,PP3, PP4 |
| c.853C>A p.(Pro285Thr) | Missense | EE | +++ | Novel | Pore domain | 0 | 0 | 0 | D | D | D | PS2, PM1,PM2, PP3, PP4, PM5 |
| c.860C>T p.(Thr287Ile) | Missense | EE | +++ | VOUS | Pore domain | 0 | 0 | 0 | D | D | D | PS2, PM1, PM2, PP4, PP3 |
| c.1294C>T p.(Arg432Cys) | Missense | CSWS | + | VOUS | C‐terminal | 4.53E−05 | 0 | 0 | D | D | D | PM2, PP3 |
| c.1627G>A p.(Val543Met) | Missense | BFNC | + | VOUS | Calmodulin | 0 | 0 | 0 | D | D | D | PS3, PM2, PP3, PP4 |
| c.1741 C>T (p.Arg581*) | Nonsense | BFNC | + | Pathogenic | C‐terminal | 0 | 0 | 0 | PVS1, PM2, PP4 |
The sequence data of each patient were checked against the GenBank reference sequence and version number of KCNQ2 gene (NM_172107.3).
Abbreviations: BFNC, benign familial neonatal convulsions; EE, neonatal‐onset epileptic encephalopathy; CSWS, continuous spikes and waves during slow‐wave sleep; NCBI ClinVar: National Center for Biotechnology Information, clinical variability and predictability (
Enlarge this image.Seven mutation variants associated with KCNQ2 functional domains. CaM: calmodulin domain
The three patients with the de novo p.(Ser247Leu), p.(Pro285Thr), and p.(Thr287Ile) mutations had neonatal EE (Table ). Three index patients had BFNC. One index patient with p.(Arg432Cys) had rolandic spikes in EEGs when awakening and prominent spikes when sleeping, which is consistent with continuous spikes and waves during slow‐wave sleep (CSWS) (Table ). The pedigrees of the seven patients’ families are shown in Figure .
For patients whose first seizure onset occurred before they were 2 months old, the positive rate for a KCNQ2 mutation was 13% (6/45), and the negative rate was 87% (39/45). This was significantly (p < 0.001) different from that of patients whose first seizure onset occurred after they were 2 months old: their negative rate for a KCNQ2 mutation was 99%.
Patient 4 had the c.740 C>T p.(Ser247Leu) mutation (Figure ), frequent neonatal seizures, and apnea. His EEG shows multiple focal spikes (Figure ). He was treated with multiple antiseizure drugs: phenobarbital, vigabatrin, and clonazepam. After he had turned 4 months old, he was treated with oxcarbazepine (OXC) and his seizures abated. An MRI showed basal ganglion hyperdensity (Figure ). He also had a severe cognitive disability and could not walk at 3 years old.
Enlarge this image.Sanger sequencing shows that patient 4 has a de novo c.740C>T p.(Ser247Leu) mutation (right lower, arrow), and an interictal EEG shows multiple focal spikes (left upper). The EEG improved after the patient turned 6 months old (left lower). His MRI shows hyperdensities (right upper, arrow) in his bilateral basal ganglia. He had frequent (>10 per day) neonatal seizures
Patient 6 had the de novo p.(Pro285Thr) mutation, frequent neonatal seizures, and apnea. Her EEG (Figure ) showed burst suppression. Her amplitude‐integrated EEG (aEEG) monitor showed many seizures (Figure : arrows) with unique low‐voltage fast activity arising from the left hemisphere and followed by rhythmic theta and delta rhythms and postictal extremely low‐voltage activity during ictal recordings. She had neonatal seizures and apnea. The seizures became less frequent after she turned 2 months old, but she had a severe cognitive disability. The patient was treated with multiple antiseizure drugs: phenobarbital, phenytoin, vigabatrin, and clonazepam. The seizures abated 2 months after she had been treated with OXC.
Enlarge this image.Patient 6 has a de novo c.853C>A p.(Pro285Thr) mutation (left lower) and an EEG that shows neonatal epileptic encephalopathy with burst‐suppression (left upper). Her EEG improved and her seizures attenuated after 2 months. The MRI shows a thin corpus callosum (right upper, arrows, and right lower)
Enlarge this image.Patient 6’s amplitude‐integrated EEG monitor showed many seizures (arrows) with unique low‐voltage fast activity arising from the left hemisphere followed by rhythmic theta and delta rhythms and postictal extremely low‐voltage activity during ictal recordings
Patient 7 had the de novo p.(Thr287Ile) (Supplementary Figure S1: lower) and presented with neonatal seizures. OXC and topiramate controlled his seizures. He could walk, but he had a severe cognitive disability at 3 years old.
The computer‐based SIFT and PolyPhen algorithms predicted that the p.(Arg432Cys) mutation was deleterious. The Arginine (R) at protein position 432 is highly conserved in mammals. The patient had a mild epileptic phenotype; her first seizure (febrile) was at 1 year old, and she had an afebrile seizure at 5 years old. She was then treated with OXC, had two more seizures, and was referred to the hospital. After topiramate (2 mg kg‐1 day‐1) had been added, her seizures remitted. She had mild cognitive impairment. A genetic study showed that both she and her father, who had seizures as an infant, had the p.(Arg432Cys) mutation. An extensive epileptic panel study that included 203 genes found no other genetic defect responsible for her seizures (Supplementary Table S2). Her EEG showed bilateral central spikes during awakening and prominent spikes after sleeping. The spike waves clearly activated during sleep, compared with their EEG tracings while awake. The spike‐wave index is over 50% in non‐REM sleep and there were fewer sleep spindles visible, which is consistent with CSWS (Supplementary Figure S2) (Lesca et al., ; Scheltens‐de Boer, ). Her MRI was unremarkable, and her seizures remitted after she turned 7 years old.
This case was previously reported (Lee, Yang, Liang, et al., ). The patient's first seizure occurred when she was 2 weeks old. She had asymmetrical general tonic seizures. Her most recent previous seizure had been when she was 2 months old. Her seizures remitted after she had begun taking OXC when she was 2 months old. Her MRI was unremarkable. The family history showed that the patient's father and two of her aunts also had the p.(Val543Met) mutation and had had seizures from birth, but they had no cognitive disabilities. At 6 years and 2 months old, her cognitive development was normal.
Patient 3’s first seizure occurred when he was 3 days old. The seizures were general tonic‐clonic seizures with lip cyanosis. He was first treated with intravenous phenobarbital, after which the seizures temporarily remitted. At 1 year old, the patient had another general tonic‐clonic seizure and was treated with OXC. His MRI and neurodevelopment were unremarkable. The family history showed that the patient's mother had had seizures from birth. A genetic study for KCNQ2 showed that both he and his mother had the c.387+1 G>T mutation but no KCNQ3 mutation (Supplementary Figure S1: upper).
Patient 5’s first seizure was a general tonic‐clonic seizure with lip cyanosis when she was 3 days old. The seizures remitted after she had been treated with oral phenobarbital. Her MRI and neurodevelopment were unremarkable at 4 years old. The family history showed that the patient's mother and sister had had seizures from birth. A genetic study for KCNQ2 showed that all three had the c.1741 C>T(p.Arg581*) mutation.
Seizure onset occurred in 6 of the 7 index patients when they were younger than 1 month and in one index patient when she was older than 1 month (febrile seizures at 1 year old). In the seven families, we found 14 patients with confirmed KCNQ2 mutations. Seizure onset occurred at younger than 1 month in 12 (86%) and at older than 1 month in 2 (14%) (1 with infantile seizures (1 month to 1 year old); 1 with febrile seizures at 1 year old).
We confirmed KCNQ2 mutations in 14 patients, six (43%) of whose seizures continued after they were older than 3 years. All seven index patients had general tonic or clonic seizures. EEGs showed burst suppression or multiple focal spikes in three index patients, focal discharges in 3, and CSWS in 1.
One of the seven index patients was treated with only one antiseizure drug (patient 1: OXC); six were treated with more than 1 (four were treated with OXC, and their seizures remitted). Seizures in all seven patients completely or partially remitted after 6 months of drug treatments (Table ).
Our most important finding is that KCNQ2 mutations led to a variety of phenotypes in childhood epilepsy, for example, neonatal‐onset EE, BFNC, and CSWS. We found KCNQ2 mutations in about 5% of nonlesional childhood epilepsy patients, and in about 13% of patients with neonatal seizure onset when they were younger than 2 months. We found three de novo mutations (p.(Ser247Leu), p.(Pro285Thr), and p.(Thr287Ile)), all of which are in critical KCNQ2 domains. p.(Pro285Thr) is a novel mutation. Patients with one of these de novo mutations had worse outcomes.
The p.(Ser247Leu) and p.(Ser247Trp) mutations are pathogenic (
We also found that KCNQ2‐associated epilepsy patients had varied outcomes. Two regions involved with the important KCNQ2 functional domains—S1–S6 and CaM—might cause neonatal‐onset BFNC. However, in the most benign cases, the neurodevelopmental outcomes were relatively better. If the epilepsy is hereditary, seizure remission usually occurs after the patient turns 3 years old, and most such patients undergo normal cognitive development (Claes et al., ; Grinton et al., ; Singh et al., ).
We also found c.1545 G>C p.(Glu515Asp) in five patients with varied phenotypes: BFNC, CSWS, and unclassified epilepsy syndrome. However, they were excluded from the case series because of conflicting interpretations of p.(Glu515Asp)’s pathogenicity, despite our report (Lee, Yang, & Li, ) that there was a functional current change in HEK293 cells transfected with p.(Glu515Asp). Patients with p.(Glu515Asp) were associated with a mild BFNC phenotype, but in some patients, it was associated with cognitive delay and attention‐deficit hyperactive disorder (ADHD). Dravet syndrome patients with the p.(Glu515 Asp) mutation more often have developmental delays than do Dravet syndrome patients without p.(Glu515Asp) (Hammer et al., ). It is probable that other mutations of modified genes contributed to the phenotype. The global allele frequency of p.(Glu515Asp) is 0.002499, according to the ExAC browser (
Although BFNC are considered benign, BFNC patients might have cluster seizures, which inevitably require drug control to prevent secondary brain injury (Grinton et al., ). In neonatal EE patients, OXC, valproic acid, topiramate, vigabatrin, and clonazepam were used to treat seizures (Kato et al., ; Weckhuysen et al., , ). OXC was considered more efficacious for KCNQ2‐associated seizures in several studies (Grinton et al., ; Pisano et al., ; Sands et al., ), which is consistent with our findings. However, responses to antiseizure drugs require additional investigation.
KCNQ2 mutations accounted for 5% of all nonlesional pediatric epilepsy and 13% of patients with seizure onset before 2 months old. KCNQ2 mutations can cause variable phenotypes in children, from BFNC to severe neonatal‐onset EE. The p.(Ser247Leu), p.(Pro 285Thr), and p.(Thr287Ile) mutations can cause neonatal‐onset EE.
We thank Yi‐Ho Weng and I‐Ting Chen for performing the electroencephalography (EEG) with great patience. We thank Dr Pi‐Chuan Fan from National Taiwan University Hospital for his valuable assistance. This work was supported by grant 107‐2314‐B‐040‐021 from the Taiwan Ministry of Science and Technology.
The authors declared that they have no conflict of interest.
Copyright John Wiley & Sons, Inc. Jul 2019
Details
; Tung‐Ming Chang 2 ; Jao‐Shwann Liang 3 ; Shuan‐Yow Li 4 1 Division of Pediatric Neurology, Department of Pediatrics, Chung Shan Medical University Hospital, Taichung, Taiwan; Institute of Medicine, School of Medicine, Chung Shan Medical University, Taichung, Taiwan
2 Department of Pediatric Neurology, Changhua Christian Children's Hospital, Changhua, Taiwan; Graduate Institute of Medicine, Kaohsiung Medical University, Kaohsiung, Taiwan
3 Department of Pediatrics, Far Eastern Memorial Hospital, New Taipei City, Taiwan
4 Institute of Medicine, School of Medicine, Chung Shan Medical University, Taichung, Taiwan; Genetics Laboratory and Department of Biomedical Sciences, Chung Shan Medical University, Taichung, Taiwan