KCNQ1 Mutations Research Articles

Dual effects of mefenamic acid on the IKs molecular complex

AbstractBackground and PurposeMutations in both KCNQ1 and KCNE1, which together form the cardiac IKs current, are associated with inherited conditions such as long and short QT syndromes. Mefenamic acid, a non‐steroidal anti‐inflammatory drug, is an IKs potentiator and may be utilised as an archetype to design therapeutically useful IKs agonists. However, here we show that mefenamic acid can also act as an IKs inhibitor, and our data reveal its dual effects on KCNQ1/KCNE1 channels.Experimental ApproachEffects of mefenamic acid on wild type (WT) and mutant KCNQ1/KCNE1 channels expressed in tsA201 cells were studied using whole cell patch clamp. Molecular dynamics simulations were used to determine trajectory clustering.Key ResultsMefenamic acid inhibits WT IKs at high concentrations while preserving some attributes of current potentiation. Inhibitory actions of mefenamic acid are unmasked at lower drug concentrations by KCNE1 and KCNQ1 mutations in the mefenamic acid binding pocket, at the extracellular end of KCNE1 and in the KCNQ1 S6 helix. Mefenamic acid does not inhibit KCNQ1 in the absence of KCNE1 but inhibits IKs current in a concentration‐dependent manner in the mutant channels. Inhibition involves modulation of pore kinetics and/or voltage sensor domain‐pore coupling in WT and in the KCNE1 E43C mutant.Conclusion and ImplicationsThis work highlights the importance of structural motifs at the extracellular inter‐subunit interface of KCNQ1 and KCNE1 channels, and their interactions, in determining the nature of drug effects on the IKs channel complex and has important implications for treating patients with specific long QT mutations.

The fully activated open state of KCNQ1 controls the cardiac "fight-or-flight" response.

The cardiac KCNQ1 + KCNE1 (IKs) channel regulates heart rhythm under both normal and stress conditions. Under stress, the β-adrenergic stimulation elevates the intracellular cyclic adenosine monophosphate (cAMP) level, leading to KCNQ1 phosphorylation by protein kinase A and increased IKs, which shortens action potentials to adapt to accelerated heart rate. An impaired response to the β-adrenergic stimulation due to KCNQ1 mutations is associated with the occurrence of a lethal congenital long QT syndrome (type 1, also known as LQT1). However, the underlying mechanism of β-adrenergic stimulation of IKs remains unclear, impeding the development of new therapeutics. Here, we find that the unique properties of KCNQ1 channel gating with two distinct open states are key to this mechanism. KCNQ1's fully activated open (AO) state is more sensitive to cAMP than its intermediate open state. By enhancing the AO state occupancy, the small molecules ML277 and C28 are found to effectively enhance the cAMP sensitivity of the KCNQ1 channel, independent of KCNE1 association. This finding of enhancing AO state occupancy leads to a potential novel strategy to rescue the response of IKs to β-adrenergic stimulation in LQT1 mutants. The success of this approach is demonstrated in cardiac myocytes and also in a high-risk LQT1 mutation. In conclusion, the present study not only uncovers the key role of the AO state in IKs channel phosphorylation, but also provides a target for antiarrhythmic strategy.

Establishment of two human induced pluripotent stem cell lines from familial long QT syndrome type 1 patients carrying KCNQ1 mutation

Long QT syndrome type 1 (LQT1) is a rare heart disorder caused by a loss-of-function mutation in the KCNQ1 gene that causes loss of Kv7.1 channel function, which can lead to Palpitations, Syncope, and Sudden cardiac arrest. We derived induced pluripotent stem cells from PBMC of LQT1 patients carrying a pathogenic variant (c.734G>A; p.Gly245Glu). The non-integrative Sendai virus-mediated iPSC reprogramming method was used for iPSC line generation. These iPSC cell lines exhibit stem cell pluripotency, differentiation capability, and cell morphology, resulting in a reliable cell source to study the effects of KCNQ1 mutation in disease-specific cell types.

Lipophilic compounds restore function to neurodevelopmental-associated KCNQ3 mutations

A major driver of neuronal hyperexcitability is dysfunction of K+ channels, including voltage-gated KCNQ2/3 channels. Their hyperpolarized midpoint of activation and slow activation and deactivation kinetics produce a current that regulates membrane potential and impedes repetitive firing. Inherited mutations in KCNQ2 and KCNQ3 are linked to a wide spectrum of neurodevelopmental disorders (NDDs), ranging from benign familial neonatal seizures to severe epileptic encephalopathies and autism spectrum disorders. However, the impact of these variants on the molecular mechanisms underlying KCNQ3 channel function remains poorly understood and existing treatments have significant side effects. Here, we use voltage clamp fluorometry, molecular dynamic simulations, and electrophysiology to investigate NDD-associated variants in KCNQ3 channels. We identified two distinctive mechanisms by which loss– and gain–of function NDD-associated mutations in KCNQ3 affect channel gating: one directly affects S4 movement while the other changes S4-to-pore coupling. MD simulations and electrophysiology revealed that polyunsaturated fatty acids (PUFAs) primarily target the voltage-sensing domain in its activated conformation and form a weaker interaction with the channel’s pore. Consistently, two such compounds yielded partial and complete functional restoration in R227Q- and R236C-containing channels, respectively. Our results reveal the potential of PUFAs to be developed into therapies for diverse KCNQ3-based channelopathies.

Clinical and genetic analysis of 23 Chinese children with epilepsy associated with KCNQ2 gene mutations.

To summarize the clinical features and genetic mutation characteristics of Chinese children with KCNQ2-related epilepsy. A cohort of children with genetically caused epilepsy was evaluated at Linyi People's Hospital from January 2017 to December 2023. After next-generation sequencing and pathogenicity analysis, we summarized the medical records and genetic testing data of the children who had KCNQ2 gene mutations. We identified 23 KCNQ2 gene mutations. 73.9% (n = 17) of the mutation sites were located in S5-S6 segments and the C-terminal region. In addition to the common phenotypes, 2 new phenotypes were identified: infantile convulsion with paroxysmal choreoathetosis (ICCA) and febrile seizure plus (FS+). Of all the cases with abnormal video-electro-encephalography, three cases with self-limited familial infantile epilepsy (SeLNE) exhibited a small number of multifocal discharges. Of the patients who have taken a particular antiepileptic drug, the statistics on the number of patients who have responded to the drug are as follows: oxcarbazepine (8/9, 88.9%), levetiracetam (5/7, 71.4%), phenobarbital (9/16, 56.3%), and topiramate (2/5, 40.0%). However, the efficacy of phenobarbital varied widely in treating SeLNE and KCNQ2-DEE. At the final follow-up, 1 case with SeLNE had a transient developmental regression and 7 cases with KCNQ2-DEE had mild to severe developmental backwardness. Although clinically rare, we report 10 new KCNQ2 mutations and two new phenotypes: ICCA and FS+. This further expands genetic and phenotypic spectrum of KCNQ2-related epilepsy. The gene mutation sites are mostly located in S5-S6 segments and the C-terminal region, and the former is usually associated with KCNQ2-DEE. Sodium channel blockers (including oxcarbazepine and topiramate) and levetiracetam should be prioritized over phenobarbital for KCNQ2-DEE. Some cases with KCNQ2-related epilepsy may have transient developmental regression during periods of frequent seizures. Early treatment and early seizure control may be beneficial for willing outcomes in children with KCNQ2-DEE. This article reports 23 cases of children with KCNQ2-related epilepsy, including 10 new mutation sites and 2 new phenotypes. It further expands the genetic and phenotypic spectrum of KCNQ2-related epilepsy. In addition, the article summarizes the gene mutation characteristics and clinical manifestations of children with KCNQ2-related epilepsy, with the expectation of providing a certain theoretical basis for the diagnosis and treatment of such patients.

Establishment of a transgene-free iPS cell line (SDCHi008-A) from a young patient bearing a KCNQ2 mutation and suffering from Epilepsy

Epilepsy is a chronic neurological disease which has affected ∼ 65 million people worldwide. In this study, peripheral blood mononuclear cells were isolated from a young patient patient bearing a KCNQ2 gene mutation and suffering from Epilepsy verified by clinical and genetic diagnosis. Induced pluripotent stem cells (iPSCs) were established by a non-integrative method, using plasmids carrying OCT4, SOX2, KLF4, BCL-XL and C-MYC. The established iPSCs presented typical pluripotent cells morphology, normal karyotype, and potential to differentiate into three germ layers. Our approach offers a useful model to explore pathogenesis and therapy of Epilepsy.

Establishment of human embryonic stem cell lines carrying LQT1 mutations by CRISPR base editing

The KCNQ1 gene encodes a voltage-gated potassium channel required for cardiac action potentials. Mutations in this gene have been associated with hereditary long QT syndrome 1, Jervell and Lange-Nielsen syndromes, and familial atrial fibrillation. The NM_000218.3(KCNQ1): c.604 + 2T > C mutation has been categorized as the causative variant leading to LQT1. In this study, we generated a KCNQ1 (c.644 + 2T > C) mutation human embryonic stem cell line WAe009-A-1L based on CRISPR base editing system. WAe009-A-1L cell has the potential to differentiate cardiomyocytes and would be used as an in vitro disease model for mechanism exploration and drug screening.

Vestibular hair cells are more prone to damage by excessive acceleration insult in the mouse with KCNQ4 dysfunction

KCNQ4 is a voltage-gated K+ channel was reported to distribute over the basolateral surface of type 1 vestibular hair cell and/or inner surface of calyx and heminode of the vestibular nerve connected to the type 1 vestibular hair cells of the inner ear. However, the precise localization of KCNQ4 is still controversial and little is known about the vestibular phenotypes caused by KCNQ4 dysfunction or the specific role of KCNQ4 in the vestibular organs. To investigate the role of KCNQ4 in the vestibular organ, 6-g hypergravity stimulation for 24 h, which represents excessive mechanical stimulation of the sensory epithelium, was applied to p.W277S Kcnq4 transgenic mice. KCNQ4 was detected on the inner surface of calyx of the vestibular afferent in transmission electron microscope images with immunogold labelling. Vestibular function decrease was more severe in the Kcnq4p.W277S/p.W277S mice than in the Kcnq4+/+ and Kcnq4+/p.W277S mice after the stimulation. The vestibular function loss was resulted from the loss of type 1 vestibular hair cells, which was possibly caused by increased depolarization duration. Retigabine, a KCNQ activator, prevented hypergravity-induced vestibular dysfunction and hair cell loss. Patients with KCNQ4 mutations also showed abnormal clinical vestibular function tests. These findings suggest that KCNQ4 plays an essential role in calyx and afferent of type 1 vestibular hair cell preserving vestibular function against excessive mechanical stimulation.

A method of identifying the high-risk mutations of sudden cardiac death at KCNQ1 and KCNH2 genes

Sudden Cardiac Death (SCD) often shows negative anatomy results after a systemic autopsy and the gene mutations of potassium channel play a key role in the etiology of SCD. We established a feasible system to detect SCD-related mutations and investigated the mutations at KCNQ1 and KCNH2 genes in the Chinese population. We established a mutation detection system combined with multiplex PCR, SNaPshot technique, and capillary electrophoresis. We genotyped 101 putative mutations at KCNQ1 and KCNH2 genes in 60 SCD of negative anatomy and 50 controls using the established assay and compared Odd Ratio (OR). Four coding variants were identified in the KCNQ1 gene: S546S, I145I, P448R, and G643S. The mutations of I145I and S546S did not differ significantly in the SCD compared with controls. 21 SCD individuals (35 %) and 1 control individual (2 %) showed a genotype of C/G at P448R (OR = 17.5, 95 % CI [2.40–127.82]). 24 SCD individuals (40 %) and 1 control individual (2 %) showed a genotype of C/G at G643S (OR = 20.0, 95 % CI [2.75–145.25]). We established a robust assay for rapid screening the putative SCD-related mutations in KCNQ1 and KCNH2 genes. The new assay in our study is easily amenable to the majority of laboratories without the need for new specialized equipment. Our method will meet the increasing requirement of mutation screening for SCD in regular DNA laboratories and will help screen mutations in those dead of SCD and their relatives.

Genetic characterization of KCNQ1 variants improves risk stratification in type 1 long QT syndrome patients.

KCNQ1 mutations cause QTc prolongation increasing life-threatening arrhythmias risks. Heterozygous mutations [type 1 long QT syndrome (LQT1)] are common. Homozygous KCNQ1 mutations cause type 1 Jervell and Lange-Nielsen syndrome (JLNS) with deafness and higher sudden cardiac death risk. KCNQ1 variants causing JLNS or LQT1 might have distinct phenotypic expressions in heterozygous patients. The aim of this study is to evaluate QTc duration and incidence of long QT syndrome-related cardiac events according to genetic presentation. We enrolled LQT1 or JLNS patients with class IV/V KCNQ1 variants from our inherited arrhythmia clinic (September 1993 to January 2023). Medical history, ECG, and follow-up were collected. Additionally, we conducted a thorough literature review for JLNS variants. Survival curves were compared between groups, and multivariate Cox regression models identified genetic and clinical risk factors. Among the 789 KCNQ1 variant carriers, 3 groups were identified: 30 JLNS, 161 heterozygous carriers of JLNS variants (HTZ-JLNS), and 550 LQT1 heterozygous carriers of non-JLNS variants (HTZ-Non-JLNS). At diagnosis, mean age was 3.4 ± 4.7 years for JLNS, 26.7 ± 21 years for HTZ-JLNS, and 26 ± 21 years for HTZ-non-JLNS; 55.3% were female; and the mean QTc was 551 ± 54 ms for JLNS, 441 ± 32 ms for HTZ-JLNS, and 467 ± 36 ms for HTZ-Non-JLNS. Patients with heterozygous JLNS mutations (HTZ-JLNS) represented 22% of heterozygous KCNQ1 variant carriers and had a lower risk of cardiac events than heterozygous non-JLNS variant carriers (HTZ-Non-JLNS) [hazard ratio (HR) = 0.34 (0.22-0.54); P < 0.01]. After multivariate analysis, four genetic parameters were independently associated with events: haploinsufficiency [HR = 0.60 (0.37-0.97); P = 0.04], pore localization [HR = 1.61 (1.14-1.2.26); P < 0.01], C-terminal localization [HR = 0.67 (0.46-0.98); P = 0.04], and group [HR = 0.43 (0.27-0.69); P < 0.01]. Heterozygous carriers of JLNS variants have a lower risk of cardiac arrhythmic events than other LQT1 patients.

Maturing hiPSC-cardiomyocytes in cardiac microtissues for accurate preclinical in vitro modelling of long-QT syndrome type 1

Abstract Funding Acknowledgements Type of funding sources: Foundation. Main funding source(s): reNEW - Novo Nordisk Foundation Center for Stem Cell Medicine Background Long-QT syndrome type 1 (LQT1), a cardiac arrhythmia often leading to sudden cardiac death, is due to mutations in KCNQ1 gene. Human iPSC-derived cardiomyocytes (hiPSC-CMs) have been widely used to model LQT1, promoting the concept of their use in preclinical studies. However, KCNQ1 locus is subjected to developmentally regulated genomic imprinting in the heart: in fetal cardiomyocytes the paternal allele is repressed, while both alleles become expressed after birth. Since hiPSC-CMs are typically immature fetal-like cells, residual imprinting may affect evaluation of KCNQ1 mutations in this system. Purpose This study wants to address the imprinting status of KCNQ1 in hiPSC-CMs and propose maturing hiPSC-CMs as a solution for reliable LQT1 modelling. Methods We derived hiPSC-CMs from a LQT1 patient carrying a heterozygous KCNQ1 mutation on the paternal allele and compared their electrical properties with the isogenic corrected hiPSC-CMs by patch clamp. We analysed KCNQ1 expression by ddPCR and DNA methylation. We used three-dimensional cardiac microtissues (MTs) composed by hiPSC-CMs, hiPSC-derived cardiac fibroblasts and endothelial cells to induce cardiomyocte maturation. Results LQT1 and isogenic corrected hiPSC-CMs showed no difference in action potential duration (APD). We hypothesized that residual KCNQ1 imprinting in hiPSC-CMs due to their immaturity was masking the phenotype. When we analyzed different hiPSC-CM lines, we found in all an unbalanced KCNQ1 allelic expression, with paternal allele accounting for 5-15% of the total. We then investigated whether maturing hiPSC-CMs could remove KCNQ1 imprinting. We included hiPSC-CMs in MTs, as this system previously showed to promote functional maturation and upregulation of KCNQ1. Here, we observed a substantial increased expression of the paternal allele and a reduction in the expression of KCNQ1OT1, the long non-coding RNA inducing paternal allele repression. LQT1 hiPSC-CMs dissociated from MTs showed prolonged APD compared to the corrected line. We also demonstrated that this was due to the reduction of the ionic current mediated by KCNQ1 (IKs) in LQT1 hiPSC-CMs compared to the corrected controls, thus revealing the mutation causative effect. Conclusions Our findings show that residual KCNQ1 imprinting in immature hiPSC-CMs can lead to underestimate (or overestimate) functional effects of pathological variants based on the parental allele that carries the mutation. This is overcome by maturation of hiPSC-CMs in tri-cellular cardiac microtissue which promotes KCNQ1 bi-allelic expression and allow dissecting mutation mechanisms. This study brings attention to the epigenetic regulation of hiPSC models and demonstrates the utility of using matured hiPSC-CMs as in vitro preclinical model for cardiac arrhythmias.

Clinical and genetic analysis of 18 patients with KCNQ2 mutations from South China.

We aimed to delineate the genotype and phenotype of patients with KCNQ2 mutations from South China. Clinical manifestations and characteristics of KCNQ2 mutations of patients from South China were analyzed. Previous patients with mutations detected in this study were reviewed. Eighteen epilepsy patients with KCNQ2 mutations, including seven self-limited neonatal epilepsy (SeLNE), two self-limited infantile epilepsy (SeLIE) and nine developmental and epileptic encephalopathy (DEE) were enrolled. The age of onset (p=0.006), mutation types (p=0.029), hypertonia (p=0.000), and seizure offset (p=0.029) were different in self-limited epilepsy (SeLE) and DEE. De novo mutations were mainly detected in DEE patients (p=0.026). The mutation position, EEG or the age of onset were not predictive for the seizure or ID/DD outcome in DEE, while the development of patients free of seizures was better than that of patients with seizures (p=0.008). Sodium channel blockers were the most effective anti-seizure medication, while the age of starting sodium channel blockers did not affect the seizure or development offset. We first discovered the seizure recurrence ratio in SeLNE/SeLIE was 23.1% in South China. Four novel mutations (c.790T>C, c.355_363delGAGAAGAG, c.296+2T>G, 20q13.33del) were discovered. Each of eight mutations (c.1918delC, c.1678C>T, c.683A>G, c.833T>C, c.868G>A, c.638G>A, c.997C>T, c.830C>T) only resulted in SeLE or DEE, while heterogeneity was also found. Six patients in this study have enriched the known phenotype caused by the mutations (c.365C>T, c.1A>G, c.683A>G, c.833T>C, c.830C>T, c.1678C>T). This research has expanded known phenotype and genotype of KCNQ2-related epilepsy, and the different clinical features of SeLE and DEE from South China.

A LONG QT SYNDROME WITHOUT MANIFESTATION

Abstract A 66–year–old Caucasian woman presented for outpatient evaluation due to elevated blood pressure levels at home (approximately 220/120 mmHg) and a significant family history of long QT syndrome. The index case in the family appeared to be her sister, investigated following an ECG showing markedly prolonged QT interval and a family history of sudden cardiac death. The patient underwent genetic analysis, revealing a positive mutation in KCNQ1. She was currently on treatment with Levotiroxina for recently discovered hypothyroidism.The ECG showed sinus rhythm with a heart rate of 85 bpm, signs of left ventricular hypertrophy, particularly Sokolow (SV1 + RV6 70 mm) and Peguero Lo Presti (SD + SV4 50 mm). The QTc interval was 515 ms (Bazett). Echocardiography revealed severe left ventricular hypertrophy (SIVd 14 mm; PWd 12 mm; LVMi 128 g/m2; RWT 0.5) with normal overall systolic function (EF 60%). No significant valvular pathologies were observed, and the right ventricle appeared normal in size and function.The hypertrophy was attributed to uncontrolled severe arterial hypertension. However, the identification of a prolonged QT interval in a patient with a strong family component (Schwartz score 4, high probability) led to genetic testing, confirming a mutation in KCNQ1. As the patient was asymptomatic with a low risk of major arrhythmias over the next 5 years (1–2–3–LQTS–risk score 2.77%), she entered follow–up and received beta–blocker therapy, specifically nadolol, combined with other antihypertensive medications.This clinical case describes an entire family with LQTS1 (type 1) positive for KCNQ1 mutation, exhibiting phenotypic manifestations distinct from those reported in the literature. Notably, there was a prevalence in females, and the condition was incidentally discovered during a routine checkup conducted for unrelated reasons, without any history of major arrhythmias.Long QT syndrome (LQTS) is characterized by a prolonged QT interval, predisposing individuals to life–threatening arrhythmias leading to syncope and sudden death. Mutations in genes encoding ion channels account for 75% of LQTS cases. LQTS1, associated with a "loss–of–function" mutation in the KCNQ1 gene, represents one of the three genetic subtypes. LQTS1 typically manifests with arrhythmias in childhood, with a male predominance. Adrenergic triggers are crucial precipitants for arrhythmic events

Glial KCNQ K+ channels control neuronal output by regulating GABA release from glia in C. elegans

KCNQs are voltage-gated K+ channels that control neuronal excitability and are mutated in epilepsy and autism spectrum disorder (ASD). KCNQs have been extensively studied in neurons, but their function in glia is unknown. Using voltage, calcium, and GABA imaging, optogenetics, and behavioral assays, we show here for the first time in Caenorhabditis elegans (C.elegans) that glial KCNQ channels control neuronal excitability by mediating GABA release from glia via regulation of the function of L-type voltage-gated Ca2+ channels. Further, we show that human KCNQ channels have the same role when expressed in nematode glia, underscoring conservation of function across species. Finally, we show that pathogenic loss-of-function and gain-of-function human KCNQ2 mutations alter glia-to-neuron GABA signaling in distinct ways and that the KCNQ channel opener retigabine exerts rescuing effects. This work identifies glial KCNQ channels as key regulators of neuronal excitability via control of GABA release from glia.

The electrophysiologic effects of KCNQ1 extend beyond expression of IKs: evidence from genetic and pharmacologic block.

While variants in KCNQ1 are the commonest cause of the congenital long QT syndrome, we and others find only a small IKs in cardiomyocytes from human-induced pluripotent stem cells (iPSC-CMs) or human ventricular myocytes. We studied population control iPSC-CMs and iPSC-CMs from a patient with Jervell and Lange-Nielsen (JLN) syndrome due to compound heterozygous loss-of-function (LOF) KCNQ1 variants. We compared the effects of pharmacologic IKs block to those of genetic KCNQ1 ablation, using JLN cells, cells homozygous for the KCNQ1 LOF allele G643S, or siRNAs reducing KCNQ1 expression. We also studied the effects of two blockers of IKr, the other major cardiac repolarizing current, in the setting of pharmacologic or genetic ablation of KCNQ1: moxifloxacin, associated with a very low risk of drug-induced long QT, and dofetilide, a high-risk drug. In control cells, a small IKs was readily recorded but the pharmacologic IKs block produced no change in action potential duration at 90% repolarization (APD90). In contrast, in cells with genetic ablation of KCNQ1 (JLN), baseline APD90 was markedly prolonged compared with control cells (469 ± 20 vs. 310 ± 16 ms). JLN cells displayed increased sensitivity to acute IKr block: the concentration (μM) of moxifloxacin required to prolong APD90 100 msec was 237.4 [median, interquartile range (IQR) 100.6-391.6, n = 7] in population cells vs. 23.7 (17.3-28.7, n = 11) in JLN cells. In control cells, chronic moxifloxacin exposure (300 μM) mildly prolonged APD90 (10%) and increased IKs, while chronic exposure to dofetilide (5 nM) produced greater prolongation (67%) and no increase in IKs. However, in the siRNA-treated cells, moxifloxacin did not increase IKs and markedly prolonged APD90. Our data strongly suggest that KCNQ1 expression modulates baseline cardiac repolarization, and the response to IKr block, through mechanisms beyond simply generating IKs.

Investigation of Mutations in H19, IGF2, CDKN1C, KCNQ1, and NSD1 Genes in Iranian Children Suspected of Silver-Russell Syndrome (SRS) and Beckwith-Wiedemann Syndrome (BWS) with MS-MLPA

Background: Silver-Russell Syndrome (SRS) and Beckwith-Wiedemann Syndrome (BWS) are two syndromes that are poorly diagnosed in many affected people due to mild and subtle symptoms, genetic complexity, and lack of familiarity with the hallmarks. Objective: The present study was conducted with the aim of determining mutations in H19, IGF2, CDKN1C, KCNQ1, and NSD1 genes in Iranian children suspected of SRS and BWS by the MS-MLPA method. Methods: In this case series study, which was conducted in 2022 in Pars Genome Laboratory, Karaj, Iran, 10 children suspected of SRS or BWS syndrome were included. These 10 Iranian children were referred by pediatric endocrinologists. 5 ml of peripheral blood was taken per patient for DNA extraction. MS-MLPA method was undertaken for possible mutations (methylation and deletion) in H19, IGF2, CDKN1C, KCNQ1, and NSD1 genes. Results: The interpretation of MS-MLPA results showed that out of 10 children (4 boys and 6 girls) suspected of having SRS or BWS syndrome (based on the pediatric endocrinologist’s diagnosis), only 3 children were definitively diagnosed with SRS or BWS syndrome. Based on this, methylation changes in the promoter of ICR1 and ICR2, which are related to the genes H19, IGF2, CDKN1C, KCNQ1, and NSD1, lead to the development of SRS or BWS syndrome. Conclusion: The present findings showed that methylation changes in H19, IGF2, CDKN1C, KCNQ1, and NSD1 genes are associated with the occurrence of SRS or BWS syndrome. In this study, we show that MS-MLPA can serve as a rapid, inexpensive, and reliable method for the molecular diagnosis of these syndromes.

Two family members with partial hypopituitarism and gingival fibromatosis caused by a missense mutation in KCNQ1

Two family members with partial hypopituitarism and gingival fibromatosis caused by a missense mutation in KCNQ1

Abstract 17871: Heterozygous Carriers of KCNQ1 Variants Associated With the Jervell-Lange-Nielsen Syndrome Have a Better Outcome When Compared to Other Type 1 LQTS Patients

Background: KCNQ1 mutations are associated with a risk of life-threatening torsade de Pointes. In the most common presentation, the mutation is heterozygous (type 1 LQTS). The homozygous expression causes type 1 Jervell-Lange-Nielsen syndrome (JLNS) with deafness and higher risk of sudden cardiac death. Hypothesis: Heterozygous carriers of JLN mutations would have different phenotype expression than patients carrying other KCNQ1 variants. Aims: To evaluate QTc duration and incidence of LQTS-related cardiac events according to genetic presentation. Methods: All patients with class 4 or 5 KCNQ1 variants for LQT1 or JLNS followed in our center (September 1993 to January 2023) were included. Lifelong Severe Cardiac events (ACA, SCD, appropriate shocks) and cardiac events (severe event + cardiac syncope) were collected.Quantitative data were compared between groups by ANOVA. Kaplan-Meier survival curves with the log-rank test were used to compare survival between the groups. Results: Three groups were identified among 741 LQT1 patients (55.3% female, age at diagnosis 25.2 years); 30 JLNS (group 1), 557 LQT1 carrying heterozygous mutations not found in the JLNS population (group 2), and 154 heterozygous carriers of mutations found in the JLNS population (group 3). QTc interval duration was different between groups (548±60ms, 467±36ms and 450±31ms in group 1, 2, 3 respectively, p&lt;0.001).Patients carrying heterozygous JLN mutations (group 3) had a lower risk for cardiac events than patients with heterozygous non JLN mutations (group2) (HR 0.36 [0.23-0.57]; p&lt;0.01) (Figure). Four parameters were independently associated with cardiac events: QTc (HR 1.01 [1.01-1.01]; p&lt;0.01, haploinsufficiency (HR 0.57 [0.36-0.92]; p&lt;0.05), pore localization (HR 1.63 [1.16-2.30]; p&lt;0.01), and group (HR 0.50 [0.32-0.81]; p&lt;0.01). Conclusion: Heterozygous carriers of JLNS variants have a lower risk of cardiac arrhythmic events that other type 1 LQTS patients.

Generation of three induced pluripotent stem cell lines from a patient with KCNQ2 developmental and epileptic encephalopathy as a result of the pathogenic variant c.881C > T; p.Ala294Val (NUIGi059-A, NUIGi059-B, NUIGi059-C) and 3 healthy controls (NUIGi060-A, NUIGi060-B, NUIGi060-C)

Developmental and epileptic encephalopathies (DEEs) are a group of severe, early-onset epilepsies which are often caused by genetic mutations in ion channels. Mutations in KCNQ2, which encodes the voltage-gated potassium channel Kv7.2, is known to cause DEE. Here, we generated three iPSC lines from dermal fibroblasts of a 5 year-old male patient with the KCNQ2 c.881C > T (p.Ala294Val) pathogenic heterozygous variant and three iPSC lines from a healthy sibling control. These iPSC lines have been validated by SNP karyotyping, STR analysis, expression of pluripotent genes, the capacity to differentiate into three germ layers and confirmation of the mutation in the patient.

Mechanistic understanding of KCNQ1 activating polyunsaturated fatty acid analogs.

The KCNQ1 channel is important for the repolarization phase of the cardiac action potential. Loss of function mutations in KCNQ1 can cause long QT syndrome (LQTS), which can lead to cardiac arrythmia and even sudden cardiac death. We have previously shown that polyunsaturated fatty acids (PUFAs) and PUFA analogs can activate the cardiac KCNQ1 channel, making them potential therapeutics for the treatment of LQTS. PUFAs bind to KCNQ1 at two different binding sites: one at the voltage sensor (Site I) and one at the pore (Site II). PUFA interaction at Site I shifts the voltage dependence of the channel to the left, while interaction at Site II increases maximal conductance. The PUFA analogs, linoleic-glycine and linoleic-tyrosine, are more effective than linoleic acid at Site I, but less effective at Site II. Using both simulations and experiments, we find that the larger head groups of linoleic-glycine and linoleic-tyrosine interact with more residues than the smaller linoleic acid at Site I. We propose that this will stabilize the negatively charged PUFA head group in a position to better interact electrostatically with the positively charges in the voltage sensor. In contrast, the larger head groups of linoleic-glycine and linoleic-tyrosine compared with linoleic acid prevent a close fit of these PUFA analogs in Site II, which is more confined. In addition, we identify several KCNQ1 residues as critical PUFA-analog binding residues, thereby providing molecular models of specific interactions between PUFA analogs and KCNQ1. These interactions will aid in future drug development based on PUFA-KCNQ1 channel interactions.