New phenotype of severe neonatal episodic laryngospasm due to a missense mutation in SCN4A: A case report and literature review / 中南大学学报(医学版)

Severe neonatal episodic laryngospasm (SNEL) is an ion channel disease characterized by recurrent life-threatening myotonia of respiratory muscle due to mutations in the voltage-gated sodium channel genes. Here we reported a newborn manifested as paroxysmal cyanosis and limb myotonia after birth. The neonate also developed muscle hypertrophy and stunted growth during the follow-up. Whole exome sequencing confirmed c.2395G>A, p. Ala799Thr heterozygous mutation of SCN4A. Carbamazepine was found to be effective on treating the disease. This case expands our understanding of the phenotype resulting from SCN4A mutations. By summarizing the characteristics of reported 16 cases in SNEL, we found they were mainly in the p.G1306E mutation. The common symptoms were upper airway muscle stiffness and feeding difficulties during neonates. When grow up, most patients have different degrees of recurrent attacks of myotonia and progressed muscle hypertrophy. Some of them have athlete-like special faces but all showed myotonic discharge in eletromyogram.

Flunarizine: a review of its role in migraine prophylaxis

Flunarizine, a potent calcium channel blocker has been used for more than three decades for the prophylactic management of migraine. Theories suggest that flunarizine may act through multiple mechanisms such as inhibition of cortical spreading depression, neurogenic inflammation and channelopathy. Flunarizine is efficacious in the management of various types of migraines such as common, classical, vestibular, abdominal, hemiplegic and pediatric migraine. It has a manageable safety profile with weight gain and drowsiness being commonly reported.

A novel in-frame mutation at the boundary between exon 21 and intron 21 of SCN4A in a family with paramyotonia congenita

@#Nondystrophic myotonias and periodic paralyses are an important group of genetic skeletal muscle disorders characterized by dysfunction of ion channels that regulate cell membrane excitability. Mutations in the Sodium Voltage-Gated Channel Alpha Subunit 4 (SCN4A) gene are associated with a spectrum of a heterogeneous group of skeletal muscle such as sodium channel myotonia, paramyotonia congenita, hyperkalemic periodic paralysis, congenital myasthenia, and congenital myopathy. Gain of function mutations in SCN4A cause three muscle disorders with overlapping clinical phenotypes: myotonia, paramyotonia congenita, and hyperkalemic periodic paralysis. Here, we describe the clinical and genetic features of a new family with paramyotonia. The proband, an eight-year-old girl, began to experience muscle stiffness in her hands and limbs on exposure to exercise exercise at the age of four and presented with myotonia. She was initially misdiagnosed with myotonic dystrophy because of worsening weakness with significant elevation of serum creatinine kinase levels. Two other affected family members had paradoxical myotonia in the face and hands on exposure to cold muscle stiffness in her face, hands, and limbs on exposure to cold and showed grip myotonia on physical examination. A novel heterozygous in-frame insertion, c.3911_3912+1dupAGA, at the boundary between exon 21 and intron 21 of SCN4A was identified using whole exome sequencing. Our finding enhances our understanding of the genotype and phenotype of patients with paramyotonia congenita, caused by mutations in the SCN4A gene.

Síndrome de Brugada como causa de muerte súbita de origen cardíaco / Brugada syndrome as a cause of sudden cardiac death

ResumenMuerte súbita se define como un evento fatal e inesperado que ocurre en un individuo aparentemente sano. Una de las principales causas son las de origen cardiovascular, entre las cuales se encuentran las anormalidades electrofisiológicas primarias como lo es el síndrome de Brugada. Este se define como una canalopatía que afecta canales de sodio, producto de una variante genética, principalmente de herencia autosómica dominante.Se ha determinado que la mutación del gen SCN5A es la más asociada con el síndrome. El diagnóstico se realiza mediante historia clínica y patrones electrocardiográficos específicos y generalmente se presenta como síncope o como muerte súbita resucitada debida a taquicardia ventricular polimórfica o fibrilación ventricular. El desfibrilador automático implantable es la principal herramienta para la prevención de muerte súbita, sin embargo, previo a su uso debe hacerse una adecuada estratificación de los pacientes, tanto para prevenir muerte súbita, como para evitar el uso innecesario del dispositivo.

AbstractSudden death is defined as an unexpected fatal event occurring in an apparently healthy subject. Sudden cardiac death is a leading cause, among which are primary electrical abnormalities such as Brugada Syndrome. Brugada Syndrome is an autosomal dominant channelopathy affecting the sodium channel. SCN5A has emerged as the most common gene associated with Brugada syndrome. The diagnosis is suggested by the clinical history in a patient with specific electrocardiographic pattern. The most typical presentation is syncope or resuscitated sudden death due to polymorphic ventricular tachycardia or ventricular fibrillation. An implantable cardioverter defibrillator is the main tool for preventing sudden death, and correct risk stratification in these patients is important both to prevent sudden death and to avoid unnecessary implantable cardioverter defibrillator use.

Structure-based assessment of disease-related mutations in human voltage-gated sodium channels

Voltage-gated sodium (Na) channels are essential for the rapid upstroke of action potentials and the propagation of electrical signals in nerves and muscles. Defects of Na channels are associated with a variety of channelopathies. More than 1000 disease-related mutations have been identified in Na channels, with Na1.1 and Na1.5 each harboring more than 400 mutations. Na channels represent major targets for a wide array of neurotoxins and drugs. Atomic structures of Na channels are required to understand their function and disease mechanisms. The recently determined atomic structure of the rabbit voltage-gated calcium (Ca) channel Ca1.1 provides a template for homology-based structural modeling of the evolutionarily related Na channels. In this Resource article, we summarized all the reported disease-related mutations in human Na channels, generated a homologous model of human Na1.7, and structurally mapped disease-associated mutations. Before the determination of structures of human Na channels, the analysis presented here serves as the base framework for mechanistic investigation of Na channelopathies and for potential structure-based drug discovery.

Highlights for the 6th International Ion Channel Conference: ion channel structure, function, disease and therapeutics

To foster communication and interactions amongst international scholars and scientists in the field of ion channel research, the 6th International Ion Channel Conference (IICC-2017) was held between June 23-27, 2017 in the eastern coastal city of Qingdao, China. The meeting consisted of 450 attendees and 130 speakers and poster presenters. The program consisted of research progress, new findings and ongoing studies that were focused on (1) Ion channel structure and function; (2) Ion channel physiology and human diseases; (3) Ion channels as targets for drug discovery; (4) Technological advances in ion channel research. An insightful overview was presented on the structure and function of the mechanotransduction channelNOMPC (No mechanoreceptor potential C), a member of the transient receptor potential (TRP) channel family. Recent studies on Transmembrane protein 16 or Anoctamin-1 (TMEM16A, a member of the calcium-activated chloride channel [CaCC] family) were summarized as well. In addition, topics for ion channel regulation, homeostatic feedback and brain disorders were thoroughly discussed. The presentations at the IICC-2017 offer new insights into our understanding of ion channel structures and functions, and ion channels as targets for drug discovery.

Genetic and Clinical Aspects of Brugada Syndrome.

Death is always dreadful and the diseases those causes sudden death are universal threats in health concern. Brugada syndrom is a recently identified entity of arrhythmia and sudden cardiac death. This genetic and male dominant disorder is prevalent in Southeast Asian region. At least seven genes have been identified to associate with its occurrence though the detail pathophysiological mechanism is till to be resolved. The correlation of ion channel genes to Brugada syndrom is still dubious as the same genes also related to other cardiac diseases. Here we review the genetic aspects of Brugada syndrom with a breif overview of epidemiology, diagnosis and management system.

Intractable hyperkalemia due to nicorandil induced potassium channel syndrome.

Nicorandil is a commonly used antianginal agent, which has both nitrate‑like and ATP‑sensitive potassium (KATP) channel activator properties. Activation of potassium channels by nicorandil causes expulsion of potassium ions into the extracellular space leading to membrane hyperpolarization, closure of voltage‑gated calcium channels and finally vasodilatation. However, on the other hand, being an activator of KATP channel, it can expel K+ ions out of the cells and can cause hyperkalemia. Here, we report a case of nicorandil induced hyperkalemia unresponsive to medical treatment in a patient with diabetic nephropathy.

The Relationship Between Gastric Myoelectric Activity and SCN5A Mutation Suggesting Sodium Channelopathy in Patients With Brugada Syndrome and Functional Dyspepsia: A Pilot Study

BACKGROUND/AIMS: SCN5A encodes the cardiac-specific NaV1.5 sodium channel, and Brugada syndrome is a cardiac conduction disorder associated with sodium channel alpha-subunit (SCN5A) mutation. The SCN5A-encoded NaV1.5 channel is also found on gastrointestinal smooth muscle and interstitial cells of Cajal. We investigated the relationship between functional dyspepsia (FD) and SCN5A mutation to evaluate sodium channelopathy in FD. METHODS: Patients with Brugada syndrome or FD were examined using upper endoscopy, electrogastrography (EGG), FD symptom questionnaire based on Rome III criteria and genetic testing for SCN5A mutation. Symptom scores of FD and EGG findings were analyzed according to SCN5A mutation. RESULTS: A total of 17 patients (4 Brugada syndrome and 13 FD) participated in the study. An SCN5A mutation was noted in 75.0% of the patients with Brugada syndrome and in 1 (7.7%) of the patients with FD. Of 4 patients with SCN5A mutation, 2 (50%) had FD. Postprandial tachygastria and bradygastria were noted in 2 (50%) and 1 (25%) of the patients with SCN5A mutation, respectively. The EGG findings were not significantly different between positive and negative mutation in 17 patients. CONCLUSIONS: Although we did not find statistically significant results, we suggest that it is meaningful to attempt to identify differences in symptoms and gastric myoelectric activity according to the presence of an SCN5A mutation by EGG analysis. The relationship between FD and sodium channelopathy should be elucidated in the future by a large-scale study.

Parálisis periódica hiperpotasémica / Hyperpotassemia periodic paralysis

La parálisis periódica hiperpotasémica es una canalopatía del músculo esquelético que se caracteriza por episodios recurrentes de debilidad muscular que pueden ser desencadenados por el ejercicio, el frío, el reposo poco después del ejercicio y el aporte de potasio. Se presenta el caso de una paciente de 13 años de edad, con diagnóstico de parálisis periódica hiperpotasémica, sin antecedentes familiares de esta entidad y sin miotonía asociada. Los ataques de debilidad muscular sucedían en ocasiones diariamente y cada 2 o 3 días, con duración variable desde media hora hasta 24 a 48 h. Durante un episodio de debilidad muscular se constataron concentraciones de potasio en sangre de 7,14 mmol/L y el electromiograma mostró un patrón miopático. Se observó una disminución de la frecuencia de los episodios de debilidad muscular a los 2 meses de iniciado el tratamiento con acetazolamida por vía oral

The periodic hyperpotassemia paralysis is a striated muscle channelopathy characterized by recurrent episodes of muscular asthenia that may to be triggered by exercise, cold, not rest after exercise and potassium support. This the case of a female patient aged 13 diagnosed with hyperpotassemia periodic paralysis without family backgrounds of this entity and also without associated myotonia. The seizures of muscular asthenia occurred almost daily and each 2 or 3 days with a variable length from a half hour to 24 to 48 hours. During a episode of muscular asthenia there were blood potassium concentrations of 7,14 mmol/L and the electromyogram showed a myopathic pattern. There was a frequency decrease of episodes of muscular asthenia at 2 months of treatment onset with oral acetazolamide

Andersen-Tawil Syndrome – Periodic Paralysis with Dysmorphism.

Andersen-Tawil syndrome is a rare type of channelopathy characterized by the presence of periodic paralysis, cardiac arrhythmia (prolonged QT interval or ventricular arrhythmia) and distinct dysmorphic abnormalities. It is a type of potassium channelopathy that occurs sporadically or by autosomal dominant inheritance. We report a 14 year old boy with Andersen-Tawil syndrome.

Ion channelopathies in endocrinology: recent genetic findings and pathophysiological insights / Canalopatias em endocrinologia: achados genéticos recentes e fisiopatologia

Ion channels serve diverse cellular functions, mainly in cell signal transduction. In endocrine cells, these channels play a major role in hormonal secretion, Ca2+-mediated cell signaling, transepithelial transport, cell motility and growth, volume regulation and cellular ionic content and acidification of lysosomal compartments. Ion channel dysfunction can cause endocrine disorders or endocrine-related manifestations, such as pseudohypoaldosteronism type 1, Liddle syndrome, Bartter syndrome, persistent hyperinsulinemic hypoglycemia of infancy, neonatal diabetes mellitus, cystic fibrosis, Dent's disease, hypomagnesemia with secondary hipocalcemia, nephrogenic diabetes insipidus and, the most recently genetically identified channelopathy, thyrotoxic hypokalemic periodic paralysis. This review briefly recapitulates the membrane action potential in endocrine cells and offers a short overview of known endocrine channelopathies with focus on recent progress regarding the pathophysiological mechanisms and functional genetic defects.

Canais iônicos auxiliam diferentes funções celulares, principalmente na transdução de sinal. Nas células endócrinas, esses canais têm funções importantes na secreção hormonal, sinalização do Ca2+, transporte transepitelial, regulação da motilidade, volume e conteúdo iônico celular e da acidificação do compartimento lisossomal (pH). Como esperado, as alterações nos canais iônicos podem causar distúrbios endocrinológicos, como pseudo-hipoaldosteronismo tipo 1, síndrome de Liddle, síndrome de Bartter, hipoglicemia hiperinsulinêmica da infância, diabetes melito neonatal, fibrose cística, doença de Dent, hipomagnesemia com hipocalcemia secundária, diabetes insípido nefrogênico e paralisia periódica tirotóxica hipocalêmica. Este artigo propõe uma breve revisão das canalopatias endócrinas conhecidas, com foco particular nos recentes progressos no conhecimento dos mecanismos fisiopatológicos adquirido a partir das alterações funcionais encontradas.

Supraventricular tachyarrhythmia and Brugada syndrome: a case of Atrial Fibrillation and Brugada syndrome in a young patient without structural heart disease / Taquiarritmia supraventricular y síndrome de Brugada: un caso de fibrilación atrial y síndrome de Brugada en un paciente joven sin cardiopatía estructural

We report a case of a 29-year old man who initially presented with a single episode of syncope. The initial electrocardiogram (ECG) showed atrial fibrillation and an ST segment elevation on lead V1. A flecainide test unmasked the Brugada syndrome. The pathophysiology of Brugada syndrome and atrial fibrillation in this patient could be connected by sodium channel dysfunction throughout the heart. In addition, we reviewed the possible connection between Brugada syndrome and atrial fibrillation.

Reportamos el caso de un hombre de 29 años de edad que se presentó inicialmente con un solo episodio de síncope. El electrocardiograma inicial (ECG) mostró fibrilación atrial y una elevación del segmento ST en la derivación V1. Una prueba de flecainida reveló la presencia del síndrome de Brugada. La patofisiología del síndrome de Brugada y la fibrilación atrial en este paciente podrían estar conectados por una disfunción del canal de sodio a través del corazón. Además, examinamos la posible conexión entre el síndrome de Brugada y la fibrilación atrial.

Clinical and molecular diagnosis of a Costa Rican family with autosomal recessive myotonia congenita (Becker disease) carrying a new mutation in the CLCN1 gene

Myotonia congenita is a muscular disease characterized by myotonia, hypertrophy, and stiffness. It is inherited as either autosomal dominant or recessive known as Thomsen and Becker diseases, respectively. Here we confirm the clinical diagnosis of a family diagnosed with a myotonic condition many years ago and report a new mutation in the CLCN1 gene. The clinical diagnosis was established using ocular, cardiac, neurological and electrophysiological tests and the molecular diagnosis was done by PCR, SSCP and sequencing of the CLCN1 gene. The proband and the other affected individuals exhibited proximal and distal muscle weakness but no hypertrophy or muscular pain was found. The myotatic reflexes were lessened and sensibility was normal. Electrical and clinical myotonia was found only in the sufferers. Slit lamp and electrocardiogram tests were normal. Two affected probands presented diminution of the sensitive conduction velocities and prolonged sensory distal latencies. The clinical spectrum for this family is in agreement with a clinical diagnosis of Becker myotonia. This was confirmed by molecular diagnosis where a new disease-causing mutation (Q412P) was found in the family and absent in 200 unaffected chromosomes. No latent myotonia was found in this family; therefore the ability to cause this subclinical sign might be intrinsic to each mutation. Implications of the structure-function-genotype relationship for this and other mutations are discussed. Adequate clinical diagnosis of a neuromuscular disorder would allow focusing the molecular studies toward the confirmation of the initial diagnosis, leading to a proper clinical management, genetic counseling and improving in the quality of life of the patients and relatives.

La miotonía congénita es una enfermedad muscular caracterizada por miotonía, hipertrofia y rigidez. Se presenta con dos patrones de herencia, autosómica dominante en cuyo caso recibe el nombre de miotonía de Thomsen, o autosómica recesiva conocida como miotonía de Becker. En este trabajo se confirmó el diagnóstico clínico presuntivo hecho hace algunos años en una familia con una condición miotónica y se reporta una nueva mutación en el gen CLCN1. El diagnóstico clínico se estableció después de estudios oculares, cardíacos, neurológicos y electrofisiológicos. El diagnóstico molecular fue hecho mediante la PCR, SSCP y secuenciación del gen CLCN1. El caso índice y los otros individuos afectados exhibieron debilidad muscular proximal y distal, pero no se encontró hipertrofia ni dolor muscular. Los reflejos miotáticos estuvieron disminuidos y la sensibilidad fue normal. Se encontró miotonía clínica y eléctrica solo en los individuos afectados. Las pruebas de lámpara de hendidura y electrocardiograma resultaron normales. Dos individuos afectados presentaron disminución de las velocidades de conducción sensitiva y latencias distales sensoriales prolongadas. El cuadro clínico concuerda con la miotonía de Becker, lo cual se confirmó con el hallazgo de una mutación responsable de la enfermedad en el gen CLCN1 (Q412P), la cual se encontró en la familia y estuvo ausente en 200 cromosomas provenientes de la población general. No se encontró miotonía latente, por lo que probablemente la habilidad de causar este signo subclínico es intrínsica de cada mutación. Afinar el diagnóstico clínico diferencial de las enfermedades neuromusculares permitiría enfocar los estudios moleculares hacia la confirmación del diagnóstico inicial en forma eficiente, lo cual permitiría un manejo clínico y asesoramiento genético más adecuados y una mejora en la calidad de vida de los pacientes y sus familias.

Possibility of Epithelial Sodium Channelopathy as a Pathogenesis of Meniere's Disease

BACKGROUND AND OBJECTIVES: Meniere's disease is a paroxysmal disorder with vertigo and hearing loss. Its episodic nature of vertigo attacks and responsiveness to diuretics is similar to several neurologic disorders with channelopathy. We performed this study to identify the possibility sodium channelopathy in the patients with Meniere's disease. MATERIALS AND METHOD: Thirty patients with definite Meniere's disease and 25 normal controls were included in this study. Clinical features of the patients with Meniere's disease were collected using dizziness chart. Whole blood was taken from all the patients with Meniere's disease and normal controls and used for DNA testing. alphaENaC gene was screened for mutations using direct DNA sequencing. RESULTS: Patients with Meniere's disease in this study showed the various clinical features of onset age, number of attacks and hearing levels. Many of them showed the caloric response reduction and abnormal electrocochleogram. Genetic analysis did not identify any mutations or differences in alphaENaC gene in normal controls and the patients with Meniere's disease. CONCLUSION: Na channelopathy due to alphaENaC gene mutation might not be a pathogenesis of Meniere's disease. Further studies with other subunits of ENaC and other ion channel genes are needed to explore the possibility of channelopathy as a pathogenesis of Meniere's disease.

Possibility of Epithelial Sodium Channelopathy as a Pathogenesis of Meniere's Disease

BACKGROUND AND OBJECTIVES: Meniere's disease is a paroxysmal disorder with vertigo and hearing loss. Its episodic nature of vertigo attacks and responsiveness to diuretics is similar to several neurologic disorders with channelopathy. We performed this study to identify the possibility sodium channelopathy in the patients with Meniere's disease. MATERIALS AND METHOD: Thirty patients with definite Meniere's disease and 25 normal controls were included in this study. Clinical features of the patients with Meniere's disease were collected using dizziness chart. Whole blood was taken from all the patients with Meniere's disease and normal controls and used for DNA testing. alphaENaC gene was screened for mutations using direct DNA sequencing. RESULTS: Patients with Meniere's disease in this study showed the various clinical features of onset age, number of attacks and hearing levels. Many of them showed the caloric response reduction and abnormal electrocochleogram. Genetic analysis did not identify any mutations or differences in alphaENaC gene in normal controls and the patients with Meniere's disease. CONCLUSION: Na channelopathy due to alphaENaC gene mutation might not be a pathogenesis of Meniere's disease. Further studies with other subunits of ENaC and other ion channel genes are needed to explore the possibility of channelopathy as a pathogenesis of Meniere's disease.

Genetics of Channelopathy: Familial Periodic Paralysis

Familial periodic paralysis (FPP) is inherited as a dominant trait, and the intermittent failure to maintain the skeletal muscle resting potential is due to mutations in the genes coding for the voltage-gated ion channels. Because several variants of FPP have been delineated on the bases of clinical features, the expectation was that these variants might be due to involvement of different classes of ion channels. The reality of the situation has proven to be more complicated. Mutation-induced defects in the same channel may give rise to diverse phenotypes (phenotypic heterogeneity) and, conversely, mutation in different channel genes may produce a common phenotype (genetic heterogeneity). Regardless of which type of ion channel is defective, the final common pathway is the depolarization-induced loss of muscle excitability; gain-of-function defect in voltage-gated Na channel may cause myotonia, periodic paralysis or both, clinical features of hyperkalemic periodic paralysis and paramyotonia congenita, and loss-of-function defects in voltage-gated Na and Ca channel and K channel may be responsible for periodic paralysis, cardiac arrhythmia or both in hypokalemic periodic paralysis or Andersen's syndrome, respectively. This review focuses on the clinical features, molecular genetic defects, and pathophysiologic mechanisms that underlie FPP.