A cardiac sodium channel mutation identified in Brugada syndrome associated with atrial standstill

Mutations in the cardiac Na+ channel gene SCN5A are responsible for multiple lethal ventricular arrhythmias including Brugada syndrome and congenital long QT syndrome. Here we report a case of Brugada syndrome with ST elevation in the right precordial and inferior leads accompanied by atrial standstill and spontaneous ventricular fibrillation. Atrial standstill and J wave elevation were provoked by procainamide. Genetic analysis revealed a missense mutation (R367H) in SCN5A. The resultant mutant Na+ channel was nonfunctional when expressed heterologously in Xenopus oocytes. Our study suggests that genetic defects in SCN5A may be associated with atrial standstill in combination with ventricular arrhythmias.     

Genetic analysis of Brugada syndrome in Western Japan: two novel mutations.

BACKGROUND: Brugada syndrome is a form of idiopathic ventricular fibrillation characterized by right bundle-branch block pattern and ST elevation in the right precordial leads of the ECG. The SCN5A gene encodes the alpha-subunit of the human heart sodium channel, which plays a critical role in cardiac excitability, and mutations of SCN5A could underlie Brugada syndrome. METHODS AND RESULTS: To detect mutations of SCN5A, DNA samples from 12 Japanese patients with Brugada syndrome were analyzed using direct sequencing. Two patients had novel mutations, G292S and S835L, but no other mutations of SCN5A were detected in the remaining patients. The first mutation, G292S, was identified adjacent to the pore-lining region between the DIS5 and DIS6 transmembrane segments of SCN5A, and the second mutation, S835L, was in the intracellular loop connecting the DIIS4 to DIIS5. Both mutations were not detected in 100 unrelated control subjects. CONCLUSION: Two novel SCN5A mutations have been found in Japanese patients with Brugada syndrome.     

Genetic Modulation of Brugada Syndrome by a Common Polymorphism

Background: Brugada syndrome predisposes some subjects to ventricular tachyarrhythmias and sudden cardiac death. Mutations in SCN5A gene have been associated with ∼25% of Brugada syndrome patients. A common variant in SCN5A, H558R has shown to improve sodium channel activity in mutated channels. We studied whether common variant H558R has any clinical implications in the phenotype of Brugada syndrome.
Methods: Our study population consisted of Brugada syndrome subjects 75 with SCN5A mutation and 92 without SCN5A mutation. Their mean age was 39 ± 15 and 42 ± 17 years, and 65% and 86% were male, respectively. We measured PR-, QRS-, QTc-intervals from leads II and V2 of the 12-lead ECG. We also evaluated J-point amplitude from lead V2 and R'/S ratio from lead aVR (the "aVR sign"). The H558R (A→G) genotype was detected with direct sequencing of the SCN5A gene.
Results: The AA genotype carriers had longer QRS duration in lead II (P = 0.017) and higher J-point elevation in lead V2 (P = 0.013), higher "aVR sign" (P = 0.005) and a trend toward more subjects with symptoms (P = 0.067) than G allele carriers. None of the results were significant in Brugada syndrome subjects without SCN5A mutation.
Conclusion: The common variant H558R seems to be a genetic modulator of Brugada syndrome among carriers of a SCN5A mutation, in whom the presence of the less common allele G improves the ECG characteristics and clinical phenotype.     

Brugada综合征相关基因SCN5A新突变位点的检测

目的 研究中国人Brugada综合征相关基因SCN5A突变情况。方法 利用多聚酶链反应及DNA测序对1个Brugada综合征家系SCN5A基因的全部28个外显子进行基因检测。结果 在国内外已知突变点均无突变，发现1个新的错义突变位点(A5471G)，其相应的氨基酸改变为N1774S。结论 在中国人Brugada综合征患者的SCN5A基因上发现1个新的突变位点。     

Novel pore mutation in SCN5A manifests as a spectrum of phenotypes ranging from atrial flutter, conduction disease, and Brugada syndrome to sudden cardiac death

OBJECTIVES: The purpose of this study was to determine the clinical and biophysical characteristics of a novel SCN5A mutation. BACKGROUND: Brugada syndrome and isolated cardiac conduction defect have been linked to SCN5A mutations. METHODS: Eleven members of a western European family underwent electrophysiologic investigations and mutation analysis of the SCN5A gene. Wild-type and mutant SCN5A channels were expressed in HEK293 cells, and whole cell currents were studied using patch clamp procedures. RESULTS: A novel mutation, R376H, in the first pore segment of SCN5A variably causes Brugada syndrome and/or conduction disease in a single family. Biophysical analysis demonstrated a significant current reduction for the mutant, a pathophysiologic profile consistent with Brugada syndrome and isolated cardiac conduction defect. Among 11 family members, 9 were carriers of the mutation. The proband's initial presentation was a saddleback Brugada ECG, atrial flutter, and diffuse conduction disturbances. He had no inducible ventricular arrhythmias but experienced sudden cardiac death. His brother was affected by atrial flutter and had a clear conduction disorder, but he did not display baseline or evocable ECG signs of Brugada syndrome. He received an implantable cardioverter-defibrillator that delivered one appropriate shock after 1 year of follow-up. The phenotype in the family members was highly variable and ranged from noninducible and inducible asymptomatic carriers of the mutations to isolated conduction disease and to symptomatic Brugada syndrome. CONCLUSIONS: We describe the functional characterization of a novel SCN5A pore mutation, R376H, with variable clinical expression in the same family. Differentiating between electrophysiologic entities (Brugada syndrome-isolated cardiac conduction defect) is more challenging. Recognition of factors modifying the clinical presentation may be important for clinical decision making.     

The Brugada syndrome--an update

Brugada syndrome is characterized by ST-segment elevation in the right precordial leads (V1-V3) and an episode of ventricular fibrillation (VF) in the absence of structural heart disease. A number of reports from the world have unveiled the clinical, electrocardiographic, electrophysiologic and prognostic features of Brugada syndrome, and two recent consensus reports have suggested the diagnostic criteria of Brugada syndrome and the risk stratification for the identification of high risk Brugada patients for sudden cardiac death. SCN5A, the gene encoding the alpha subunit of the sodium channel, is the only gene thus far linked to Brugada syndrome; its prognostic value remains unclear. On the other hand, advances in the understanding of the cellular mechanism for Brugada phenotype derived from experimental studies have suggested possibilities for the development of strategies for managing and treating patients with Brugada syndrome. In this review, the recent understanding and knowledge of Brugada syndrome will be updated.     

七例Brugada综合征患者SCN5A基因突变检测

目的 对7例Brugada综合征患者进行SCN5A基因突变检测,分析其分子遗传学特征. 方法 提取7例Brugada综合征患者外周血DNA样本,设计41对引物进行多聚核苷酸聚合酶链式反应,扩增SCN5A基因28对外显子,并采用双脱氧链终止法进行直接测序. 结果 SCN5A基因外显子部分未发现新的突变位点. 结论 Brugada综合征可能存在除SCN5A基因之外的其他相关基因突变.     

High risk for bradyarrhythmic complications in patients with Brugada syndrome caused by SCN5A gene mutations.

OBJECTIVES: We carried out a complete screening of the SCN5A gene in 38 Japanese patients with Brugada syndrome to investigate the genotype-phenotype relationship. BACKGROUND: The gene SCN5A encodes the pore-forming alpha-subunit of voltage-gated cardiac sodium (Na) channel, which plays an important role in heart excitation/contraction. Mutations of SCN5A have been identified in 15% of patients with Brugada syndrome. METHODS: In 38 unrelated patients with clinically diagnosed Brugada syndrome, we screened for SCN5A gene mutations using denaturing high-performance liquid chromatography and direct sequencing, and conducted a functional assay for identified mutations using whole-cell patch-clamp in heterologous expression system. RESULTS: Four heterozygous mutations were identified (T187I, D356N, K1578fs/52, and R1623X) in 4 of the 38 patients. All of them had bradyarrhythmic complications: three with sick sinus syndrome (SSS) and the other (D356N) with paroxysmal complete atrioventricular block. SCN5A-linked Brugada patients were associated with a higher incidence of bradyarrhythmia (4 of 4) than non-SCN5A-linked Brugada patients (2 of 34). Families with T187I and K1578fs/52 had widespread penetrance of SSS. Notably, the patient with K1578fs/52, who had been diagnosed as having familial SSS without any clinical signs of Brugada syndrome, showed a Brugada-type ST-segment elevation after intravenous administration of pilsicainide and programmed electrical stimulation-induced ventricular tachycardia. All of the mutations encoded non-functional Na channels, and thus were suggested to cause impulse propagation defect underlying bradyarrhythmias. CONCLUSIONS: Our findings suggest that loss-of-function SCN5A mutations resulting in Brugada syndrome are distinguished by profound bradyarrhythmias.     

Clinical and electrophysiological characteristics of Brugada syndrome caused by a missense mutation in the S5-pore site of SCN5A

Brugada syndrome is an inherited cardiac disorder caused by mutations in the SCN5A gene encoding the cardiac sodium channel alpha-subunit, and potentially leads to ventricular fibrillation and sudden death. We report a case of a novel SCN5A mutation associated with Brugada syndrome. A 51-year-old man suffered from recurrent nocturnal syncopal attacks due to polymorphic ventricular tachycardia. His electrocardiogram showed ST-segment elevation in V1-V3 leads, but there was no evidence of structural heart disease. DNA sequence analysis of SCN5A in this patient revealed a missense mutation (R282H) in the S5-pore region of domain I. This mutational change was not present in 100 healthy Japanese controls. In the patient's family, a 36-year-old brother had died suddenly. Genetic analysis identified two other carriers of the R282H mutation, who had ST-segment elevation and slightly increased QRS widths, but they experienced no syncopal episodes or ventricular fibrillation. Electrophysiological investigation of the R282H mutant channel expressed in cultured cells showed a severe reduction in sodium current density and a mild positive shift of activation curve. R282H did not enhance intermediate inactivation. Single-channel conductance of R282H was slightly decreased compared with WT. The electrophysiological characteristics of the R282H channel are suggested to be closely related to the clinical phenotype of Brugada syndrome.     

Brugada综合征SCN5A基因的三个新突变

目的 研究Brugada综合征相关基因SCN5A突变情况。方法 以4例Brugada综合征患者和9例临床可疑Brugada综合征患者为研究对象,采用聚合酶链反应和双脱氧末端终止测序法对所有患者进行SCNSA基因扫描。对阳性结果者进行家系中其他成员的筛查。结果 在1个Brugada综合征家系发现两个杂合突变,即SCN5A基因第3外显子上发现一错义突变（G283A）,导致代表缬氨酸残基的第95位密码子突变为异亮氨酸残基（V95I）,第28外显子上也发现一错义突变（CA946T）,导致代表丙氨酸的第1649位密码子突变为缬氨酸（A1649V）。在1个临床可疑Brugada综合征家系发现一杂合突变,即SCN5A基因第28外显子缺失3个碱基（TCT）,导致代表苯丙氨酸残基的第1617位密码子缺失（delF1617）。结论 在Brugada综合征患者发现了3个SCN5A基因新突变（V95I、A1649V、delF1617）。     

中国一家系Brugada综合征相关基因SCN5A突变位点的检测

目的研究一个中国家系Brugada综合征相关基因SCNSA的突变情况。方法收集一个Brugada家系的临床资料,采用聚合酶链反应及直接测序法对该家系进行SCN5A基因突变检测,同时对136例家系外健康对照者的该位点进行单链构象多态性分析。结果在Brugada家系中发现了两个杂合变异,即SCN5A基因第二外显子上发现一个同义变异（A129G）,没有导致氨基酸的改变（A29A）;第26外显子发现一个错义变异（T4492A）,导致代表酪氨酸的1494位密码子突变为天门冬酰胺（Y1494N）。结论在中国人Brugada综合征患者的SCNSA基因上发现了一个已经报道的同义多态位点（A29A）及一个新的错义突变位点（Y1494N）。     

Phenotypic characterization of a large European family with Brugada syndrome displaying a sudden unexpected death syndrome mutation in SCN5A:

INTRODUCTION: Brugada syndrome is characterized by sudden death secondary to malignant arrhythmias and the presence of ST segment elevation in leads V(1) to V(3) of patients with structurally normal hearts. This ECG pattern often is concealed but can be unmasked using potent sodium channel blockers. Like congenital long QT syndrome type 3 (LQT3) and sudden unexpected death syndrome, Brugada syndrome has been linked to mutations in SCN5A. METHODS AND RESULTS: We screened a large European family with Brugada syndrome. Three members (two female) had suffered malignant ventricular arrhythmias. Ten members showed an ECG pattern characteristic of Brugada syndrome at baseline, and eight showed the pattern only after administration of ajmaline (total 12 female). Haplotype analysis revealed that all individuals with positive ECG at baseline shared the SCN5A locus. Sequencing of SCN5A identified a missense mutation, R367H, previously associated with sudden unexpected death syndrome. Two of the eight individuals who displayed a positive ECG after the administration of ajmaline, but not before, did not have the R367H mutation, and sequencing analysis failed to identify any other mutation in SCN5A. The R367H mutation failed to generate any current when heterologously expressed in HEK cells. CONCLUSION: Our results support the hypothesis that (1) sudden unexpected death syndrome and Brugada syndrome are the same disease; (2) male predominance of the phenotype observed in sudden unexpected death syndrome does not apply to this family, suggesting that factors other than the specific mutation determine the gender distinction; and (3) ajmaline may provide false-positive results. These findings have broad implications relative to the diagnosis and risk stratification of family members of patients with the Brugada syndrome.     

Exclusion of multiple candidate genes and large genomic rearrangements in SCN5A in a Dutch Brugada syndrome cohort.

BACKGROUND: The Brugada syndrome is an inherited cardiac electrical disorder associated with a high incidence of life-threatening arrhythmias. Screening for mutations in the cardiac Na+ channel-encoding gene SCN5A uncovers a mutation in approximately 20% of Brugada syndrome cases. Genetic heterogeneity and/or undetected SCN5A mutations, such as exon duplications and deletions, could be involved in the remaining 80% mutation-negative patients. OBJECTIVES: Thirty-eight SCN5A mutation-negative Dutch Brugada syndrome probands were studied. The SCN5A gene was investigated for exon duplication and deletion, and a number of candidate genes (Caveolin-3, Irx-3, Irx-4, Irx-5, Irx-6, Plakoglobin, Plakophilin-2, SCN1B, SCN2B, SCN3B, and SCN4B) were tested for the occurrence of point mutations and small insertions/deletions. METHODS: We used a quantitative multiplex approach to determine SCN5A exon copy numbers. Mutation analysis of the candidate genes was performed by direct sequencing of polymerase chain reaction-amplified coding regions. RESULTS: No large genomic rearrangements in SCN5A were identified. No mutations were found in the candidate genes. Twenty novel polymorphisms were identified in these genes. CONCLUSION: Large genomic rearrangements in SCN5A are not a common cause of Brugada syndrome. Similarly, the studied candidate genes are unlikely to be major causal genes of Brugada syndrome. Further studies are required to identify other genes responsible for this syndrome.     

Novel SCN5A mutation (Q55X) associated with age-dependent expression of Brugada syndrome presenting as neurally mediated syncope.

BACKGROUND: An association between Brugada syndrome and neurally mediated syncope has been described. Although mutations in SCN5A have been identified in Brugada syndrome, the genetic link between Brugada syndrome and neurally mediated syncope has not been determined. OBJECTIVES: The purpose of the study was to clinically and genetically characterize a man with recurrent syncope that originally was diagnosed as neurally mediated syncope at age 8 years but subsequently manifested as Brugada syndrome at age 17 years. METHODS: The proband underwent clinical examination, which included head-up tilt test, sodium channel provocation test, and electrophysiologic study. Genetic screening of SCN5A was performed for the proband and his family members. The biophysical properties of a mutant SCN5A channel in a heterologous expression system were studied using whole-cell, patch clamp technique. RESULTS: The proband showed positive head-up tilt test, coved-type ST elevation recorded from the third intercostal space, and positive pilsicainide provocation test. Ventricular fibrillation was inducible at programmed electrical stimulation, consistent with characteristics of both Brugada syndrome and neurally mediated syncope. A novel nonsense SCN5A mutation (Q55X) was identified in the proband, his mother, and his asymptomatic brother. The heterologously expressed mutant channel was nonfunctional. CONCLUSION: We genetically determined an SCN5A mutation in a patient showing the combined phenotype of neurally mediated syncope and Brugada syndrome. Neurally mediated syncope and Brugada syndrome may share, at least in part, a common pathophysiologic mechanism.     

Brugada综合征一家系中2例患者的SCN5A基因突变及意义

目的 观察Brugada综合征一家系中2例患者的SCN5A基因突变情况,并探讨其意义.方法 选择Brugada综合征一家系2例患者,采用直接测序法对其SCN5A基因突变进行检测.结果 该家系中发现1个纯合变异,即SCN5A基因第28外显子上的同义变异（C5457T）,其所编码的1819位天冬氨酸密码子没有发生改变.结论 该Brugada综合征家系2例患者的SCN5A基因上存在1个同义变异,但SCN5A基因不是患者的致病基因.     

SCN5A基因移码突变导致Brugada综合征

目的：检测Brugada综合征的致病基因突变位点。方法：对1个Brugada综合征家系11名成员和20名正常人的DNA样本应用双脱氧链终止基因测序法进行心脏钠离子通道α亚单位（voltage-gated sodium channel type V,SCN5A)基因测序。结果：SCN5A基因测序发现Brugada综合征家系第22个外显子存在1个杂合基因移码突变位点，经克隆传代后测序发现该突变为4087insC。该突变使通道蛋白1314－1317位氨基酸发生改变并在1318位终止，导致钠离子通道第3结构域S4结构变化，S5－6及第4结构域全部缺失。该突变在Brugada综合征家系中分布符合常染色体显性分布规律。对照组未发现相同突变。结论：SCN5A基因4087insC是国内首次发现的导致Brugada 综合征的基因突变位点，也是国际上发现的第2个引起Brugada综合征的SCN5A基因移码突变     

Genetic and biophysical basis for bupivacaine-induced ST segment elevation and VT/VF. Anesthesia unmasked Brugada syndrome.

BACKGROUND: Brugada syndrome is an inherited disease associated with sudden cardiac death. The electrocardiographic pattern associated with Brugada syndrome has been linked to the use of sodium channel blockers, including antiarrhythmics, trycyclics and anesthetics. OBJECTIVE: We report a case of bupivacaine-induced Brugada syndrome, in which we investigated the genetic, biophysical and path physiological mechanism involved. METHODS AND RESULTS: The patient developed a Brugada-like electrocardiographic pattern twice under the influence of bupivacaine. The first occurrence was accompanied by ventricular tachycardia (VT) which subsided after withdrawal of the anesthetic. The VT was also observed during co-administration of diltiazem and isosorbide-5-mononitrate, agents thought to facilitate ST segment elevation in the Brugada syndrome. Genetic analysis revealed a missense mutation in the alpha subunit of the cardiac sodium channel, SCN5A. Biophysical analysis by whole-cell patch-clamping revealed a reduction in sodium current as a result of the mutation. The study of bupivacaine in the wedge model revealed use-dependent changes in conduction, heterogeneous loss of the action potential dome in RV epicardium and phase 2 re-entry when the preparations were pretreated with low concentrations of the calcium channel blocker verapamil. CONCLUSION: Our findings indicate that bupivacaine may induce the electrocardiographic and arrhythmic manifestations of the Brugada syndrome in silent carriers of SCN5A mutations. The data have important implications in the management of patients who develop ST segment elevation when under the influence of anesthetics such as bupivacaine.     

A newly characterized SCN5A mutation underlying Brugada syndrome unmasked by hyperthermia

Febrile illness has been rarely reported to modulate ST segment elevation in right precordial leads on ECG or even precipitate ventricular fibrillation in patients with Brugada syndrome. We report the case of a patient whose Brugada ECG pattern was unmasked by hyperthermia secondary to acute cholangitis. Serial ECGs showed progressive attenuation of ST segment elevation as body temperature gradually returned to normal. Structural heart disease was ruled out. Intravenous flecainide injection reproduced a less remarkable ST segment elevation. Genetic screening demonstrated a single amino acid substitution (H681P) in the SCN5A gene, thus confirming the diagnosis of Brugada syndrome. In vitro expression of this newly characterized genetic defect revealed novel biophysical abnormalities consisting of a shift in both steady-state activation and inactivation, resulting in a 60% reduction of sodium window current. Thus, SCN5A-H681P mutation induces a significant loss of transmembrane current and is clinically associated with a pathologic phenotype that is elicited by hyperthermia. Overall the observed clinical features are in agreement with previous observations and strongly suggest that fever may be an environmental modifier among Brugada syndrome patients with a detrimental (and possibly arrhythmogenic) effect on cardiac repolarization.     

Double SCN5A mutation underlying asymptomatic Brugada syndrome

OBJECTIVES: The purpose of this study was to identify risk markers in patients with Brugada syndrome. BACKGROUND: Patients with Brugada syndrome who experience syncope or aborted sudden death are at high risk for recurrent lethal arrhythmias. The prognosis and therapeutic approaches in asymptomatic individuals with a Brugada-type ECG (asymptomatic Brugada syndrome) are controversial. METHODS: We genetically screened 30 asymptomatic probands (29 men and 1 woman; mean age 47.1 years) exhibiting a spontaneous Brugada-type ECG. Family members of patients with Brugada syndrome were excluded from the study. RESULTS: Twenty-nine of 30 patients (96.7%) remained symptom-free for at least 3 years. One patient (case 1) with a family history of sudden death died suddenly during sleep. Ventricular fibrillation was induced by programmed electrical stimulation in 14 of 18 subjects (78%), but none of these 18 subjects developed spontaneous ventricular arrhythmias. Genetic screening failed to identify SCN5A mutations in most cases but demonstrated a novel double missense mutation (K1527R and A1569P) located on the same allele in another asymptomatic subject (case 2). Heterologously expressed mutant Na channels exhibited a negative shift of steady-state inactivation (9.2 mV) and enhanced slow inactivation, suggesting this individual harbors a subclinical channel dysfunction compatible with symptomatic Brugada syndrome. CONCLUSIONS: Asymptomatic individuals with a Brugada-type ECG generally have a better prognosis than their symptomatic counterparts, but a subgroup of these individuals may have a poor prognosis. Severe Na channel dysfunction as a result of SCN5A mutations may not be sufficient to cause symptoms or arrhythmias in patients with Brugada syndrome, suggesting unknown factors or modifier genes influence arrhythmogenesis.     

Ventricular tachycardia in a Brugada syndrome patient caused by a novel deletion in SCN5A

The aim of the present study was to identify the molecular mechanism behind ventricular tachycardia in a patient with Brugada syndrome. Arrhythmias in patients with Brugada syndrome often occur during sleep. However, a 28-year-old man with no previously documented arrhythmia or syncope who experienced shortness of breath and chest pain during agitation is described. An electrocardiogram revealed monomorphic ventricular tachycardia; after he was converted to nodal rhythm, he spontaneously went into sinus rhythm, and showed classic Brugada changes with coved ST elevation in leads V₁ to V₂. Mutation analysis of SCN5A revealed a novel mutation, 3480 deletion T frame shift mutation, resulting in premature truncation of the protein. Heterologous expression of this truncated protein in human embryonic kidney 293 cells showed a markedly reduced protein expression level. By performing whole-cell patch clamp experiments using human embryonic kidney 293 cells transfected with the mutated SCN5A, no current could be recorded. Hence, the results suggest that the patient suffered from haploinsufficiency of Na_v1.5, and that this mutation was the cause of his Brugada syndrome.