OBJECTIVE: To explore the correlation between DSG2, TTN and GATA4 genes and Brugada syndrome in Henan Province of China. METHODS: From February 2017 to February 2019, 100 patients with Brugada syndrome and 100 healthy individuals were selected as the study and the control groups, respectively. Electrocardiogram and echocardiography were carried out, and peripheral blood samples was collected. Coding regions of DSG2, TTN and GATA4 genes were amplified by PCR and sequenced. The results were compared with standard sequences from GenBank. RESULTS: Electrocardiogram showed that all patients from the study group had ventricular arrhythmia, 87 cases (87%) presented ventricular tachycardia (VT), 84 cases (84%) presented T wave inversion, and 51 cases (51%) presented Epsilon wave. Echocardiography showed that the right ventricle in the study group was enlarged with the inner diameter of the right ventricle being (40.0±13.3) mm, and the right ventricle showed various degree of abnormal systolic function. The enlargement of right atrium accounted for 64%, and the involvement of the left ventricle accounted for 27%. The right ventricular diameter and left ventricular diastolic diameter of the study group were significantly greater than those of the control group (P< 0.05). DNA sequencing showed that 60 patients carried DSG2 gene variants, among which 18 had missense variant of exon 8. Fifty patients carried TTN gene variants, including 8 in the A-band domain and 3 in the I-band domain. Twenty patients carried 3 variants of the GATA4 gene. CONCLUSION Variants of the DSG2, TTN and GATA4 genes in Henan region are correlated with the onset of Brugada syndrome.
Arrhythmogenic Right Ventricular Dysplasia ; Brugada Syndrome/genetics* ; China ; Connectin ; Desmoglein 2/genetics* ; GATA4 Transcription Factor ; Humans ; Pedigree ; Sequence Analysis, DNA

OBJECTIVEBrugada syndrome is an inherited channelopathy that characterized by ST-segment elevation in the right precordial lead (V(1)-V(3)) on the electrocardiogram with or without right bundle branch block and related with high risk of sudden cardiac death and structurally normal hearts. The first and only gene linked to this disease is SCN5A, a gene encodes for alpha subunit of the cardiac sodium channel. The objective of this study is to explore SCN5A gene mutations in Chinese patients with Brugada syndrome.

METHODSFour patients diagnosed as Brugada syndrome and nine patients with suspected Brugada syndrome were chosen for the study. The exons in the functional regions of SCN5A gene were amplified with polymerase chain reaction and the amplified products were sequenced with Sanger method. If a mutation was identified, patient's family members were also screened.

RESULTSTwo heterozygous mutations were found in one family diagnosed as Brugada syndrome. One missense mutation was a G-->A transition in the first nucleotide of codon 95 in SCN5A gene exon 3, which was predicted to result in substitution of Valine with Isoleucine (V95I). The other missense mutation was a C-->T transition in the second nucleotide of codon 1649 in SCN5A gene exon 28, which was predicted to result in substitution of Alanine with Valine (A1649V). A heterozygous mutation was identified in one family suspected to have the disease. The mutation was a three nucleotides (TCT) deletion that caused Phenylalanine deletion in codon 1617 in SCN5A gene exon 28. The three mutations were not detected in 100 control chromosomes.

CONCLUSIONSMutation in SCN5A gene is one of the causes of Brugada syndrome in Chinese. Three novel SCN5A gene mutations were identified in Chinese with Brugada syndrome, which expands the spectrum of SCN5A mutations associated with the disease.

Adolescent ; Adult ; Aged ; Brugada Syndrome ; genetics ; Case-Control Studies ; Exons ; genetics ; Humans ; Male ; Middle Aged ; Muscle Proteins ; genetics ; Mutation ; NAV1.5 Voltage-Gated Sodium Channel ; Sodium Channels ; genetics

OBJECTIVETo elucidate the molecular and electrophysiological mechanisms of Brugada syndrome through functional analysis of a novel SCN5A gene mutation G1712C.

METHODSA recombinant plasmid pRc

RESULTSAn HEK293 cell line that stably expressed Nachannel β1-subunit was successfully established. After transient transfection with the WT subunit, large Nacurrents were recorded from the stable β1-cell line. Transient transfection with the G1712C subunit, however, did not elicit a Nacurrent in the cells.

CONCLUSIONCompared with normal Nachannel, the wild-type channel exhibits a similar sodium current. The characteristic kinetics of sodium channel of WT-hH1 was identical to that in normal cardiac muscle cell, and the missense mutation (G1712C) in the P-loop region of the domain IV may have caused the failure of sodium channel expression.

Brugada Syndrome ; genetics ; Genotype ; HEK293 Cells ; Humans ; Mutagenesis, Site-Directed ; Mutation ; NAV1.5 Voltage-Gated Sodium Channel ; genetics ; Patch-Clamp Techniques ; Polymerase Chain Reaction ; Transfection

The early cardiac biological pacemaker studies were mostly around HCN channel, and how to build a biological pacemaker through the enhanced If current. In recent years, however, people found that the genes of Tbx3 could play an important role in the development of cardiac conduction system, especially in processes of the maturity of the sinoatrial node and maintenance of its function. And the Tbx3 can further optimize the biological pacemaker. Therefore, it could be a new therapeutic focus in biological pacemaker and treatment of cardiac conduction system disease. This paper summarizes some of the latest research progress of the Tbx3 in biological pacemaker in recent years. We hope that this review could provide theoretical basis for the clinical applications of Tbx3.
Arrhythmias, Cardiac ; genetics ; Biological Clocks ; Brugada Syndrome ; Cardiac Conduction System Disease ; Heart ; physiopathology ; Heart Conduction System ; abnormalities ; Humans ; Sinoatrial Node ; T-Box Domain Proteins ; genetics

Sudden cardiac death accounts for majority of deaths in human. Evident cardiac lesions that may explain the cause of death can be detected in comprehensive postmortem investigation in most sudden cardiac death. However, no cardiac morphological abnormality is found in a considerable number of cases although the death is highly suspected from cardiac anomaly. With the advances in the modern molecular biology techniques, it has been discovered that many of these sudden deaths are caused by congenital ion channelopathies in myocardial cell, i.e., Brugada syndrome, long QT syndrome, catecholaminergic polymorphic ventricular tachycardia, and short QT syndrome, etc. This article presents the molecular genetics, electrocardiographic abnormalities, clinical manifestations, and mechanisms leading to sudden cardiac death with emphasis on the role of postmortem genetic testing in certification of cause of death. It may provide helpful information in investigating sudden cardiac death due to ion channelopathies in medico-legal practice.
Arrhythmias, Cardiac/genetics* ; Autopsy/methods* ; Brugada Syndrome/genetics* ; Cause of Death ; Channelopathies/genetics* ; Death, Sudden, Cardiac/pathology* ; Electrocardiography ; Forensic Pathology ; Genetic Testing ; Heart Conduction System/physiopathology* ; Humans ; Ion Channels/genetics* ; Long QT Syndrome/genetics* ; Mutation ; Tachycardia, Ventricular/genetics*

OBJECTIVETo analyze the gene mutations on the cardiac sodium channel gene SCN5A in a Chinese family with Brugada syndrome.

METHODPolymerase chain reaction and DNA sequencing were used to screen gene mutations on the cardiac sodium channel gene SCN5A in all family members of a Chinese pedigree with Brugada syndrome, single strand conformation polymorphism analysis were performed in 136 normal controls to detect the mutations of SCN5A gene.

RESULTTwo heterozygosis mutations, which include a missense mutation (Y1494N) and a same sense mutation (A29A), were identified on SCN5A gene in the proband with Brugada syndrome and these mutations were not detected in other family members with Brugada syndrome and in controls.

CONCLUSIONWe detected a reported polymorphism site (A29A) and a novel missense mutation (Y1494N) on SCN5A in this Chinese family with Brugada syndrome.

Adult ; Asian Continental Ancestry Group ; genetics ; Brugada Syndrome ; genetics ; Case-Control Studies ; Female ; Humans ; Male ; Muscle Proteins ; genetics ; Mutation ; NAV1.5 Voltage-Gated Sodium Channel ; Pedigree ; Polymorphism, Single-Stranded Conformational ; Sodium Channels ; genetics

Arrhythmias, Cardiac ; diagnosis ; genetics ; pathology ; Brugada Syndrome ; diagnosis ; genetics ; pathology ; Channelopathies ; diagnosis ; genetics ; pathology ; DNA Mutational Analysis ; Electrocardiography ; Genetic Testing ; Heart Conduction System ; physiopathology ; Humans ; Infant ; Long QT Syndrome ; diagnosis ; genetics ; pathology ; Muscle Proteins ; genetics ; Mutation ; NAV1.5 Voltage-Gated Sodium Channel ; genetics ; Sodium Channels ; genetics ; Sudden Infant Death ; etiology

OBJECTIVE: To find the mutation of disease-causing genes of sudden unexplained death syndrome (SUDS) in the young by whole exome sequencing in one case. METHODS: One SUDS case was found no obvious fatal pathological changes after conventional autopsy and pathological examination. The whole exome sequencing was performed with the Ion Torrent PGM™ System with hg19 as reference sequence for sequencing data. The functions of mutations were analyzed by PhyloP, PolyPhen2 and SIFT. A three-step bioinformatics filtering procedure was carried out to identify possible significative single nucleotide variation (SNV), which was missense mutation with allele frequency < 1% of myocardial cell. RESULTS: Four rare suspicious pathogenic SNV were identified. Combined with the analysis of conventional autopsy and pathological examination, the mutation MYOM2 (8_2054058_G/A) was assessed as high-risk deleterious mutation by PolyPhen2 and SIFT, respectively. CONCLUSION Based on the second generation sequencing technology, analysis of whole exome sequencing can be a new method for the death cause investigation of SUDS. The gene MYOM2 is a new candidate SUDS pathogenic gene for mechanism research.
Autopsy ; Brugada Syndrome/genetics* ; Cause of Death ; DNA Mutational Analysis/methods* ; Death, Sudden/etiology* ; Exome ; Gene Frequency ; Genetic Testing/methods* ; High-Throughput Nucleotide Sequencing/methods* ; Humans ; Molecular Biology ; Molecular Diagnostic Techniques/methods* ; Molecular Sequence Data ; Mutation

Channelopathies are a heterogeneous group of disorders resulting from the dysfunction of ion channels located in the membranes of all cells and many cellular organelles. These include diseases of the nervous system (e.g., generalized epilepsy with febrile seizures plus, familial hemiplegic migraine, episodic ataxia, and hyperkalemic and hypokalemic periodic paralysis), the cardiovascular system (e.g., long QT syndrome, short QT syndrome, Brugada syndrome, and catecholaminergic polymorphic ventricular tachycardia), the respiratory system (e.g., cystic fibrosis), the endocrine system (e.g., neonatal diabetes mellitus, familial hyperinsulinemic hypoglycemia, thyrotoxic hypokalemic periodic paralysis, and familial hyperaldosteronism), the urinary system (e.g., Bartter syndrome, nephrogenic diabetes insipidus, autosomal-dominant polycystic kidney disease, and hypomagnesemia with secondary hypocalcemia), and the immune system (e.g., myasthenia gravis, neuromyelitis optica, Isaac syndrome, and anti-NMDA [N-methyl-D-aspartate] receptor encephalitis). The field of channelopathies is expanding rapidly, as is the utility of molecular-genetic and electrophysiological studies. This review provides a brief overview and update of channelopathies, with a focus on recent advances in the pathophysiological mechanisms that may help clinicians better understand, diagnose, and develop treatments for these diseases.
Ataxia ; Bartter Syndrome ; Brugada Syndrome ; Cardiovascular System ; Channelopathies* ; Diabetes Insipidus, Nephrogenic ; Diabetes Mellitus ; Endocrine System ; Epilepsy, Generalized ; Genetics ; Hypoglycemia ; Hypokalemic Periodic Paralysis ; Immune System ; Ion Channels ; Isaacs Syndrome ; Long QT Syndrome ; Membranes ; Migraine with Aura ; Myasthenia Gravis ; Nervous System ; Neuromyelitis Optica ; Organelles ; Polycystic Kidney Diseases ; Respiratory System ; Seizures, Febrile