UMLS:C0011053 - FACTA Search

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Query: UMLS:C0011053 (deafness)
10,271 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Jervell and Lange-Nielsen syndrome (MIM 220400; JLNS), is a rare form of profound congenital deafness combined with syncopal attacks and sudden death due to prolonged QTc; it is an autosomal recessive trait. After its first description in Norway in 1957, later reports from many other countries have confirmed its occurrence. Nowhere is the prevalence so high as in Norway, where we estimate a prevalence of at least 1:200,000. The KCNQ1 and KCNE1 proteins coassemble in a potassium channel, and mutations in either the KCNQ1 gene or the KCNE1 gene disrupt endolymph production in the stria vascularis in the cochlea, causing deafness. KCNQ1 seems to be the major gene in JLNS. Long QT syndrome (LQTS) is a separate disorder of either autosomal dominant or recessive inheritance caused by mutations in four different ion channel genes; KCNQ1 is the one most frequently involved. Some heterozygous carriers of JLNS mutations in either gene may suffer from prolonged QTc and be symptomatic LQTS patients with a need for appropriate medical treatment to prevent life-threatening cardiac arrhythmia. In general, frameshift/stop mutations cause JLNS, and missense/splice site mutations cause LQTS, but a precise genotype-phenotype correlation in LQTS and JLNS is not established, which complicates both genetic counseling and clinical risk evaluation in carriers. We review JLNS from a Norwegian perspective because of the unusually high prevalence, the genetic homogeneity associated with considerable mutational heterogeneity, and some evidence for recurrent mutational events as well as one founder mutation. We outline the clinical implications for investigation of deaf children and cases of sudden infant death syndrome as well as careful electrocardiographic monitoring of identified mutation carriers to prevent sudden death. Am. J. Med. Genet. (Semin. Med. Genet.) 89:137-146, 1999.
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PMID:Jervell and Lange-Nielsen syndrome: a Norwegian perspective. 1070 88

The congenital long QT syndrome is characterised by the presence of syncopes due to torsades de pointe which may degenerate to ventricular fibrillation and cause sudden death. These syncopes occur in young subjects with electrocardiographic abnormalities and prolongation of the QT interval. Patients with the autosomally dominant transmitted Romano-Ward syndrome with normal audition are classically opposed to those with the Jervell and Lange-Nielsen autosomally recessive syndrome who have bilateral total deafness. Our understanding of the congenital long QT syndrome has improved in recent years with respect to the physiopathology, diagnosis and treatment, due to research in the fields of genetics, electrocardiography and electrophysiology. The diagnosis is based on analysis of the phenotype and genotypes. A family enquiry is always necessary to detect unrecognised forms. Five culprit genes have been identified for the Romano-Ward syndrome. All code for subunits of sodium or potassium channels: two a subunits of the potassium channels (QVLQT1 for LQT1, HERG for LQT2), the a subunit of the sodium channel INa (SCN5A for LQT3), and two regulatory subunits of potassium channels (KCNE1 for LQT5 regulating the KvLQT1 channel and MiRP1 regulating HERG). The concept of genetic heterogeneity of the congenital long QT syndrome may thus be understood: different genes may be responsible for the same phenotype. Except for specific cases, the usual treatment is life-long betablocker therapy and the avoidance of a large number of drugs, the list of which is continually updated. A multicentre trial is underway to validate betablocker therapy for the prevention of cardiac events in a LQT1 genotype population. Prospective studies will be necessary to assess gene-specific treatments.
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PMID:[Present concepts of congenital long QT syndrome]. 1081 97

KCNQ1 encodes KCNQ1, which belongs to a family of voltage-dependent K(+) ion channel proteins. KCNQ1 associates with a regulatory subunit, KCNE1, to produce the cardiac repolarizing current, I(Ks). Loss-of-function mutations in the human KCNQ1 gene have been linked to Jervell and Lange-Nielsen Syndrome (JLNS), a disorder characterized by profound bilateral deafness and a cardiac phenotype. To generate a mouse model for JLNS, we created a line of transgenic mice that have a targeted disruption in the Kcnq1 gene. Behavioral analysis revealed that the Kcnq1(-/-) mice are deaf and exhibit a shaker/waltzer phenotype. Histological analysis of the inner ear structures of Kcnq1(-/-) mice revealed gross morphological anomalies because of the drastic reduction in the volume of endolymph. ECGs recorded from Kcnq1(-/-) mice demonstrated abnormal T- and P-wave morphologies and prolongation of the QT and JT intervals when measured in vivo, but not in isolated hearts. These changes are indicative of cardiac repolarization defects that appear to be induced by extracardiac signals. Together, these data suggest that Kcnq1(-/-) mice are a potentially valuable animal model of JLNS.
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PMID:Targeted disruption of the Kcnq1 gene produces a mouse model of Jervell and Lange-Nielsen Syndrome. 1122 72

KCNQ genes encode a growing family of six transmembrane domains, single pore-loop, K(+) channel alpha-subunits that have a wide range of physiological correlates. KCNQ1 (KvLTQ1) is co-assembled with the product of the KCNE1 (minimal K(+)-channel protein) gene in the heart to form a cardiac-delayed rectifier-like K(+) current. Mutations in this channel can cause one form of inherited long QT syndrome (LQT1), as well as being associated with a form of deafness. KCNQ1 can also co-assemble with KCNE3, and may be the molecular correlate of the cyclic AMP-regulated K(+) current present in colonic crypt cells. KCNQ2 and KCNQ3 heteromultimers are thought to underlie the M-current; mutations in these genes may cause an inherited form of juvenile epilepsy. The KCNQ4 gene is thought to encode the molecular correlate of the I(K,n) in outer hair cells of the cochlea and I(K,L) in Type I hair cells of the vestibular apparatus, mutations in which lead to a form of inherited deafness. The recently identified KCNQ5 gene is expressed in brain and skeletal muscle, and can co-assemble with KCNQ3, suggesting it may also play a role in the M-current heterogeneity. This review will set this family of K(+) channels amongst the other known families. It will highlight the genes, physiology, pharmacology, and pathophysiology of this recently discovered, but important, family of K(+) channels.
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PMID:KCNQ potassium channels: physiology, pathophysiology, and pharmacology. 1144 22

Sensory transduction in the cochlea and the vestibular labyrinth depends on the cycling of K+. In the cochlea, endolymphatic K+ flows into the sensory hair cells via the apical transduction channel and is released from the hair cells into perilymph via basolateral K+ channels including KCNQ4. K+ may be taken up by fibrocytes in the spiral ligament and transported from cell to cell via gap junctions into strial intermediate cells. Gap junctions may include GJB2, GJB3 and GJB6. K+ is released from the intermediate cells into the intrastrial space via the KCNJ10 K+ channel that generates the endocochlear potential. From the intrastrial space, K+ is taken up across the basolateral membrane of strial marginal cells via the Na+/2Cl-/K+ cotransporter SLC12A2 and the Na+/K+-ATPase ATP1A1/ATP1B2. Strial marginal cells secrete K+ across the apical membrane into endolymph via the K+ channel KCNQ1/KCNE1, which concludes the cochlear cycle. A similar K+ cycle exists in the vestibular labyrinth. Endolymphatic K+ flows into the sensory hair cells via the apical transduction channel and is released from the hair cells via basolateral K+ channels including KCNQ4. Fibrocytes connected by gap junctions including GJB2 may be involved in delivering K+ to vestibular dark cells. Extracellular K+ is taken up into vestibular dark cells via SLC12A2 and ATP1A1/ATP1B2 and released into endolymph via KCNQ1/KCNE1, which concludes the vestibular cycle. The importance of K+ cycling is underscored by the fact that mutations of KCNQ1, KCNE1, KCNQ4, GJB2, GJB3 and GJB6 lead to deafness in humans and that null mutations of KCNQ1, KCNE1, KCNJ10 and SLC12A2 lead to deafness in mouse models.
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PMID:K+ cycling and the endocochlear potential. 1203 9

Jervell and Lange-Nielsen syndrome (JLNS) is characterized by sensorineural deafness, QT prolongation, abnormal T waves, ventricular tachyarrhythmias, and autosomal recessive inheritance. Previously homozygous mutations in the potassium channel-encoding genes, KvLQT1 (alpha-subunit) and KCNE1 (beta-subunit), have been described in consanguineous families with JLNS. We screened two nonconsanguineous families with JLNS for mutations in KvLQT1, using single-strand conformation polymorphism analysis, denaturing high-performance liquid chromatography, and DNA sequencing. In one family, a missense mutation was identified in exon 6 of KvLQT1 on the maternal side, resulting in a glycine to aspartic acid substitution at codon 269 (G269D). The apparently normal father had an incompletely penetrant missense mutation in exon 3 of KvLQT1, introducing a premature stop codon at position 171. In the other family, a missense mutation resulting in the substitution of asparagine for aspartic acid at codon 202 (D202N) was identified in the mother and maternal grandmother, who had QTc prolongation (borderline in the mother), while the father and paternal grandfather, who were clinically normal, had a deletion of nucleotide 585, resulting in a frameshift and premature termination. In both families, the proband inherited both mutations. In this report we provide evidence that not only homozygous but also compound heterozygous mutations in KvLQT1 may cause JLNS in nonconsanguineous families. Incomplete penetrance in individuals with mutations appears to be frequent, indicating a higher prevalence of mutations than estimated previously. Interestingly, mutations resulting in truncation of the protein appear to be benign, with heterozygous carriers being asymptomatic.
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PMID:Compound heterozygous mutations in KvLQT1 cause Jervell and Lange-Nielsen syndrome. 1205 62

Long QT syndrome is characterized by a prolongation of the QT interval on the surface ECG. This clinically and genetically heterogeneous cardiac disease is potentially lethal due to ventricular polymorphic tachyarrhythmias leading to syncope or sudden death. It is transmitted according to different mendelian modes due to mutations in several genes coding for cardiac ion channels. Heterozygous mutations in KCNQ1, HERG, SCN5A, KCNE1 and KCNE2 genes are responsible for the dominant form without deafness whereas homozygous mutations in KCNQ1 and KCNE1 are responsible for the recessive form (Jervell and Lange-Nielsen syndrome) associated with congenital deafness. We report the case of a 5 year-old boy referred for syncope with a prolongation of the QTc interval (526 ms) and a 2/1 Atrio-Ventricular (AVB) block on the surface ECG. Under beta-blocking therapy, the sinus rate decreased and the 2/1 AVB disappeared. Electrophysiological study evidenced an infra-hisian block and a unipolar ventricular endocardial pacemaker was implanted. A V1777M missense mutation was identified in the C-terminal part of SCN5A, cardiac sodium channel gene, at the homozygous state in the proband and at the heterozygous state in both parents and 2 sibblings. Only the proband had a severe phenotype with syncope and AV conduction anomalies. All other genetically affected subjects were asymptomatic. This study provides evidence for the involvement of homozygous LQT3 forms in "functional" AVB.
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PMID:[Homozygotous mutation of the SCN5A gene responsible for congenital long QT syndrome with 2/1 atrioventricular block]. 1208 42

Potassium (K(+)) plays a very important role in the cochlea. K(+) is the major cation in endolymph and the charge carrier for sensory transduction and the generation of the endocochlear potential. The importance of K(+) handling in the cochlea is marked by the discovery of several forms of hereditary deafness that are due to mutations of K(+) channels. Deafness results from mutations of KCNQ4, a K(+) channel in the sensory hair cells, as well as from mutations of the gap junction proteins GJB2, GJB3 and GJB6 that may facilitate cell-to-cell movements of K(+). Deafness results also from mutations of KCNQ1 or KCNE1, subunits of a K(+) channel that carries K(+) from strial marginal cells and vestibular dark cells into endolymph. Further, deafness results from mutations of KCNJ10, a K(+) channel that generates the endocochlear potential in conjunction with the high K(+) concentration in strial intermediate cells and the low K(+) concentration in the intrastrial fluid spaces. This review details recent advances in the understanding of K(+) transport and its regulation in the cochlea and the vestibular labyrinth.
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PMID:K(+) cycling and its regulation in the cochlea and the vestibular labyrinth. 1209 19

A case of familial prolonged QT interval and congenital sensorineural hearing loss is described emphasising the diagnostic and management implications. Jervell and Lange-Nielsen syndrome is important because of its potential association with sudden death in children with congenital sensorineural deafness. It is known to be associated with mutations of the genes KCNQ1 (KVQTI) and KCNE1 (Isk). The underlying molecular abnormality leads to cardiac and cochlear dysfunction through a potassium channel defect. All children with congenital sensorineural hearing loss who have suffered unexplained syncopal attacks or convulsions should be screened for this syndrome. There is also a strong case for including a 12 lead ECG as part of the investigative work up of all children with congenital sensorineural deafness in whom a firm aetiology has not been established.
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PMID:Cochlear implantation in Jervell and Lange-Nielsen syndrome. 1244 9

The congenital long QT syndrome (LQTS) is a variable clinical and genetic entity characterised by prolongation of the QT interval on the ECG associated with the risk of serious ventricular arrhythmias (torsades de pointe, ventricular fibrillation) which may cause syncope and sudden death in patients with otherwise normal hearts. To date, 6 loci have been identified with the genes responsible for the forms LQT1, LQT2, LQT5 and LQT6, coding for the potassium channels (KCNQ1, HERG, KCNE1 and KCNE2, respectively) which, in the heterozygote state, are responsible for the main forms of LQTS without deafness and, in the homozygote state (KCNQ1 and KCNE1) for the recessive forms of LQTS with or without deafness. The gene for the LQT3 form codes for the cardiac sodium channel (SCN5A). The genetic variability observed in the LQTS corresponds to the diversity of cardiac ionic channels implicated in the genesis of the action potential, so making the LQTS a disease of the ionic channels or a "channelopathy". The potential severity of the prognosis justifies testing of subjects with long QT intervals on the ECG and Holter recording. In order to identify subjects with the genetic abnormality who are asymptomatic, these investigations associated with genetic testing should be made in all close members of the family of an affected person. The major problem remains the evaluation of the risk of sudden death in asymptomatic subjects with a genetic abnormality. At present, in the absence of clearly proven prognostic factors and in the knowledge that effective treatment without major secondary effects is available, all patients should be given prophylactic betablocker therapy.
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PMID:[Value of genetic testing in the management of the congenital long QT syndrome]. 1283 49

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