Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0018799 (heart disease)
34,133 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The long-QT syndrome (LQT; Ward-Romano syndrome) is a cardiac disorder that is inherited as an autosomal dominant trait. Affected family members suffer from recurrent syncope and sudden death due to ventricular arrhythmias. Recently, we identified a DNA marker on the short arm of chromosome 11 (the Harvey ras-1 locus [H-ras-1]) that was completely linked to the LQT locus in one large family. In the study presented here, we performed linkage investigations on six new and unrelated families with LQT. The LQT locus was again completely linked to the H-ras-1 locus in all families examined, with a combined lod score of 5.25 at a recombination fraction of 0. This work confirms our previous assignment of the LQT locus to chromosome 11p and supports the hypothesis that LQT is genetically homogeneous. As no obligate recombinants were identified in either this or our previous study, the H-ras-1 protooncogene remains a candidate for the LQT disease gene. Identification of LQT families with locus homogeneity is an important step in the development of a refined genetic map of this locus and will help determine whether the H-ras-1 marker would be of general use for presymptomatic diagnosis of this potentially fatal, but treatable, disorder.
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PMID:Consistent linkage of the long-QT syndrome to the Harvey ras-1 locus on chromosome 11. 174 60

The long QT syndrome is an autosomally dominantly inherited cardiac disorder characterized by abnormalities of myocardial repolarization, exercise- or stress-related syncopal attacks and risk of sudden death due to cardiac arrhythmias. Genetic linkage studies have defined three LQT loci on chromosomes 11p15.5, 3q21-24 and 7p35-36. We performed linkage analyses in three Finnish LQT families using five amplifiable markers assigned to chromosome 11p15. By multipoint linkage analyses we obtained a maximal lod score of 5.503, suggesting that the LQT1 locus maps between D11S922 and D11S1338 on chromosome 11. Our data provide a step towards closer definition of the exact borderlines of the LQT1 locus in chromosome 11 and demonstrate markers with high utility in identification of gene carriers in the affected families.
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PMID:Linkage of the long QT syndrome to the short arm of chromosome 11: use of five highly polymorphic markers towards more detailed localization of the mutant gene. 755 59

Recently, there has been intense excitement in the field of cardiac arrhythmias. Molecular genetic studies have led to significant progress in characterizing molecular mechanisms underlying long QT syndrome, an inherited cardiac disorder that causes syncope, seizures, and sudden death from ventricular arrhythmias. Three long QT syndrome genes have been identified: SCN5A on 3p21-24, HERG on 7q35-36, and KVLQT1 on 11p15.5; all encode cardiac mycote ion channels. Molecular and electrophysiological characterization of these three long QT syndrome genes has led to identification of three critical electrical currents in the human heart (INa, IKr, IKa) and provides insight into our fundamental understanding of cardiac function. Genetic testing and gene-specific therapies are now available for some families with long QT syndrome.
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PMID:Molecular genetics of long QT syndrome from genes to patients. 924 89

Inward rectifying potassium currents (Ikr and Iks) during phase 3 repolarization of the myocyte from the beginning to the end of repolarization of the myocardial syncytium will inscribe a T-U-wave on the surface electrocardiogram (ECG). Type two congenital long QT syndrome (LQT2) is a phenotype of human ether-a-go-go-related gene (HERG) mutation on the chromosome 7q 35-36. Type one congenital long QT syndrome (LQT1) is a phenotype of KvLQT1 mutation on the chromosome 11p15.5. Both LQT1 and LQT2 relate with inward rectifying potassium currents and is repolarization related, therefore, it is speculate that patients of LQT1 and LQT2 may have an abnormal T-U-wave on their surface ECG. To two probands of congenital LQT, 8 patients of structural heart disease treated by open heart surgery, 13 patients of structural heart disease without open-heart surgery, and 10 patients of normal controls, 24 hour-Holter monitoring was performed from July to December 1996. Their corrected QT interval (QTc) as well as the RR interval of every heart beat was calculated by a computer. The results showed that all 33 patients exhibited beat-by-beat fluctuation of their QTc and RR daily. The RR intervals of these two probands of congenital LQT were somewhile more than 1200 ms during circadian waking time, while 31 cases without LQT showed their RR prolongation only during the circadian sleeping time. A multi-undulant T-U-wave, or a beat-to-beat changing of vectors or amplitudes of their T-U-wave observed in these two probands of congenital LQT, were not observable in those 31 patients without congenital LQT. Therefore, we concluded that multi-undulant T-U-wave, sinus bradycardia and a longer QTc was a phenotype of the mutated genes which control the inward rectifying potassium currents during phase 3 repolarization.
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PMID:Multi-undulant T-U-wave, sinus bradycardia and long QT syndrome: a possible phenotype of mutant genes controlling the inward potassium rectifiers. 929 27

Cardiac arrhythmias cause more than 300,000 sudden deaths each year in the USA alone. Long QT syndrome (LQT) is a cardiac disorder that causes sudden death from ventricular tachyarrhythmias, specifically torsade de pointes. Four LQT genes have been identified: KVLQT1 (LQT1) on chromosome 11p15.5, HERG (LQT2) on chromosome 7q35-36, SCN5A (LQT3) on chromosome 3p21-24, and MinK (LQT5) on chromosome 21q22. SCN5A encodes the cardiac sodium channel, and LQT-causing mutations in SCN5A lead to the generation of a late phase of inactivation-resistant whole-cell inward currents. Mexiletine, a sodium channel blocker, is effective in shortening the QT interval corrected for heart rate (QTc) of patients with SCN5A mutations. HERG encodes the cardiac I(Kr) potassium channel. Mutations in HERG act by a dominant-negative mechanism or by a loss-of-function mechanism. Raising the serum potassium concentration can increase outward HERG potassium current and is effective in shortening the QTc of patients with HERG mutations. KVLQT1 is a cardiac potassium channel protein that interacts with another small potassium channel MinK to form the cardiac I(Ks) potassium channel. Like HERG mutations, mutations in KVLQT1 and MinK can act by a dominant-negative mechanism or a loss-of-function mechanism. An effective treatment for LQT patients with KVLQT1 or MinK mutations is expected to be developed based on the functional characterization of the I(Ks) potassium channel. Genetic testing is now available for some patients with LQT.
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PMID:Genetics, molecular mechanisms and management of long QT syndrome. 955 90

Long QT syndrome (LQT) is a cardiac disorder causing syncope and sudden death from arrhythmias. LQT is characterized by prolongation of the QT interval on electrocardiogram, an indicationof abnormal cardiac repolarization. Mutations in KVLQT1, HERG, SCN5A, and KCNE1, genes encoding cardiac ion channels, cause LQT. Here, we define thecomplete genomic structure of three LQT genesand use this information to identify disease-associated mutations. KVLQT1 is composed of 16 exonsand encompasses approximately 400 kb. HERG consists of 16 exons and spans 55 kb. Three exons make up KCNE1. Each intron of these genes contains the invariant GT and AG at the donor and acceptor splice sites, respectively. Intron sequences were used to design primer pairs for the amplification of all exons. Familial and sporadic cases affected bymutations in KVLQT1, HERG, and KCNE1 can nowbe genetically screened to identify individuals at risk of developing this disorder. This work has clinical implications for presymptomatic diagnosis and therapy.
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PMID:Genomic structure of three long QT syndrome genes: KVLQT1, HERG, and KCNE1. 969 36

Long QT syndrome (LQT) is a cardiac disorder that causes sudden death from ventricular tachyarrhythmias, specifically torsade de pointes. Two types of LQT have been reported, autosomal-dominant LQT (Romano-Ward syndrome) and autosomal-recessive LQT (Jervell and Lange-Nielsen syndrome); Jervell and Lange-Nielsen syndrome is also associated with deafness. Four LQT genes have been identified for autosomal-dominant LQT: K+ channel genes KVLQT1 on chromosome 11p15.5, HERG on 7q35-36 and minK on 21q22, and the cardiac Na+ channel gene SCN5A on chromosome 3p21-24. Two genes, KVLQT1 and minK, have been identified for Jervell and Lange-Nielsen syndrome. Genetic testing and gene-specific therapies are available for some LQT patients.
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PMID:The molecular basis of long QT syndrome and prospects for therapy. 979 61

The molecular genetic background of inherited cardiac arrhythmias has only recently been uncovered. This late development in comparison to other inherited cardiac disorders has partly been due to the high mortality and early disease onset of these arrhythmias resulting in mostly small nucleus families. Thus, traditional genetic linkage studies, which are based on the genetic information obtained from large multi-generation families, were made difficult. Inherited arrhythmogenic disorders can be divided into 'primary electrical disorders' (e.g., long-QT [LQT] syndrome) in which a detectable, organic heart disease is not evident, and into inherited diseases of the myocardial structure (e.g., hypertrophic cardiomyopathies) in which the arrhythmias occur combined with the structural alterations. To date, all inherited arrhythmogenic disorders in which the causative genes have been identified turned out to be channelopathies, since the genes encode channel subunits that regulate important ion currents that tune the cardiac action potential. The discovery of the genetic bases of the LQT syndrome became a new methodologic paradigm; because with the use of 'classical' genetic linkage strategies (named [positional] candidate strategies) not only the causative genes have been found, but moreover, functional components with a previously unknown but fundamental role for a normal repolarization process were discovered. Disease mutations turned out to be not only a family-specific event with a distinct phenotype and the potential of an additional diagnostic tool, but also, when expressed in heterologous expression systems, characterize the defective ion channel in a topological way and lead to a more specific understanding of ion channel function. Most, if not all, primary electrical cardiac disorders show a high genetic diversity. For the LQT syndromes, sixth disease loci and the responsible gene have been recently discovered (so-called locus or genetic heterogeneity). Within all disease genes, the mutations are spread over the entire gene (allelic heterogeneity); in addition, more than one disease mutation may be present. This complexity requires, at least, complete mutation analysis of all LQT genes before medical advice should be given. Meanwhile, genotype-phenotype correlations in large families are being used to evaluate intergene, interfamilial and intrafamilial differences in the clinical phenotype, reflecting gene specific, gene-site specific and individual consequences of a given mutation. A widespread phenotypic heterogeneity even within mutation carriers in the same family raises the importance of modifying factors and genes that are mostly unknown to date. The reduced penetrance and variable expressivity associated with the LQT mutations remain still to be explained. First insights into the complex actions of mutations are being extracted, from expression data; these preliminary results may lead to potential implications for a specific (gene-site directed) therapy. This paper discusses the current data on molecular genetics and genotype-phenotype correlations in LQT syndrome and related disorders and the potential implications for diagnosis and treatment.
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PMID:Molecular genetics of arrhythmias--a new paradigm. 1081 Jul 73

Sudden cardiac death occurs in the United States with an incidence of more than 300,000 persons per year. The underlying cause of death is commonly considered to be due to primary or secondary arrhythmias. In young persons in whom no structural heart disease can be identified, the long QT syndromes (LQTS) are commonly considered as likely causes. Multiple genes causing LQTS have been identified thus far, all of which encode cardiac ion channels. These include two potassium channel alpha subunits (KVLQT1 and HERG), two potassium channel beta subunits (minK and MiRP1), and one sodium channel gene (SCN5A). The purpose of this review is to describe the current understanding of the molecular genetics of LQTS and the resultant phenotypes, particularly in young patients.
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PMID:Current concepts in long QT syndrome. 1105 Feb 78

Sudden cardiac death occurs in the United States with an incidence greater than 300,000 persons per year. The underlying cause of death is commonly considered to be due to primary or secondary arrhythmias. In cases in which no structural heart disease can be identified, the long QT syndromes (LQTS) are now commonly considered as likely causes. Multiple genes causing LQTS have been identified thus far, all encoding cardiac ion channels. These include two potassium channel alpha-subunits (KVLQT1, HERG), two potassium channel beta-subunits (minK, MiRP1), and one sodium channel gene (SCN5A). The purpose of this review is to describe the current understanding of the molecular genetics of LQTS and the resultant phenotypes.
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PMID:Genotype and severity of long QT syndrome. 1125 55


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