Identification of genes encoding ionic channels in congenital long QT syndrome has enabled a unique understanding of complex genotype-phenotype correlations and gene-specific clinical patterns.
Major progress has taken place, and at a very rapid pace, in the understanding of the congenital long QT syndrome (LQTS). This has been the direct consequence of the identification of several of the genes responsible for LQTS and of the studies that have followed, at both basic and clinical levels. A key issue is represented by the fact that all LQTS genes identified so far encode for ionic channels involved in the control of repolarization. The expression studies of the mutated genes have allowed identification of the specific electrophysiologic consequences of the specific mutations and have demonstrated alterations in the NA + and in K + currents sufficient to explain the prolongation of action potential duration and, hence, of the QT interval. Ongoing studies in the selected LQTS patients, for whom the specific mutations are known, are allowing a unique understanding of the complex genotype‐phenotype correlation. These studies indicate the existence of what appear to be gene‐specific patterns in many clinically important features such as the response to therapeutic interventions, the response to increases in heart rate, and in the factors that precipitate the life‐threatening arrhythmias typical of this intriguing disease.
Schwartz et al. (Thu,) conducted a review in congenital long QT syndrome (LQTS). Identification of genes encoding ionic channels in congenital long QT syndrome has enabled a unique understanding of complex genotype-phenotype correlations and gene-specific clinical patterns.