BACKGROUND In subclinical or silent long QT syndrome, the QT interval is normal under basal conditions. The hypothesis that insults to the repolarization reserve may cause arrhythmias in silent mutation carriers but not in noncarriers has been proposed as a general principle, yet crucial aspects remain descriptive, lacking quantification. OBJECTIVE To utilize accurate mathematical models of the human action potential and beta-adrenergic stimulation to quantitatively investigate arrhythmia-formation mechanisms peculiar to silent long QT syndrome, using mutation Q357R in KCNQ1 (alpha subunit of slow-delayed rectifier I-Ks) as a paradigm. METHODS Markov models were formulated to account for altered I-Ks kinetics in Q357R compared with wild type and introduced into a detailed model of the human ventricular myocyte action potential. RESULTS Dominant negative loss of I-Ks available reserve accurately represents Q357R. Action potential prolongation with mutant I-Ks was minimal, reproducing the silent phenotype. Partial block of rapid delayed rectifier current (I-Kr) was needed in addition to fast pacing and isoproterenol application to cause early after-depolarizations (EADs) in epicardial cells with mutant I-Ks, but this did not produce EADs in wild type. Reduced channel expression at the membrane, not I-Ks kinetic differences, caused EADs in the silent mutant. With mutant I-Ks, isoproterenol plus partial IKr block resulted in dramatic QT prolongation in the pseudo-electrocardiogram and EADs formed without I-Kr block in mid-myocardial cells during simulated exercise onset. CONCLUSION Multiple severe insults are needed to evince an arrhythmic phenotype in silent mutation Q357R. Reduced membrane I-Ks expression, not kinetic changes, underlies the arrhythmic phenotype.

• 出版日期2012-2