Cardiac memory evolves with age in association with development of the transient outward current.

BACKGROUND: Calcium-insensitive transient outward current (I(to)) is important to the development of cardiac memory (CM), which itself reflects the capacity of the heart to remodel electrophysiologically. We used cardiac pacing to test the hypothesis that CM evolution can be explained by developmental maturation of I(to). METHODS AND RESULTS: Acutely anesthetized dogs from 1 day old to adult were paced from the left ventricle (VP, n=29) or left atrial appendage (AP, n=12) to induce CM. T-wave vector displacement (TVD) obtained during VP was greater than with AP (adults, 0.39+/-0.06 mV; neonates, 0.04+/-0.01 mV; P<0.05). TVD began to increase at approximately 40 days of age, reaching adult levels by approximately 200 days. Microelectrode studies performed in 18 dogs (ages 3 to 94 days) after completing the CM protocol and 20 additional dogs (1 day old to adult) revealed that the epicardial action potential notch was absent in neonates, became apparent in the young, and was deepest in adults. The relationship between TVD and epicardial notch was such that as notch magnitude increased, TVD increased (r=-0.65, P<0.05). KChIP2 and Kv4.3 mRNA (measured via reverse transcription-polymerase chain reaction) also increased with age. CONCLUSIONS: The inducibility of CM gradually increases with age in association with evolution of the epicardial action potential notch and mRNA expression for KChIP2 and Kv4.3. This suggests that the capacity of the heart to remodel electrophysiologically and to manifest memory during development depends in part on evolution of the determinants of I(to).

Cardiac memory is associated with decreased levels of the transcriptional factor CREB modulated by angiotensin II and calcium.

Cardiac memory (CM) has short- (STCM) and long-term (LTCM) components modulated by calcium and angiotensin II. LTCM is associated with reduced Ito and Kv4.3 mRNA levels. Because the cAMP response element binding protein, CREB, contributes to CNS memory transcription, we hypothesized that it might be a transcriptional factor in CM, influenced by calcium and angiotensin II. We studied STCM in dogs that were AV sequentially paced (AVP) for 2 hours or sham-operated. STCM was evaluated with ECG and vectorcardiogram (VCG), and subepicardial biopsies were taken at 5 to 120 minutes and investigated for CREB. LTCM was studied in dogs paced for 3 weeks and in sham controls. At 3 weeks the heart was excised, biopsies obtained, and CRE binding tested. STCM induction occurred in AVP dogs but not in sham or AVP dogs treated with saralasin or nifedipine. Nuclear CREB was significantly decreased at 2 hours in the AVP no-drug group only. LTCM dogs manifested reduced binding of nuclear proteins to CRE, and CRE binding activity in the promoter region of Kv4.3. In conclusion, there is an association between STCM induction and decreased nuclear CREB that is angiotensin-modulated and calcium-dependent. Moreover, the decreased CRE binding after 3 weeks of AVP combined with CRE binding activity in the Kv4.3 promoter can explain the Kv4.3 mRNA and Ito downregulation that characterize LTCM.

Developmental changes in IKr and IKs contribute to age-related expression of dofetilide effects on repolarization and proarrhythmia.

OBJECTIVE: Clinical and experimental studies suggest that immature hearts are as or more sensitive than adult hearts to adverse effects of I(Kr) blocking drugs. We hypothesized that age-dependent changes in I(Kr) and I(Ks) contribute to the different repolarization reserves and proarrhythmic effects of I(Kr) blockers in the young and adult heart. METHODS: Dogs aged 1-150 days and adults were used to study (1) proarrhythmic effects in situ of the I(Kr) blocker dofetilide; (2) dofetilide effects on action potential duration (APD) recorded with microelectrodes from left ventricular (LV) slabs; (3) I(Kr) and I(Ks) in single LV myocytes using whole-cell voltage clamp. RESULTS: In situ, dofetilide-induced proarrhythmia occurred in 40% of adults, 86% of young (20-150 day) dogs and 0% of neonatal (1-19 day) dogs (P<0.05). Isolated tissue experiments showed no transmural gradient for repolarization from neonate through 3 months of age, after which the gradient increased through adulthood. In the presence of dofetilide, the greatest APD prolongation occurred in neonates. Yet, transmural dispersion did not increase in neonates but significantly increased in young and adults. Dofetilide-induced early after depolarization (EAD) incidence was 23% in adults, 59% in young and 8% in neonates (P<0.05). I(Kr) but not I(Ks) was expressed at <30 days, whereas both currents were present in adult myocardium. CONCLUSIONS: Our data suggest that a lack of I(Ks) results in a greater dependence on I(Kr) for repolarization in neonates and is associated with exaggerated effects of I(Kr)-blockade on APD. However, APD prolongation alone is insufficient for expression of proarrhythmia, which also requires transmural dispersion of repolarization and EADs. The extent to which APD prolongation, transmural dispersion and EADs are manifested at various ages in the absence and presence of I(Kr) blocking drugs appears to be the ultimate determinant of proarrhythmia.

Role of L-type calcium channels in pacing-induced short-term and long-term cardiac memory in canine heart.

BACKGROUND: We tested the hypothesis that ICa,L is important to the development of cardiac memory. METHODS AND RESULTS: The effects of L-type Ca2+ channel blockade and beta-blockade were tested on acutely anesthetized and on chronically instrumented, conscious dogs. Short-term memory (STM) was induced by 2 hours of ventricular pacing and long-term memory (LTM) by ventricular pacing for 21 days. STM dogs received placebo, nifedipine, or propranolol, and LTM dogs received placebo, atenolol, or amlodipine. AT1 receptor blockade (candesartan) and ACE inhibition (trandolapril) were also tested in LTM. Microelectrodes were used to record transmembrane potentials from isolated epicardial and endocardial slabs using a protocol simulating STM in intact animals. Left ventricular epicardial myocytes from LTM or sham control dogs were dissociated, and ICa,L was recorded (whole-cell patch-clamp technique). Evolution of STM and LTM was attenuated by ICa,L blockers but not beta-blockers. Neither AT1 receptor blockade nor ACE inhibition suppressed LTM. In microelectrode experiments, pacing induced an epicardial-endocardial gradient change mimicking STM that was suppressed by nifedipine. In patch-clamp experiments, peak ICa,L density in LTM and control were equivalent, but activation was more positive and time constants of inactivation longer in LTM (P<0.05). CONCLUSIONS: ICa,L blockade but not beta-adrenergic blockade suppresses cardiac memory. LTM evolution is unaffected by angiotensin II blockade and is associated with altered ICa,L kinetics.

Cellular electrophysiologic properties of old canine atria provide a substrate for arrhythmogenesis.

OBJECTIVE: The incidence of atrial fibrillation increases with age. We hypothesized that aging-associated changes in the atrial action potential (AP) and conduction velocity provide a substrate for abnormal conduction and arrhythmogenesis. METHODS: We used microelectrode techniques to record AP from the endocardium of the right atrial wall of dogs aged 1-5 (adult) and >8 years (old). Conduction velocity was measured between two microelectrodes 3-10 mm apart. Histological study was carried out to assess fibrosis. RESULTS: Whereas resting potential, AP amplitude and V(max) did not differ with age, the plateau was more negative and AP duration was longer in old tissue. The L-type calcium current (I(Ca,L)) agonist Bay K8644 (10(-8)-10(-6) mol/l) elevated the plateau and shortened APD more in old than in adult, such that AP contour in old atria approached that of adult. In contrast, the I(Ca,L) blocker nisoldipine (10(-8)-10(-5) mol/l) depressed the plateau in adult and had no effect in old. There was no difference between the two groups in conduction velocity of normal beats, whereas for early premature impulses, reduced conduction velocity and a wider time window manifesting slow conduction were detected in old in comparison to adult tissue. A twofold increase in the amount of fibrous tissue was detected in old atria. CONCLUSIONS: Our data show significant differences in contour of AP in adult and old atria. The responses to Bay K8644 and nisoldipine suggest a decreased I(Ca,L) in old atrial tissue. The alterations in AP contour and increased fibrosis may be responsible for slower conduction of early premature beats in old atria. The age-related changes in conduction of premature beats are consistent with those observed in patients with paroxysmal atrial fibrillation and may contribute to the greater propensity to atrial fibrillation in the aged.