WITHDRAWN: Sex differences in the expression of sodium/calcium exchanger influence the arrhythmia phenotype in the long QT syndrome type 2.

The paper entitled "Sex differences in the expression of sodium/calcium exchanger influence the arrhythmia phenotype in the long QT syndrome type 2" by Salama et al, which was published online on 19 May 2008, has been withdrawn at the authority of the editor and the publisher.

N-(6-chloro-pyridin-3-yl)-3,4-difluoro-benzamide (ICA-27243): a novel, selective KCNQ2/Q3 potassium channel activator.

KCNQ2 (Kv7.2) and KCNQ3 (Kv7.3) are voltage-gated K(+) channel subunits that underlie the neuronal M current. In humans, mutations in these genes lead to a rare form of neonatal epilepsy (Biervert et al., 1998; Singh et al., 1998), suggesting that KCNQ2/Q3 channels may be attractive targets for novel antiepileptic drugs. In the present study, we have identified the compound N-(6-chloro-pyridin-3-yl)-3,4-difluoro-benzamide (ICA-27243) as a selective activator of the neuronal M current and KCNQ2/Q3 channels. In SH-SY5Y human neuroblastoma cells, ICA-27243 produced membrane potential hyperpolarization that could be prevented by coadministration with the M-current inhibitors 10,10-bis(4-pyridinylmethyl)-9(10H)-anthracenone dihydrochloride (XE-991) and linopirdine. ICA-27243 enhanced both (86)Rb(+) efflux (EC(50) = 0.2 microM) and whole-cell currents in Chinese hamster ovary cells stably expressing heteromultimeric KCNQ2/Q3 channels (EC(50) = 0.4 microM). Activation of KCNQ2/Q3 channels was associated with a hyperpolarizing shift of the voltage dependence of channel activation (V((1/2)) shift of -19 mV at 10 microM). In contrast, ICA-27243 was less effective at activating KCNQ4 and KCNQ3/Q5 and was selective over a wide range of neurotransmitter receptors and ion channels such as voltage-dependent sodium channels and GABA-gated chloride channels. ICA-27243 (1-10 microM) was found to reversibly suppress seizure-like activity in an ex vivo hippocampal slice model of epilepsy and demonstrated in vivo anticonvulsant activity (ED(50) = 8.4 mg/kg) in the mouse maximal electroshock epilepsy model. In conclusion, ICA-27243 represents the first member of a novel chemical class of selective KCNQ2/Q3 activators with anticonvulsant-like activity in experimental models of epilepsy.

Myocarditis following adeno-associated viral gene expression of human soluble TNF receptor (TNFRII-Fc) in baboon hearts.

Sequestration of tumor necrosis factor-alpha (TNFalpha) by TNF-receptor immunoglobulin G (IgG)-Fc fusion proteins can limit heart failure progression in rodent models. In this study we directly injected an adeno-associated viruses (AAV)-2 construct encoding a human TNF receptor II IgG-Fc fusion protein (AAV-TNFRII-Fc) into healthy baboon hearts and assessed virally encoded gene expression and clinical response. Adult baboons received direct cardiac injections of AAV-TNFRII-Fc ( approximately 5 x 10(12) viral/genomes/baboon) or an equivalent dose of AAV-2 empty capsids, and were analyzed after 5 or 12 weeks. Viral genomes were restricted to the myocardium, and routine analyses (blood cell counts, clinical chemistries) remained unremarkable. Echocardiograms were unchanged but electrocardiograms revealed marked ST- and T-wave changes consistent with myocarditis only in baboons receiving AAV-TNFRII-Fc. TNFRII serum levels peaked at approximately 3 times the baseline levels at 1-2 weeks postinjection and subsequently declined to baseline levels. TNFRII-Fc protein and transcripts were detected in the heart at harvest. After AAV injection, anti-AAV-2 antibody levels increased in all baboons, while anti-TNFRII-Fc could not be detected. Baboons that received AAV-TNFRII-Fc developed myocardial infiltrates including CD8+ cells. Thus, a cellular immune response to cardiac delivery of AAV encoding foreign proteins may be an important consideration for AAV-based cardiac gene therapy.

Cardiovascular tissues contain independent circadian clocks.

Acute cardiovascular events exhibit a circadian rhythm in the frequency of occurrence. The mechanisms underlying these phenomena are not yet fully understood, but they may be due to rhythmicity inherent in the cardiovascular system. We have begun to characterize rhythmicity of the clock gene mPer1 in the rat cardiovascular system. Luciferase activity driven by the mPer1 gene promoter is rhythmic in vitro in heart tissue explants and a wide variety of veins and arteries cultured from the transgenic Per1-luc rat. The tissues showed between 3 and 12 circadian cycles of gene expression in vitro before damping. Whereas peak per1-driven bioluminescence consistently occurred during the late night in the heart and all arteries sampled, the phases of the rhythms in veins varied significantly by anatomical location. Varying the time of the culture procedure relative to the donor animal's light:dark cycle revealed that, unlike some other rat tissues such as liver, the phases of in vitro rhythms of arteries, veins, and heart explants were affected by culture time. However, phase relationships among tissues were consistent across culture times; this suggests diversity in circadian regulation among components of the cardiovascular system.

Dominant-negative subunits reveal potassium channel families that contribute to M-like potassium currents.

M-currents are K+ currents generated by members of the KCNQ family of K+ channels (Wang et al., 1998). However, in some cells, M-like currents may be contaminated by members of other K+ channel gene families, such as the erg family (Meves et al., 1999; Selyanko et al., 1999). In the present experiments, we have used the acute expression of pore-defective mutants of KCNQ3 (DN-KCNQ3) and Merg1a (DN-Merg1a) as dominant negatives to separate the contributions of these two families to M-like currents in NG108-15 neuroblastoma hybrid cells and rat sympathetic neurons. Two kinetically and pharmacologically separable components of M-like current could be recorded from NG108-15 cells that were individually suppressed by DN-Merg1a and DN-KCNQ3, respectively. In contrast, only DN-KCNQ3, and not DN-Merg1a, reduced currents recorded from sympathetic neurons. Pharmacological tests suggested that the residual current in DN-KCNQ3-treated sympathetic neurons was carried by residual KCNQ channels. Ineffectiveness of DN-Merg1a in sympathetic neurons was not caused by lack of expression, as judged by confocal microscopy of Flag-tagged DN-Merg1a. These results accord with previous inferences regarding the roles of erg and KCNQ channels in generating M-like currents. This experimental approach should therefore be useful in delineating the contributions of members of these two gene families to K+ currents in other cells.

Cardiac arrhythmias: from (transgenic) mice to men.

Transgenic and gene-targeted mice now are frequently used to study cardiac arrhythmias due to the ease with which the mouse genome can be manipulated. Marked electrophysiologic differences are present between the mouse and human heart, however, and the utility of the mouse as a model for arrhythmias and sudden death remains controversial. Tachyarrhythmias, bradyarrhythmias, and ECG in the mouse need to be interpreted with extreme care and without preconceptions based on our experience with humans. Despite its limitations, the mouse can provide a powerful tool to further our understanding of basic mechanisms that underlie human cardiac electrophysiology.

Targeted replacement of KV1.5 in the mouse leads to loss of the 4-aminopyridine-sensitive component of I(K,slow) and resistance to drug-induced qt prolongation.

The K(+) channel mKv1.5 is thought to encode a 4-aminopyridine (4-AP)-sensitive component of the current I(K,slow) in the mouse heart. We used gene targeting to replace mKv1.5 with the 4-AP-insensitive channel rKv1.1 (SWAP mice) and directly test the role of Kv1.5 in the mouse ventricle. Kv1.5 RNA and protein were undetectable, rKv1.1 was expressed, and Kv2.1 protein was upregulated in homozygous SWAP hearts. The density of the K(+) current I(K,slow) (depolarizations to +40 mV, pA/pF) was similar in left ventricular myocytes isolated from SWAP homozygotes (17+/-1, n=27) and littermate controls (16+/-2, n=19). The densities and properties of I(peak), I(to,f), I(to,s), and I(ss) were also unchanged. In homozygous SWAP myocytes, the 50-micromol/L 4-AP-sensitive component of IK,slowwas absent (n=6), the density of the 20-mmol/L tetraethylammonium-sensitive component of I(K,slow) was increased (9+/-1 versus 5+/-1, P<0.05), and no 100- to 200-nmol/L alpha-dendrotoxin-sensitive current was found (n=8). APD(90) in SWAP myocytes was similar to controls at baseline but did not prolong in response to 30 micromol/L 4-AP. Similarly, QTc (ms) was not prolonged in anesthetized SWAP mice (64+/-2, homozygotes, n=9; 62+/-2, controls, n=9), and injection with 4-AP prolonged QTc only in controls (63+/-1, homozygotes; 72+/-2, controls; P<0.05). SWAP mice had no increase in arrhythmias during ambulatory telemetry monitoring. Thus, Kv1.5 encodes the 4-AP-sensitive component of I(K,slow) in the mouse ventricle and confers sensitivity to 4-AP-induced prolongation of APD and QTC: Compensatory upregulation of Kv2.1 may explain the phenotypic differences between SWAP mice and the previously described transgenic mice expressing a truncated dominant-negative Kv1.1 construct.

Pharmacogenetic interactions between beta-blocker therapy and the angiotensin-converting enzyme deletion polymorphism in patients with congestive heart failure.

BACKGROUND: Activation of the renin-angiotensin and sympathetic nervous systems adversely affect heart failure progression. The ACE deletion allele (ACE D) is associated with increased renin-angiotensin activation; however, its influence on patient outcomes remains uncertain, and the pharmacogenetic interactions with beta-blocker therapy have not been previously evaluated. METHODS AND RESULTS: We prospectively followed 328 patients (age, 56.1+/-11.9 years) with systolic dysfunction (left ventricular ejection fraction, 0.24+/-0.08) to assess the impact of the ACE D allele on transplant-free survival (median follow-up, 21 months). Transplant-free survival was compared by genotype for the whole cohort and separately in patients with (n=120) and those without beta-blocker therapy (n=208) at the time of entry. Transplant-free survival was significantly poorer for patients with the D: allele (1-year percent survival II/ID/DD=94/77/75; 2-year=78/65/60; ordered log-rank test, P:=0.044). In patients not treated with beta-blockers, the adverse impact of ACE D allele was dramatically increased (1-year percent survival II/ID/DD=95/75/67; 2-year=81/61/48; P:=0.005). In contrast, in patients receiving beta-blocker therapy, no influence of ACE genotype on transplant-free survival was evident (1-year percent survival II/ID/DD=91/80/86; 2-year=70/71/77; P:=0.73). CONCLUSIONS: In a cohort of patients with systolic dysfunction, the ACE D allele was associated with a significantly poorer transplant-free survival. This effect was primarily evident in patients not treated with beta-blockers and was not seen in patients receiving therapy. These findings suggest a potential pharmacogenetic interaction between the ACE D/I polymorphism and therapy with beta-blockers in the determination of heart failure survival.

Functional consequences of elimination of i(to,f) and i(to,s): early afterdepolarizations, atrioventricular block, and ventricular arrhythmias in mice lacking Kv1.4 and expressing a dominant-negative Kv4 alpha subunit.

It was recently reported that the slow transient outward K(+) current, I(to, s), that is evident in mouse left ventricular septal cells is eliminated in mice with a targeted deletion of the Kv1.4 gene (Kv1.4(-/-)). The rapidly inactivating transient outward K(+) current, I(to, f), in contrast, is selectively eliminated in ventricular myocytes isolated from transgenic mice expressing a dominant-negative Kv4 alpha subunit, Kv4.2W362F. Expression of Kv4. 2W362F results in marked prolongation of action potentials and QT intervals. In addition, a slow transient outward K(+) current, that is similar to I(to,s) in wild-type mouse left ventricular septal cells, is evident in all Kv4.2W362F-expressing (left and right) ventricular cells. To test directly the hypothesis that upregulation of Kv1.4 alpha subunit underlies the appearance of this slow transient outward K(+) current in Kv4.2W362F-expressing ventricular cells and to explore the functional consequences of elimination of I(to,f) and I(to,s), mice expressing Kv4.2W362F in the Kv1.4(-/-) background (Kv4.2W362FxKv1.4(-/-)) were generated. Histological and echocardiographic studies revealed no evidence of structural abnormalities or contractile dysfunction in Kv4.2W362FxKv1.4(-/-) mouse hearts. Electrophysiological recordings from the majority (approximately 80%) of cells isolated from the right ventricle and left ventricular apex of Kv4.2W362FxKv1.4(-/-) animals demonstrated that both I(to, f) and I(to,s) are eliminated; action potentials are prolonged significantly; and, in some cells, early afterdepolarizations were observed. In addition, in vivo telemetric ECG recordings from Kv4.2W362FxKv1.4(-/-) animals revealed marked QT prolongation, atrioventricular block, and ventricular tachycardia. These observations demonstrate that upregulation of Kv1.4 contributes to the electrical remodeling evident in the ventricles of Kv4.2W362F-expressing mice and that elimination of both I(to,f) and I(to,s) has dramatic functional consequences.

Inducible polymorphic ventricular tachyarrhythmias in a transgenic mouse model with a long Q-T phenotype.

We created a mouse model with a prolonged Q-T interval and spontaneous arrhythmias by overexpressing the NH(2) terminus and first transmembrane segment (Kv1.1N206Tag) of a delayed rectifier potassium channel (LQT(+/-) mouse). Analyses were performed using whole cell recordings of cardiac myocytes, surface electrocardiography, and programmed electrical stimulation. Action potential duration (APD) was prolonged to the same extent and was more highly variable in myocytes derived from LQT(+/-) and LQT(+/+) mice than in myocytes derived from wild-type (WT) FVB mice. Under ketamine anesthesia, the Q-T interval of both LQT(+/+) and LQT(+/-) mice was comparably prolonged versus that of WT mice. Stimulation of the right ventricle using an intracardiac catheter induced polymorphic ventricular tachyarrhythmias in 50% of the LQT(+/-) mice and 36% of the LQT(+/+) mice, whereas polymorphic ventricular tachyarrhythmias were not inducible in WT mice. The analyses of LQT(+/-) and LQT(+/+) mice indicate that prolongation of the Q-T interval in LQT mice is associated with prolonged APD, increased dispersion of APD among cardiocytes, and inducibility of polymorphic ventricular tachycardia, providing the substrate for spontaneous arrhythmias in these animals.

Enhanced dispersion of repolarization and refractoriness in transgenic mouse hearts promotes reentrant ventricular tachycardia.

The heterogeneous distribution of ion channels in ventricular muscle gives rise to spatial variations in action potential (AP) duration (APD) and contributes to the repolarization sequence in healthy hearts. It has been proposed that enhanced dispersion of repolarization may underlie arrhythmias in diseases with markedly different causes. We engineered dominant negative transgenic mice that have prolonged QT intervals and arrhythmias due to the loss of a slowly inactivating K(+) current. Optical techniques are now applied to map APs and investigate the mechanisms underlying these arrhythmias. Hearts from transgenic and control mice were isolated, perfused, stained with di-4-ANEPPS, and paced at multiple sites to optically map APs, activation, and repolarization sequences at baseline and during arrhythmias. Transgenic hearts exhibited a 2-fold prolongation of APD, less shortening (8% versus 40%) of APDs with decreasing cycle length, altered restitution kinetics, and greater gradients of refractoriness from apex to base compared with control hearts. A premature impulse applied at the apex of transgenic hearts produced sustained reentrant ventricular tachycardia (n=14 of 15 hearts) that did not occur with stimulation at the base (n=8) or at any location in control hearts (n=12). In transgenic hearts, premature impulses initiated reentry by encountering functional lines of conduction block caused by enhanced dispersion of refractoriness. Reentrant VT had stable (>30 minutes) alternating long/short APDs associated with long/short cycle lengths and T wave alternans. Thus, optical mapping of genetically engineered mice may help elucidate some electrophysiological mechanisms that underlie arrhythmias and sudden death in human cardiac disorders.

Molecular basis of transient outward K+ current diversity in mouse ventricular myocytes.

1. Two kinetically and pharmacologically distinct transient outward K+ currents, referred to as Ito,f and Ito,s, have been distinguished in mouse left ventricular myocytes. Ito,f is present in all left ventricular apex cells and in most left ventricular septum cells, whereas Ito,s is identified exclusively in left ventricular septum cells. 2. Electrophysiological recordings from ventricular myocytes isolated from animals with a targeted deletion of the Kv1.4 gene (Kv1.4-/- mice) reveal that Ito,s is undetectable in cells isolated from the left ventricular septum (n = 26). Ito,f density in both apex and septum cells, in contrast, is not affected by deletion of Kv1.4. 3. Neither the 4-AP-sensitive, slowly inactivating K+ current, IK,slow, nor the steady-state non-inactivating K+ current, ISS, is affected in Kv1.4-/- mouse left ventricular cells. 4. In myocytes isolated from transgenic mice expressing a dominant negative Kv4.2 alpha subunit, Kv4.2W362F, Ito,f is eliminated in both left ventricular apex and septum cells. In addition, a slowly inactivating transient outward K+ current similar to Ito,s in wild-type septum cells is evident in myocytes isolated from left ventricular apex of Kv4.2W362F-expressing transgenics. The density of Ito,s in septum cells, however, is unaffected by Kv4.2W362F expression. 5. Western blots of fractionated mouse ventricular membrane proteins reveal a significant increase in Kv1.4 protein level in Kv4.2W362F-expressing transgenic mice. The protein levels of other Kv alpha subunits, Kv1.2 and Kv2.1, in contrast, are not affected by the expression of the Kv4.2W362F transgene. 6. The results presented here demonstrate that the molecular correlates of Ito,f and Ito,s in adult mouse ventricle are distinct. Kv1.4 underlies mouse ventricular septum Ito,s, whereas Kv alpha subunits of the Kv4 subfamily underlie mouse ventricular apex and septum Ito, f. The appearance of the slow transient outward K+ current in Kv4. 2W362F-expressing left ventricular apex cells with properties indistinguishable from Ito,s in wild-type cells is accompanied by an increase in Kv1.4 protein expression, suggesting that the upregulation of Kv1.4 underlies the observed electrical remodeling in Kv4.2W362F-expressing transgenics.

Two types of K(+) channel subunit, Erg1 and KCNQ2/3, contribute to the M-like current in a mammalian neuronal cell.

The potassium M current was originally identified in sympathetic ganglion cells, and analogous currents have been reported in some central neurons and also in some neural cell lines. It has recently been suggested that the M channel in sympathetic neurons comprises a heteromultimer of KCNQ2 and KCNQ3 (Wang et al., 1998) but it is unclear whether all other M-like currents are generated by these channels. Here we report that the M-like current previously described in NG108-15 mouse neuroblastoma x rat glioma cells has two components, "fast" and "slow", that may be differentiated kinetically and pharmacologically. We provide evidence from PCR analysis and expression studies to indicate that these two components are mediated by two distinct molecular species of K(+) channel: the fast component resembles that in sympathetic ganglia and is probably carried by KCNQ2/3 channels, whereas the slow component appears to be carried by merg1a channels. Thus, the channels generating M-like currents in different cells may be heterogeneous in molecular composition.

Characterization of a slowly inactivating outward current in adult mouse ventricular myocytes.

We recently have reported that suppression of the slowly inactivating component of the outward current, Islow, in ventricular myocytes of transgenic mice (long QT mice) overexpressing the N-terminal fragment and S1 segment of Kv1.1 resulted in a significant prolongation of action potential duration and the QT interval. Here we describe the detailed biophysical properties and physiological role of Islow by applying the whole-cell patch-clamp technique at both room temperature and 37 degreesC. This current activates rapidly with time constants ranging from 3.8+/-0.8 ms at -20 mV to 2.1+/-0.5 ms at 50 mV at room temperature. The half-activation voltage and slope factor are -12.5+/-2.6 mV and 7. 7+/-1.0 mV, respectively. The inactivation of this current is slow compared with the fast inactivating component Ito, with time constants of approximately 100 ms at 37 degreesC. The steady-state inactivation of Islow is not temperature-dependent, with half-inactivation voltages and slope factors of -35.1+/-1.3 and -5. 4+/-0.4 mV at 37 degreesC, and -37.6+/-1.8 and -5.8+/-0.6 mV at room temperature. Double exponentials were required to describe the time-dependent recovery of Islow from steady-state inactivation, with time constants of 233+/-34 and 3730+/-702 ms at 37 degreesC, and 830+/-240 and 8680+/-2410 ms at room temperature. Islow is highly sensitive to 4-aminopyridine but is insensitive to tetraethylammonium, alpha-dendrotoxin, and E-4031. Stimulation with action-potential waveforms under voltage-clamp mode revealed that this current plays an important role in the early and middle phases of repolarization of the cardiac action potential. We conclude that the biophysical properties and pharmacological profiles of Islow are similar to those of Kv1.5-encoded currents.

The transient outward current in mice lacking the potassium channel gene Kv1.4.

1. The transient outward current (Ito) plays a prominent role in the repolarization phase of the cardiac action potential. Several K+ channel genes, including Kv1.4, are expressed in the heart, produce rapidly inactivating currents when heterologously expressed, and may be the molecular basis of Ito. 2. We engineered mice homozygous for a targeted disruption of the K+ channel gene Kv1.4 and compared Ito in wild-type (Kv1.4+/+), heterozygous (Kv1.4+/-) and homozygous 'knockout' (Kv1.4-/-) mice. Kv1.4 RNA was truncated in Kv1.4-/- mice and protein expression was absent. 3. Adult myocytes isolated from Kv1.4+/+, Kv1.4+/- and Kv1.4-/- mice had large rapidly inactivating outward currents. The peak current densities at 60 mV (normalized by cellular capacitance, in pA pF-1; means +/- s.e.m.) were 53.8 +/- 5. 3, 45.3 +/- 2.2 and 44.4 +/- 2.8 in cells from Kv1.4+/+, Kv1.4+/- and Kv1.4-/- mice, respectively (P < 0.02 for Kv1.4+/+ vs. Kv1.4-/-). The steady-state values (800 ms after the voltage clamp step) were 30.9 +/- 2.9, 26.9 +/- 3.8 and 23.5 +/- 2.2, respectively (P < 0.02 for Kv1.4+/+ vs. Kv1.4-/-). The inactivating portion of the current was unchanged in the targeted mice. 4. The voltage dependence and time course of inactivation were not changed by targeted disruption of Kv1.4. The mean best-fitting V (membrane potential at 50 % inactivation) values for myocytes from Kv1.4 +/+, Kv1.4+/- and Kv1. 4-/- mice were -53.5 +/- 3.7, -51.1 +/- 2.6 and -54.2 +/- 2.4 mV, respectively. The slope factors (k) were -10.1 +/- 1.4, -8.8 +/- 1.4 and -9.5 +/- 1.2 mV, respectively. The fast time constants for development of inactivation at -30 mV were 27.8 +/- 2.2, 26.2 +/- 5. 1 and 19.6 +/- 2.1 ms in Kv1.4+/+, Kv1.4+/- and Kv1.4-/- myocytes, respectively. At +30 mV, they were 35.5 +/- 2.6, 30.0 +/- 2.1 and 28. 7 +/- 1.6 ms, respectively. The time constants for the rapid phase of recovery from inactivation at -80 mV were 32.5 +/- 8.2, 23.3 +/- 1.8 and 39.0 +/- 3.7 ms, respectively. 5. Nearly the entire inactivating component as well as more than 60 % of the steady-state outward current was eliminated by 1 mM 4-aminopyridine in Kv1.4+/+, Kv1.4+/- and Kv1.4-/- myocytes. 6. Western blot analysis of heart membrane extracts showed no significant upregulation of the Kv4 subfamily of channels in the targeted mice. 7. Thus, Kv1.4 is not the molecular basis of Ito in adult murine ventricular myocytes.

Long QT and ventricular arrhythmias in transgenic mice expressing the N terminus and first transmembrane segment of a voltage-gated potassium channel.

Voltage-gated potassium channels control cardiac repolarization, and mutations of K+ channel genes recently have been shown to cause arrhythmias and sudden death in families with the congenital long QT syndrome. The precise mechanism by which the mutations lead to QT prolongation and arrhythmias is uncertain, however. We have shown previously that an N-terminal fragment including the first transmembrane segment of the rat delayed rectifier K+ channel Kv1.1 (Kv1.1N206Tag) coassembles with other K+ channels of the Kv1 subfamily in vitro, inhibits the currents encoded by Kv1.5 in a dominant-negative manner when coexpressed in Xenopus oocytes, and traps Kv1.5 polypeptide in the endoplasmic reticulum of GH3 cells. Here we report that transgenic mice overexpressing Kv1.1N206Tag in the heart have a prolonged QT interval and ventricular tachycardia. Cardiac myocytes from these mice have action potential prolongation caused by a significant reduction in the density of a rapidly activating, slowly inactivating, 4-aminopyridine sensitive outward K+ current. These changes correlate with a marked decrease in the level of Kv1.5 polypeptide. Thus, overexpression of a truncated K+ channel in the heart alters native K+ channel expression and has profound effects on cardiac excitability.

Two isoforms of the mouse ether-a-go-go-related gene coassemble to form channels with properties similar to the rapidly activating component of the cardiac delayed rectifier K+ current.

HERG, the human ether-a-go-go-related gene, encodes a K(+)-selective channel with properties similar to the rapidly activating component of the delayed rectifier K+ current (IKr). Mutations of HERG cause the autosomal-dominant long-QT syndrome (LQTS), presumably by disrupting the normal function of IKr. The current produced by HERG is not identical to IKr, however, and the mechanism by which HERG mutations cause LQTS remains uncertain. To better define the role of Erg in the heart, we cloned Merg1 from mouse genomic and cardiac cDNA libraries. Merg1 has 16 exons and maps to mouse chromosome 5 in an area syntenic to human chromosome 7q, the map locus of HERG. We isolated three cardiac isoforms of Merg1: Merg1a is homologous to HERG and is expressed in heart, brain, and testes, Merg1a' lacks the first 59 amino acids of Merg1a and is not expressed abundantly, and Merg1b has a markedly shorter divergent N-terminal cytoplasmic domain and is expressed specifically in the heart. The Merg1 isoforms, like HERG, produce inwardly rectifying E-4031-sensitive currents when heterologously expressed in Xenopus oocytes. Merg1a and HERG produce currents with slow deactivation kinetics, whereas Merg1a' and Merg1b currents deactivate more rapidly. Merg1b coassembles with Merg1a to form channels with deactivation kinetics that are more rapid than those of Merg1a or HERG and nearly identical to IKr. In addition, a homologue of Merg1b is present in human cardiac and smooth muscle. Thus, we have identified a novel N-terminal Erg isoform that is expressed specifically in the heart, has rapid deactivation kinetics, and coassembles with the longer isoform in Xenopus oocytes. This N-terminal Erg isoform may determine the properties of IKr and contribute to the pathogenesis of LQTS.