HCN cation channel mRNA expression was determined in the rabbit heart and neonatal and adult rat ventricle using RNase protection assays. In the rabbit SA node, the dominant HCN transcript is HCN4, representing >81% of the total HCN message. HCN1 is also expressed, representing >18% of the total HCN mRNA. Rabbit Purkinje fibers contained almost equal amounts of HCN1 and HCN4 transcripts with low levels of HCN2, whereas rabbit ventricle contained predominantly HCN2. The SA node contained 25 times the total HCN message of Purkinje fibers and 140 times the total HCN message of ventricle. No reports of hyperpolarization-activated current (If) exist in rabbit Purkinje fibers, and we could not record If in rabbit ventricular myocytes. To investigate the possible role of isoform switching in determining the voltage dependence of If, we determined the prevalence of HCN isoforms in neonatal and adult rat ventricle. We had previously determined the threshold for activation of If to be approximately -70 mV in neonatal rat ventricle and -113 mV in adult rat ventricle. In both neonatal and adult rat ventricle, only HCN2 and HCN4 transcripts are present. The ratio of HCN2 to HCN4 is approximately 5:1 in the neonate and 13:1 in the adult. Taken together, these results suggest that different cardiac regions express different isoforms of the HCN family. The HCN1 and HCN4 isoforms are most closely associated with a depolarized threshold for If activation, whereas the HCN2 isoform is associated with a more negative activation curve.
Two new potassium channel genes, erg2 and erg3, that are expressed in the nervous system of the rat were identified. These two genes form a small gene family with the previously described erg1 (HERG) gene. The erg2 and erg3 genes are expressed exclusively in the nervous system, in marked contrast to erg1, which is expressed in both neural and non-neural tissues. All three genes are expressed in peripheral sympathetic ganglia. The erg3 channel produces a current that has a large transient component at positive potentials, whereas the other two channels are slowly activating delayed rectifiers. Expression of the erg1 gene in the sympathetic nervous system has potential implications for the etiology of the LQT2 form of the human genetic disease long QT syndrome.
Expression of four members of the KChIP family of potassium channel β subunits was examined in canine heart. Only one member of the gene family, KChIP2, was expressed in heart. There was a steep gradient of KChIP2 mRNA expression across the canine ventricular free wall. KChIP2 mRNA was 25‐fold more abundant in the epicardium than in the endocardium, and this gradient paralleled the gradient in transient outward current (Ito) expression. In contrast, Kv4.3 potassium channel α subunit mRNA was expressed at equal levels across the ventricular wall. There was no difference in the pharmacological sensitivity of epicardial and endocardial Ito channels to flecainide, suggesting that the current is produced by the same channel in the two tissues. A similar gradient of KChIP2 expression was found across the ventricular wall of human heart, but not rat heart. It is concluded that transcriptional regulation of the KChIP2β subunit gene, rather than the Kv4.3α subunit gene, is the primary determinant regulating the transmural gradient of Ito expression in the ventricular free wall of canine and human heart.
The expression of 15 different potassium channel genes in rat atrial and ventricular muscle was quantitatively compared by use of an RNase protection assay. Of these genes, only five, Kv1.2, Kv1.4, Kv1.5, Kv2.1, and Kv4.2, were expressed at significant levels in cardiac muscle. In comparisons of atrial and ventricular RNA samples, transcripts from the Kv1.2 and Kv4.2 genes showed the largest differences in relative abundance. There was an approximately twofold decrease in total Kv4 subfamily mRNA expression in atrial muscle relative to ventricular muscle and a 70% increase in total Kv1 subfamily mRNA. Variation of potassium channel mRNA expression within the left ventricular wall was also examined. There was a large gradient of Kv4.2 expression across the ventricular wall, and Kv4.2 expression in epicardial muscle was more than eight times higher than in papillary muscle. Other potassium channel genes were expressed at relatively uniform levels across the ventricular wall. The results suggest that transcriptional regulation makes a significant contribution to the control of potassium channel expression in cardiac muscle and to the variation of the electrophysiological phenotype of myocytes from different regions of the myocardium.
These data provide further support for the hypothesis that Kv4.3 encodes all or part of the native cardiac Ito in humans and that part of the downregulation of this current in heart failure may be transcriptionally regulated.
Background-Cardiac memory refers to an altered T-wave morphology induced by ventricular pacing or arrhythmias that persist for variable intervals after resumption of sinus rhythm. Methods and Results-We induced long-term cardiac memory (LTM) in conscious dogs by pacing the ventricles at 120 bpm for 3 weeks. ECGs were recorded daily for 1 hour, during which time pacing was discontinued. At terminal study, the heart was removed and the electrophysiology of left ventricular epicardial myocytes was investigated. Control (C) and LTM ECG did not differ, except for T-wave amplitude, which decreased from 0.12Ϯ0.18 to Ϫ0.34Ϯ0.21 mV (ϮSEM, PϽ0.05), and T-wave vector, which shifted from Ϫ37Ϯ12°to Ϫ143Ϯ4°(PϽ0.05). Epicardial action potentials revealed loss of the notch and lengthening of duration at 20 days (both PϽ0.05). Calcium-insensitive transient outward current (I to ) was investigated by whole-cell patch clamp. No difference in capacitance was seen in C and LTM myocytes. I to activated on membrane depolarization to Ϫ25Ϯ1 mV in C and Ϫ7Ϯ1 mV (PϽ0.05) in LTM myocytes, indicating a positive voltage shift of activation. I to density was reduced in LTM myocytes, and a decreased mRNA level for Kv4.3 was observed. Recovery of I to from inactivation was significantly prolonged: it was 531Ϯ80 ms (nϭ10) in LTM and 27Ϯ6 ms (nϭ9) in C (PϽ0.05) at Ϫ65 mV. Conclusions-I to changes are associated with and can provide at least a partial explanation for action-potential and T-wave changes occurring with LTM. (Circulation. 1999;99:1898-1905.)
Abstract-The HCN family of ion channel subunits underlies the currents I f in heart and I h and I q in the nervous system.In the present study, we demonstrate that minK-related peptide 1 (MiRP1) is a  subunit for the HCN family. As such, it enhances protein and current expression as well as accelerating the kinetics of activation. Because MiRP1 also functions as a  subunit for the cardiac delayed rectifier I Kr , these results suggest that this peptide may have the unique role of regulating both the inward and outward channels that underlie cardiac pacemaker activity. The full text of this article is available at http://www.circresaha.org. (Circ Res. 2001;88:e84-e87.)Key Words: HCN family Ⅲ MiRP1 Ⅲ KCNE family Ⅲ  subunit T he HCN (hyperpolarization-activated cyclic nucleotidegated) family of ion channel subunits has been identified as the molecular correlate of the currents I f in heart and I h and I q in neurons. [1][2][3] However, several ion channels are heteromultimers of a large ␣ subunit (like the HCN family members) and smaller  subunits. The cardiac delayed rectifiers I Kr 4 and I Ks 5 are examples of this basic principle. Their ␣ subunits derive from the ERG and KCNQ families, respectively, but both also contain  subunits from the KCNE family of single transmembranespanning proteins called minK and minK-related peptides (MiRPs). In this study, we report that MiRP1 enhances the expression and speeds the kinetics of activation of the HCN family of channel subunits. From immunoprecipitation experiments, we show that it most probably forms a complex with HCN1. Using RNase protection assays (RPAs), we demonstrate that MiRP1 mRNA is prevalent in the primary cardiac pacemaking region, the sinoatrial (SA) node, and barely detectable in ventricle. Cardiac pacemaker activity is generated by a narrow balance of inward (I f ) and outward (I Kr ) currents. Our results demonstrate for the first time the potential importance of a single  subunit in simultaneously regulating both the expression and gating of both inward and outward cardiac pacemaker channels. Materials and Methods Heterologous Expression in Xenopus OocytescRNA encoding mouse HCN1 or HCN2, rat MiRP1 with or without an HA tag at the carboxy-terminal, and rat minK were transcribed using the mMessage mMachine kit (Ambion). Xenopus laevis oocytes were isolated, injected with 2 to 5 ng (50 to 100 nL) of cRNA, and maintained in Barth medium at 18°C for 1 to 3 days. For experiments using both HCN1 or HCN2 and MiRP1 or minK, the respective cRNAs were injected in a 1:0.04 to 1 ratio. Electrophysiological studies on oocytes used the 2-microelectrode voltage clamp. The extracellular recording solution (OR2) contained, in mmol/L, NaCl 80, KCl 2, MgCl 2 1, and Na-HEPES 5 (pH 7.6). Group data are presented as meanϮSEM. Tests of statistical significance for midpoint and slope of activation curves were performed using unpaired Student's t tests. PϽ0.05 is considered significant. RNase Protection AssaysThe procedures for the preparation of total RNA from rabbit he...
The expression of 15 different K+ channels in canine heart was examined, and a new K+ channel gene (Kv4.3), which encodes a rapidly inactivating K+ current, is described. The Kv4.3 channel was found to have biophysical and pharmacological properties similar to the native canine transient outward current (I(to)). The Kv4.3 gene is also expressed in human and rat heart. It is concluded that the Kv4.3 channel underlies the bulk of the I(to) in canine ventricular myocytes, and probably in human myocytes. Both the Kv4.3 and Kv4.2 channels are likely to contribute to the I(to) in rat heart, and differential expression of these two channels can account for observed differences in the kinetic properties of the I(to) in different regions of rat ventricle. There are significant differences in the pattern of K+ channel expression in canine heart, compared with rat heart, and these differences may be an adaptation to the different requirements for cardiac function in mammals of markedly different sizes. It is possible that the much longer ventricular action potential duration observed in canine heart compared with rat heart is due, in part, to the lower levels of Kv1.2, Kv2.1, and Kv4.2 gene expression in canine heart.
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