Modulation of skeletal muscle sodium channels by human myotonin protein kinase.

In myotonic muscular dystrophy, abnormal muscle Na currents underlie myotonic discharges. Since the myotonic muscular dystrophy gene encodes a product, human myotonin protein kinase, with structural similarity to protein kinases, we tested the idea that human myotonin protein kinase modulates skeletal muscle Na channels. Coexpression of human myotonin protein kinase with rat skeletal muscle Na channels in Xenopus oocytes reduced the amplitude of Na currents and accelerated current decay. The effect required the presence of a potential phosphorylation site in the inactivation mechanism of the channel. The mutation responsible for human disease, trinucleotide repeats in the 3' untranslated region, did not prevent the effect. The consequence of an abnormal amount of the kinase would be altered muscle cell excitability, consistent with the clinical finding of myotonia in myotonic dystrophy.

Contributions of charged residues in a cytoplasmic linking region to Na channel gating.

Na channels inactivate quickly after opening, and the very highly positively charged cytoplasmic linking region between homologous domains III and IV of the channel molecule acts as the inactivation gate. To test the hypothesis that the charged residues in the domain III to domain IV linker have a role in channel function, we measured currents through wild-type and two mutant skeletal muscle Na channels expressed in Xenopus oocytes, each lacking two or three charged residues in the inactivation gate. Microscopic current measures showed that removing charges hastened activation and inactivation. Macroscopic current measures showed that removing charges altered the voltage dependence of inactivation, suggesting less coupling of the inactivation and activation processes. Reduced intracellular ionic strength shifted the midpoint of equilibrium activation gating to a greater extent, and shifted the midpoint of equilibrium inactivation gating to a lesser extent in the mutant channels. The results allow the possibility that an electrostatic mechanism contributes to the role of charged residues in Na channel inactivation gating.

Modulation of Xenopus oocyte-expressed phospholemman-induced ion currents by co-expression of protein kinases.

Phospholemman (PLM), the major sarcolemmal substrate for phosphorylation by cAMP-dependent kinase (PKA) protein kinase C (PKC) and NIMA kinase in muscle, induces hyperpolarization-activated anion currents in Xenopus oocytes, most probably by enhancing endogenous oocyte currents. PLM peptides from the cytoplasmic tail are phosphorylated by PKA at S68, by NIMA kinase at S63, and by PKC at both S63 and S68. We have confirmed the phosphorylation sites in the intact protein, and we have investigated the role of phosphorylation in the regulatory activity of PLM using oocyte expression experiments. We found: (1) the cytoplasmic domain is not essential for inducing currents in oocytes; (2) co-expression of PKA increased the amplitude of oocyte currents and the amount of PLM in the oocyte membrane largely, but not exclusively, through phosphorylation of S68; (3) co-expression of PKA had no effect on a PLM mutant in which all putative phosphorylation sites had been inactivated by serine to alanine mutation (SSST 62, 63, 68, 69 AAAA); (4) co-expression of PKC had no effect in this system; (5) co-expression of NIMA kinase increased current amplitude and membrane protein level, but did not require PLM phosphorylation. These findings point to a role for phosphorylation in the function of PLM.

Coexistence of type I atrial flutter and intra-atrial re-entrant tachycardia in patients with surgically corrected congenital heart disease.

OBJECTIVES: This study assessed the coexistence of intra-atrial re-entrant tachycardia (IART) and isthmus-dependent atrial flutter (IDAF) in patients presenting with supraventricular tachyarrhythmias after surgical correction of congenital heart disease (CHD). BACKGROUND: In patients with CHD, atrial tachyarrhythmias may result from IART or IDAF. The frequency with which IART and IDAF coexist is not well defined. METHODS: Both IDAF and IART were diagnosed in 16 consecutive patients using standard criteria and entrainment mapping. Seven patients had classic atrial flutter morphology on surface electrocardiogram (ECG), whereas nine had atypical morphology. RESULTS: A total of 24 circuits were identified. Three patients had IDAF only, five had IART only, seven had both, and one had a low right atrial wall tachycardia that could not be entrained. Twenty-two different reentry circuits were ablated. Successful ablation was accomplished in 13 of 14 (93%) IART and 9 of 10 (90%) IDAF circuits. There was one IART recurrence. The slow conduction zone involved the region of the right atriotomy scar in 12 of 14 (86%) IART circuits. No procedural complications and no further recurrences were seen after a mean follow-up of 24 months. CONCLUSIONS: Both IDAF and IART are the most common mechanisms of atrial re-entrant tachyarrhythmias in patients with surgically corrected CHD, and they frequently coexist. The surface ECG is a poor tool for identifying patients with coexistent arrhythmias. The majority of IART circuits involve the lateral right atrium and may be successfully ablated by creating a lesion extending to the inferior vena cava.

Inotropic and vasodilator effects of amrinone on isolated human tissue.

The effects of amrinone on human umbilical artery and human myocardium were studied. Amrinone produced dose related increases in tension, dT/dtmax and dT/dtmin in myocardium from patients who were NYHA grade I (n = 1) and II (n = 4). The responses to amrinone of these tissues were similar to the response seen in normal guinea-pig myocardium (n = 34). The drug had no inotropic effect on tissue from NYHA grade III patients (n = 5). The inotropic response of the tissues to amrinone was inversely related to length of history and severity of heart failure in the patients from whom the tissues were obtained. Amrinone caused dose related relaxation of the human umbilical artery. The vasodilator properties, but not the positive inotropic effects of amrinone were detectable at concentrations of the drug obtained during oral therapy (0.4 to 4.0 micrograms X ml-1). These findings support the view that in patients with congestive cardiac failure amrinone acts by vasodilatation with no clinically important positive inotropic effect.

Skeletal muscle Na currents in mice heterozygous for Six5 deficiency.

Myotonic dystrophy results from a trinucleotide repeat expansion between the myotonic dystrophy protein kinase gene (Dmpk), which encodes a serine-threonine protein kinase, and the Six5 gene, which encodes a homeodomain protein. The disease is characterized by late bursts of skeletal muscle Na channel openings, and this is recapitulated in Dmpk -/- and Dmpk +/- murine skeletal muscle. To test whether deficiency of the nearby Six5 gene also affected Na channel gating in murine skeletal muscle, we measured Na currents from cell-attached patches in Six5 +/- mice and age-matched wild-type and Dmpk +/- mice. Late bursts of Na channel activity were defined as an opening probability >10% measured from 10 to 110 ms after depolarization. There was no significant difference in the occurrence of late Na channel bursts in wild-type and Six5 +/- muscle, whereas in Dmpk +/- muscle there was greater than fivefold increase in late bursts (P < 0.001). Compared with wild-type mice, Na current amplitude was unchanged in Six5 +/- muscle, whereas in Dmpk +/- muscle it was 36% reduced (P < 0.05). Thus, since Six5 +/- mice do not exhibit the Na channel gating abnormality of Dmpk deficiency, we conclude that Six5 deficiency does not contribute to the Na channel gating abnormality seen in dystrophia myotonica patients.

Gene structure and expression of phospholemman in mouse.

Phospholemman (PLM) is a small transmembrane cardiac protein that is the major sarcolemmal substrate for phosphorylation in response to adrenergic stimulation. PLM likely plays a role in muscle contractility and cell volume regulation through its function as a channel or a channel regulator. We are the first to describe the structure of the PLM gene and to demonstrate PLM cDNA splice variants. We cloned the murine PLM cDNA and used it as a probe to isolate the gene from a 129/SvJ genomic library. The gene contains seven introns and eight exons. The coding sequence is interrupted by five introns; the 5' untranslated region by two. Using rapid amplification of 5' cDNA ends we identified transcription start sites and four splice variants of the 5' untranslated domain. There was no TATA box or CAAT box in the putative promoter regions. The gene has several stretches of dinucleotide repeats. The 3' untranslated domains of mouse PLM cDNA clones show sequence differences not accounted for by alternative splicing. Mouse PLM shares 93, 83 and 80% amino acid identity with rat, dog, and human PLMs, respectively. Tissue expression of murine PLM parallels that in other species, being highest in heart, skeletal muscle, and liver.

Predictors of acute and long-term success after radiofrequency catheter ablation of type 1 atrial flutter.

A history of atrial fibrillation and right atrial size are both determinants of procedural and long-term outcome after RF catheter ablation of type 1 atrial flutter. The results of this study suggest that patients with no history of atrial fibrillation and a normal right atrial size have the best short- and long-term results from this procedure.

Transient ST elevation after transthoracic cardioversion in patients with hemodynamically unstable ventricular tachyarrhythmia.

The significance of ST-segment elevation after resuscitation from arrhythmias not associated with ischemia was examined in a group of patients who received transthoracic shocks for hemodynamically unstable ventricular tachyarrhythmias during electrophysiologic studies. ST-segment elevation was seen in 15.4%, was transient, and was not associated with clinical evidence of myocardial infarction.

Sodium channel isoform-specific effects of halothane: protein kinase C co-expression and slow inactivation gating.

The modulatory effect of protein kinase C (PKC) on the response of Xenopus oocyte-expressed Na channel alpha-subunits to halothane (2-bromo-2-chloro-1,1,1-trifluroethane) was studied. Na currents through rat skeletal muscle, rat brain and human cardiac muscle Na channels were assessed using cell-attached patch clamp recordings. PKC activity was increased by co-expression of a constitutively active PKC alpha-isozyme. Decay of macroscopic Na currents could be separated into fast and slow exponential phases. PKC co-expression alone slowed Na current decay in neuronal channels, through enhancement of the amplitude of the slower phase of decay. Halothane (1.0 mM) was without effect on any of the three isoforms expressed alone but, after co-expression of PKC, there was enhancement of Na current decay with reduction in charge movement through skeletal muscle and neuronal channels. Cardiac channels were relatively insensitive to halothane. Enhanced Na current decay resulted from suppression of the slow phase, without effect on the faster phase or on either decay tau. Suppression of Na current through skeletal muscle channels was concentration-dependent over the therapeutic range and was described by third order reaction kinetics, with an IC(50) of 0.55 mM. We conclude that the halothane suppresses skeletal muscle and brain Na channel activity in this preparation through a reduction in the slow mode of inactivation gating, but only after PKC co-expression. Cardiac Na channels were relatively insensitive to halothane. The mechanism is likely to involve phosphorylation of the channel inactivation gate, although phosphorylation of other sites in the channel may account for the isoform specific differences.

Protein kinase C co-expression and the effects of halothane on rat skeletal muscle sodium channels.

1. Voltage-gated Na channels, which are potential targets for general anaesthetics, are substrates for PKC, which phosphorylates a conserved site in the channel inactivation gate. We investigated the idea that PKC modulates the effect of volatile anaesthetics on Na channels via phosphorylation of this inactivation gate site. 2. Na currents through rat skeletal muscle Na channel alpha-subunits expressed in Xenopus oocytes were measured by two-microelectrode voltage clamp in the presence of the volatile anaesthetic agent halothane (2-bromo-2-chloro-1,1,1-trifluroethane). PKC activity was modulated by co-expression of a constitutively active PKC alpha-isozyme. 3. Halothane (0.4 mM) had no effect on Na currents. With co-expression of PKC, however, halothane dose-dependently enhanced the rate of Na current decay and caused a small, but statistically significant reduction in Na current amplitude. 4. The enhancement of Na current decay was absent in a Na channel mutant in which the inactivation gate phosphorylation site was disabled. Effects of halothane on amplitude were independent of this mutation. 5. Co-expression of a PKC alpha-isozyme permits an effect of halothane to hasten current decay and reduce current amplitude, at least in part through interaction with the inactivation gate phosphorylation site. We speculate that the interaction between halothane and Na channels is direct, and facilitated by PKC activity and by phosphorylation of a site in the channel inactivation gate.

Radiofrequency ablation of a Mahaim fiber following localization of Mahaim pathway potentials.

We report radiofrequency ablation of a Mahaim fiber in a patient with wide complex supraventricular tachycardia. Pathway potentials from the lateral aspect of the right AV groove were recorded, which were distinct from the His potential. During atrial pacing, decremental properties of the fiber were demonstrated, which resulted in prolongation of the interval between the atrial electrogram and the Mahaim pathway potential. The pathway potentials, preexcitation, and tachycardia disappeared after a single application of radiofrequency energy, after which the patient has remained free of palpitations. Mapping of a Mahaim fiber by identifying pathway potentials thus allowed accurate localization and successful ablation with minimal energy. We therefore suggest that, where possible, recording of such Mahaim potentials may be the optimal technique for Mahaim fiber localization.

The effects of cyanide on intracellular ionic exchange in ferret and rat ventricular myocardium.

The effects of cyanide on Ca2+ exchange in isolated ventricular myocytes and on the intracellular concentrations of Ca2+, Na+ and H+ have been investigated to assess the contribution that mitochondria might play in cellular Ca2+ metabolism. Ionic levels were measured with ion-selective electrodes. KCN (2.5 mM) inhibited a component of Ca2+ exchange in myocytes that could be attributed to mitochondrial exchange, but was without effect on non-mitochondrial Ca2+ exchange. NaCN (2.5 mM) caused a transient reduction of [H+]i, [Na+]i and [Ca2+]i when applied to the superfusate bathing ventricular trabeculae or papillary muscles. The transient changes of [Na+]i were accentuated when the preparation was exposed to a solution which would be expected to increase the cellular calcium content. The reduction of [Na+]i which accompanies a reduction of the extracellular sodium concentration, [Na]o, was attenuated in the presence of NaCN, but the intracellular acidosis resulting from a reduction of [Na]o was unaffected by NaCN. A small, but significant, rise of [Ca2+]i accompanied a reduction of [Na]o but only when NaCN was present in the superfusate. It is concluded that cyanide ions have a reasonably specific action on cardiac cellular ionic metabolism. Its primary action is to prevent mitochondrial Ca2+ sequestration. It is postulated that a Na+/H+ exchange, possibly at the sarcolemma, could account for some of the changes to sarcoplasmic ionic levels observed. In a solution of low [Na]o, it is concluded that mitochondria could sequester at least 30% of the calcium accumulated by the cell even though the sarcoplasmic [Ca2+] does not exceed 0.3 microM.

Skeletal muscle sodium channel gating in mice deficient in myotonic dystrophy protein kinase.

Myotonic dystrophy, a progressive autosomal dominant disorder, is associated with an expansion of a CTG repeat tract located in the 3'-untranslated region of a serine/threonine protein kinase, DMPK. DMPK modulates skeletal muscle Na channels in vitro, and thus we hypothesized that mice deficient in DMPK would have altered muscle Na channel gating. We measured macroscopic and single channel Na currents from cell-attached patches of skeletal myocytes from mice heterozygous (DMPK(+/-)) and homozygous (DMPK(-/-)) for DMPK loss. In DMPK(-/-) myocytes, Na current amplitude was reduced because of reduced channel number. Single channel recordings revealed Na channel reopenings, similar to the gating abnormality of human myotonic muscular dystrophy (DM), which resulted in a plateau of Na current. The gating abnormality deteriorated with increasing age. In DMPK(+/-) muscle there was reduced Na current amplitude and increased Na channel reopenings identical to those in DMPK(-/-) muscle. Thus, these mouse models of complete and partial DMPK deficiency reproduce the Na channel abnormality of the human disease, providing direct evidence that DMPK deficiency underlies the Na channel abnormality in DM.

Mechanical, but not infective, pacemaker erosion may be successfully managed by re-implantation of pacemakers.

OBJECTIVE: When a pacemaker box causes erosion it is usually removed and a new pacemaker implanted at a contralateral site. In this study when there was no evidence of systemic infection an attempt was made to clean and reimplant the same pacemaker in the same site. RESULTS: Over 10 years 62 patients had pacemaker reimplantation. In 18 patients the procedure was repeated a second time. Reimplantation was successful after at least six months follow up in 38 patients (61%): in nine two attempts had been made. Mean hospital stay for all patients was 21.3 days; for patients in whom the procedure was successful it was 12.5 days and for those in whom it was unsuccessful it was 35.4 days. 31 (82%) of the 38 patients in whom reimplantation was successful had no bacterial growth from wound swabs from 17/24 (71%) patients in whom reimplantation was unsuccessful (p < 0.001). Bacteria were grown from swabs from 7/8 patients with a protruding wire compared with 9/23 patients with a protruding pacemaker (p = 0.05). Thin patients and those who were older were more likely to have successful reimplantation: neither association reached statistical significance. A clinical impression of infection was not helpful. If re-implantation had been attempted only in the patients with negative wound swabs or intact skin the success rate would have been 74% at a cost of 5010 pounds per patient compared with a cost of 6509 pounds per patient for explantation and a reimplantation of a new contralateral pacemaker. CONCLUSION: These data support the hypothesis that pacemaker erosion is caused by primary infection or by a non-infective process (probably mechanical pressure). Pacemaker erosion that is not caused by infection can be successfully managed by ipsilateral reimplantation and this approach saves money.

Correlation of temperature and pathophysiological effect during radiofrequency catheter ablation of the AV junction.

BACKGROUND: Accelerated junctional rhythms have been observed before the development of AV nodal block during radiofrequency (RF) catheter ablation of the AV junction. However, the time course and temperatures required to induce an accelerated junctional rhythm and AV nodal block during this procedure have not yet been characterized. METHODS AND RESULTS: Nineteen patients underwent RF ablation of the AV junction with a thermistor ablation catheter. RF energy was initially delivered at 10 W for 9 seconds and then increased by 5-W increments for 9 seconds at each power level up to a maximum power of 50 W. If a junctional rhythm was observed during the power titration, a 30- to 60-second RF application was then delivered at the same power level. The power was then further increased to a maximum of 50 W if AV nodal block was not observed after 20 seconds of RF delivery. The procedure was successful in all 19 patients. A median of one RF application (range, one to eight applications) was required to produce permanent AV nodal block. An accelerated junctional rhythm was observed during 89% of successful attempts versus 70% of unsuccessful deliveries (P = NS). The median time to onset of the junctional rhythm was significantly shorter during successful compared with unsuccessful applications (1.8 versus 7.7 seconds, respectively; P < .001). Similarly, the mean time to appearance of AV nodal block was significantly shorter during successful compared with unsuccessful attempts (19.6 +/- 9.4 versus 36.8 +/- 19.0 seconds, respectively; P < .01). The catheter tip temperatures associated with the development of an accelerated junctional rhythm were significantly lower than those associated with the appearance of AV nodal block (51 +/- 4 degrees C versus 58 +/- 6 degrees C, respectively; P < .001). Mean temperatures in the range of 60 +/- 7 degrees C were required to produce permanent AV nodal block. CONCLUSIONS: The development of an accelerated junctional rhythm within 5 seconds and the appearance of AV nodal block within 30 seconds of RF onset were both highly characteristic of successful target sites during RF ablation of the AV junction. The accelerated junctional rhythm and AV nodal block were both highly temperature dependent. The temperatures associated with the onset of AV nodal block were significantly higher than the temperatures resulting in an accelerated junctional rhythm.