Changes in myofilament proteins, but not Ca²âº regulation, are associated with a high-fat diet-induced improvement in contractile function in heart failure.

Pathological conditions such as diabetes, insulin resistance, and obesity are characterized by elevated plasma and myocardial lipid levels and have been reported to exacerbate the progression of heart failure (HF). Alterations in cardiomyocyte Ca(2+) regulatory properties and myofilament proteins have also been implicated in contractile dysfunction in HF. However, our prior studies reported that high saturated fat (SAT) feeding improves in vivo myocardial contractile function, thereby exerting a cardioprotective effect in HF. Therefore, we hypothesized that SAT feeding improves contractile function by altering Ca(2+) regulatory properties and myofilament protein expression in HF. Male Wistar rats underwent coronary artery ligation (HF) or sham surgery (SH) and were fed normal chow (SHNC and HFNC groups) or a SAT diet (SHSAT and HFSAT groups) for 8 wk. Contractile properties were measured in vivo [echocardiography and left ventricular (LV) cannulation] and in isolated LV cardiomyocytes. In vivo measures of contractility (peak LV +dP/dt and -dP/dt) were depressed in the HFNC versus SHNC group but improved in the HFSAT group. Isolated cardiomyocytes from both HF groups were hypertrophied and had decreased percent cell shortening and a prolonged time to half-decay of the Ca(2+) transient versus the SH group; however, SAT feeding reduced in vivo myocyte hypertrophy in the HFSAT group only. The peak velocity of cell shortening was reduced in the HFNC group but not the HFSAT group and was positively correlated with in vivo contractile function (peak LV +dP/dt). The HFNC group demonstrated a myosin heavy chain (MHC) isoform switch from fast MHC-α to slow MHC-ß, which was prevented in the HFSAT group. Alterations in Ca(2+) transients, L-type Ca(2+) currents, and protein expression of sarco(endo)plasmic reticulum Ca(2+)-ATPase and phosphorylated phospholamban could not account for the changes in the in vivo contractile properties. In conclusion, the cardioprotective effects associated with SAT feeding in HF may occur at the level of the isolated cardiomyocyte, specifically involving changes in myofilament function but not sarcoplasmic reticulum Ca(2+) regulatory properties.

Ascorbate attenuates atrial pacing-induced peroxynitrite formation and electrical remodeling and decreases the incidence of postoperative atrial fibrillation.

Atrial fibrillation (AF), the most common chronic arrhythmia, increases the risk of stroke and is an independent predictor of mortality. Available pharmacological treatments have limited efficacy. Once initiated, AF tends to self-perpetuate, owing in part to electrophysiological remodeling in the atria; however, the fundamental mechanisms underlying this process are still unclear. We have recently demonstrated that chronic human AF is associated with increased atrial oxidative stress and peroxynitrite formation; we have now tested the hypothesis that these events participate in both pacing-induced atrial electrophysiological remodeling and in the occurrence of AF following cardiac surgery. In chronically instrumented dogs, we found that rapid (400 min(-1)) atrial pacing was associated with attenuation of the atrial effective refractory period (ERP). Treatment with ascorbate, an antioxidant and peroxynitrite decomposition catalyst, did not directly modify the ERP, but attenuated the pacing-induced atrial ERP shortening following 24 to 48 hours of pacing. Biochemical studies revealed that pacing was associated with decreased tissue ascorbate levels and increased protein nitration (a biomarker of peroxynitrite formation). Oral ascorbate supplementation attenuated both of these changes. To evaluate the clinical significance of these observations, supplemental ascorbate was given to 43 patients before, and for 5 days following, cardiac bypass graft surgery. Patients receiving ascorbate had a 16.3% incidence of postoperative AF, compared with 34.9% in control subjects. In combination, these studies suggest that oxidative stress underlies early atrial electrophysiological remodeling and offer novel insight into the etiology and potential treatment of an enigmatic and difficult to control arrhythmia. The full text of this article is available at http://www.circresaha.org.

Impaired myofibrillar energetics and oxidative injury during human atrial fibrillation.

BACKGROUND: Atrial fibrillation (AF) is associated with severe contractile dysfunction and structural and electrophysiological remodeling. Mechanisms responsible for impaired contractility are undefined, and current therapies do not address this dysfunction. We have found that myofibrillar creatine kinase (MM-CK), an important controller of myocyte contractility, is highly sensitive to oxidative injury, and we hypothesized that increased oxidative stress and energetic impairment during AF could contribute to contractile dysfunction. Methods and Results-- Right atrial appendages were obtained from AF patients undergoing the Maze procedure and from control patients who were in normal sinus rhythm and undergoing cardiac surgery. MM-CK activity was reduced in AF patients compared with controls (25.4+/-3.4 versus 18.2+/-3.8 micromol/mg of myofibrillar protein per minute; control versus AF; P<0.05). No reduction in total CK activity or myosin ATPase activity was detected. This selective reduction in MM-CK activity was associated with increased relative expression of the beta-myosin isoform (25+/-6 versus 63+/-5%beta, CTRL versus AF; P<0.05). Western blotting of AF myofibrillar isolates demonstrated no changes in protein composition but showed increased prevalence of protein oxidation as detected by Western blotting for 3-nitrotyrosine (peroxynitrite biomarker) and protein carbonyls (hydroxyl radical biomarker; P<0.05). Patterns of these oxidative markers were distinct, which suggests discrete chemical events and differential protein vulnerabilities in vivo. MM-CK inhibition was statistically correlated to extent of nitration (P<0.01) but not to carbonyl presence. CONCLUSIONS: The present results provide novel evidence of oxidative damage in human AF that altered myofibrillar energetics may contribute to atrial contractile dysfunction and that protein nitration may be an important participant in this condition.

C-reactive protein elevation in patients with atrial arrhythmias: inflammatory mechanisms and persistence of atrial fibrillation.

BACKGROUND: Atrial fibrillation (AF) may persist due to structural changes in the atria that are promoted by inflammation. C-reactive protein (CRP), a marker of systemic inflammation, predicts cardiovascular events and stroke, a common sequela of AF. We hypothesized that CRP is elevated in patients with atrial arrhythmias. METHODS AND RESULTS: Using a case-control study design, CRP in 131 patients with atrial arrhythmias was compared with CRP in 71 control patients. Among arrhythmia patients, 6 had frequent atrial ectopy or tachycardia, 86 had paroxysmal AF, 39 had persistent AF lasting >30 days, and 70 had lone arrhythmias. CRP was higher in arrhythmia than in control patients (median, 0.21 versus 0.096 mg/dL; P<0.001). Arrhythmia patients in AF within 24 hours before sampling had higher CRP than those in sinus rhythm (0.30 versus 0.15 mg/dL; P<0.001). CRP in controls was not different than in patients with atrial ectopy or tachycardia. Lone arrhythmia patients had a CRP of 0.21 mg/dL, which was not significantly lower than arrhythmia patients with structural heart disease (CRP, 0.23 mg/dL) but higher than controls (P=0.002). Persistent AF patients had a higher CRP (0.34 mg/dL) than paroxysmal AF patients (0.18 mg/dL; P=0.008); both groups had higher CRP levels than controls (P

Mechanosensitive gating of atrial ATP-sensitive potassium channels.

Cell-attached and inside-out excised-patch recording techniques were used to search for mechanosensitive ion channels in neonatal and adult rat atrial myocytes. A channel activated by negative pressure applied to the patch, with a single-channel conductance of 52 pS in symmetric potassium solutions, was frequently observed. This channel has been identified as the atrial ATP-sensitive potassium (KATP) channel on the basis of its potassium selectivity, as well as its inhibition by ATP or tolbutamide in the inside-out excised patch. Mechanosensitive modulation of the KATP channel has not previously been reported. In the presence of 1 mM ATP, 10-50 microM pinacidil (a specific KATP channel agonist) does not significantly increase basal KATP channel activity; however, these concentrations of pinacidil potentiated the mechanosensitive modulation of the KATP channel. A hypotonic swelling protocol (a mechanical stimulus) was used in an effort to determine whether mechanosensitive modulation of this channel can generate significant whole-cell currents. Under perforated-patch whole-cell recording conditions, superfusion of atrial myocytes with a 240 mosm/kg solution (control solution, 290 mosm/kg) stimulated whole-cell currents with a magnitude similar to those activated by 10 microM pinacidil. These results demonstrate that the gating of the atrial KATP channel is mechanosensitive and suggest that mechanosensitive modulation may be an additional and significant mechanism, modulating channel activity under both physiological and pathological conditions.

Phenylephrine suppresses outward K+ currents in rat atrial myocytes.

The modulation of whole cell K+ currents by the alpha 1-adrenergic agonist, phenylephrine, was studied in isolated rat atrial myocytes by use of perforated-patch whole cell recording techniques. The out ward K+ current in these myocytes consists of two inactivating components (iK,f and iK,s), which differ in the kinetics of inactivation and recovery from inactivation, and a noninactivating component, (iK,ss). Superfusion of these myocytes with 10 microM phenylephrine caused a rapid suppression of iK,ss, with little effect on the other current components. This effect of phenylephrine could be mimicked by exogenous application of 1,2-dioctanoyl-sn-glycerol (20 microM), a membrane-permeant diacylglycerol analogue; however, it was clearly distinct from the effect of 5 nM alpha-dendrotoxin, which selectively suppressed the slowly inactivating current component, iK,s, while having no effect on iK,ss. At a dose of 50 microM, phenylephrine also suppressed iK,s. There was no significant effect of phenylephrine (10 or 50 microM) or alpha-dendrotoxin (5 nM) on the rapidly inactivating current component, iK,f. The kinetic and pharmacological differences between these current components suggest that they represent the activity of distinct K+ channels.

Molecular basis of electrical remodeling in atrial fibrillation.

Atrial fibrillation (AF) is the most common cardiac arrhythmia, and is often associated with other cardiovascular disorders and diseases. AF can lead to thromboembolism, reduced left ventricular function and stroke, and, importantly, it is independently associated with increased mortality. AF is a progressive disease; numerous lines of evidence suggest that disease progression results from cumulative electrophysiological and structural remodeling of the atria. There is considerable interest in delineating the molecular mechanisms involved in the remodeling that occurs in the atria of patients with AF. Cellular electrophysiological studies have revealed marked reductions in the densities of the L-type voltage-gated Ca2+ current, I(Ca,L), the transient outward K+ current, I(TO), and the ultrarapid delayed rectifier K+ current, I(Kur), in atrial myocytes from patients in chronic AF. Similar (but not identical) changes in currents are evident in myocytes isolated from a canine model of AF and, in this case, the changes in currents are correlated with reduced expression of the underlying channel forming subunits. In both human and canine AF, the reduction in I(Ca,L) appears to be sufficient to explain the observed decreases in action potential duration and effective refractory period that are characteristic features of the remodeled atria. In addition, expression of the sarcoplasmic reticulum Ca2+ ATPase is reduced, suggesting that calcium cycling is affected in AF. These recent studies suggest that calcium overload and perturbations in calcium handling play prominent roles in AF-induced atrial remodeling. Although considerable progress has been made, further studies focused on defining the detailed structural, cellular and molecular changes that accompany the different stages of AF in humans, as well as in animal models of AF, are clearly warranted. It is anticipated that molecular insights gleaned from these studies will facilitate the development of improved therapeutic approaches to treat AF and to prevent the progression of the arrhythmia.

Arachidonic acid and endothelin potentiate Ca2+ transients in rat cardiac myocytes via inhibition of distinct K+ channels.

The release of arachidonic acid by phospholipases in response to cell surface receptor activation may be an important step in the initiation of inotropic events in cardiac muscle. Endothelin has been shown to activate phospholipase A2 and release arachidonic acid in isolated rat hearts. Endothelin also has a positive inotropic effect in cardiac muscle, suggesting that endothelin increases Ca2+ influx or the amount of Ca2+ released from the sarcoplasmic reticulum. We used suspensions of adult rat ventricular myocytes loaded with fura-2/AM to compare the effects of arachidonic acid and endothelin on Ca2+ transients evoked by extracellular ATP. We showed recently (Damron, D.S., and Bond, M. (1993) Circ. Res. 72, 376-386) that pretreatment of cardiac myocytes with arachidonic acid significantly potentiated the amplitude of the ATP-triggered Ca2+ transient. We now report that endothelin also enhances the ATP-triggered Ca2+ transient and that the effect of the combination of maximal doses of endothelin and arachidonic acid is additive. Neither endothelin nor arachidonic acid was found to affect the size of the sarcoplasmic reticulum Ca2+ store. The potentiating effects of both arachidonic acid and endothelin were sensitive to inhibitors of protein kinase C. Endothelin was also found to stimulate phospholipase C but not phospholipase A2. Application of arachidonic acid to individual cardiac muscle cells resulted in inhibition of the transient outward K+ current, whereas application of endothelin inhibited the delayed rectifier current. These effects of arachidonic acid and endothelin were additive, and both effects could be blocked by the protein kinase C inhibitor, staurosporine. Similarly, staurosporine inhibited endothelin-induced increases in isometric contractions in ventricular papillary muscle. We conclude that arachidonic acid and endothelin may be involved in the modulation of inotropic activity in cardiac muscle by means of protein kinase C-dependent inhibition of two distinct K+ channels. This would result in a prolongation of action potential duration and thus an increase in Ca2+ influx across the sarcolemma.

Effect of intravenous anesthetics on inward rectifier potassium current in rat and human ventricular myocytes.

BACKGROUND: Inhibition of the inward rectifying potassium current (I(K1)) may cause cardiac dysrhythmias by decreasing resting membrane potential or prolonging action potential. METHODS: The effects of thiopental, ketamine, and propofol on I(K1) conductance were evaluated in rat ventricular myocytes. The effect of thiopental on I(K1) conductance was also evaluated in human ventricular myocytes. Currents were recorded using the nystatin-perforated whole-cell patch-clamp technique (holding potential, -50 mV; test potentials, -140 to -40 mV). Pipette solution contained 130 mM KCl, 5 mM MgCl2, 5 mM HEPES, and 5 mM EGTA,pH 7.2. Bath solution (32 degrees C) contained 134 mM NaCI, 4 mM KCl, 1 mM MgCl2, 1 mM CaCl2, 0.3 mM CdCl2, 5 mM HEPES, and 5 mM d-glucose,pH 7.4. Drug concentrations examined encompassed the range of clinically relevant unbound plasma concentrations. Currents were normalized for cell capacitance. Conductance was calculated as current density/delta mV from -140 to -100 mV. Analysis of variance was used to test for changes in conductance as a function of drug concentration. RESULTS: Thiopental reduced I(K1) conductance in a concentration-dependent manner (P < 0.0001). Thiopental-induced changes in I(K1) conductance in rat ventricular myocytes were fit to an inhibitory E(max) model, with a median inhibitory concentration of 10.5 microM. The effect of thiopental on I(K1) conductance in human ventricular cells was comparable to that observed in rat ventricular myocytes. Neither ketamine nor propofol altered I(K1) conductance. CONCLUSIONS: Thiopental reduces I(K1) conductance in a concentration-dependent manner at clinically relevant concentrations in both rat and human ventricular myocytes.

Virtual electrode-induced phase singularity: a basic mechanism of defibrillation failure.

Delivery of a strong electric shock to the heart remains the only effective therapy against ventricular fibrillation. Despite significant improvements in implantable cardioverter defibrillator (ICD) therapy, the fundamental mechanisms of defibrillation remain poorly understood. We have recently demonstrated that a monophasic defibrillation shock produces a highly nonuniform epicardial polarization pattern, referred to as a virtual electrode pattern (VEP). The VEP consists of large adjacent areas of strong positive and negative polarization. We sought to determine whether the VEP may be responsible for defibrillation failure by creating dispersion of postshock repolarization and reentry. Truncated exponential biphasic and monophasic shocks were delivered from a bipolar ICD lead in Langendorff-perfused rabbit hearts. Epicardial electrical activity was mapped during and after defibrillation shocks and shocks applied at the plateau phase of a normal action potential produced by ventricular pacing. A high-resolution fluorescence mapping system with 256 recording sites and a voltage-sensitive dye were used. Biphasic shocks with a weak second phase (<20% leading-edge voltage of the second phase with respect to the leading-edge voltage of the first phase) produced VEPs similar to monophasic shocks. Biphasic shocks with a strong second phase (>70%) produced VEPs of reversed polarity. Both of these waveforms resulted in extra beats and arrhythmias. However, biphasic waveforms with intermediate second-phase voltages (20% to 70% of first-phase voltage) produced no VEP, because of an asymmetric reversal of the first-phase polarization. Therefore, there was no substrate for postshock dispersion of repolarization. Shocks producing strong VEPs resulted in postshock reentrant arrhythmias via a mechanism of phase singularity. Points of phase singularity were created by the shock in the intersection of areas of positive, negative, and no polarization, which were set by the shock to excited, excitable, and refractory states, respectively. Shock-induced VEPs may reinduce arrhythmias via a phase-singularity mechanism. Strong shocks may overcome the preshock electrical activity and create phase singularities, regardless of the preshock phase distribution. Optimal defibrillation waveforms did not produce VEPs because of an asymmetric effect of phase reversal on membrane polarization.

Transmembrane voltage changes produced by real and virtual electrodes during monophasic defibrillation shock delivered by an implantable electrode.

INTRODUCTION: Epicardial point stimulation produces nonuniform changes in the transmembrane voltage of surrounding cells with simultaneous occurrence of areas of transient positive and negative polarization. This is the phenomenon of virtual electrode. We sought to characterize the responses of epicardial ventricular tissue to the application of monophasic electric shocks from an internal transvenous implantable cardioverter defibrillator (ICD) lead. METHODS AND RESULTS: Langendorff-perfused rabbit hearts (n = 12) were stained with di-4-ANEPPS. A 9-mm-long distal electrode was placed in the right ventricle. A 6-cm proximal electrode was positioned horizontally 3 cm posteriorly and 1 cm superiorly with respect to the heart. Monophasic anodal and cathodal pulses were produced by discharging a 150-microF capacitor. Shocks were applied either during the plateau phase of an action potential (AP) or during ventricular fibrillation. Leading-edge voltage of the pulse was 50 to 150 V, and the pulse duration was 10 msec. Transmembrane voltage was optically recorded during application of the shock, simultaneously from 256 sites on a 11 x 11 mm area of the anterior right ventricular epicardium directly transmural to the distal electrode. The shock effect was evaluated by determining the difference between the AP affected by the shock and the normal AP. During cathodal stimulation an area of depolarization near the electrode was observed, surrounded by areas of hyperpolarization. The amplitude of polarization gradually decreased in areas far from the electrode. Inverting shock polarity reversed this effect. CONCLUSION: ICD monophasic defibrillation shocks create large dynamically interacting areas of both negative and positive polarization.

High-resolution fluorescent imaging does not reveal a distinct atrioventricular nodal anterior input channel (fast pathway) in the rabbit heart during sinus rhythm.

INTRODUCTION: We sought to determine the precise pathways of engagement of the AV node during sinus rhythm. METHODS AND RESULTS: Langendorff-perfused rabbit hearts were stained with 20 microM of the voltage-sensitive dye di-4-ANEPPS. Preparations containing the right atrium, sinoatrial (SA) and AV nodes, and interatrial septum were subsequently dissected and mapped in vitro using a 16 X 16 photodiode array with an adjustable resolution of 150 to 750 microns per diode. Motion artifacts were eliminated by using 15 mM 2,3-butanedione monoxime (BDM). Activation time-points were defined as (-dF/dt)max' where F = fluorescence. Isochronal maps of activation were plotted using the triangulation method. In all preparations, spontaneous activation began at the SA node, rapidly spread along the crista terminalis (CrT), entered the AV nodal region via the posterior "slow" pathway, and retrogradely spread to the septal region with a smaller conduction velocity compared to that along the CrT. Collision of anterograde and retrograde wavefronts was frequently observed in the mid-septum. Notably, there was no evidence for the presence of a distinct anterior entrance into the AV node. CONCLUSIONS: Fast pathway conduction during sinus rhythm results from a broad posterior wavefront that envelops the AV node with subsequent retrograde atrial septal activation.

Effects of 2,3-butanedione monoxime on atrial-atrioventricular nodal conduction in isolated rabbit heart.

INTRODUCTION: 2,3-Butanedione monoxime (BDM) has been found to reversibly block cardiac contraction, without blocking electrical conduction. This study characterizes the dose-dependent effects of BDM on the conduction through the atrioventricular node (AVN) of rabbit heart. METHODS AND RESULTS: Thirteen isolated atrial-AVN preparations were used in control, during and after exposure to 5, 10, and 20 mM BDM. Anterograde and retrograde pacing protocols were used to obtain the Wenckebach cycle length, effective and functional refractory periods of the AVN, index of AVN conduction delay (the area under the AVN conduction curve), as well as index of intra-atrial conduction delay between the AVN inputs. Compared to control, 5 and 10 mM BDM produced either shortening or no effect on all of the above parameters except a slight (6% and 14%, respectively) increase in the intra-atrial delay. At 20 mM, BDM produced a further increase in the intra-atrial delay (up to 50%) as well as in the retrograde AVN conduction delay (up to 16%), while the characteristics of the anterograde conduction were still improved. The effects of perfusion with BDM on these parameters were reversible after washout. CONCLUSIONS: Aside from its known effect as an electromechanical uncoupler, BDM reversibly altered some of the electrical responses of the AVN. Most of these alterations, however, did not impede but rather improved AVN conduction. Since a dose of 10 mM is sufficient to fully eliminate undesirable motion, BDM should be considered a safe and valuable tool in AVN studies in vitro requiring a mechanically quiescent preparation.

Outward K+ current densities and Kv1.5 expression are reduced in chronic human atrial fibrillation.

Chronic atrial fibrillation is associated with a shortening of the atrial action potential duration and atrial refractory period. To test the hypothesis that these changes are mediated by changes in the density of specific atrial K+ currents, we compared the density of K+ currents in left and right atrial myocytes and the density of delayed rectifier K+ channel alpha-subunit proteins (Kv1.5 and Kv2.1) in left and right atrial appendages from patients (n = 28) in normal sinus rhythm with those from patients (n = 15) in chronic atrial fibrillation (AF). Contrary to our expectations, nystatin-perforated patch recordings of whole-cell K+ currents revealed significant reductions in both the inactivating (ITO) and sustained (IKsus) outward K+ current densities in left and right atrial myocytes isolated from patients in chronic AF, relative to the ITO and IKsus densities in myocytes isolated from patients in normal sinus rhythm. Quantitative Western blot analysis revealed that although there was no change in the expression of the Kv2.1 protein, the expression of Kv1.5 protein was reduced by > 50% in both the left and the right atrial appendages of AF patients. The finding that Kv1.5 expression is reduced in parallel with the reduction in delayed rectifier K+ current density is consistent with recent suggestions that Kv1.5 underlies the major component of the delayed rectifier K+ current in human atrial myocytes, the ultrarapid delayed rectifier K+ current, IKur. The unexpected finding of reduced voltage-gated outward K+ current densities in atrial myocytes from AF patients demonstrates the need to further examine the details of the electrophysiological remodeling that occurs during AF to enable more effective and safer therapeutic strategies to be developed.

Relation of the atrial input sites to the dual atrioventricular nodal pathways: crossing of conduction curves generated with posterior and anterior pacing.

INTRODUCTION: The usually accepted definition of the dual pathway electrophysiology requires the presence of conduction curves with a discontinuity ("jump"). However, AV nodal reentrant tachycardia has been observed in patients with "smooth" conduction curves, whereas discontinuity of the conduction curve does not guarantee induction of stable reentry. We hypothesize that the duality of AV nodal conduction can be revealed by careful choice of stimulation sites during the generation of AV nodal conduction curves. METHODS AND RESULTS: In 21 rabbit heart atrial-AV nodal preparations, programmed electrical stimulation with S1-S2-S3 pacing protocol was applied either posteriorly at the crista terminalis input site (CrT) or anteriorly at the lower interatrial septum input site (IAS), or (in 8 preparations with surgically divided input sites) at both. We found that in intact preparations with "smooth" conduction curves, pacing at long coupling intervals produced shorter AV nodal conduction times from the IAS (56 +/- 9.8 msec vs 69 +/- 10.1 msec; P < 0.01). At short coupling intervals, in contrast, shorter conduction times were obtained from the CrT (173 +/- 21.8 msec vs 188 +/- 22.8 msec; P < 0.01). This resulted in a characteristic crossing of the superimposed IAS and CrT conduction curves. After division of the inputs, the IAS site had rapid conduction to the His bundle but a longer refractory period, whereas the CrT site had long conduction times and shorter refractory periods. Wavefronts entering the AV node from these two inputs can summate, resulting in improved conduction. CONCLUSION: Pacing protocols designed to accentuate the asymmetry between the AV nodal inputs can help to reveal the functional difference between the dual pathways and thus to better assess the properties of AV nodal conduction.

Phenylephrine-induced Ca2+ oscillations in canine pulmonary artery smooth muscle cells.

Modulation of [Ca2+]i in response to receptor activation is a critical determinant of vascular smooth muscle tone. In this study, we examined the effect of continuous stimulation of alpha 1-adrenoceptors with phenylephrine (PE) on [Ca2+]i in single pulmonary artery smooth muscle cells (PASMCs) cultured from explants of canine intrapulmonary artery. Fura 2-loaded PASMCs pretreated with propranolol (5 mumol/L) were continuously superfused with PE at 37 degrees C on the stage of an inverted fluorescence microscope, and [Ca2+]i was measured using a dual-wavelength spectrofluorometer. Resting values of [Ca2+]i were 96 +/- 4 nmol/L. PE (10 mumol/L) stimulated oscillations in [Ca2+]i at a frequency of 1.35 +/- 0.07/min, which reached a peak [Ca2+]i of 650 +/- 26 nmol/L (n = 69 cells). The oscillations lasted for > 30 minutes and were constant in amplitude and frequency. Both the amplitude and frequency of PE-induced [Ca2+]i oscillations increased in a dose-dependent (3 x 10(-8) to 10(-4) mol/L) manner. Pretreatment with the alpha 1-adrenoceptor antagonist prazosin (50 nmol/L) or removal of extracellular Ca2+ abolished the repetitive [Ca2+]i oscillations induced by PE. The voltage-operated Ca2+ channel blockers nifedipine (1 mumol/L) and verapamil (1 mumol/L) had no effect on the [Ca2+]i oscillations. In contrast, inhibition of phospholipase C with U73122 (10(-7) to 10(-5) mol/L) attenuated the oscillations in a dose-dependent fashion. The nonselective protein kinase inhibitor staurosporine (10(-9) to 10(-7) mol/L) had a minimal inhibitory effect on the oscillations. Caffeine (30 mmol/L) and thapsigargin (1 mumol/L) abolished the oscillations, whereas pretreatment with ryanodine (1 to 100 mumol/L) had no effect. In freshly dispersed PASMCs, PE (10 mumol/L) induced oscillations in [Ca2+]i similar to those observed in cultured cells, and patch-clamp experiments revealed oscillations in membrane potential. These results indicate that PE induces [Ca2+]i oscillations in PASMCs via stimulation of alpha 1-adrenoceptors coupled to phospholipase C activation. Voltage-operated Ca2+ channels and protein kinases are not required for the oscillations. The requirement for extracellular Ca2+ and intracellular Ca2+ stores indicates that both Ca2+ influx and intracellular Ca2+ release play a role in the maintenance of the oscillations.

Virtual electrode-induced reexcitation: A mechanism of defibrillation.

Mechanisms of defibrillation remain poorly understood. Defibrillation success depends on the elimination of fibrillation without shock-induced arrhythmogenesis. We optically mapped selected epicardial regions of rabbit hearts (n=20) during shocks applied with the use of implantable defibrillator electrodes during the refractory period. Monophasic shocks resulted in virtual electrode polarization (VEP). Positive values of VEP resulted in a prolongation of the action potential duration, whereas negative polarization shortened the action potential duration, resulting in partial or complete recovery of the excitability. After a shock, new propagated wavefronts emerged at the boundary between the 2 regions and reexcited negatively polarized regions. Conduction velocity and maximum action potential upstroke rate of rise dV/dt (max) of shock-induced activation depended on the transmembrane potential at the end of the shock. Linear regression analysis showed that dV/dt(max) of postshock activation reached 50% of that of normal action potential at a V(m) value of -56.7+/-0.6 mV postshock voltage (n=9257). Less negative potentials resulted in slow conduction and blocks, whereas more negative potentials resulted in faster conduction. Although wavebreaks were produced in either condition, they degenerated into arrhythmias only when conduction was slow. Shock-induced VEP is essential in extinguishing fibrillation but can reinduce arrhythmias by producing excitable gaps. Reexcitation of these gaps through progressive increase in shock strength may provide the basis for the lower and upper limits of vulnerability. The former may correspond to the origination of slow wavefronts of reexcitation and phase singularities. The latter corresponds to fast conduction during which wavebreaks no longer produce sustained arrhythmias.

Atrial L-type Ca2+ currents and human atrial fibrillation.

Chronic atrial fibrillation (AF) is characterized by decreased atrial contractility, shortened action potential duration, and decreased accommodation of action potential duration to changes in activation rate. Studies on experimental animal models of AF implicate a reduction in L-type Ca2+ current (I(Ca)) density in these changes. To evaluate the effect of AF on human I(Ca), we compared I(Ca) in atrial myocytes isolated from 42 patients in normal sinus rhythm at the time of cardiac surgery with that of 11 chronic AF patients. I(Ca) was significantly reduced in the myocytes of patients with chronic AF (mean -3.35+/-0.5 pA/pF versus -9.13+/-1. 0 pA/pF in the controls), with no difference between groups in the voltage dependence of activation or steady-state inactivation. Although I(Ca) was lower in myocytes from the chronic AF patients, their response to maximal beta-adrenergic stimulation was not impaired. Postoperative AF frequently follows cardiac surgery. Half of the patients in the control group (19/38) of this study experienced postoperative AF. Whereas chronic AF is characterized by reduced atrial I(Ca), the patients with the greatest I(Ca) had an increased incidence of postoperative AF, independent of patient age or diagnosis. This observation is consistent with the concept that calcium overload may be an important factor in the initiation of AF. The reduction in functional I(Ca) density in myocytes from the atria of chronic AF patients may thus be an adaptive response to the arrhythmia-induced calcium overload.

Voltage-sensitive dye RH421 increases contractility of cardiac muscle.

Voltage-sensitive dyes and imaging techniques have proved to be indispensable tools for use in in vitro electrophysiological studies. To avoid motion artifacts in optical recordings, electromechanical uncouplers such as 2,3-butanedione monoxime (BDM) are required. In this study, we sought to determine whether the voltage-sensitive dye RH421 had an effect on the contractility of heart muscle, either alone or in the presence of BDM. Ventricular contractility was studied in (i) isolated rat myocytes and (ii) Langendorff-perfused rat hearts under control conditions, and during perfusion with RH421 or RH421 + BDM. The following results were obtained. (i) The amplitude of cell shortening increased progressively from 6.24 +/- 0.64 to 9.95 +/- 1.02 microm during 15 min of superfusion with 5 microM RH421 (n = 11), and further increased to 12.54 +/- 0.97 microm during washout. In seven cells first perfused with 15 mM BDM and then with 15 mM BDM + 5 microM RH421, the amplitude of the cell shortening first decreased from 5.17 +/- 0.51 to 0.41 +/- 0.19 microm, then the amplitude increased to 2.63 +/- 0.25 microm. (ii) Left ventricular pressure (LVP) of the heart (n = 7) was reduced by 15 mM BDM from 60.7 +/- 2.5 to 2.8 +/- 0.5 mmHg (1 mmHg = 133.3 Pa). LVP increased to 12.8 +/- 1.1 mmHg during subsequent perfusion with 10 microM RH421 in the presence of BDM and did not change (LVP = 12.4 +/- 2.4 mmHg) during washout of the dye. Therefore, RH421 increased the contractility of rat hearts and isolated myocytes with and without BDM.