Scott T. Lamp

Sulfonylureas, ATP-sensitive K+ channels, and cellular K+ loss during hypoxia, ischemia, and metabolic inhibition in mammalian ventricle.

Sulfonylurea derivatives glibenclamide and tolbutamide are selective blockers of ATP-sensitive K+ (KATP) channels. However, their ability to prevent cellular K+ loss and shortening of action potential duration during ischemia or hypoxia in the intact heart is modest compared with their efficacy at blocking KATP channels in excised membrane patches. In the isolated arterially perfused rabbit interventricular septum, the increase in unidirectional K+ efflux and shortening of action potential duration during substrate-free hypoxia were effectively blocked by glibenclamide, but only by very high concentrations (100 microM); during hypoxia with glucose present, glibenclamide was only partially effective at reducing K+ loss. During total global ischemia (10 minutes), up to 100 microM glibenclamide or 1 mM tolbutamide attenuated shortening of action potential duration but only reduced [K+]0 accumulation by a maximum of 32 +/- 6%. In isolated patch-clamped guinea pig ventricular myocytes in which the whole-cell ATP-sensitive K+ current was activated by exposure to the metabolic inhibitors, glibenclamide (up to 100 microM) and tolbutamide (10 mM) were only partially effective at blocking the whole-cell ATP-sensitive K+ current (maximum block, 51 +/- 10% and 50 +/- 9%, respectively), especially when ADP was included in the patch electrode solution. In inside-out membrane patches excised from these myocytes, glibenclamide blocked unitary currents through KATP channels with a Kd of 0.5 microM and a Hill coefficient of 0.5 in the absence of ADP at the cytosolic membrane surface, but block was incomplete when 100 microM ADP (+2 mM free Mg2+) was present. ADP had a similar effect on block of KATP channels by tolbutamide. These findings suggest that free cytosolic [ADP], which rises rapidly to the 100 microM range during early myocardial ischemia and hypoxia, may account for the limited efficacy of sulfonylureas at blocking ischemic and hypoxic cellular K+ loss under these conditions.

ATP‐sensitive K+ channels and cellular K+ loss in hypoxic and ischaemic mammalian ventricle.

1. The contribution of ATP‐sensitive K+ (K+ATP) channels to the rapid increase in cellular K+ efflux and shortening of action potential duration (APD) during early myocardial ischaemia and hypoxia remains controversial, because for the first 10 min of ischaemia or hypoxia in intact hearts cytosolic [ATP] remains about two orders of magnitude greater than the [ATP] causing half‐maximal blockade of K+ATP channels in excised membrane patches. The purpose of this study was to investigate this apparent discrepancy. 2. During substrate‐free hypoxia, total, diastolic and systolic unidirectional K+ efflux rates increased by 43, 26 and 103% respectively after 8.3 min in isolated arterially perfused rabbit interventricular septa loaded with 42K+. APD shortened by 39%. From the Goldman‐Hodgkin‐Katz equation, the relative increases in systolic and diastolic K+ efflux rates were consistent with activation of a voltage‐independent K+ conductance. 3. During total global ischaemia, [K+]o measured with intramyocardial valinomycin K(+)‐sensitive electrodes increased at a maximal rate of 0.68 mM min‐1, which could be explained by a less than 26% increase in unidirectional K+ efflux rate (assuming no change in K+ influx), less than the increase during hypoxia. APD shortened by 23% over 10 min. 4. During hypoxia and ischaemia, cytosolic [ATP] decreased by about one‐third from 6.8 +/‐ 0.5 to 4.3 +/‐ 0.3 and 4.6 +/‐ 0.4 mM respectively, and free cytosolic [ADP] increased from 15 to 95 and approximately 63 microM respectively. 5. To estimate the percentage of activation of current through K+ATP channels (IK,ATP) necessary to double the systolic K+ efflux rate (comparable to the increase during hypoxia), K+ efflux during a single simulated action potential was measured by blocking non‐K+ currents under control conditions and after IK,ATP was fully activated by metabolic inhibitors. Activation of 0.41 +/‐ 0.07% of maximal IK,ATP was sufficient to double the systolic K+ efflux rate. The equivalent amount of constant hyperpolarizing current also shortened the APD in the isolated myocytes by 41 +/‐ 5%, compared to the 39% APD shortening observed during hypoxia in the intact heart. 6. The degree of activation of IK,ATP expected to occur during hypoxia and ischaemia was estimated by characterizing the ATP sensitivity of K+ATP channels in the presence of 2 mM‐free Mgi2+ and 0, 10, 100 and 300 microM‐ADPi in inside‐out membrane patches excised from guinea‐pig ventricular myocytes.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanism of hypoxic K loss in rabbit ventricle.

Although a critical factor causing lethal ischemic ventricular arrhythmias, net cellular K loss during myocardial ischemia and hypoxia is poorly understood. We investigated whether selective activation of ATP-sensitive K (KATP) channels causes net cellular K loss by examining the effects of the KATP channel agonist cromakalim on unidirectional K efflux, total tissue K content, and action potential duration (APD) in isolated arterially perfused rabbit interventricular septa. Despite increasing unidirectional K efflux and shortening APD to a comparable degree as hypoxia, cromakalim failed to induce net tissue K loss, ruling out activation of KATP channels as the primary cause of hypoxic K loss. Next, we evaluated a novel hypothesis about the mechanism of hypoxic K loss, namely that net K loss is a passive reflection of intracellular Na gain during hypoxia or ischemia. When the major pathways promoting Na influx were inhibited, net K loss during hypoxia was almost completely eliminated. These findings show that altered Na fluxes are the primary cause of net K loss during hypoxia, and presumably also in ischemia. Given its previously defined role during hypoxia and ischemia in promoting intracellular Ca overload and reperfusion injury, this newly defined role of intracellular Na accumulation as a primary cause of cellular K loss identifies it as a central pathogenetic factor in these settings.

Local regulation of the threshold for calcium sparks in rat ventricular myocytes: role of sodium‐calcium exchange

1 To determine whether Na+‐Ca2+ exchange modulates Ca2+ sparks, we studied enzymatically isolated patch clamped rat ventricular myocytes loaded with the Ca2+‐sensitive indicator fluo‐3, using confocal microscopy at 20–22 °C. Two‐dimensional images of Ca2+ sparks were recorded at 240 Hz using a laser scanning confocal microscope, allowing observation of a large area of the cell (820 μm2) at one time. 2 At a holding potential of −75 mV, spontaneous sparks were infrequent. Removal of extracellular Na+ for 520 ms, which in the absence of pipette Na+ should block Na+‐Ca2+ exchange bidirectionally, was associated with a fourfold increase in spark frequency, without a significant change in cytoplasmic [Ca2+], sarcoplasmic reticulum (SR) Ca2+ content, or spark intensity, size or time course. 3 These findings are consistent with a model of excitation‐contraction coupling in which Na+‐Ca2+ exchange locally regulates the resting Ca2+ concentration in the diadic cleft (T‐tubule‐SR junction), thereby modulating the threshold for triggering Ca2+ sparks.

Coexistence of two types of ventricular fibrillation during acute regional ischemia in rabbit ventricle.

Introduction: We previously reported that a normal ventricle can demonstrate two types of ventricular fibrillation (VF), depending on the underlying electrophysiologic characteristics at the time of VF induction. We hypothesize that the two types of VF can coexist in acutely ischemic ventricles.

Activation of ATP-sensitive K+ channels by cromakalim. Effects on cellular K+ loss and cardiac function in ischemic and reperfused mammalian ventricle.

Pharmacological modulation of [K+]o accumulation and action potential changes during acute myocardial ischemia is under evaluation as a promising new antiarrhythmic and cardioprotective strategy during myocardial ischemia and reperfusion. We studied the effects of cromakalim, a K+ channel opener that activates ATP-sensitive K+ channels, in isolated arterially perfused rabbit interventricular septa subjected to ischemia and reperfusion and, through use of the patch clamp technique, in inside-out membrane patches excised from guinea pig ventricular myocytes. During aerobic perfusion, 5 microM cromakalim shortened action potential duration (APD) from 217 +/- 7 to 201 +/- 10 msec, had no effect on [K+]o, and reduced tension by 17 +/- 3% (n = 11). During ischemia, pretreatment with 5 microM cromakalim resulted in 1) more rapid APD shortening (71 +/- 9 versus 166 +/- 7 msec at 10 minutes and 63 +/- 12 versus 122 +/- 8 msec at 30 minutes), 2) similar [K+]o accumulation after 10 minutes (8.9 +/- 0.3 versus 9.6 +/- 0.5 mM) but a trend toward increased [K+]o accumulation after 30 minutes (11.0 +/- 1.7 versus 9.6 +/- 1.0 mM), and 3) similar times for tension to decline to 50% of control (2.14 +/- 0.16 versus 2.14 +/- 0.19 minutes) but shorter time to fall to 20% of control (4.34 +/- 0.33 versus 4.90 +/- 0.22 minutes; p = 0.003). After 60 minutes of reperfusion following 30 minutes of ischemia, recovery of function was similar, with a trend toward better recovery of developed tension (to 58 +/- 9% versus 39 +/- 10% of control; p = 0.18) and tissue ATP levels in cromakalim-treated hearts but no differences in APD or rest tension. Thus, 5 microM cromakalim had mild effects in normal heart but greatly accelerated APD shortening during ischemia without markedly increasing [K+]o accumulation, possibly because the more rapid APD shortening reduced the time-averaged driving force for K+ efflux through ATP-sensitive K+ channels. A significant cardioprotective effect during 30 minutes of ischemia plus 60 minutes of reperfusion could not be demonstrated in this model. In excised membrane patches studied at room temperature, the ability of cromakalim to activate ATP-sensitive K+ channels was significantly potentiated by 100 microM but not 15 microM cytosolic ADP, suggesting that in addition to the modest fall in cytosolic ATP during early ischemia, the rapid increases in cytosolic ADP may further sensitize cardiac ATP-sensitive K+ channels to activation by cromakalim.(ABSTRACT TRUNCATED AT 400 WORDS)

Atrioventricular Ring Reentry in Embryonic Mouse Hearts

Background— During development, AV conduction switches from base-to-apex to apex-to-base conduction after emergence of the conduction system. We hypothesize that after this transition, the bulk of the AV ring, although no longer required for AV conduction, remains transiently able to conduct, providing a potential arrhythmia substrate. We studied AV conduction during this transition and its sensitivity to autonomic modulation. Methods and Results— Simultaneous voltage and Ca2+ mapping with RH-237 and Rhod-2 was performed with 2 CCD cameras in embryonic mouse hearts (n=43). Additionally, isolated calcium mapping was performed in 309 hearts with fluo-3AM. Propagation patterns in voltage and Ca2+ mapping coincided. Arrhythmias were uncommon under basal conditions, with AV block in 14 (4%) and junctional rhythms in 4 (1%). Arrhythmias increased after stimulation with isoproterenol—junctional rhythm in 9 (3%) and ventricular rhythms in 22 (6%)—although AV block decreased (3 hearts, 1%). Adding carbachol after isoproterenol caused dissociated antegrade and retrograde AV ring conduction in 30 (8.6%) of E10.5 and E11.5 hearts, occurring preferentially in the right and left sides of the ring, respectively. In 2 cases, reentry occurred circumferentially around the AV ring, perpendicular to normal propagation. Reentry persisted for multiple beats, lasting from 3 to 22 minutes. No episodes of AV ring reentry occurred in E9.5 hearts. Conclusions— AV ring reentry can occur by spatial dissociation of antegrade and retrograde conduction during combined adrenergic and muscarinic receptor stimulation. Critical maturation (>E9.5) seems to be required to sustain reentry.

Metabolic inhibition alters subcellular calcium release patterns in rat ventricular myocytes: implications for defective excitation-contraction coupling during cardiac ischemia and failure.

Metabolic inhibition (MI) contributes to contractile failure during cardiac ischemia and systolic heart failure, in part due to decreased excitation-contraction (E-C) coupling gain. To investigate the underlying mechanism, we studied subcellular Ca2+ release patterns in whole cell patch clamped rat ventricular myocytes using two-dimensional high-speed laser scanning confocal microscopy. In cells loaded with the Ca2+ buffer EGTA (5 mmol/L) and the fluorescent Ca2+-indicator fluo-3 (1 mmol/L), depolarization from −40 to 0 mV elicited a striped pattern of Ca2+ release. This pattern represents the simultaneous activation of multiple Ca2+ release sites along transverse-tubules. During inhibition of both oxidative and glycolytic metabolism using carbonyl cyanide-p-trifluoromethoxyphenylhydrazone (FCCP, 50 nmol/L) and 2-deoxyglucose (2-DG, 10 mmol/L), there was a decrease in inward Ca2+ current (ICa), the spatially averaged Ca2+ transient, and E-C coupling gain, but no reduction in sarcoplasmic reticulum Ca2+ content. The striped pattern of subcellular Ca2+ release became fractured, or disappeared altogether, corresponding to a marked decrease in the area of the cell exhibiting organized Ca2+ release. There was no significant change in the intensity or kinetics of local Ca2+ release. The mechanism is not fully explained by dephosphorylation of L-type Ca2+ channels, because a similar degree of ICa“rundown” in control cells did NOT result in fracturing of the Ca2+ release pattern. We conclude that metabolic inhibition interferes with E-C coupling by (1) reducing trigger Ca2+, and (2) directly inhibiting sarcoplasmic reticulum Ca2+ release site open probability.

Burst pacemaker activity of the sinoatrial node in sodium–calcium exchanger knockout mice

Significance The sinoatrial node (SAN) generates cardiac pacemaker activity through the interplay of membrane ionic currents and intracellular calcium cycling. SAN dysfunction is a common disorder that usually requires implantation of costly electronic pacemakers. To study the role of intracellular calcium regulation by the sodium/calcium exchanger (NCX) in SAN pacing, we generated an atrial-specific NCX knockout mouse. The SAN beating pattern in these mice is abnormal, with bursts of activity interrupted by frequent pauses reminiscent of clinical SAN disease. We found that cellular calcium accumulation was responsible for this abnormal beating pattern, underscoring the importance of NCX-mediated calcium efflux to normal pacing. We propose that burst firing is a common feature of SAN dysfunction caused by elevated cytoplasmic calcium. In sinoatrial node (SAN) cells, electrogenic sodium–calcium exchange (NCX) is the dominant calcium (Ca) efflux mechanism. However, the role of NCX in the generation of SAN automaticity is controversial. To investigate the contribution of NCX to pacemaking in the SAN, we performed optical voltage mapping and high-speed 2D laser scanning confocal microscopy (LSCM) of Ca dynamics in an ex vivo intact SAN/atrial tissue preparation from atrial-specific NCX knockout (KO) mice. These mice lack P waves on electrocardiograms, and isolated NCX KO SAN cells are quiescent. Voltage mapping revealed disorganized and arrhythmic depolarizations within the NCX KO SAN that failed to propagate into the atria. LSCM revealed intermittent bursts of Ca transients. Bursts were accompanied by rising diastolic Ca, culminating in long pauses dominated by Ca waves. The L-type Ca channel agonist BayK8644 reduced the rate of Ca transients and inhibited burst generation in the NCX KO SAN whereas the Ca buffer 1,2-Bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid (acetoxymethyl ester) (BAPTA AM) did the opposite. These results suggest that cellular Ca accumulation hinders spontaneous depolarization in the NCX KO SAN, possibly by inhibiting L-type Ca currents. The funny current (If) blocker ivabradine also suppressed NCX KO SAN automaticity. We conclude that pacemaker activity is present in the NCX KO SAN, generated by a mechanism that depends upon If. However, the absence of NCX-mediated depolarization in combination with impaired Ca efflux results in intermittent bursts of pacemaker activity, reminiscent of human sinus node dysfunction and “tachy-brady” syndrome.

Role of Intracellular Ca2+ Dynamics in Supporting Spiral Wave Propagation

The intracellular Ca2+ dynamics play a key role in the transition from ventricular tachycardia to ventricular fibrillation through their influence on Ca-sensitive membrane currents. That was shown in our previous publication which deals with modified Luo and Rudy cardiac cell model. Here using the same model we study the effect of increasing sensitivity of non-specific calcium current, Ins(Ca), to [Ca2+]i on wave propagation in two dimensional tissue model under conditions of ventricular tachycardia. Under these conditions some of the tissue cells come across high rates of stimulation with subsequent calcium overload and release from the Junctional Sarcoplasmic Reticulum. Our results show that increasing sensitivity of Ins(Ca) to [Ca]i leads to progressive prolongation of the action potential duration in some of the tissue cells. That causes a non-uniform increase in the length of the propagated spiral wave to such an extent that the size of the tissue becomes insufficient for further propagation. The temporary block of propagation causes the appearance of cells with single and multiple early after depolarization (EAD), which formed in a portion of space with retarding repolarization. This area is the source of consequent initiation of direct or backward spiral waves, when the surrounding tissue goes out of excitation.