Rapid in vivo monitoring of chemotherapeutic response using weighted sodium magnetic resonance imaging.

A novel pulse sequence strategy uses sodium magnetic resonance imaging to monitor the response to chemotherapy of mouse xenograft tumors propagated from human prostate cancer cell lines. An inversion pulse suppresses sodium with long longitudinal relaxation times, weighting the image toward intracellular sodium nuclei. Comparing these weighted sodium images before and 24 h after administration of antineoplastics, we measured a 36 +/- 4% (P < 0.001; n = 16) increase in signal intensity. Experiments with these same drugs and cells, treated in culture, detected a significant intracellular sodium elevation (10-20 mM) using a ratiometric fluorescent dye. Flow cytometry studies showed that this elevation preceded cell death by apoptosis, as determined by fluorescent end-labeling of apoptotic nuclei or Annexin V binding. Histopathology on formalin-fixed sections of explanted tumors confirmed that drug administration reduces proliferation (2.2 versus 8.6 mitotic figures per high power field; P < 0.0001), an effect that inversely correlates with the sodium magnetic resonance image response on a tumor-to-tumor basis (P < 0.02; n = 10). Morphological features, such as central zones of nonviable cells, rims of active apoptosis, and areas of viable tumor, could be distinguished by comparing weighted and unweighted images. Advantages of this sodium imaging technique include rapid determination of drug efficacy, improved diagnosis of lesions, ease of coregistration with high resolution proton magnetic resonance imaging, and absence of costly or toxic reagents.

Nitric oxide triggers programmed cell death (apoptosis) of adult rat ventricular myocytes in culture.

Excessive nitric oxide (NO) production within the heart is implicated in the pathogenesis of myocyte death, but the mechanism whereby NO kills cardiac myocytes is not known. To determine whether NO may trigger programmed cell death (apoptosis) of adult rat ventricular myocytes in culture, the NO donor S-nitroso-N-acetylpenicillamine (SNAP) was shown to kill purified cardiac myocytes in a dose-dependent fashion. In situ analysis of ventricular myocytes plated on chamber slides using nick-end labeling of DNA demonstrated that SNAP induces cardiac myocyte apoptosis, which was confirmed by the identification of oligonucleosomal DNA fragmentation on agarose gel electrophoresis. Similarly, treatment of cardiac myocytes with cytokines that induce inducible NO synthase was shown to cause an NO-dependent induction of apoptosis. Addition of reduced hemoglobin to scavenge NO liberated by SNAP extinguished both the increase in percentage of apoptotic cells and the appearance of DNA ladders. Treatment with SNAP (but not with N-acetylpenicillamine or SNAP + hemoglobin) not only induced apoptosis but resulted in a marked increase in p53 expression in cardiac myocytes detected by Western blotting and immunohistochemistry. These data indicate that NO has the capacity to kill cardiac myocytes by triggering apoptosis and suggest the involvement of p53 in this process.

Zatebradine slows ectopic ventricular rhythms in canine heart 24 hours after coronary artery ligation.

Arrhythmias occur 24 h after occlusion of the left anterior descending (LAD) coronary artery in the canine heart and have been attributed to the abnormal spontaneous activity in subendocardial Purkinje fibers, which are markedly depolarized. The major current underlying normal automaticity in these fibers is i(f). Although the i(f) activation range is generally considered to be more negative than the diastolic membrane potential in these depolarized fibers in infarcts, this activation range has been shown to shift in a positive direction in response to hormonal influences. Thus i(f) could still mediate automaticity in these fibers in infarcts. Furthermore, recent reports indicate that a depolarizing diastolic current, probably i(f), also can be measured in ventricular muscle during abnormal experimental conditions, which may occur during ischemia. To test whether there is a role of i(f) currents in sustaining ventricular ectopy, we administered the selective i(f) channel blocker, zatebradine, 24 h after LAD ligation in canine hearts. We report that intravenous injections of zatebradine (0.25 or 1.0 mg/kg) significantly slow ventricular rhythms (with average reductions of 19 or 26%, respectively). Moreover, because zatebradine also slows sinus nodal rate, it can lead to an increased incidence of ectopic beats. However, during right atrial pacing, when sinus slowing has no effect on ventricular rhythms, capture of ventricular rhythms occurs at lower rates in the presence of zatebradine. The reduction of capture threshold is comparable to the reduction in the rate of the ectopic rhythm. Thus zatebradine eliminated the arrhythmia when the right atrium was paced at the original sinus rate.

Endothelin-dependent actions in cultured AT-1 cardiac myocytes. The role of the epsilon isoform of protein kinase C.

The consequences of endothelin receptor activation were examined in atrial tumor myocytes derived from transgenic mice (AT-1 cells). Endothelin-1 (endothelin) stimulates phosphoinositide hydrolysis in a dose-dependent manner. Endothelin also induces the rapid and transient translocation of protein kinase C (PKC)-epsilon immunoreactivity from the soluble to the particulate cell fraction. The subcellular distributions of PKCalpha and PKCzeta (also expressed by AT-1 cells) are not influenced by endothelin. Using quantitative fluorescence microscopy with fura 2, we examined the effects of endothelin on intracellular calcium. In electrically driven myocytes, endothelin induces a rapid and transient increase in the amplitude of the calcium transient. This is blocked by both phorbol 12-myristate 13-acetate (PMA) pretreatment to downregulate PKC and the PKC inhibitor chelerythrine, arguing that PKCepsilon plays a critical role in endothelin receptor-dependent increases in intracellular calcium. Endothelin also stimulates mitogen-activated protein kinase (MAPK). MAPK activation is markedly attenuated by pretreatment with PMA or pertussis toxin (PTX, to activate susceptible G protein alpha subunits); it is completely prevented by combined pretreatment with PMA and PTX. In contrast, it is not attenuated by chelation of intracellular calcium with BAPTA. These findings indicate that the pathway for endothelin receptor stimulation of MAPK involves PKCepsilon and PTX-sensitive G protein(s). Thus, these studies identify a functional role for PKCepsilon as a mediator of endothelin receptor-dependent increases in cytosolic calcium and MAPK activity in AT-1 cells. Accordingly, the AT-1 cell system should provide a uniquely useful model to identify the intracellular targets for PKCepsilon and investigate their function in the regulation of intracellular calcium homeostasis and the induction of the growth response in cardiac myocytes.

Gating of IsK expressed in Xenopus oocytes depends on the amount of mRNA injected.

IsK is a K+ channel of the delayed rectifier type widely distributed throughout both excitable and nonexcitable cells. Its structure is different from other cloned K+ channels and molecular details of its gating remain obscure. Here we show that the activation kinetics of IsK expressed in Xenopus oocytes depend upon the amount of its mRNA injected, with larger amounts resulting in slower activation kinetics with a longer initial delay during activation. Similar changes in activation kinetics occur with time after a single injection of IsK mRNA. We present two kinetic schemes which illustrate how our experimental results could arise. Both imply an interaction among individual channel proteins during IsK activation. The dependence of channel gating on mRNA concentration provides a novel mechanism for long term regulation of ion current kinetics.

Spontaneous activity in transgenic mouse heart: comparison of primary atrial tumor with cultured AT-1 atrial myocytes.

INTRODUCTION: We have generated transgenic animals that heritably develop atrial tumors composed of differentiated proliferating cardiomyocytes. Experiments were initiated to characterize the electrical properties of these cells. METHODS AND RESULTS: We show that the primary atrial tumors are composed of discrete foci that exhibit spontaneous automatic activity. A direct correlation was observed between tumor size and firing rate of these foci. In addition to the primary atrial tumors, we examined the properties of cultured cardiomyocytes isolated from a transplantable transgenic tumor lineage (designated AT-1 cells). Cultured AT-1 cells are also spontaneously automatic. The action potential configuration from these preparations is similar to that observed in nontransgenic atrial cardiomyocytes, albeit somewhat more depolarized and of longer duration. As would be expected for cardiomyocytes of atrial origin, the transgenic cardiomyocyte preparations hyperpolarize during muscarinic stimulation due to increased K+ conductance mediated by a pertussis toxin sensitive G-protein. Assessment of pharmacologic blockage of the "if" pacemaker current suggests that the automaticity of both transgenic cardiomyocyte preparations may be of novel origin. In this context, the cultured AT-1 cells showed spontaneous behavior that was clearly of cellular origin; this activity was manifest as transient bursts of electrical activity followed by periods of electrical quiescence. This bursting pattern is unusual for normal adult cardiomyocytes, but has been observed in several other cell types. In the primary tumors, automatic behavior may arise from a similar cellular origin or alternatively from a microreentrant phenomena. CONCLUSION: Primary tumors and AT-1 cells show essential atrial electrophysiology with important novel features.

Statistical properties predicted by the ball and chain model of channel inactivation.

It has been proposed that part of a voltage gated channel is a tethered ball and that inactivation occurs when this wandering ball binds to a site in the channel. In order to be able to quantitatively test this model by comparison to experiments we developed analytical solutions and numerical simulations of the distribution of times it takes the ball to reach the binding site when the motion of the ball is random and when it is also influenced by a directed force. If the motion of the ball is one-dimensional, at long times this distribution is a single exponential with a rate constant that is inversely proportional to the square of the length of the chain and does not depend on the starting position of the ball. This dependence on the chain length is not significantly altered if there are short range electrical forces between the ball and its binding site. These predictions suggest that to confirm the validity of this model additional experiments should be done to more precisely determine the form of this distribution and its dependence on the length of the chain.

Expression and characterization of a canine hippocampal inwardly rectifying K+ current in Xenopus oocytes.

1. An inwardly rectifying potassium current expressed in Xenopus laevis oocytes injected with canine hippocampal poly(A)+ RNA was investigated with the two-microelectrode voltage clamp technique. 2. Xenopus oocytes injected with canine hippocampal poly(A)+ RNA expressed a current activated by hyperpolarization. This current contained an instantaneous and a time-dependent component. Both components were inwardly rectifying and could be blocked by extracellular Cs+ or Ba2+. 3. The expressed current was carried mainly by K+. Its reversal potential measured in different [K+]os could be fitted by the Nernst equation with a slope of -50.7 per tenfold change in [K+]o. Extracellular Cl- and Na+ made minimal contributions to the current. 4. The activation of the expressed current depended on both voltage and [K+]o. Activation started near EK and the activation curve shifted along the voltage axis in parallel with EK when [K+]o was altered. 5. The activation time constants of the expressed current also depended on both voltage and [K+]o. The voltage dependence of the time constants was bell-shaped and the peak value was at a potential 30-50 mV more negative than EK. The voltage dependence of the time constants shifted along the voltage axis when EK was changed. 6. The poly(A)+ RNA extracted from canine hippocampus was fractionated in a 10-31% linear sucrose gradient. The size of the mRNA required to express the inwardly rectifying current was estimated to be around 4 kb. 7. In conclusion, the expressed current is an inwardly rectifying potassium current. The canine hippocampal mRNA should be an excellent source for expression-cloning of the inward rectifier channel.

Time course of changes in intracellular K+, Na+, and pH of subendocardial Purkinje cells during the first 24 hours after coronary occlusion.

We investigated the basis for the alterations in the intracellular potassium and sodium activity occurring in subendocardial Purkinje fibers surviving in 24-hour infarcts by examining ion activities in these Purkinje fibers removed from infarcting hearts at earlier times. Specifically, we examined intracellular potassium activity, sodium activity, and pH at 1 and 3 hours after ligation of the left anterior descending coronary artery, and we correlated the changes in ion activity with changes in maximum diastolic potential. We tested various mechanistic hypotheses relating to how the ion activity changes develop and how they affect membrane potential. We found that intracellular sodium activity in tissue removed 1 hour after ligation was on average already maximally elevated by a factor of 2 over control (19.2 +/- 2.0 mM [mean +/- SEM] versus 9.4 +/- 0.4 mM). Potassium activity diminished progressively over the first 24 hours (from normal of 112.0 +/- 2.7 to 61.6 +/- 2.8 mM), although half of the decrease occurred during the first hour (to 86.8 +/- 4.1 mM). Intracellular pH did not change at either 1 or 3 hours. Whereas maximum diastolic potential depolarization exceeded the calculated depolarization of the potassium equilibrium potential by a factor of 2 in 24-hour infarcts, the depolarization at 1 and 3 hours could be more nearly attributed to the loss of potassium. The change in the dependence of maximum diastolic potential on potassium equilibrium potential may be due to changes in membrane conductance caused by ionic or biochemical factors. The changes in ion activity continuously develop during the first day after ligation and may be due to multiple factors and mechanisms.

Interaction of intracellular ion buffering with transmembrane-coupled ion transport.

The role of the Na/Ca exchanger in the control of cellular excitability and tension development is a subject of current interest in cardiac physiology. It has been suggested that this coupled transporter is responsible for rapid changes in intracellular calcium activity during single beats, generation of plateau currents, which control action potential duration, and control of intracellular sodium during Na/K pump suppression, which may occur during terminal states of ischemia. The actual behavior of this exchanger is likely to be complex for several reasons. First, the exchanger transports two ionic species and thus its instantaneous flux rate depends on both intracellular sodium and calcium activity. Secondly, the alteration in intracellular calcium activity, which is caused by a given transmembrane calcium flux, and which controls the subsequent exchanger rate, is a complex function of available intracellular calcium buffering. The buffers convert the ongoing transmembrane calcium fluxes into changes in activity that are a small and variable fraction of the change in total calcium concentration. Using a number of simple assumptions, we model changes in intracellular calcium and sodium concentration under the influence of Na/Ca exchange, Na/K ATPase and Ca-ATPase pumps, and passive sodium and calcium currents during periods of suppression and reactivation of the Na/K ATPase pump. The goal is to see whether and to what extent general notions of the role of the Na/Ca exchanger used in planning and interpreting experimental studies are consistent with its function as derived from current mechanistic assumptions about the exchanger. We find, for example, that based on even very high estimates of intracellular calcium buffering, it is unlikely that Na/Ca exchange alone can control intracellular sodium during prolonged Na/K pump blockade. It is also shown that Na/Ca exchange can contaminate measurements of Na/K pump currents under a variety of experimental conditions. The way in which these and other functions are affected by the dissociation constants and total capacity of the intracellular calcium buffers are also explored in detail.

Effects of alpha-adrenergic stimulation on intracellular sodium activity and automaticity in canine Purkinje fibers.

Approximately 60% of adult canine Purkinje fibers respond to alpha 1-adrenergic stimulation with a decrease in automaticity. Recent studies of disaggregated Purkinje myocytes have suggested that this negative chronotropic effect results from alpha 1-adrenergic activation of the Na-K pump. In this study we evaluated 1) whether Na-K pump activation is associated with the negative chronotropic effect of alpha 1-adrenergic stimulation in adult canine Purkinje fibers and 2) if the effect of alpha-agonists on the pump is direct or mediated by an increase in intracellular sodium activity (aNai). We used sodium selective microelectrodes to determine the effects of 5 x 10(-9) and 5 x 10(-8) M phenylephrine on aNai. Phenylephrine decreased automaticity in five of eight Purkinje fibers while an increase occurred in the other three. The rate decrease was always accompanied by a decrease in aNai (-3.9 mM; p less than 0.05), whereas in fibers showing an increase in rate, aNai was unchanged. To evaluate the effect of phenylephrine in the absence of changes in automaticity, 10 Purkinje fibers were studied during pacing. A clear-cut reduction in aNai (-2.8 mM) was present in six fibers; no change was seen in the other four. The effect of phenylephrine was blocked by prazosin but not by propranolol. We conclude that the effect of alpha 1-adrenergic stimulation to reduce aNai is consistent with activation of the Na-K pump. Moreover, this action of alpha 1-adrenergic stimulation is closely linked to its negative chronotropic effect.

Intracellular pH of canine subendocardial Purkinje cells surviving in 1-day-old myocardial infarcts.

A large reduction of intracellular potassium activity in depolarized subendocardial Purkinje fibers 24 hours after coronary artery ligation is accompanied by a much smaller increase in intracellular sodium activity. Similar intracellular ionic changes also occur during acute ischemia in ventricular muscle and are consistent with mechanisms based on intracellular acidification, which is known to occur in acutely ischemic muscle. To determine if canine subendocardial Purkinje cells 24 hours after myocardial infarction are also acidic, their intracellular pH, surface pH, and maximum diastolic potential (MDP) were measured with double-barrel pH-sensitive microelectrodes and compared with control fibers in noninfarcted hearts. In 12 mM bicarbonate Tyrode's solution (5% CO2-95% O2), the average intracellular pH was not significantly different (p greater than 0.25) for normal tissue (6.83 +/- 0.08, SD, MDP = -83.5 +/- 3.2 mV), for depolarized Purkinje fibers in infarct preparations during the first hour of superfusion (6.88 +/- 0.11, MDP = -47.8 +/- 11.8 mV), and for partially recovered Purkinje fibers in infarcts averaged over the third to sixth hours of superfusion (6.85 +/- 0.12, MDP = -74.5 +/- 9.6 mV). In 24 mM bicarbonate Tyrode's solution, infarct intracellular pH during both the first hour of superfusion (7.08 +/- 0.13, MDP = -57.6 +/- 15.7 mV) and during the third to sixth hours of superfusion (7.06 +/- 0.15, MDP = -76.5 +/- 9.6 mV) was significantly alkaline (p less than 0.0005) compared with average control pH (6.92 +/- 0.12, MDP = 82.1 +/- 3.7 mV). In 24 mM bicarbonate Tyrode's solution, the intracellular pH did vary with MDP (0.0032 pH units/mV). During superfusion of normal Purkinje fibers with hypoxic Tyrode's solution, intracellular pH acidified by 0.22 pH units as they depolarized. Therefore, intracellular acidification does not seem to be a cause of the depolarization of subendocardial Purkinje cells 24 hours after myocardial infarction.

Models of the Na-K pump in cardiac muscle predict the wrong intracellular Na+ activity.

The Na-K pump in cardiac Purkinje strands has been carefully studied with voltage clamp and Na+-selective microelectrodes. In three of these studies both the rate of change of intracellular Na+ activity, a(Nai), after pump blockade, and the time constant of reduction of a(Nai) after an Na+ load were measured. These two parameters can be employed with a formalism relating pump activity to a(Nai) in order to predict the a(Nai) in the steady state. Several formalisms were tested: (a) a first-order dependence on a(Nai); (b) a model based on the assumption of a single, saturable, Na+-binding site that must be occupied for transport to occur; (c) a model based on n equivalent, saturable, Na+ binding sites per pump molecule all of which must be occupied for transport to occur. The first two models predicted an a(Nai) that is far below the value of about 6 mM that is experimentally obtained. The third model would work for n greater than or equal to 4. These results suggest that either the cardiac Na-K pump is not well described by available Na-K pump models for n less than 4 or that the measured Na+ influx rate, extrusion rate or a(Nai) are in error.

Triggered activity in atrial fibres of canine coronary sinus: role of extracellular potassium accumulation and depletion.

1. Bursts of triggered activity can be induced in atrial fibres of the canine coronary sinus exposed to catecholamines. During a triggered burst there is an initial acceleration of rate accompanied by depolarization of the maximum diastolic potential (m.d.p.) followed by slowing of the rate and termination accompanied by hyperpolarization. 2. We have used extracellular K+-sensitive micro-electrodes (potassium ISE) to monitor extracellular K+ concentration ([K+]o) during and following triggered activity, while simultaneously measuring membrane potential with conventional intracellular micro-electrodes. 3. We found that the initial increase in rate during triggered activity is accompanied by increased [K+]o and depolarization. Later rate slowing and m.d.p. hyperpolarization is accompanied by decline of extracellular K+ accumulation. Following termination of triggered activity, extracellular K+ depletion occurred. 4. The decline of [K+]o and slowing of rate are known responses to enhanced Na+-K+ pump activation, as is the post-triggering depletion of extracellular K+. 5. Strophanthidin, which blocks the Na+-K+ pump, also blocks the [K+]o decline, the slowing of rate seen towards the end of the triggered episode, and the post-triggering depletion of extracellular K+. 6. Separate experiments studying the effects of elevated bath K+ and depolarizing current on triggering rate and delayed after-depolarization amplitude support our hypothesis that the rate profile of the triggered episode is to a large extent controlled by variations in m.d.p. subsequent to extracellular K+ accumulation and Na+-K+ pump activation.

Intracellular K+ activity, intracellular Na+ activity and maximum diastolic potential of canine subendocardial Purkinje cells from one-day-old infarcts.

The basis for the reduced maximum diastolic potential of canine cardiac subendocardial Purkinje fibers surviving one day after extensive transmural infarction was investigated, using double-barrel potassium and sodium ion-sensitive microelectrodes. The maximum diastolic potential of Purkinje fibers in infarct preparations from the left ventricular apex measured during the first hour of superfusion in a tissue bath was -50.1 +/- 13.7 mV, a value markedly reduced from the value in control Purkinje fibers from noninfarcted preparations (-85.0 +/- 4.5 mV). The intracellular potassium ion activity was reduced by 50.4 mM during this time (intracellular potassium ion activity equals 61.6 +/- 16.1 mM, as compared to control intracellular potassium ion activity of 112 +/- 19.8 mM). The potassium equilibrium potential was reduced by 16.0 mV (from -97.2 +/- 4.7 mV in controls to -81.2 +/- 6.9 mV), thus accounting for about one half of the reduction in the maximum diastolic potential. After 6 hours of superfusion, the maximum diastolic potential increased to -78.9 +/- 8.7 mV (still significantly less than control). The potassium equilibrium potential had largely recovered (-93.8 +/- 5.9 mV). The intracellular sodium ion activity of Purkinje fibers in the infarcts (15.6 +/- 6.9 mM) was elevated during the first hour of superfusion by 6.2 mM compared to control (9.4 +/- 2.6 mM), and this was only 12% as much as the initial intracellular potassium ion activity decrease. Sodium ion activity after 3-6 hours of superfusion was not significantly different than normal (12.1 +/- 4.9 mM). In conclusion, only a portion of the maximum diastolic potential changes can be explained by a reduction of the potassium equilibrium potential. It is likely that change(s) in the cell membrane sodium-potassium pump's function and in the membrane conductance are also involved. Furthermore, the lack of a compensatory increase in intracellular sodium ion activity accompanying the large reduction of intracellular potassium ion activity may be a consequence of the cellular acidosis, which is known to occur during myocardial ischemia.

Extracellular calcium ion depletion in frog cardiac ventricular muscle.

The extracellular free [Ca++] in frog ventricular muscle strips was monitored using single-barrel calcium ion-selective microelectrodes. During trains of repetitive stimulation, a heart rate-dependent, sustained fall (depletion) of the extracellular free [Ca++] occurs, which is most likely a consequence of net Ca++ influx into ventricular cells. The magnitude of the [Ca++]0 depletion increases for higher Ringer's solution [Ca++], and is reversibly blocked by manganese ion. Prolonged repetitive field stimulation (20-30 min) activates additional cellular Ca++ efflux, which can balance the additional Ca++ influx caused by stimulation, resulting in abolition of extratrabecular [Ca++]0 depletion in 20-30 min, and hence zero net transmembrane Ca++ flux at steady state. In the poststimulation period of quiescence, cellular Ca++ efflux persists and causes an elevation (accumulation) of the extracellular free [Ca++]. From these [Ca++]0 depletions, quantitative estimates for the net transmembrane Ca++ flux were derived using an analytical solution to the diffusion equation. In the highest Ringer's solution [Ca++] used (1 mM) the calculated net increase of the total intracellular calcium per beat was 6.5 +/- 1.4 mumol/l of intracellular space. This corresponds to an average net transmembrane Ca++ influx of 0.81 +/- 0.17 pmol/cm2/s during the 800-ms action potential. In lower bath [Ca++] the net transmembrane [Ca++] flux was proportionately reduced.

Light-induced potassium fluxes in the skate retina.

Changes in the extracellular concentration of potassium [K+]0 in response to photic stimulation were studied in the skate retina with the aid of ion-selective electrodes. The results confirm earlier studies in demonstrating that the light-evoked changes originate at three intraretinal sites; an efflux of K+ was recorded in the regions of the two plexiform (synaptic) layers, whereas a decrease in [K+]0 occurred in the extracellular space surrounding the photoreceptors. Prolonged illumination induced long-term alterations in the levels of [K+]0 which, depending upon the retinal depth of the recording electrode, contained contributions from the various sinks and sources of [K+]0. In addition, the marked undershoot of the baseline level of [K+]0 that followed termination of the stimulus suggested the activity of a metabolically driven process for the uptake of extracellular potassium.

Extracellular [K+] fluctuations in voltage-clamped canine cardiac Purkinje fibers.

Membrane currents and extracellular [K+] were measured in canine Purkinje strands during voltage-clamp steps to plateau or diastolic potentials. Extracellular [K+] increased during step depolarizations and decreased during step hyperpolarizations. On hyperpolarization, the largest fraction of the K+ depletion occurred during the initial 500 ms of the voltage-clamp step and was correlated with a potassium depletion current, the id. A slower component of the depletion also occurred on hyperpolarization and had a time constant consistent with cylindrical diffusion of potassium within the Purkinje strands. On depolarization, there is an accumulation of K+ that is correlated with the plateau current ix. On termination of depolarizing test pulses, the K+ accumulation decays with a time course similar to the ix tail current. Surprisingly, no accumulation of K+ occurred during the arrhythmogenic transient inward current, TI, suggesting that the selectivity of this current should be reevaluated.

Effects of phencyclidine on cardiac action potential: pH dependence and structure-activity relationships.

The effects of phencyclidine [1-(1-phenylcyclohexyl)-piperidine; PCP] on cardiac action potential duration (APD) were compared to those of some of its derivatives, in strips of isolated frog ventricular muscle perfused with normal Ringer solution. We studied compounds with PCP-like behavioral actions (N-ethyl-1-phenyl-cyclohexylamine: PCE; and m-amino-PCP) as well as behaviorally inactive analogs (m-nitro-PCP; the quaternary derivative PCP-methyl iodide; and various fragments of the PCP molecule). Exposure to PCP, 3 microM to 1 mM, produced reversible, dose- and pH-dependent prolongations, of the APD to over 100% above control. The observed effects of the drugs are compatible with a mechanism of blockade of potassium conductance. An intracellular site for this action is suggested by: (i) the inactivity of the quaternary analog; (ii) the marked increase in the potency of the compounds when the external pH is changed in the region of their respective pKa values to increase the concentration of the unionized species; and (iii) the pronounced acceleration of the termination of the PCP effect by washout with a series of buffer solutions with decreasing pH values. The rank order of potency of the compounds in lengthening APD (PCE greater than m-amino PCP greater than PCP much much greater than m-nitro-PCP) is the same as reported from other pharmacological studies of specific PCP actions, and matches the rank of behavioral activity of the drugs.

Voltage-clamp studies on the canine Purkinje strand.

Purkinje strands were excised from the left and right ventricles of adult mongrel dogs and cut to lengths of less than 2.0 mm in order to apply the two-microelectrodes voltage-clamp technique. A sizeable fraction of these preparations fully recover following dissection, with resting potentials more negative than--80 mV and upstroke velocities faster than 290 V s-1. Analysis of the voltage response to small current pulses shows that the short Purkinje strands can be treated as simple finite one-dimensional cables with ends of infinite resistance. The average length constant is 2.5 mm. In keeping with the relatively long length constant, insertion of a third microelectrode along the strand demonstrates a high degree of longitudinal homogeneity of the voltage clamp. Analysis of the capacity transient gives an estimate of the total capacity, normalized to cylindrical surface area, of 11.5 muF cm-2. The final decay of the capacity transient is a single exponential with an average time constant of 1 ms. A second slower component to the final decay of the capacity transient is absent in solutions of normal conductivity as well as in solutions of reduced (13%) conductivity. This suggests that the extracellular series resistance may be relatively small. The magnitude of the K+ depletion current was estimated by measuring the ratio of depletion current to instantaneous current. This ratio averaged 10%. These two results are consistent with the morphometric data described in the accompanying paper, which show that the canine preparation has wider extracellular clefts than the ungulate preparation. The existence of the full complement of inward and outward currents, including the pacemaker current, is demonstrated. The presence of wide clefts does not affect the potential at which the pacemaker current reverses (about--107 mV in 4 mM [K+] Tyrode solution), since the pacemaker current reverses at approximately the same potential in the canine Purkinje preparation as it does in the ungulate.