Sodium currents in toad cardiac pacemaker cells

Cells in the pacemaker region of toad (Bufo marinus) sinus venosus had spontaneous rhythmic action potentials. The rate of firing of action potentials, the rate of diastolic depolarization and the maximum rate of rise of action potentials were reduced by TTX (10 nm to 1 m). Currents were recorded with the whole cell, tight seal technique from cells enzymatically dissociated from this region. Cells studied were identified as pacemaker cells by their characteristic morphology, spontaneous rhythmic action potential activity that could be blocked by cobalt but not by TTX and lack of inward rectification. When calcium, potassium and nonselective cation currents (I_f) activated by hyperpolarization were blocked, depolarization was seen to generate transient and persistent inward currents. Both were sodium currents: they were abolished by tetrodotoxin (10 to 100 nm), their reversal potential was close to the sodium equilibrium potential and their amplitude and reversal potential were influenced as expected for sodium currents when extracellular sodium ions were replaced with choline ions. The transient sodium current was activated at potentials more positive than –40 mV while the persistent sodium current was obvious at more negative potentials. It was concluded that, in toad pacemaker cells, TTX-sensitive sodium currents contributing both to the upstroke of action potentials and to diastolic depolarization may play an important role in setting heart rate.We thank the Australian National Heart Foundation for their support. D.A.S. is an NHMRC Senior Research Officer.     

Pacemaker Current in Frog Atrium

PACEMAKER currents have been investigated by voltage clamp studies in Purkinje fibres^1,2 but not in tissues from those regions of the heart where the natural pacemaker lies: the amphibian sinus and mammalian sino-atrial node. Repetitive activity can often be induced in normally quiescent frog atrial trabeculae by application of small depolarizing constant current pulses³. These currents impose on the atrial cells the low membrane potential characteristic of sinus muscle⁴, Moreover, the potential changes involved are very similar to those which may be recorded from spontaneously active sinus, successive action potentials being separated by phases of slow diastolic depolarization⁴ (Fig. 1a). It seems likely therefore that the membrane current controlling this diastolic depolarization in atrium will closely resemble that which generates the natural sinus pacemaker.     

Electrophysiological characteristics of cardiac pacemaker cells of the frog Caudiverbera caudiverbera

1. The cardiac pacemaker cells of the frog Caudiverbera caudiverbera are centrally located in the sinus venosus. These cells are rounded, smaller than contractile fibres and have large nuclei. 2. Intracellular recording confirmed the existence of primary and transitional pacemaker cells. 3. Action potentials from primary cells were resistant to blockade by tetrodotoxin (TTX), but were abolished by verapamil suggesting that their bioelectric activity is dependent on a slow inward current. 4. Transitional cells appeared to have two different inward currents contributing to the upstroke: a fast TTX-sensitive and a slow verapamil-sensitive current.     

On The Mechanism of Spontaneous Impulse Generation in the Pacemaker of the Heart

Rhythmic activity in Purkinje fibers of sheep and in fibers of the rabbit sinus can be produced or enhanced when a constant depolarizing current is applied. When extracellular calcium is reduced successively, the required current strength is less, and eventually spontaneous beating occurs. These effects are believed due to an increase in steady-state sodium conductance. A significant hyperpolarization occurs in fibers of the rabbit sinus bathed in a sodium-free medium, suggesting an appreciable sodium conductance of the "resting" membrane. During diastole, there occurs a voltage-dependent and, to a smaller extent, time-dependent reduction in potassium conductance, and a pacemaker potential occurs as a result of a large resting sodium conductance. It is postulated that the mechanism underlying the spontaneous heart beat is a high resting sodium current in pacemaker tissue which acts as the generator of the heart beat when, after a regenerative repolarization, the decrease in potassium conductance during diastole reestablishes the condition of threshold.     

Effect of formaldehyde and glutaraldehyde on electrical properties of cardiac Purkinje fibers

The effects of formaldehyde, glutaraldehyde, 1-fluoro-2,4-dinitrobenzene, and 1,5-difluoro-2,4-dinitrobenzene on the electrophysiological properties of cardiac Purkinje fibers were studied. At concentrations of 2.5 mM the aldehydes produced a transient hyperpolarization, lengthening of the plateau of the action potential, and an increase in action potential overshoot and upstroke velocity. If exposure to aldehyde was continued, the fiber failed to repolarize after an action potential and the membrane potential stabilized at about -30 mv. If exposure was terminated before this, recovery was usually complete. At the time the fibers were hyperpolarized the input resistance was increased without much change in length constant, leading to an increase in both calculated membrane resistance and calculated core resistance. Although it was anticipated that an effect of the aldehydes on the membrane was to increase fixed negative charge, it was difficult to explain all the electrophysiological changes on this basis. The major effects of the fluorobenzene compounds were not the same; they produced a shortening of the action potential and a rapid loss of excitability.     

Parallel metabotropic pathways in the heart of the toad, Bufo marinus

This study examined the transduction pathways activated by epinephrine in the pacemaker region of the toad heart. Recordings of membrane potential, force, and intracellular Ca(2+) concentration ([Ca(2+)](i)) were made from arrested toad sinus venosus. Sympathetic nerve stimulation activated non-alpha-, non-beta-adrenoceptors to evoke a membrane depolarization and a transient increase in [Ca(2+)](i). In contrast, the beta-adrenoceptor agonist isoprenaline (10 microM) caused membrane hyperpolarization and decreased [Ca(2+)](i). The phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (0.5 mM) mimicked the isoprenaline-evoked membrane hyperpolarization. Epinephrine (10-50 microM) caused an initial membrane depolarization and an increase in [Ca(2+)](i) followed by membrane hyperpolarization and decreased [Ca(2+)](i). The membrane depolarizations evoked by sympathetic nerve stimulation or epinephrine were abolished either by the phospholipase C inhibitor U-73122 (20 microM) or by the blocker of D-myo-inositol 1,4,5,-trisphosphate-induced Ca(2+) release, 2-aminoethoxydiphenyl borate (2-APB, 60 microM). Neither U-73122 nor 2-APB had an affect on the membrane hyperpolarization evoked by beta-adrenoceptor activation. These results suggest that in the toad sinus venosus, two distinct transduction pathways can be activated by epinephrine to cause an increase in heart rate.     

The Electrical Activity of Canine Cardiac Purkinje Fibers in Sodium-Free, Calcium-Rich Solutions

Propagated action potentials can be obtained in canine cardiac Purkinje fibers exposed to Na-free solutions containing no inorganic cation other than Ca and K. Essentially similar action potentials are obtained if Na is replaced by tetraethylammonium (TEA), tetramethylammonium (TMA), or choline. In a solution containing 128 mM TEA and 16.2 mM Ca the characteristics of these electrical responses were: maximum diastolic potential, -59 ± 3.3 mV; overshoot, 20 ± 6.8 mV; maximum upstroke velocity, 3.7 ± 2.3 V/s; conduction velocity, 0.1 m/s; and action potential duration, 360 ± 45 ms. The magnitude of the overshoot varied with log Ca_o with a slope of about 30 mV/10-fold concentration change. The upstroke velocity was an approximately linear function of Ca_o. The active response was greatly diminished or abolished by Mn and D-600 but was unaffected by tetrodotoxin. These Ca-dependent responses appeared in a region of transmembrane potential (about -50 mV) at which the rapid Na-dependent upstroke is abolished even when Na is present.     

Resting membrane potentials of pacemaker and non pacemaker areas in rat uterus

Microelectrode studies of pacemaker and non pacemaker cells in pregnant rat uterus have shown the pacemaker areas to have a constant value of RMP throughout pregnancy which was always significantly smaller than that of non pacemaker cells. The development of new pacemaker areas was associated with membrane depolarization. A number of agents and conditions which caused membrane depolarization also induced pacemaker activity in previously non pacemaker areas but did so at different levels of membrane depolarization. Potassium depolarization failed to induce pacemaker activity. It is concluded that a low level of RMP is an important factor but not sufficient alone to explain the occurence of pacemaker activity.The resting membrane potentials (RMP) of spontaneously active smooth muscles are appreciably smaller than those of nonspontaneously active muscles (3) and comparable in magnitude to those of other tissues showing spontaneous activity such as the frog sinus venosus(7), rabbit sino-auricular node (10) and embryonic heart muscle (6). In intestinal smooth muscle, where all cells appear to be spontaneously active, a clear relationship can be demonstrated between fluctuating levels of RMP and the incidence of action potential activity, and the ionic and metabolic basis of slow wave activity has been extensively investigated (5, 8). In other smooth muscles, such as the ureter and uterus, where electrical activity arises from pacemaker areas (11, 12), the underlying causes of spontaneous activity are less well understood and the relationships between pacemaker activity, RMP and excitability have not been clearly defined. As an initial approach to studying this problem we have chosen to investigate the relationship between RMP and pacemaker activity in the uterus of the pregnant rat.     

Bioelectrical analysis of the regulatory interaction of sympathetic and parasympathetic nervous influences on the heart rhythm]

The changes of chronotropic effect on the isolated sinus node of the frog heart were studied during the separate and simultaneous stimulation of the sympathetic and intracardiac reflex parasympathetic pathways. Intracellular activity of the pacemaker cells was recorded. The separate stimulation of the intracardiac reflex system resulted in bradycardia (in winter) or tachycardia (in summer). Stimulation of sympathetic chain supervening the activation of the intracardiac pathways induced an intensification of both the parasympathetic bradycardia and tachycardia; these effects were cholinergic in nature. The recording of the intracellular pacemaker activity showed the existence of the complicated interaction between the sympathetic and parasympathetic pulse-mediator actions on the heart pacemaker both on the prepulase process and on the membrane polarization and other action potential parameters. Possible mechanisms of this interaction are discussed.     

Conduction Velocity and Intracellular Action Potentials of the Tunicate Heart

The tubular heart of tunicates is composed of a single layer of myoendothelial cells. The direction of contraction reverses every few minutes. The conduction times in both directions are the same. Conduction velocity was greatest in the middle of the arms of the V-shaped heart and slowest in the apex. The greater the heart length, the greater was the conduction velocity. The Q₁₀ of conduction velocity was 2–2.3. Removal of the raphe which attaches the heart to the pericardium and removal of a line of undifferentiated cells opposite the raphe did not change the conduction velocity or prevent the heart from reversing the direction of conduction. The median resting potential of 42 cells was -71 mv and the median action potential was 75 mv. At 20°C the duration of the action potential was 1.2 sec and the maximal rate of depolarization was 3–10 v/sec. An increase in the beat frequency produced by electrically stimulating the heart decreased the resting potential, rate of rise, the duration, and the overshoot of the action potential. The shape of the action potential was sometimes different in the two directions of conduction. The electrophysiological evidence indicates only one cell type and suggests that the mode of the spread of excitation is by local current flow from cell to cell.     

Electrical Characteristics and Activation Potential of Bufo Eggs

Electrical characteristics and their changes during activation were studied with the microelectrodes on the oocytes and eggs of the toad, Bufo vulgaris formosus Boulenger. In young oocytes, the membrane characteristics had some similarities to those of nerve and muscle, except for a relatively large resistance of 25 KΩcm.² and an absence of the action potential in the former. After maturation, however, the membrane characteristics became entirely different from those of oocytes and other excitable tissues. In the mature eggs the membrane resistance was measured to be as high as 200 KΩcm.², and no specific permeability of the membrane to potassium ions was observable. A slow monophasic change in the membrane potential was recorded in every activation produced by mechanical stimulation, and termed "activation potential." In fresh water, its amplitude was as large as 80 to 90 mv. with an overshoot of about 50 mv. The activation potential might be comparable to the action potential of nerve and muscle, but was fundamentally different in ionic mechanism from the latter, since the former was caused by a marked increase in permeability to chloride ions.     

Effects of 8-bromo-cyclic GMP on slow channel mediated action potentials of 3-days-old embryonic chick ventricle.

The role of cyclic GMP in modulation of cardiac slow channel activity was investigated by observing the effects of 8-bromo-cyclic GMP (8-Br-cGMP) on action potentials of isolated ventricle of 3-days-old chick embryo, which exhibit upstroke primarily due to slow channels. 8-Br-cGMP (0.5 & 1 mM) reduced the maximum diastolic potential, maximal upstroke velocity (+Vmax) and overshoot in 30-60 min. 8-Bromo-cyclic AMP (8 Br-cAMP, 0.5 & 1 mM), isoproterenol (Iso, 0.5-5 microM) and forskolin (0.5-2 microM) caused an increase in +Vmax and overshoot. 8-Br-cGMP antagonised this enhancement of +Vmax. Increase in +Vmax and overshoot by Bay-K-8644 (1 microM) was also blocked by 8-Br-cGMP. These findings show that 8-Br-cGMP inhibited the early embryonic cardiac slow channel activity, which contributes significantly to the upstroke of action potential, under basal conditions as well as after its accentuation by elevation of cyclic AMP levels (by 8-Br-cAMP, Iso & Forskolin) or by direct stimulation of the channel activity (by Bay-K-8644). It is suggested on the basis of these findings that cyclic GMP plays a key role in down modulation of the cardiac slow channel activity in early embryonic chick heart.     

Beyond Bowditch: the convergence of cardiac chronotropy and inotropy

The ability of the heart to acutely beat faster and stronger is central to the vertebrate survival instinct. Released neurotransmitters, norepinephrine and epinephrine, bind to beta-adrenergic receptors (beta-AR) on pacemaker cells comprising the sinoatrial node, and to beta-AR on ventricular myocytes to modulate cellular mechanisms that govern the frequency and amplitude, respectively, of the duty cycles of these cells. While a role for sarcoplasmic reticulum Ca(2+) cycling via SERCA2 and ryanodine receptors (RyR) has long been appreciated with respect to cardiac inotropy, recent evidence also implicates Ca(2+) cycling with respect to chronotropy. In spontaneously beating primary sinoatrial nodal pacemaker cells, RyR Ca(2+) releases occurring during diastolic depolarization activate the Na(+)-Ca(2+) exchanger (NCX) to produce an inward current that enhances their diastolic depolarization rate, and thus increases their beating rate. beta-AR stimulation synchronizes RyR activation and Ca(2+) release to effect an increased beating rate in pacemaker cells and contraction amplitude in myocytes: in pacemaker cells, the beta-AR stimulation synchronization of RyR activation occurs during the diastolic depolarization, and augments the NCX inward current; in ventricular myocytes, beta-AR stimulation synchronizes the openings of unitary L-type Ca(2+) channel activation following the action potential, and also synchronizes RyR Ca(2+) releases following depolarization, and in the absence of depolarization, both leading to the generation of a global cytosolic Ca(i) transient of increased amplitude and accelerated kinetics. Thus, beta-AR stimulation induced synchronization of RyR activation (recruitment of additional RyRs to fire) and of the ensuing Ca(2+) release cause the heart to beat both stronger and faster, and is thus, a common mechanism that links both the maximum achievable cardiac inotropy and chronotropy.     

迷走神经对家兔在体心脏心室肌细胞跨膜电位的影响

本研究观察了电刺激迷走神经对家兔在体心脏心室肌细胞跨膜电位的作用及钾通道阻滞剂氯化四乙基铵对这一作用的影响。结果表明,在自然心率条件下,迷走神经刺激可使静息电位(RP)、动作电位振幅(APA)和0相最大上升速率(dv/dt)_(max)增加,动作电位时程(APD)缩短。冠脉注射氯化四乙基铵使心室肌细胞复极过程明显延长,迷走神经刺激不再引起 RP、APA 增大,动作电位时程不再缩短,(dv/dt)_(max)反而减小。这些结果提示,迷走神经刺激对正常心室肌细胞跨膜电位的影响可能是通过外向 K~ 流增加引起的。     

Membrane Currents in Mammalian Ventricular Heart Muscle Fibers Using a Voltage-Clamp Technique

Bundles of sheep ventricular fibers were voltage-clamped utilizing a modified sucrose gap technique and intracellular voltage control. An action potential was fired off in the usual way, and the clamp circuit was switched on at preselected times during activity. Clamping the membrane back to its resting potential during the early part of an action potential resulted in a surge of inward current. The initial amplitude of this current surge decreased as the clamp was switched on progressively later during the action potential. Inward current decreasing as a function of time was also recorded if the membrane potential was clamped beyond the presumed K equilibrium potential (to -130 mv). Clamping the membrane to the inside positive range (+40 mv to +60 mv) at different times of an action potential resulted in a step of outward current which was not time-dependent. The results suggest that normal repolarization of sheep ventricle depends on a time-dependent decrease of inward current (Na, Ca) rather than on a time-dependent increase of outward current (K).     

The control of membrane ionic currents by the membrane potential of muscle

Comparisons between electrotronic potentials and certain predicted curves allow the identification of the membrane potential at which the sodium and potassium currents are switched on in frog sartorius. The activation potentials (the membrane potentials at which the ionic currents are great enough to be resolved by the method) are functions of the resting potential and time but not of ionic concentration. In the normal fiber, the activation potential for sodium lies nearer the resting potential and depolarizations set off sodium currents and action potentials. Below a resting potential of 55 to 60 mv. sodium activation is lost and conduction is impossible. A tenfold increase of calcium concentration lowers (moves further from the resting potential) the sodium activation potential by 20 to 25 mv. whereas the potassium activation potential is lowered by only 15 mv. Certain consequences of this are seen in the behavior of the muscle cell when it is stimulated with long duration shock.     

Diastolic calcium release controls the beating rate of rabbit sinoatrial node cells: numerical modeling of the coupling process

Recent studies employing Ca2+ indicators and confocal microscopy demonstrate substantial local Ca2+ release beneath the cell plasma membrane (subspace) of sinoatrial node cells (SANCs) occurring during diastolic depolarization. Pharmacological and biophysical experiments have suggested that the released Ca2+ interacts with the plasma membrane via the ion current (INaCa) produced by the Na+/Ca2+ exchanger and constitutes an important determinant of the pacemaker rate. This study provides a numerical validation of the functional importance of diastolic Ca2+ release for rate control. The subspace Ca2+ signals in rabbit SANCs were measured by laser confocal microscopy, averaged, and calibrated. The time course of the subspace [Ca2+] displayed both diastolic and systolic components. The diastolic component was mainly due to the local Ca2+ releases; it was numerically approximated and incorporated into a SANC cellular electrophysiology model. The model predicts that the diastolic Ca2+ release strongly interacts with plasma membrane via INaCa and thus controls the phase of the action potential upstroke and ultimately the final action potential rate.     

Electrical and Mechanical Responses in Deep Abdominal Extensor Muscles of Crayfish and Lobster

Electrical and mechanical studies have been made of the deep abdominal extensor muscles, medial (DEAM) and lateral (DEAL), of crayfish and lobster. The medial muscle responds to direct (intracellular) and indirect stimulation with a transient membrane depolarization which exhibits the properties of a propagated non-decremental action potential but does not overshoot the zero level. The amplitude is about 30 mv in crayfish and 50 mv in lobster. It is followed by a fast all-or-none twitch whose duration at 20°C is 30 to 50 msec. and whose developed tension is 500 gm/cm² or about half the tetanic value. Membrane potential is K⁺-dependent and immersion in high K⁺ induces a brief transient tension rise as in other twitch-type muscles. The action potential and twitch are normal even if all external Na⁺ is replaced with sucrose but vary with external Ca⁺⁺, the action potential increasing 8 to 10 mv for a twofold increase in Ca⁺⁺. The lateral muscle (DEAL) is much slower and responds to intracellular stimulation only with an electrotonic or a local response. Mechanical responses and relaxation speeds are slow with minimal duration of contraction of 0.5 to 2 seconds. Immersion in high K solutions induces large maintained tensions. Sarcomere length in the fast DEAM is uniform and about 2 µ at rest, but in the DEAL speed is less and sarcomere length is greater averaging about 4.5 µ but with a mixed population of fibers.