Effects of rapid changes of external Na+ concentration at different moments during the action potential in guinea-pig myocytes

Activation of hTREK-1 by polyunsaturated fatty acids involves direct interaction

TREK-1 is a mechanosensitive channel activated by polyunsaturated fatty acids (PUFAs). Its activation is supposed to be linked to changes in membrane tension following PUFAs insertion. Here, we compared the effect of 11 fatty acids and ML402 on TREK-1 channel activation using the whole cell and the inside-out configurations of the patch-clamp technique. Firstly, TREK-1 activation by PUFAs is variable and related to the variable constitutive activity of TREK-1. We observed no correlation between TREK-1 activation and acyl chain length or number of double bonds suggesting that the bilayer-couple hypothesis cannot explain by itself the activation of TREK-1 by PUFAs. The membrane fluidity measurement is not modified by PUFAs at 10 µM. The spectral shift analysis in TREK-1-enriched microsomes indicates a KD,TREK1 at 44 µM of C22:6 n-3. PUFAs display the same activation and reversible kinetics than the direct activator ML402 and activate TREK-1 in both whole-cell and inside-out configurations of patch-clamp suggesting that the binding site of PUFAs is accessible from both sides of the membrane, as for ML402. Finally, we proposed a two steps mechanism: first, insertion into the membrane, with no fluidity or curvature modifications at 10 µM, and then interaction with TREK-1 channel to open it.

Calcium signaling in taste cells

The sense of taste is a common ability shared by all organisms and is used to detect nutrients as well as potentially harmful compounds. Thus taste is critical to survival. Despite its importance, surprisingly little is known about the mechanisms generating and regulating responses to taste stimuli. All taste responses depend on calcium signals to generate appropriate responses which are relayed to the brain. Some taste cells have conventional synapses and rely on calcium influx through voltage-gated calcium channels. Other taste cells lack these synapses and depend on calcium release to formulate an output signal through a hemichannel. Beyond establishing these characteristics, few studies have focused on understanding how these calcium signals are formed. We identified multiple calcium clearance mechanisms that regulate calcium levels in taste cells as well as a calcium influx that contributes to maintaining appropriate calcium homeostasis in these cells. Multiple factors regulate the evoked taste signals with varying roles in different cell populations. Clearly, calcium signaling is a dynamic process in taste cells and is more complex than has previously been appreciated. This article is part of a Special Issue entitled: 13th European Symposium on Calcium.

Dendritic mechanisms contribute to stimulus-specific adaptation in an insect neuron

Reduced neuronal activation to repetitive stimulation is a common feature of information processing in nervous systems. Such stimulus-specific adaptation (SSA) occurs in many systems, but the underlying neural mechanisms are not well understood. The Neoconocephalus (Orthoptera, Tettigoniidae) TN-1 auditory neuron exhibits an SSA-like process, characterized by reliably detecting deviant pulses after response cessation to common standard pulses. Therefore, TN-1 provides a model system to study the cellular mechanisms underlying SSA with an identified neuron. Here we test the hypothesis that dendritic mechanisms underlie TN-1 response cessation to fast-pulse rate repeated signals. Electrically stimulating TN-1 with either high-rate or continuous-current pulses resulted in a decreased ability in TN-1 to generate action potentials but failed to elicit cessation of spiking activity as observed with acoustic stimulation. BAPTA injection into TN-1 delayed the onset of response cessation to fast-pulse rate acoustic stimuli in TN-1 but did not eliminate it. These results indicate that calcium-mediated processes contribute to the fast cessation of spiking activity in TN-1 but are insufficient to cause spike cessation on its own. Replacing normal saline with low-Na(+) saline (replacing sodium chloride with either lithium chloride or choline chloride) eliminated response cessation, and TN-1 no longer responded selectively to the deviant pulses. Sodium-mediated potassium channels are the most likely candidates underlying sodium-mediated response suppression in TN-1, triggered by Na(+) influx in dendritic regions activated by acoustic stimuli. On the basis of these results, we present a model for a cellular mechanism for SSA in a single auditory neuron.

Successes and failures in modeling heart cell electrophysiology

Mathematical models of the electrical activity of the heart using equations for protein ion channels and other transporters began with the Noble 1962 model. These models then developed over a period of about 50 years. Cell types in all regions have been modeled and now are available for download from the CellML website (www.cellml.org). Simulation is a necessary tool of analysis in attempting to understand biological complexity. We often learn as much from the failures as from the successes of mathematical models. It is the iterative interaction between experiment and simulation that is important.

The electrogenic Na+/HCO3- cotransport modulates resting membrane potential and action potential duration in cat ventricular myocytes

Perforated whole-cell configuration of patch clamp was used to determine the contribution of the electrogenic Na+/HCO3- cotransport (NBC) on the shape of the action potential in cat ventricular myocytes. Switching from Hepes to HCO3- buffer at constant extracellular pH (pH(o)) hyperpolarized resting membrane potential (RMP) by 2.67 +/- 0.42 mV (n = 9, P < 0.05). The duration of action potential measured at 50% of repolarization time (APD50) was 35.8 +/- 6.8% shorter in the presence of HCO3- than in its absence (n = 9, P < 0.05). The anion blocker SITS prevented and reversed the HCO3- -induced hyperpolarization and shortening of APD. In addition, no HCO3- -induced hyperpolarization and APD shortening was observed in the absence of extracellular Na+. Quasi-steady-state currents were evoked by 8 s duration voltage-clamped ramps ranging from -130 to +30 mV. A novel component of SITS-sensitive current was observed in the presence of HCO3-. The HCO3- -sensitive current reversed at -87 +/- 5 mV (n = 7), a value close to the expected reversal potential of an electrogenic Na+/HCO3- cotransport with a HCO3-:Na+ stoichiometry ratio of 2: 1. The above results allow us to conclude that the cardiac electrogenic Na+/HCO3- cotransport has a relevant influence on RMP and APD of cat ventricular cells.

From the Hodgkin-Huxley axon to the virtual heart

Experimentally based models of the heart have been developed since 1960, starting with the discovery and modelling of potassium channels. The early models were based on extensions of the Hodgkin-Huxley nerve impulse equations. The first models including calcium balance and signalling were made in the 1980s and have now reached a high degree of physiological detail. During the 1990s these cell models have been incorporated into anatomically detailed tissue and organ models to create the first virtual organ, the Virtual Heart. With over 40 years of interaction between simulation and experiment, the models are now sufficiently refined to begin to be of use in drug development.

Fundamental importance of Na+-Ca2+ exchange for the pacemaking mechanism in guinea-pig sino-atrial node

Na+-Ca2+ exchange (NCX) current has been suggested to play a role in cardiac pacemaking, particularly in association with Ca2+ release from the sarcoplasmic reticulum (SR) that occurs just before the action potential upstroke. The present experiments explore in more detail the contribution of NCX to pacemaking. Na+-Ca2+ exchange current was inhibited by rapid switch to low-Na+ solution (with Li+ replacing Na+) within the time course of a single cardiac cycle to avoid slow secondary effects. Rapid switch to low-Na+ solution caused immediate cessation of spontaneous action potentials. ZD7288 (3 microM), to block I(f) (funny current) channels, slowed but did not stop the spontaneous activity, and tetrodotoxin (10 microM), to block Na+ channels, had little effect, but in the presence of either of these agents, rapid switch to low-Na+ solution again caused immediate cessation of spontaneous action potentials. Spontaneous electrical activity was also stopped following loading of the cells with the Ca2+ chelators BAPTA and EGTA, and by exposure to the NCX inhibitor KB-R7943 (5 microM). When rapid switch to low-Na+ solution caused cessation of spontaneous activity, this was found (using confocal microscopy, with fluo-4 as the Ca2+ probe) to be accompanied by an initial fall in cytosolic [Ca2+], with subsequent appearance of Ca2+ waves. Inhibition of SR Ca2+ uptake with cyclopiazonic acid (CPA, 30 microM) slowed but did not stop spontaneous activity. Rapid switch to low-Na+ solution in the presence of CPA caused abolition of spontaneous Ca2+ transients and a progressive rise in cytosolic [Ca2+]. With ratiometric fluorescence methods (indo-5F as the Ca2+ probe), the minimum level of [Ca2+] between beats was found to be approximately 225 nM, and abolition of beating with nifedipine, acetylcholine or adenosine caused a fall in cytosolic [Ca2+] below this level. These observations support the hypothesis that NCX current is essential for normal pacemaker activity under the conditions of our experiments. A continuous depolarizing influence of current through the NCX protein might result from maintained electrogenic NCX (with 3:1 stoichiometry, supported by a cytosolic [Ca2+] that normally does not fall below 225 nM between beats) and/or from a novel, recently suggested role of the NCX protein to allow a Na+ leak pathway.

Ca2+ currents in cardiac myocytes: Old story, new insights

Calcium is a ubiquitous second messenger which plays key roles in numerous physiological functions. In cardiac myocytes, Ca2+ crosses the plasma membrane via specialized voltage-gated Ca2+ channels which have two main functions: (i) carrying depolarizing current by allowing positively charged Ca2+ ions to move into the cell; (ii) triggering Ca2+ release from the sarcoplasmic reticulum. Recently, it has been suggested than Ca2+ channels also participate in excitation-transcription coupling. The purpose of this review is to discuss the physiological roles of Ca2+ currents in cardiac myocytes. Next, we describe local regulation of Ca2+ channels by cyclic nucleotides. We also provide an overview of recent studies investigating the structure-function relationship of Ca2+ channels in cardiac myocytes using heterologous system expression and transgenic mice, with descriptions of the recently discovered Ca2+ channels alpha(1D) and alpha(1E). We finally discuss the potential involvement of Ca2+ currents in cardiac pathologies, such as diseases with autoimmune components, and cardiac remodeling.

Modeling the Heart

Models of the heart have been developed since 1960, starting with the discovery and modeling of potassium channels. The first models of calcium balance were made in the 1980s and have now reached a high degree of physiological detail. During the 1990s, these cell models were incorporated into anatomically detailed tissue and organ models.

Effects of Na+/Ca2+ exchange induced by SR Ca2+ release on action potentials and afterdepolarizations in guinea pig ventricular myocytes

In cardiac cells, evoked Ca2+ releases or spontaneous Ca2+ waves activate the inward Na+/Ca2+ exchange current (INaCa), which may modulate membrane excitability and arrhythmogenesis. In this study, we examined changes in membrane potential due to INaCa elicited by sarcoplasmic reticulum (SR) Ca2+ release in guinea pig ventricular myocytes using whole cell current clamp, fluorescence, and confocal microscopy. Inhibition of INaCa by Na+-free, Li+-containing Tyrode solution reversibly abbreviated the action potential duration at 90% repolarization (APD90) by 50% and caused SR Ca2+ overload. APD90 was similarly abbreviated in myocytes exposed to the Na+/Ca2+ exchange inhibitor KB-R7943 (5 microM) or after inhibition of SR Ca2+ release with ryanodine (20 microM). In the absence of extracellular Na+, spontaneous SR Ca2+ releases caused minimal changes in resting membrane potential. After the myocytes were returned to Na+-containing solution, the potentiated intracellular Ca2+ concentration ([Ca2+]i) transients dramatically prolonged APD90 and [Ca2+]i oscillations caused delayed and early afterdepolarizations (DADs and EADs). Laser-flash photolysis of caged Ca2+ mimicked the effects of spontaneous [Ca2+]i oscillations, confirming that APD prolongation, DADs, and EADs could be ascribed to intracellular Ca2+ release. These results suggest that Na+/Ca2+ exchange is a major physiological determinant of APD and that INaCa activation by spontaneous SR Ca2+ release/oscillations, depending on the timing, can account for both DADs and EADs during SR Ca2+ overload.

Multitrack system for superfusing isolated cardiac myocytes

A new system for studying mechanical activity of freshly isolated cardiac myocytes from up to four experimental groups simultaneously is described. Suspensions of cardiac myocytes isolated from adult rat hearts were drawn into microhematocrit capillary tubes, which were then mounted in parallel fashion between two four-channel tubing manifolds placed on the movable stage of an inverted microscope. Within a few minutes, cells settled and attached to the bottom of the tubes and then could be superfused with various test solutions. The system allowed for electrical field stimulation, rapid changes in bathing solutions, control of temperature, and simulation of ischemia and reperfusion with measurements of the effects of such interventions on both populations of cells (low power survey) and individual myocytes (high power). Myocyte responses to these various interventions are described. The primary advantage of this system is the ability to conduct experiments on cardiac myocytes isolated concurrently from multiple experimental groups at the same time and under identical conditions.

Modelling the heart: insights, failures and progress

Mathematical models of the heart have developed over a period of about 40 years. Cell types in all regions of the heart have been modelled and they are now being incorporated into anatomically detailed models of the whole organ. This combination is leading to the creation of the first 'virtual organ,' which is being used in drug discovery and testing, and in simulating the action of devices, such as cardiac defibrillators. Simulation is a necessary tool of analysis in attempting to understand biological complexity. We often learn as much from the failures as from the successes of mathematical models. It is the iterative interaction between experiment and simulation that is important. Examples are given where this process has been instrumental in some of the major advances in the field.

Simple experiments to understand the ionic origins and characteristics of the ventricular cardiac action potential

Electrophysiological experiments are helpful for students to understand the role of electrical activity in heart function. Papillary muscle, which belongs to the ventricle, offers the advantage of being easily studied using glass microelectrodes. In addition, there is commercially available software that simulates ventricular electrical activity and can help overcome some difficulties, such as voltage clamp experiments, which need expensive apparatus when used for studies on living preparations. Here, we present a class practical session that is taken by undergraduate students at our University. In the first part of this class, students record action potentials from papillary muscles with the use of glass microelectrodes, and they change extracellular conditions to study the ionic basis of the action potential. In the second part of the class, students simulate action potentials using the Oxsoft Heart model (v. 4.0) and model their previous experiments on papillary muscle to quantify the effects. In particular, the model is very helpful in promoting understanding of the effect that extracellular potassium has on cardiac action potential by simulating voltage clamp experiments. This twin approach of papillary muscle experiments and computer modeling leads to a good understanding of the functioning of the action potential and can help introduce discussion of some abnormal cardiac functioning.

Functional differences between cardiac and renal isoforms of the rat Na+-Ca2+ exchanger NCX1 expressed in Xenopus oocytes

The transcript of the Na+-Ca2+ exchanger gene NCX1 undergoes alternative splicing to produce tissue-specific isoforms. The cloned NCX1 isoforms were expressed in Xenopus oocytes and studied using a two-electrode voltage clamp method to measure Na+-Ca2+ exchanger activity. The cardiac isoform (NCX1.1) expressed in oocytes was less sensitive to depolarizing voltages and to activation by [Ca2+]i than the renal isoform (NCX1.3). The cardiac isoform of NCX1 is more sensitive to activation by protein kinase A (PKA) than the renal isoform which may be explained by preferential phosphorylation. The cardiac isoform of NCX1 is phosphorylated to a greater extent than the renal isoform. The action of PKA phosphorylation which increases the activity of the cardiac isoform of the Na+-Ca2+ exchanger in oocytes was confirmed in adult rat ventricular cardiomyocytes by measuring Na+-dependent Ca2+ flux. We conclude that alternative splicing of NCX1 confers distinct functional characteristics to tissue-specific isoforms of the Na+-Ca2+ exchanger.

Calcium-dependent modulation of the plateau phase of action potential in isolated ventricular cells of rabbit heart

[Ca2+]i-dependent modulation of the action potential has been studied in Fura-2 dialysed ventricular myocytes of the rabbit using the whole-cell current-clamp method. Fifteen consecutive action potentials (AP1-AP15) and [Ca2+]i transients were elicited at a frequency of 0.2 Hz. A single, brief application of caffeine (during AP9) first enhanced and thereafter attenuated the [Ca2+]i transients accompanying AP9 and AP10-AP12, respectively. This approach provided direct comparison between time courses of action potentials: during the initial steady state (e.g. AP8) and when Ca2+ release from the sarcoplasmic reticulum was increased by caffeine (AP9) or decreased by depletion (AP10). The increase in [Ca2+]i facilitated repolarization and decreased action potential duration. However, action potentials at reduced Ca2+ release (AP10) had longer duration than during steady state. The caffeine-induced changes in L-type Ca2+ current (ICa,L), during voltage-clamp conditions partially explained the effects of caffeine on action potentials. When ICa,L was blocked by 500 micromol L-1 Cd2+, enhanced [Ca2+]i transients revealed an extra current component which was outward at +10 mV and inward at the resting membrane potential (most probably the transient inward current). In the presence of Cd2+, however, AP8 and AP10 had identical time courses, suggesting that ICa,L alone was responsible for the lengthening of AP10. Alterations in the transmembrane Na+ gradient resulted in changes of the steady state action potential durations (AP8) consistently with the expected modulation of the Na+-Ca2+ exchange current. However, the contribution of this current to the [Ca2+]i-dependent behaviour of action potential plateau could not be demonstrated.

The role of Na(+)-Ca2+ exchange current in electrical restitution in ferret ventricular cells

1. The mechanisms underlying electrical restitution (recovery of action potential duration after a preceding beat) were investigated in ferret ventricular cells. The time to 80% recovery (t80) of action potential duration was approximately 204 ms. 2. At a holding potential of -80 mV, the Ca2+ current (ICa) reactivated and the delayed rectifier K+ current (IK) deactivated very rapidly (t80: approximately 32 and approximately 93 ms, respectively). The kinetics of both currents are too fast to account for electrical restitution alone. 3. The putative inward Na(+)-Ca2+ exchange current (INa-Ca) produced by the Na(+)-Ca2+ exchanger in response to the intracellular Ca2+ transient reprimed (t80: 189 ms) with the same time course as mechanical restitution (recovery of contraction) and with a similar time course to electrical restitution. 4. Substantial reduction of inward INa-Ca, by buffering intracellular Ca2+ with the acetyl methyl ester form of BAPTA, shortened the action potential and greatly altered the electrical restitution curve. Subsequent addition of nifedipine (to block ICa) or 4-aminopyridine (4-AP) (to block the transient outward current, ITO) further altered the electrical restitution curve. 5. Any time-dependent current that contributes to the action potential is likely to affect the time course of electrical restitution. Although ICa, IK and ITO were previously thought to be the only currents involved in electrical restitution, we conclude that inward INa-Ca also plays an important role.

The role of inward Na(+)-Ca2+ exchange current in the ferret ventricular action potential

1. Inward Na(+)-Ca2+ exchange current (iNaCa) was either blocked in ferret ventricular cells by replacing extracellular Na+ with Li+ or substantially reduced by the almost complete elimination of the Ca2+ transient by buffering intracellular Ca2+ with the acetoxymethyl ester form of BAPTA (BAPTA AM). 2. During square wave voltage clamp pulses to 0 mV, replacing extracellular Na+ with Li+ or buffering intracellular Ca2+ with BAPTA AM resulted in the loss of a transient inward current. This current was increased by the application of isoprenaline (expected to increase the underlying Ca2+ transient) and displayed the voltage-dependent characteristics of inward iNaCa. 3. Replacing extracellular Na+ with Li+ or buffering intracellular Ca2+ caused a significant shortening of the action potential (at -65 mV, 44 +/- 2% with Li+ and 20 +/- 2% with BAPTA AM). The shortening can be explained by changes in iNaCa. 4. The action potential clamp technique was used to measure the BAPTA-sensitive current (putative iNaCa) and the Ca2+ current (ica; measured using nifedipine) during the action potential. Under control conditions, the inward BAPTA-sensitive current makes approximately the same contribution as iCa during much of the action potential plateau. These results suggest an important role for inward iNaCa in the ferret ventricular action potential.

Re-entrant activity and its control in a model of mammalian ventricular tissue

We characterize the meander of re-entrant excitation in a model of a sheet of mammalian ventricular tissue, and its control by resonant drift under feedback driven stimulation. The Oxsoft equations for excitability in a guinea pig single ventricular cell were incorporated in a two dimensional reaction-diffusion system to model homogeneous, isotropic tissue with a plane wave conduction velocity of 0.35 m s-1. Re-entrant spiral wave solutions have a spatially extended transient motion (linear core) that settles down into rotation with an irregular period of 100-110 ms around an irregular, multi-lobed spiky core. In anisotropic tissue this would appear as a linear conduction block. The typical velocity of drift of the spiral wave induced by low amplitude resonant forcing is 0.4 cm s-1.

A method for making rapid changes of superfusate whilst maintaining temperature at 37 degrees C

We have developed a technique for making a rapid solution change, whilst at the same time maintaining the temperature of the preparation at 37 degrees C. It is technically difficult to use rapid solution changes when experiments are performed at normal mammalian body temperature. As a solution is heated from room temperature to 37 degrees C, gas bubbles form in the rapid-flowing solution streams, and these disturb a cell or attached recording pipettes. We describe a system that has been developed to eliminate these problems. We show how to construct the different components of the system, and we have designed an electronic circuit to control solution changes. We have performed tests to characterise the function of this system. Solution flow out of the nozzle of the device (0.88 ml min-1, linear flow velocity 11.6 cm s-1) caused a fall in the steady-state temperature at the experimental preparation of only 0.3 degrees C. The device which takes between 0.5 and 1 s to completely change the superfusate of a single cell, was used routinely with five different experimental solutions. This system may be valuable in studies which require rapid solution changes to be performed at a normal mammalian body temperature.

Effect on the fura-2 transient of rapidly blocking the Ca2+ channel in electrically stimulated rabbit heart cells

1. We used a rapid solution switcher technique to investigate mechanisms that might trigger intracellular Ca2+ release in rabbit ventricular myocytes. The study was carried out at 36 degrees C, intracellular Ca2+ (Ca2+i) was monitored with fura-2, and myocytes were electrically stimulated. 2. In patch-clamped cells, using the switcher to apply 20 microM nifedipine (an L-type Ca2+ current (ICa,L) blocker) 4 s before a depolarization to +10 mV reduced the amplitude of ICa,L to 10.25 +/- 2.25% of control (mean +/- S.E.M., n = 7 cells). 3. In externally stimulated cells, a rapid switch to 20 microM nifedipine 4 s before a stimulus reduced the amplitude of the fura-2 transient to 64.01 +/- 2.09% of control (mean +/- S.E.M., n = 19 cells). Using an in vivo calibration curve for fura-2, this was equivalent to a reduction in the Ca2+ transient to 50% during nifedipine application. Since an identical nifedipine switch reduced ICa,L to 10.25%, it would seem that blocking a large fraction of ICa,L inhibited only half the Ca2+ transient. 4. The Na(+)-Ca2+ exchanger is inhibited by 5 mM nickel. Switching to 20 microM nifedipine +5 mM nickel 4 s before a stimulus abolished the fura-2 transient completely, consistent with the hypothesis that Ca2+ entry via reverse Na(+)-Ca2+ exchange might trigger a fraction of the fura-2 transient that remained during nifedipine. 5. After the Na(+)-K+ pump was inhibited by strophanthidin to increase intracellular Na+ (Na+i), a switch to 20 microM nifedipine became progressively less effective in reducing the fura-2 transient. This suggests that as Na+i rose, other mechanisms (perhaps reverse Na(+)-Ca2+ exchange) appeared able to substitute for ICa,L in triggering the Ca2+ transient. 6. In cells depleted of Nai+ to inhibit the triggering of sarcoplasmic reticulum (SR) Ca2+ release by reverse Na(+)-Ca2+ exchange, a nifedipine switch reduced the fura-2 transient to 10.9 +/- 4.19% (mean +/- S.E.M., n = 7; equivalent to 6.5% of the Ca2+ transient). 7. A switch to Na(+)-free (Li+) solution 100 ms before an electrical stimulus caused an increase in the fura-2 transient of 12.2 +/- 1.5% (mean +/- S.E.M., n = 7; equivalent to a 22% increase in the Ca2+ transient). 8. The results confirm that ICa,L is an important trigger for SR Ca2+ release and the resulting Ca2+ transient. However, since 50% of the Ca2+ transient remained when ICa,L was largely inhibited, it would seem likely that other SR trigger mechanisms might exist in addition. These data are consistent with the idea that Ca2+ entry via reverse Na(+)-Ca2+ exchange during the upstroke of the normal cardiac action potential might trigger a fraction of SR Ca2+ release and the resulting Ca2+ transient.

The effect of internal sodium and caesium on phasic contraction of patch-clamped rabbit ventricular myocytes

1. The voltage dependence of phasic contraction was assessed in rabbit ventricular myocytes. Phasic contraction at all potentials was abolished by exposure to ryanodine-thapsigargin, showing that it was due primarily to Ca2+ release from the sarcoplasmic reticulum (SR). Experiments were performed at 35 degrees C, cells were whole-cell patch clamped and contraction was measured optically as unloaded shortening. Cells were held at -40 mV to inactivate the Na+ current (INa) and T-type Ca2+ current. A standard cellular Ca2+ load was established by applying a train of conditioning pulses at 0.5 Hz before each test pulse. The effect of replacing K+ with Cs+ in the dialysing pipette solution, and the effect of altering dialysing [Na+] between 0 and 20 mM, was assessed on contraction. 2. Cells dialysed with a K(+)-based, Na(+)-free solution exhibited a 'bell-shaped' voltage dependence of the L-type Ca2+ channel current (ICa,L), with a maximum ICa,L at +10 mV. Replacing internal K+ with Cs+, or altering pipette [Na+], did not affect the voltage dependence of ICa,L. 3. The voltage dependence of phasic contraction in cells dialysed with a K(+)-based solution was modulated by pipette [Na+]. The voltage dependence of phasic contraction was bell-shaped with 0 Na+, became much loss bell-shaped with 10 mM Na+ and with 20 mM Na+ the phasic contraction elicited at +100 mV was 1.6-fold larger than that at +10 mV. 4. Replacing 80% of K+ with Cs+ in the pipette dialysis solution led to a significant reduction in contraction amplitude and a more rapid decline in contraction amplitude after beginning the dialysis of the cell. 5. Cells dialysed with a Cs(+)-based solution displayed a voltage dependence of phasic contraction which was more bell-shaped (i.e. more similar to that of ICa,L) than that obtained with the corresponding K(+)-based dialysis solution. The level of pipette [Na+] still modulated the voltage dependence of phasic contraction in cells dialysed with a Cs(+)-based solution. 6. Time-to-peak contraction (tpk) also displayed voltage dependence; it had a minimum value between 0 and +20 mV (the voltage range for maximum ICa,L), but increased at more negative and positive potentials. Alteration of tpk contraction is discussed in relation to the stochastic behaviour of L-type Ca2+ channels and SR Ca2+ release channels. 7. The shape of the voltage dependence of contraction in rabbit myocytes at 35 degrees C is modulated by dialysing [Na+] over the tested range, 0-20 mM. Modulation of voltage dependence of contraction by dialysing [Na+] is consistent with an influence of reverse Na(+)-Ca2+ exchange in triggering intracellular Ca2+ release, in addition to the trigger Ca2+ which enters via ICa,L. 8. The marked effect of dialysing Cs+ on contraction amplitude, and on the voltage dependence of phasic contraction, does not appear to have been reported previously. Internal dialysis with Cs+ is a commonly used technique for blocking interfering outward K+ currents, in order to measure ICa,L more selectively. The present study suggests that Cs+ might also interfere with processes involved in excitation-contraction coupling and indicates that it might be wise to exercise caution with the use of internal Cs+ in experiments investigating excitation-contraction coupling.

Effects of action potential duration on excitation-contraction coupling in rat ventricular myocytes. Action potential voltage-clamp measurements

Although each of the fundamental processes involved in excitation-contraction coupling in mammalian heart has been identified, many quantitative details remain unclear. The initial goal of our experiments was to measure both the transmembrane Ca2+ current, which triggers contraction, and the Ca2+ extrusion due to Na(+)-Ca2+ exchange in a single ventricular myocyte. An action potential waveform was used as the command for the voltage-clamp circuit, and the membrane potential, membrane current, [Ca2+]i, and contraction (unloaded cell shortening) were monitored simultaneously. Ca(2+)-dependent membrane current during an action potential consists of two components: (1) Ca2+ influx through L-type Ca2+ channels (ICa-L) during the plateau of the action potential and (2) a slow inward tail current that develops during repolarization negative to approximately -25 mV and continues during diastole. This slow inward tail current can be abolished completely by replacement of extracellular Na+ with Li+, suggesting that it is due to electrogenic Na(+)-Ca2+ exchange. In agreement with this, the net charge movement corresponding to the inward component of the Ca(2+)-dependent current (ICa-L) was approximately twice that during the slow inward tail current, a finding that is predicted by a scheme in which the Ca2+ that enters during ICa is extruded during diastole by a 3 Na(+)-1 Ca2+ electrogenic exchanger. Action potential duration is known to be a significant inotropic variable, but the quantitative relation between changes in Ca2+ current, action potential duration, and developed tension has not been described in a single myocyte. We used the action potential voltage-clamp technique on ventricular myocytes loaded with indo 1 or rhod 2, both Ca2+ indicators, to study the relation between action potential duration, ICa-L, and cell shortening (inotropic effect). A rapid change from a "short" to a "long" action potential command waveform resulted in an immediate decrease in peak ICa-L and a marked slowing of its decline (inactivation). Prolongation of the action potential also resulted in slowly developing increases in the magnitude of Ca2+ transients (145 +/- 2%) and unloaded cell shortening (4.0 +/- 0.4 to 7.6 +/- 0.4 microns). The time-dependent nature of these effects suggests that a change in Ca2+ content (loading) of the sarcoplasmic reticulum is responsible. Measurement of [Ca2+]i by use of rhod 2 showed that changes in the rate of rise of the [Ca2+]i transient (which in rat ventricle is due to the rate of Ca2+ release from the sarcoplasmic reticulum) were closely correlated with changes in the magnitude and the time course of ICa-L.(ABSTRACT TRUNCATED AT 400 WORDS)