A. W. Trafford

Measurement of sarcoplasmic reticulum Ca2+ content and sarcolemmal Ca2+ fluxes in isolated rat ventricular myocytes during spontaneous Ca2+ release.

1 Intracellular calcium concentration ([Ca2+]i) and Na+–Ca2+ exchange currents were measured in calcium‐overloaded voltage‐clamped rat ventricular myocytes loaded with the Ca2+sensitive fluorescent indicator indo‐1. Sarcoplasmic reticulum (SR) Ca2+ content was measured from the integral of the caffeineevoked current. In cells that had spontaneous SR Ca2+ release in 1 mm external Ca2+ concentration ([Ca2+]o), raising [Ca2+]o increased the frequency of release with no effect on SR Ca2+ content. In quiescent cells, increased [Ca2+]o produced spontaneous Ca2+ release associated with increased SR Ca2+ content. Further increase of [Ca2+]o had no effect on SR Ca2+ content. The amount of Ca2+ leaving the cell during each release was constant over a wide range of frequencies and [Ca2+]o values. It appears there is a maximum level of SR Ca2+ content, perhaps because spontaneous Ca2+ release results when the content reaches a threshold. 2 From the relationship between [Ca2+]i and Na+–Ca2+ exchange current during a caffeine response, it is possible to estimate the changes in Na+–Ca2+ exchange current expected from a change of [Ca2+]i. The data show that the calcium oscillations contribute a significant fraction of the total extra Ca2+ efflux induced by increasing [Ca2+]o. Raising [Ca2+]o decreased the rate of calcium removal from the cell as measured from the rate of decay of the caffeine response, suggesting that both inhibition of Ca2+ efflux and increased Ca2+ entry account for the Ca2+ overload at elevated [Ca2+]o. 3 Inhibiting spontaneous SR Ca2+ release increases resting [Ca2+]i. The Ca2+ efflux is identical to that in the presence of release. It is concluded that spontaneous release of calcium, although potentially arrhythmogenic, is an effective way to activate Ca2+ efflux in overloaded conditions and minimizes any increase of diastolic tension.

A novel, rapid and reversible method to measure Ca buffering and time-course of total sarcoplasmic reticulum Ca content in cardiac ventricular myocytes

Abstract This paper outlines a simple method of estimating both the Ca-buffering properties of the cytoplasm and the time-course of changes of sarcoplasmic reticulum (s.r.) Ca concentration during systole. The experiments were performed on voltage-clamped ferret single ventricular myocytes loaded with the free acid of fluo-3 through a patch pipette. The application of caffeine (10 mM) resulted in a Na-Ca exchange current and a transient increase of the free intracellular Ca concentration ([Ca2+]i). The time-course of change of total Ca in the cell was obtained by integrating the current and this was compared with the measurements of [Ca2+]i to obtain a buffering curve. This could be fit with a maximum capacity for the intrinsic buffers of 114±18 µmol l–1 and Kd of 0.59±0.17 µM (n=8). During the systolic rise of [Ca2+]i, the measured changes of [Ca2+]i and the buffering curve were used to calculate the magnitude and time-course of the change of total cytoplasmic Ca and thence of both s.r. Ca content and Ca release flux. This method provides a simple and reversible mechanism to measure Ca buffering and the time-course of both total cytoplasmic and s.r. Ca.

Comparison of subsarcolemmal and bulk calcium concentration during spontaneous calcium release in rat ventricular myocytes

1. The aim of these experiments was to compare the time course of changes in intracellular Ca2+ concentration ([Ca2+]i) measured in the bulk cytoplasm with those estimated to occur near the sarcolemma. Sarcolemmal Na(+)‐Ca2+ exchange current and [Ca2+]i were measured in single, voltage‐clamped ventricular myocytes. 2. Spontaneous Ca2+ release from the sarcoplasmic reticulum (SR) resulted in a transient inward current. This current developed and decayed more quickly than the accompanying changes in [Ca2+]i (measured with indo‐1) resulting in a hysteresis between [Ca2+]i and current. A similar hysteresis was also observed if [Ca2+]i was elevated with caffeine and was removed if the current was low pass filtered with a time constant of 132 ms. 3. Digital video imaging (using fluo‐3 or calcium green‐1 to measure [Ca2+]i) allowed measurement of [Ca2+]i at all points in the cell during the wave of spontaneous Ca2+ release. The hysteresis between [Ca2+]i and current remained, even after allowing for the spatial and temporal properties of this wave. 4. The hysteresis can be accounted for if there is a barrier to diffusion of Ca2+ ions separating the bulk cytoplasm from the space under the sarcolemma (into which Ca2+ is released from the sarcoplasmic reticulum). The calculated subsarcolemmal [Ca2+] rises and falls more quickly (and reaches a higher peak) than does the bulk [Ca2+]. The delay introduced by this barrier is equivalent to a time constant of 133 ms. 5. The subsarcolemmal space described in this paper may be equivalent to the ‘fuzzy space’ previously suggested to be important in controlling SR Ca2+ release.

Enhanced Ca2+ Current and Decreased Ca2+ Efflux Restore Sarcoplasmic Reticulum Ca2+ Content After Depletion

[Ca2+]i was measured using the fluorescent indicator indo 1 in voltage-clamped ferret and rat ventricular myocytes. The Ca2+ content of the sarcoplasmic reticulum (SR) was estimated from the integral of the Na(+)-Ca2+ exchange current activated by caffeine. Refilling of the SR after caffeine removal was enhanced by stimulation. As the systolic Ca2+ transient recovered, the integral of the L-type Ca2+ current decreased and that of the Na(+)-Ca2+ exchange tail current increased. For the early pulses, the gain of Ca2+ via the Ca2+ current is greater than the loss via the exchanger, and during steady state stimulation, the fluxes are equal. The difference in the integrals gives a measure of the net gain of cell Ca2+ with each pulse. When these are summed, the calculated gain of cell Ca2+ agrees well with the increase of SR Ca2+ produced by stimulation, as measured from the caffeine-evoked currents. There was a nonlinear relationship between SR Ca2+ content and the magnitude of the systolic Ca2+ transient such that at high SR Ca2+ content a given increase of content had a greater effect on the Ca2+ transient than did an increase at low SR content. In conclusion, the effects of systolic Ca2+ on the Ca2+ current and Na(+)-Ca2+ exchange current provide a means to regulate SR Ca2+ content and thence the systolic Ca2+ transient.

Stimulation of Ca-induced Ca release only transiently increases the systolic Ca transient: measurements of Ca fluxes and sarcoplasmic reticulum Ca

OBJECTIVE To investigate the effects of stimulating calcium induced Ca release with low concentrations (100-200 microM) of caffeine and, in particular, to study the cellular mechanisms responsible for the transient responses found previously. METHODS Experiments were performed on isolated rat ventricular myocytes. Intracellular calcium concentration ([Ca2+]i) was measured with Indo-1, the cells were voltage-clamped with the perforated patch technique and sarcoplasmic reticulum (s.r.) Ca content was estimated from the integral of the caffeine-evoked current. RESULTS The systolic Ca transient produced by the first depolarization in the presence of caffeine was larger than the control. Over the next few pulses the magnitude of the Ca transient returned to control levels despite the maintained presence of caffeine. The s.r. Ca content was decreased by 9% after one pulse in caffeine and by 21% after several pulses in caffeine. The first pulse in the low concentration of caffeine was followed by an enhanced inward (Na-Ca exchange) current tail indicating increased efflux of calcium from the cell. The extra loss of calcium calculated from the tail current agreed quantitatively with that from the change of s.r. Ca content. CONCLUSIONS These results show that stimulating calcium induced calcium release produces only a transient increase of the systolic Ca transient. This is due to the larger Ca transient decreasing the s.r. Ca content. It is concluded that any agent whose sole mode of action is stimulation of calcium-induced calcium release will not produce a maintained inotropic effect. The consequences of this for the effects of other modulators of calcium induced calcium release are discussed.

Propagating calcium waves initiated by local caffeine application in rat ventricular myocytes.

1. Caffeine was applied locally to one region of a resting cell via an extracellular pipette while simultaneously imaging the concentrations of intracellular calcium ([Ca2+]i) and intracellular caffeine ([caffeine]i). 2. Local application of caffeine produced a rise of [caffeine]i which was confined to the region of the cell near the pipette. There was also a local increase of [Ca2+]i which then, in most resting cells, propagated along the cell as a linear Ca2+ wave. The initial magnitude of the rise of [Ca2+]i was greater than that of the electrically stimulated Ca2+ transient. 3. As the wave of increase of [Ca2+]i propagated along the cell it decreased in both amplitude and velocity in cells that had not been treated to elevate the cellular Ca2+ load. 4. In some cells the caffeine response did not propagate significantly. In these cases an increase of the cellular Ca2+ load enabled caffeine‐induced Ca2+ wave propagation along the entire cell length without significant decay in amplitude and velocity. 5. Previous work has shown that an electrically evoked local systolic Ca2+ transient does not propagate. The fact that the caffeine‐evoked response does propagate and the correlation between decay of amplitude and velocity suggest that the transient has to be a certain size before it can propagate. It is suggested that one of the factors which favour propagation of waves under conditions of elevated sarcoplasmic reticulum Ca2+ content is the increased release of Ca2+.

Ca-activated chloride current and Na-Ca exchange have different timecourses during sarcoplasmic reticulum Ca release in ferret ventricular myocytes

Abstract The aim of this work was to measure membrane currents activated by Ca release from the cardiac sarcoplasmic reticulum (s.r.). Intracellular Ca concentration ([Ca2+]i) was measured using fluo-3 in patch clamped cells. Calcium release from the s.r. (whether occurring spontaneously or evoked by caffeine) produced changes of membrane current which could be separated into a Ca-activated Cl current which was inhibited by DIDS or Cl removal and a Na-Ca exchange current. Both these currents had different time courses from the measured [Ca2+]i. Furthermore the Ca-activated Cl current decayed more quickly than did Na-Ca exchange. Possible explanations for the different kinetics of these two Ca-sensitive currents are discussed.

A measurable reduction of s.r. Ca content follows spontaneous Ca release in rat ventricular myocytes.

Abstract The Ca content of the sarcoplasmic reticulum (s.r.) was measured in voltage-clamped rat ventricular myocytes from the integral of the Na-Ca exchange current evoked by applying caffeine to release the s.r. Ca content. Following spontaneous release of Ca from the s.r., the s.r. Ca content was decreased. The magnitude of this decrease was equal to that of the amount of calcium directly measured to have been pumped out of the cell during the spontaneous release. Following a spontaneous release, the s.r. Ca content recovered linearly. These results are shown to be consistent with the hypothesis that the frequency of spontaneous release is determined by the time taken for the cell and s.r. to reaccumulate the Ca2+ ions pumped out of the cell during spontaneous release.

Factors affecting the propagation of locally activated systolic Ca transients in rat ventricular myocytes

A method is described to activate the systolic rise of [Ca2+]i in only one region of a single, isolated cell. This is achieved by applying the calcium chelator BAPTA to the rest of the cell from a pipette. Under control conditions electrical stimulation produced a Ca transient which was uniform throughout the cell. If a BAPTA containing solution was applied to one region of the cell for 100–500 ms before stimulation then there was no systolic Ca transient in that region of the cell. In the rest of the cell, however, the Ca transient was identical to that in control conditions. If BAPTA application was discontinued the Ca transient was normal throughout the cell on the next stimulation. In the presence of ouabain the locally activated systolic Ca transient propagated through the cell. Propagation was associated with an increase of systolic but not diastolic [Ca2+]i. These results show that the systolic Ca transient propagates if the cell Ca content is elevated. We suggest that the fact that Ca-overload produces spontaneous Ca release may be due to the fact that it allows spontaneous Ca release (which may always be occurring) to propagate.

2,3-Butanedione monoxime (BDM) decreases sarcoplasmic reticulum Ca content by stimulating Ca release in isolated rat ventricular myocytes

Abstract The effects of 2,3-butanedione monoxime (BDM) were examined using rat ventricular myocytes loaded with Indo-1 to measure the intracellular Ca concentration ([Ca2+]i). BDM (10 mM) produced a transient increase of the systolic Ca transient with no steady-state effect on its magnitude. This transient increase was more marked when BDM was applied after having decreased the external Ca concentration from 1 to 0.1 mM. There was a transient increase of resting [Ca2+]i in both quiescent and electrically stimulated cells. Prior application of BDM decreased the rise of [Ca2+]i produced by caffeine. In voltage-clamped cells the rise of [Ca2+]i produced by BDM was accompanied by a transient inward current attributed to the electrogenic Na-Ca exchange. The amount of Ca lost from the cell upon application of 10 mM BDM could be estimated either from the integral of the BDM-evoked current or from the reduction of the integral of a caffeine-evoked current and corresponded to about 50% of the sarcoplasmic reticulum (s.r.) Ca content. The decrease of s.r. Ca content and the transient potentiation of the systolic Ca transient suggest that BDM acts by stimulating Ca-induced Ca release. These effects must be allowed for when using BDM.