Ca2+ and voltage inactivate Ca2+ channels in guinea-pig ventricular myocytes through independent mechanisms

Localization of calcium entry through calcium channels in olfactory receptor neurones using a laser scanning microscope and the calcium indicator dyes Fluo-3 and Fura-Red

The intracellular calcium concentration [Ca2+]i in olfactory receptor neurones of Xenopus laevis was imaged with high spatial and temporal resolution. A new method using a mixture of the calcium indicator dyes Fluo-3 and Fura-Red was employed. The fluorescence patterns in two wavelength bands were measured on the emission side of a confocal laser scanning microscope, and the ratio R of the fluorescence intensities was taken as an estimate of [Ca2+]i. When the neurones were depolarized by elevating the extracellular potassium concentration [K+]o they showed one of three types of responses: a fast increase in [Ca2+]i, a slow increase in [Ca2+]i, or no change in [Ca2+]i. The fast increase in [Ca2+]i took place in the soma compartment. For at least 4 s after the onset of depolarization the calcium distribution in the dendrite remained essentially unchanged. To study the fast increase with high time resolution, line scan images were taken. The neurones were depolarized for brief periods applying a solution containing high [K+] onto the soma from an application pipette. The fast increase in [Ca2+]i began with a delay of about 200 ms and went from the resting concentration to about 110 nM above resting concentration. Following the depolarization, recovery from elevated [Ca2+]i to resting levels had a time constant of about 15 s. The slow response seemed to depend on the removal of [Na+] from the bath rather than on the elevated [K+] in the bath. The response was also observed with Cd2+, Ni2+, and Co2+ (1.5 mM each) in the bath.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium-dependent inactivation of L-type calcium channels in planar lipid bilayers

Intracellular Ca2+ can inhibit the activity of voltage-gated Ca channels by modulating the rate of channel inactivation. Ca(2+)-dependent inactivation of these channels may be a common negative feedback process important for regulating Ca2+ entry under physiological and pathological conditions. This article demonstrates that the inactivation of cardiac L-type Ca channels, reconstituted into planar lipid bilayers and studied in the presence of a dihydropyridine agonist, is sensitive to Ca2+. The rates and extents of inactivation, determined from ensemble averages of unitary Ba2+ currents, decreased when the calcium concentration facing the intracellular surface of the channel ([Ca2+]i) was lowered from approximately 10 microM to 20 nM by the addition of Ca2+ chelators. The rates and extents of Ba2+ current inactivation could also be increased by subsequent addition of Ca2+ raising the [Ca2+]i to 15 microM, thus demonstrating that the Ca2+ dependence of inactivation could be reversibly regulated by changes in [Ca2+]i. In addition, reconstituted Ca channels inactivated more quickly when the inward current was carried by Ca2+ than when it was carried by Ba2+, suggesting that local increases in [Ca2+]i could activate Ca(2+)-dependent inactivation. These data support models in which Ca2+ binds to the channel itself or to closely associated regulatory proteins to control the rate of channel inactivation, and are inconsistent with purely enzymatic models for channel inactivation.

Does the use of DM-nitrophen, nitr-5, or diazo-2 interfere with the measurement of indo-1 fluorescence?

Emission spectra of the photolabile Ca2+ chelators DM-nitrophen, nitr-5, and diazo-2 were studied alone, and in the presence of indo-1, to investigate potential interactions that would make the simultaneous manipulation and ratiometric measurement of the intracellular Ca2+ concentration difficult. Neither diazo-2 nor its photoproduct were found to be significantly fluorescent, and consequently concentrations of diazo-2 up to 20 times that of indo-1 did not distort the emission spectra of indo-1. DM-nitrophen was scarcely fluorescent, but its fluorescence did increase upon photolysis. In contrast to diazo-2 and DM-nitrophen, nitr-5 itself was found to be quite fluorescent, and this fluorescence was significantly increased upon photolysis. Thus, combined use of nitr-5 and indo-1 poses the most difficulty. The emission spectra of all the investigated compounds were used to define experimental conditions and calibration procedures that make possible simultaneous measurement and manipulation of the intracellular Ca2+ concentration.

Inactivation of the voltage-dependent Ca2+ channel current in smooth muscle cells isolated from the guinea-pig detrusor

1. Whole-cell voltage clamp techniques were applied to single smooth muscle cells enzymatically dissociated from guinea-pig urinary bladder. The inactivation and recovery of voltage-dependent Ca2+ channel currents were examined by manipulating the membrane potential over a wide range and by changing the extracellular divalent cation concentrations. 2. After exposing the cells to conditioning potentials (-100 to +80 mV in 20 mV increments), the degree of inactivation was estimated by stepping to a 0 mV test potential. In the presence of 2.5 mM Ca2+, the inactivation of the current was U-shaped with respect to the conditioning potential, with maximum inactivation at 0 mV. The maximal inactivation was 60 and 90% after conditioning durations of 0.8 and 5 s, respectively. The U-shaped curve is characteristic of Ca(2+)-dependent inactivation. When conditioning potentials of +80 mV with either duration were applied, the inward current at the test potential and the subsequent tail current on returning to the holding potential were larger than in control conditions (when the conditioning potential = the holding potential, -60 mV). 3. A U-shaped inactivation curve was also observed in the presence of 2.5 mM Ba2+. The inactivation was maximal with a conditioning potential of about -20 mV, and the inactivation was smaller than seen with Ca2+ entry. 4. Paired-pulse protocols were applied to examine the voltage dependence of recovery of the Ca2+ inward current. After the inward current had been inactivated during a 100 ms depolarization at 0 mV, it took 700 ms at -60 mV for nearly complete recovery of the current. Recovery was also observed at +80 mV. When the potential of the paired pulses was increased to +20 mV, less recovery was seen when the interpulse potential was at +80 mV. When a longer (3 s) depolarization was applied, the peak amplitude of the inward current took much longer to recover, and had not completely recovered after 4 s at either of the interpulse potentials, although recovery was greater with an interpulse potential of -60 mV than with one of +80 mV. Similar recoveries were observed in the presence of Ba2+. 5. During a long depolarization (8 s, 0 mV), the effects of rapid changes in the extracellular solution were examined. Partial recovery of the inward current occurred after a period in which Ca2+ was replaced with Mg2+. This recovery was not observed in the presence of Ba2+.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanisms of beta-adrenergic stimulation of cardiac Ca2+ channels revealed by discrete-time Markov analysis of slow gating

Individual cardiac Ca2+ channels cycle slowly between a mode of gating in which the channel is available to open, and one in which the channel remains silent. The regulation of this multisecond cycling process by isoproterenol was investigated by single-channel recording and the development of a discrete-time Markov model that describes the slow switching among modes in terms of (de) phosphorylation reactions. The results provide evidence that isoproterenol increases Ca2+ channel activity by a reciprocal regulatory mechanism: not only is the phosphorylation rate of the channel increased, but also the dephosphorylation rate decreased. The discrete-time Markov formalism should prove useful as a general tool for understanding the mode switching demonstrated by a number of ionic channels.

Phosphorylation enhances inactivation of N-type calcium channel current in bullfrog sympathetic neurons

We have investigated the effects of phosphatase and protein kinase inhibitors on calcium channel currents of bullfrog sympathetic neurons using the whole cell configuration of the patch clamp technique. Intracellular dialysis with the phosphatase inhibitors okadaic acid and calyculin A markedly enhanced the decline of inward current during a depolarizing voltage step. Tail current analysis demonstrated that this was genuine inactivation of calcium channel current, not activation of an outward current. The rapidly inactivating current is N-type calcium current (blocked by omega-conotoxin and resistant to nifedipine). Staurosporine, a nonselective protein kinase inhibitor, prevented the action of okadaic acid, suggesting that protein phosphorylation is involved. Under control conditions, the time course of inactivation could be described by the sum of two exponentials (tau = 150 ms and 1200 ms), plus a constant (apparently noninactivating) component, during depolarizations lasting 2 s. Okadaic acid induced a rapid inactivation process (tau = 15 ms) that was absent or negligible under control conditions, without obvious effect on the two slower time constants. As in control cells, inactivation in okadaic-acid-treated cells was strongest near -20 mV, with less inactivation at more positive voltages. However, inactivation did not depend on calcium influx. Modulation of calcium channel activity by phosphorylation may underly the spontaneous shift between inactivating and noninactivating modes recently observed for N-type calcium channels. Differences in basal phosphorylation levels could also explain why N-type calcium channels, originally described as rapidly and completely inactivating, inactivate slowly and incompletely in many neurons.

Ca channel kinetics during the spontaneous heart beat in embryonic chick ventricle cells

The ability of Ca ions to inhibit Ca channels presents one of the most intriguing problems in membrane biophysics. Because of this negative feedback, Ca channels can regulate the current that flows through them. The kinetics of the channels depend on voltage, and, because the voltage controls the current, a strong interaction exists between voltage dependence and Ca dependence. In addition to this interaction, the proximity of pores and the local concentration of ions also determine how effectively the Ca ions influence channel kinetics. The present article proposes a model that incorporates voltage-dependent kinetics, current-dependent kinetics, and channel clustering. We have based the model on previous voltage-clamp data and on Ca and Ba action currents measured during the action potential in beating heart cells. In general we observe that great variability exists in channel kinetics from patch to patch: Ba or Ca currents have low or high amplitudes and slow or fast kinetics during essentially the same voltage regime, either applied step-protocols or spontaneous cell action potentials. To explain this variability, we have postulated that Ca channels interact through shared ions. The model we propose expands on our previous model for Ba currents. We use the same voltage-dependent rate constants for the Ca currents that we did for the Ba currents. However, we vary the current-dependent rate constants according to the species of the conducting ion. The model reproduces the main features of our data, and we use it to predict Ca channel kinetics under physiological conditions. Preliminary reports of this work have appeared (DeFelice et al., 1991, Biophys. J. 59:551a; Risso et al., 1992, Biophys. J. 61:248a).

Effects of excitatory neurotransmitters on Ca2+ channel current in smooth muscle cells isolated from guinea-pig urinary bladder

1. A whole-cell voltage clamp technique was used to examine the effects of purinoceptor and muscarinic receptor agonists on voltage-sensitive Ca2+ channels in guinea-pig isolated urinary bladder cells. 2. When the cell membrane was clamped at the holding potential, rapid application of ATP elicited a large inward current in normal solution containing 2.5 mM Ca2+, and reduced the subsequent Ca2+ channel current evoked by a depolarizing pulse (0 mV). Carbachol (CCh) elicited little membrane current, but similarly reduced the Ca2+ current. 3. When purinoceptor agonists were rapidly applied during conditioning depolarizations at +80 mV, an outward current was elicited, and the Ca2+ channel current evoked by the subsequent test potential of 0 mV was not affected. Application of CCh at +80 mV also elicited an outward current, but it reduced the subsequently evoked Ca2+ current. 4. The inhibitory effect of muscarinic agonists on the Ca2+ channel current was attenuated by caffeine (10 mM). 5. In Ca(2+)-free, low-Mg2+ solution, a Na+ current flowing through voltage-dependent Ca2+ channels was evoked by depolarization. This current was not reduced by bath application of purinoceptor agonists (ATP and alpha,beta-methylene ATP). 6. These results suggest that the main effect of purinoceptor stimulation is opening of non-selective cation channels, and that muscarinic stimulation triggers Ca2+ release from intracellular stores. Voltage-sensitive Ca2+ channels are inactivated through an increase in intracellular Ca2+ induced by either activation of purinoceptor or muscarinic receptors.

Ca(2+)-dependent block and potentiation of L-type calcium current in guinea-pig ventricular myocytes

1. The caged calcium compound nitr-5 has been used to investigate the response of the L-type calcium current (ICa) of guinea-pig ventricular cells to a rapid increase in the free intracellular calcium concentration ([Ca2+]i). 2. When 2 mM nitr-5 or 3 mM DM-nitrophen was loaded into cells via a patch pipette and photolysed during the decay phase of ICa, a partial block of the current developed within 75 ms. The block was reduced by increasing the pre-flash [Ca2+]i and enhanced by adding high concentrations of Ca2+ chelators to the pipette-filling solution. 3. The photolysis-induced block was not suppressed in the presence of isoprenaline, suggesting a direct action of Ca2+ on the channels rather than a mechanism involving channel phosphorylation. 4. The most prominent effect of nitr-5 photolysis was a slow potentiation of ICa. When ICa was activated at frequencies between 0.05 and 0.7 Hz with various levels of pre-flash [Ca2+]i, peak ICa was approximately doubled in amplitude following photolysis. 5. At a stimulation frequency of 0.05 Hz, when nitr-5 was the only chelator present in the pipette, the time course of the potentiation was fitted by a single exponential with a time constant (tau P) of 2.7 min. When 1 mM CaCl2 was added to the pipette-filling solution, the time course of the potentiation was slowed (tau P = 6 min), although its amplitude was unchanged. With 12 mM BAPTA (a calcium chelator) added instead of CaCl2, the response was accelerated (tau P = 1.7 min). 6. Equimolar substitution of extracellular Ca2+ with Ba2+ significantly suppressed the flash-induced potentiation. The time course of the potentiation of the barium current, IBa (tau P = 1.9 min) was similar to that of ICa with BAPTA in the pipette. Potentiation of IBa was largely blocked in Ca(2+)-depleted cells when CaCl2 was omitted from the pipette. 7. When ICa was activated at frequencies of > or = 0.1 Hz, with 1 mM CaCl2 added to the nitr-5 (2 mM) in the pipette, the onset of the flash-induced potentiation was best fitted by two exponentials; one was similar to the single component seen at 0.05 Hz and the other was approximately one order of magnitude faster. The contribution of the faster component was positively correlated to the stimulation frequency. 8. The flash-induced potentiation of ICa was suppressed in the presence of a supramaximal concentration of the beta-adrenergic agonist isoprenaline.(ABSTRACT TRUNCATED AT 400 WORDS)

Ca(2+)-dependent inactivation of Ca2+ current in Aplysia neurons: kinetic studies using photolabile Ca2+ chelators

1. The kinetics and sensitivity of the Ca(2+)-dependent inactivation of calcium current (ICa) were examined in intact cell bodies from the abdominal ganglion of Aplysia californica under two-electrode voltage clamp. 2. Rapid changes in the level of intracellular free calcium ([Ca2+]i) were generated at the cell surface by photolytic release of Ca2+ (nitr-5 and dimethoxy nitrophen) or Ca2+ buffer (diazo-4). 3. Diazo-4 increased ICa by 10-15% and slowed the rate of ICa decay when photolysed before a test pulse or between a prepulse and a test pulse. The predominant effect of further light flashes was to increase the amount of non-inactivating current (I infinity) remaining at the end of long (> 1 s) depolarizing pulses. 4. A rapid increase in [Ca2+]i buffering during ICa inactivation did not cause a rapid recovery of current but merely reduced the rate and extent of subsequent inactivation. This effect was not seen when Ba2+ was the charge carrier. 5. Photolytic release of Ca2+ from nitr-5 produced estimated Ca2+ jumps of 3-4 microM at the front surface of the cell but failed to augment inactivation either before or during ICa. In contrast, photolysis of DM-nitrophen 10-90 ms before the test pulse decreased peak ICa by about 30%. A flash given during ICa rapidly blocked 41 +/- 3% of peak current with a time constant of 3-4 ms at 17 degrees C. Similar results were seen with the barium current (IBa). 6. Microinjection of the potent phosphatase inhibitor microcystin-LR (5 microM) had variable effects on ICa inactivation and augmented the cyclic AMP-induced depression of the delayed rectifier (IK(V) by forskolin (100 microM) and 3-isobutyl-1-methylxanthine (IBMX; 200 microM). 7. Full recovery from inactivation measured in two-pulse experiments took at least 20 s. This slow recovery process was unaffected by increases in intracellular cyclic AMP elicited by direct injection or by bath application of forskolin and IBMX. It was also unaffected by decreases in cyclic AMP induced by injecting 2',5'-dideoxyadenosine (1 mM) or bath application of the Rp isomer of cyclic adenosine 3',5'-monophosphothioate (Rp-cAMPS; 200 microM). 8. A 'shell' model relating submembrane Ca2+ to inactivation was inconsistent with the experimental results since it greatly overestimated the effects of diazo-4 and predicted significant inactivation by nitr-5 photolysis. 9. A model linearly relating [Ca2+]i in a single Ca2+ channel 'domain' to inactivation more closely matched the experimental results with diazo-4 and DM-(ABSTRACT TRUNCATED AT 400 WORDS)

Activity of cardiac L-type Ca2+ channels is sensitive to cytoplasmic calcium

Ca(2+)-induced inactivation of L-type Ca2+ channels is proposed as an important negative feedback mechanism regulating Ca2+ entry. Here, for the first time, evidence for modification of heart L-type Ca2+ channel activity by cytoplasmic calcium is provided from excised inside-out membrane patches. Ba2+ currents through cardiac L-type Ca2+ channels exhibited only modest inactivation in the absence of cytoplasmic Ca2+. Elevation of cytoplasmic Ca2+ to micromolar concentrations strikingly affected L-type Ca2+ channel activity as evaluated from ensemble average Ba2+ currents. Inactivation was markedly increased concomitant with a reduction of peak inward current, which was almost completely eliminated at about 15 microM cytoplasmic Ca2+ concentration. Half maximal suppression of Ba2+ currents was observed at 2.3 microM Ca2+. The observed modifications of L-type Ca2+ channel activity show that cytoplasmic Ca2+ induces channel closure. Below 4 microM Ca2+, channels can be reversibly reactivated during repetitive depolarizations, while at high Ca2+ concentrations (approximately 15 microM) most Ca2+ channels reside in a closed state. This may allow for a delicate regulation of Ca2+ entry, and consequently of heart contraction.