Calcium currents in GH3 cultured pituitary cells under whole-cell voltage-clamp: inhibition by voltage-dependent potassium currents.

To isolate inward Ca2+ currents in GH3 rat pituitary cells, an inward Na+ current as well as two outward K+ currents, a transient voltage-dependent current (IKV) and a slowly rising Ca2+-activated current (IKCa), must be suppressed. Blockage of these outward currents, usually achieved by replacement of intracellular K+ with Cs+, reveals sustained inward currents. Selective blockage of either K+ current can be accomplished in the presence of intracellular K+ by use of quaternary ammonium ions. When IKCa and Na+ currents are blocked, the net current elicited by stepping the membrane potential (Vm) from -60 to 0 mV is inward first, becomes outward and peaks in 10-30 msec, and finally becomes inward again. Under this condition, in which both IKV and Ca2+ currents should be present throughout the duration of the voltage step, the Ca2+ current was not detected at the time of peak outward current. That is, plots of peak outward current vs. Vm are monotonic and are not modified by nisoldipine or low external Ca2+ as would be expected if Ca2+ currents were present. However, similar plots at times other than at peak current are not monotonic and are altered by nisoldipine or low Ca2+ (i.e., inward currents decrease and plots become monotonic). When K+ channels are first inactivated by holding Vm at -30 mV, a sustained Ca2+ current is always observed upon stepping Vm to 0 mV. Furthermore, substitution of Ba2+ for Ca2+ causes blockage of IKV and inhibition of this current results in inward Ba2+ currents with square wave kinetics. These data indicate that the Ca2+ current is completely inhibited at peak outward IKV and that Ca2+ conductance is progressively disinhibited as the transient K+ current declines due to channel inactivation. This suggests that in GH3 cells Ca2+ channels are regulated by IKV.     

Mechanism of calcium current modulation underlying presynaptic facilitation and behavioral sensitization in Aplysia.

Behavioral sensitization of the gill-withdrawal reflex of Aplysia is caused by presynaptic facilitation at the synapses of the mechanoreceptor sensory neurons of the reflex onto the motor neurons and interneurons. The presynaptic facilitation has been shown to be simulated by serotonin (the putative presynaptic facilitatory transmitter) and by cyclic AMP and to be accompanied by an increase in the Ca2+ current of sensory neuron cell bodies exposed to tetraethylammonium. This increase in the Ca2+ current could result from either a direct action on the Ca2+ channel or an action on an opposing K+ current. Here we report voltage clamp experiments which indicate that the increase in Ca2+ current associated with presynaptic facilitation results from a decrease in a K+ current. Stimulation of the connective (the pathway that mediates sensitization) or application of serotonin causes a decrease in a voltage-sensitive, steady-state outward current measured under voltage clamp as well as an increase in the transient net inward and a decrease in the transient outward currents elicited by brief depolarizing command steps. The reversal potential of the steady-state synaptic current is sensitive to extracellular K+ concentration, and both the steady-state synaptic current and the changes in the transient currents are blocked by K+ current blocking agents and by washout of K+. These results suggest that serotonin and the natural transmitter released by connective stimulation act to decrease a voltage-sensitive K+ current. The decrease in K+ current prolongs the action potential, and this in turn increases the duration of the inward Ca2+ current and thereby enhances transmitter release.     

Presynaptic membrane potential affects transmitter release in an identified neuron in Aplysia by modulating the Ca2+ and K+ currents

We have examined the relationships between the modulation of transmitter release and of specific ionic currents by membrane potential in the cholinergic interneuron L10 of the abdominal ganglion of Aplysia californica. The presynaptic cell body was voltage-clamped under various pharmacological conditions and transmitter release from the terminals was assayed simultaneously by recording the synaptic potentials in the postsynaptic cell. When cell L10 was voltage-clamped from a holding potential of -60 mV in the presence of tetrodotoxin, graded transmitter release was evoked by depolarizing command pulses in the membrane voltage range (-35 mV to + 10 mV) in which the Ca(2+) current was also increasing. Depolarizing the holding potential of L10 results in increased transmitter output. Two ionic mechanisms contribute to this form of plasticity. First, depolarization inactivates some K(+) channels so that depolarizing command pulses recruit a smaller K(+) current. In unclamped cells the decreased K(+) conductance causes spike-broadening and increased influx of Ca(2+) during each spike. Second, small depolarizations around resting potential (-55 mV to -35 mV) activate a steady-state Ca(2+) current that also contributes to the modulation of transmitter release, because, even with most presynaptic K(+) currents blocked pharmacologically, depolarizing the holding potential still increases transmitter release. In contrast to the steady-state Ca(2+) current, the transient inward Ca(2+) current evoked by depolarizing clamp steps is relatively unchanged from various holding potentials.     

Potassium current suppression by quinidine reveals additional calcium currents in neuroblastoma cells.

Quinine and quinidine have been evaluated with regard to their effects on the electrical activity of neuroblastoma cells. Under voltage-clamp conditions, we have found that quinine and quinidine block both the voltage-dependent and Ca2+-dependent K+ conductances. Blockage of the voltage-dependent K+ channel is manifest as an increase in the amplitude and in the duration of the action potential. Blockage of the Ca2+-dependent K+ channel in Na+-free (replaced by Tris) solutions containing 6.8 mM Ca2+ and tetraethylammonium ion or 4-aminopyridine (to block the voltage-dependent K+ current) is seen as a further prolongation of the Ca2+ action potential and diminution of the after-hyperpolarization. A critical role of the Ca2+-dependent K+ conductance in modulation of the rate and duration of trains of Ca2+ action potentials is shown by the use of low concentrations (5-40 microM) of quinine or quinidine, which diminish the Ca2+-dependent K+ conductance in a graded manner. After complete blockade of K+ currents, the peak Ca2+ currents are enhanced at all voltages, especially at values more positive than -30 mV, where a steady-state inward current appears as well. In this same voltage range, the decay of the Ca2+ current exhibits two time constants--that of the transient inward current, which is about 20 msec, and a much slower (approximately 2000 msec) component. It is suggested that neuroblastoma cells have two types of calcium channels--one which generates the Ca2+ action potential and a second, distinguished by activation at more depolarized levels and by a slow rate of inactivation, which underlies the calcium entry necessary to activate the Ca2+-dependent K+ conductance.     

Presynaptic calcium currents and their relation to synaptic transmission: Voltage clamp study in squid giant synapse and theoretical model for the calcium gate

A voltage clamp study of the presynaptic terminal in squid stellate ganglion has given quantitative results relating inward Ca2+ current to presynaptic membrane potential and postsynaptic response to inward Ca2+ current. The results indicate an S-shaped curve for the relationship between presynaptic potential and Ca2+ current and a linear relationship between Ca2+ current and postsynaptic potential. A similar S-shaped curve was found for the time-dependent properties of the Ca2+ conductance. Based on these results a mathematical model was developed which accounts for the experimental results in this and previously published papers by other authors. The model suggests that five subunits are involved in the Ca2+ gate and that the subunits change noncooperatively from an inactive to an active form upon membrane depolarization.     

Serotonin increases an anomalously rectifying K+ current in the Aplysia neuron R15.

Previous work has shown that serotonin causes an increase in K+ conductance in the identified Aplysia neuron R15. This response is mediated by cAMP-dependent protein phosphorylation. The results presented here show that the K+ channel modulated by serotonin is an anomalous or inward rectifier (designated IR) that is present in R15 together with the three other distinct K+ channels previously described for this cell. Several lines of evidence indicate that this inward rectifier is partially activated in the resting cell and is further activated by serotonin. Voltage clamp analysis of resting and serotonin-evoked membrane currents at various external K+ concentrations shows that both currents have reversal potentials close to the potassium equilibrium potential, exhibit similar dependences in magnitude on external K+ concentration, and display marked anomalous rectification. The effects of particular monovalent and divalent cations are also similar on the resting and serotonin-evoked currents. Rb+, Cs+, and Ba2+ block both currents while Tl+ can substitute for K+ as a charge carrier and channel activator in both. These properties are characteristics of anomalous rectifiers in other systems. Furthermore, measurement of the voltage dependence of inactivation for the fast transient K+ current shows that this current cannot account for the anomalously rectifying K+ conductance in R15. The inward rectifier is therefore a separate current mediated by its own channels, the activity of which can be modulated by serotonin.     

Trimebutine maleate has inhibitory effects on the voltage-dependent Ca2+ inward current and other membrane currents in intestinal smooth muscle cells

We examined effects of trimebutine maleate on the membrane currents of the intestinal smooth muscle cells by using the tight-seal whole cell clamp technique. Trimebutine suppressed the Ba2+ inward current through voltage-dependent Ca2+ channels in a dose-dependent manner. The inhibitory effect of trimebutine on the Ba2+ inward current was not use-dependent. It shifted the steady-state inactivation curve to the left along the voltage axis. Trimebutine also had inhibitory effects on the other membrane currents of the cells, such as the voltage-dependent K+ current, the Ca2(+)-activated oscillating K+ current and the acetylcholine-induced inward current. These relatively non-specific inhibitory effects of trimebutine on the membrane currents may explain, at least in part, the dual actions of the drug on the intestinal smooth muscle contractility, i.e. inhibitory as well as excitatory.     

Separate Cl- conductances activated by cAMP and Ca2+ in Cl(-)-secreting epithelial cells.

We studied the cAMP- and Ca2(+)-activated secretory Cl- conductances in the Cl(-)-secreting colonic epithelial cell line T84 using the whole-cell patch-clamp technique. Cl- and K+ currents were measured under voltage clamp. Forskolin or cAMP increased Cl- current 2-15 times with no change in K+ current. The current-voltage relation for cAMP-activated Cl- current was linear from -100 to +100 mV and showed no time-dependent changes in current during voltage pulses. Ca2+ ionophores or increased pipette Ca2+ increased both Cl- and K+ currents 2-30 times. The Ca2(+)-activated Cl- current was outwardly rectified, activated during depolarizing voltage pulses, and inactivated during hyperpolarizing voltage pulses. Addition of ionophore after forskolin further increased Cl- conductance 1.5-5 times, and the current took on the time-dependent characteristics of that stimulated by Ca2+. Thus, cAMP and Ca2+ activate Cl- conductances with different properties, implying that these second messengers activate different Cl- channels or that they induce different conductive and kinetic states in the same Cl- channel.     

Excitation-secretion coupling: ionic currents in glomerulosa cells: effects of adrenocorticotropin and K+ channel blockers

The ionic conductance of cultured rat glomerulosa cells has been studied using the whole cell variant of the patch-clamp technique. We have identified and partially characterized three currents: a transient outward current, a slow outward current, and a slow inward current. The transient outward current activated rapidly and then inactivated slowly on maintained depolarization. Activation was initiated at -30 mV, and zero current was seen at -60 to -50 mV. The slow outward current did not inactivate with time and was initiated around 0 mV; its zero current voltage was difficult to evaluate. The two outward currents were present in different proportions, which explains the different time course of the total outward current from one cell to another. A slow inward current was also found which activated near -30 mV and reached its reversal potential between 80 and 100 mV. This current was blocked by Co2+, increased with [Ca2+]o, and was insensitive to Na+-free external medium. ACTH, a potent stimulant of steroid output, was found to block the transient outward current, but was ineffective on the slow outward current and the slow inward current. Tetraethylammonium and 4-aminopyridine, K+ channel inhibitors, also blocked the transient outward current.     

Gonadotropin-releasing hormone induces oscillatory membrane currents in rat gonadotropes

Electrophysiological studies were performed to characterize membrane currents of rat gonadotropes under basal conditions and after exposure to secretagogues. Gonadotropes were identified in primary cultures of rat anterior pituitaries by a reverse hemolytic plaque assay. Giga-seal patch clamp recording with the cell-attached configuration was used to monitor membrane currents in these cells. Spontaneous spikes in basal current were seen. These were blocked by methoxyverapamil and probably reflect Ca2+-dependent action potentials. Brief GnRH stimulation induced slow oscillatory changes in membrane current that evolved into a series of large amplitude inward pulses after about 8 min. Treatment with TRH had no effect, and depolarization with K+ led to delayed inward currents without any oscillatory behavior. Under conditions of Ca2+ channel blockade, GnRH stimulation did not induce pulses of inward current, but did lead to oscillatory activation of a small conductance ion channel apparently selective for K+. Taken together these results suggest that GnRH induces oscillations in intracellular Ca2+ and that these oscillations are controlled by biochemical processes.     

Ca2+ -activated K+ conductance in internally perfused snail neurons is enhanced by protein phosphorylation.

Depolarizing voltage steps induce inward and outward currents in voltage-clamped, internally perfused neurons from the snail Helix roseneri. Addition of the catalytic subunit of cyclic AMP-dependent protein kinase (ATP:protein phosphotransferase, EC 2.7.1.37) to the internal perfusing medium results in an increase in the net outward current, with no apparent effect on the inward current. Catalytic subunit inactivated by 5,5'-dithiobis(2-nitrobenzoic acid) is without effect, indicating that the increase in net outward current results from protein phosphorylation rather than an unspecific effect of protein perfusion. Decreasing the external Ca2+ concentration from 10 to 1 mM eliminates the effect of catalytic subunit, suggesting that Ca2+ plays an important role in this response. This suggestion is supported by the fact that the stimulation by catalytic subunit can be mimicked by increasing the Ca2+ concentration in the internal perfusion medium and can be prevented by intracellular perfusion with 10 mM EGTA. The results are consistent with the hypothesis that cyclic AMP-dependent protein phosphorylation regulates the Ca2+-activated K+ conductance in these cells.     

Outward potassium currents in freshly isolated smooth muscle cell of dog coronary arteries

Outward membrane currents were characterized in single coronary smooth muscle cells of adult beagle dogs. The cells averaged 96.4 x 7.1 microns and had a resting potential of -50.7 mV, an input resistance of 307.9 M omega, a capacitance of 32.3 pF, and a calculated membrane surface area of 4,037 microns2. The cells contracted in response to external application of acetylcholine or high K+. In voltage clamp by use of the suction pipette method, outward current began to appear at -50 mV and reached 15.2 nA at 50 mV with a current density of 376.5 microA/cm2. The current was reduced by external tetraethylammonium, Ba2+, and internal Cs+, and its reversal potential had a Nernst relation to external K+ concentration. Elevation of external Ca2+ (Ca2+o) from 0 to 0.3 mM increased total K+ current by up to 300%; elevation of internal Ca2+ (Ca2+i) to 5 x 10(-7) M by internal perfusion increased total outward current to a similar extent, suggesting a large difference in Ca2+ transmembrane sensitivity. Total whole-cell K+ current consisted of two components: an initial time-independent current (Ii) followed by a time-dependent current (It). Ii and It were through separate K+ channels based on differences in a) sensitivity to Ca2+09b) modulation by an inward Ca2+ current, c) current amplitudes and activation kinetics, and d) responses to pharmacological agents. It was the largest component, measuring 4.5 nA in 0 mM Ca2+o but increasing to 11.9 nA in 0.3 mM Ca2+o with a steep 2.5 power function. It activated with a biexponential time course; in Ca2+o-free solution, its time course was relatively insensitive to voltage changes but became voltage sensitive in the presence of Ca2+o. Further, such sensitivity was abolished or enhanced by Co2+ or Bay K 8644, respectively. We concluded that there are two types of Ca2+-sensitive K+ currents, Ii and It, in coronary smooth muscle cells. Via an inward Ca2+ channel Ca2+o strongly modulates It, both in amplitude and kinetics.     

Development of a delayed outward-rectifying K+ conductance in cultured mouse peritoneal macrophages.

Patch clamp techniques were used to study ionic currents in cultured mouse peritoneal macrophages. Whole-cell voltage clamp studies of cells 1-5 hr after isolation showed only a high-resistance linear membrane. After 1 day in culture, 82 of 85 cells studied had developed a voltage- and time-dependent potassium (K+) conductance similar to the delayed outward rectifier in nerve and muscle cells. The current activated when the membrane was depolarized above -50 mV. The sigmoidally rising current rose to a peak at a rate that increased with depolarization. Inactivation proceeded exponentially with a time constant of approximately equal to 450 ms. Recovery from inactivation was slow (tau = 12 s). The reversal potentials for varying extracellular K+ concentrations followed the Nernst predictions for a K+ -specific channel. The conductance was blocked by extracellular 4-aminopyridine and by intracellular tetraethylammonium chloride, barium, and cesium. Single-channel K+ currents comprising this net current had a conductance of 16 pS, exhibited bursting behavior, and inactivated with time. No inward currents were ever detected in macrophages cultivated for up to 4 days. Short-term exposure to chemoattractant and transmitter agents failed to activate an inward current. Macrophages may change their membrane electrophysiological properties depending on their state of functional activation. We postulate that the K+ conductance develops prior to depolarizing conductances involved in the macrophage's immunological functions.     

Early afterdepolarizations: mechanism of induction and block. A role for L-type Ca2+ current

Early afterdepolarizations (EADs) are a type of triggered activity found in heart muscle. We used voltage-clamped sheep cardiac Purkinje fibers to examine the mechanism underlying EADs induced near action potential plateau voltages with the Ca2+ current agonist Bay K 8644 and the effect of several interventions known to suppress or enhance these EADs. Bay K 8644 produced an inward shift of the steady-state current-voltage relation near plateau voltages. Tetrodotoxin, lidocaine, verapamil, nitrendipine, and raising [K]o abolish EADs and shift the steady-state current-voltage relations outwardly. Using a two-pulse voltage-clamp protocol, an inward current transient was present at voltages where EADs were induced. The voltage-dependence of availability of the inward current transient and of EAD induction were similar. The time-dependence of recovery from inactivation of the inward current transient and of EAD amplitude were nearly identical. Without recovery of the inward current transient, EADs could not be elicited. The inward current transient was enhanced with Bay K 8644 and blocked by nitrendipine, but was not abolished by tetrodotoxin or replacement of [Na]o with an impermeant cation. These results support a hypothesis that the induction of EADs near action potential plateau voltages requires 1) a conditioning phase controlled by the sum of membrane currents present near the action potential plateau and characterized by lengthening and flattening of the plateau within a voltage range where, 2) recovery from inactivation and reactivation of L-type Ca2+ channels to carry the depolarizing charge can occur. Our results suggest an essential role for the L-type Ca2+ "window" current and provide a framework for understanding the role of several membrane currents in the induction and block of EADs.     

Bursting electrical activity in pancreatic beta cells caused by Ca(2+)- and voltage-inactivated Ca2+ channels.

We investigate the hypothesis that two classes of Ca2+ currents, one quickly inactivated by Ca2+ and one slowly inactivated by voltage, contribute to bursting electrical activity in pancreatic islets. A mathematical model of these currents is fit to the experimental whole-cell current-voltage and inactivation profiles, thereby fixing the Ca2+ conductance and all activation and inactivation parameters. Incorporating these currents into a model that includes delayed rectifier K+ channels and ATP-sensitive K+ channels, we show that only abnormal bursting is obtained. Modification of activation parameters to increase Ca2+ channel open times, as suggested by experiment, yields a more robust bursting similar to that observed in intact islets. This reinforces the suggestion that in addition to ATP-sensitive K+ channels, Ca2+ channels may serve as glucose sensors in the beta cell.     

Voltage-gated currents of tilapia prolactin cells

The first recordings of neuron-like electrical activity from endocrine cells were made from fish pituitary cells. However, patch-clamping studies have predominantly utilized mammalian preparations. This study used whole-cell patch-clamping to characterize voltage-gated ionic currents of anterior pituitary cells of Oreochromis mossambicus in primary culture. Due to their importance for control of hormone secretion we emphasize analysis of calcium currents (I(Ca)), including using peptide toxins diagnostic for mammalian neuronal Ca(2+) channel types. These appear not to have been previously tested on fish endocrine cells. In balanced salines, inward currents consisted of a rapid TTX-sensitive sodium current and a smaller, slower I(Ca); there followed outward potassium currents dominated by delayed, sustained TEA-sensitive K(+) current. About half of cells tested from a holding potential (V(h)) of -90 mV showed early transient K(+) current; most cells showed a small Ca(2+)-mediated outward current. I-V plots of isolated I(Ca) with 15 mM [Ca(2+)](o) showed peak currents (up to 20 pA/pF from V(h) -90 mV) at approximately +10 mV, with approximately 60% I(Ca) for V(h) -50 mV and approximately 30% remaining at V(h) -30 mV. Plots of normalized conductance vs. voltage at several V(h)s were nearly superimposable. Well-sustained I(Ca) with predominantly Ca(2+)-dependent inactivation and inhibition of approximately 30% of total I(Ca) by nifedipine or nimodipine suggests participation of L-type channels. Each of the peptide toxins (omega-conotoxin GVIA, omega-agatoxin IVA, SNX482) alone blocked 36-54% of I(Ca). Inhibition by any of these toxins was additive to inhibition by nifedipine. Combinations of the toxins failed to produce additive effects. I(Ca) of up to 30% of total remained with any combination of inhibitors, but 0.1mM cadmium blocked all I(Ca) rapidly and reversibly. We did not find differences among cells of differing size and hormone content. Thus, I(Ca) is carried by high voltage-activated Ca(2+) channels of at least three types, but the molecular types may differ from those characterized from mammalian neurons.     

Inositol trisphosphate promotes Na-Ca exchange current by releasing calcium from sarcoplasmic reticulum in cardiac myocytes

An early inward tail current evoked by membrane depolarization (from -80 to -40 mV) sufficient to activate sodium but not calcium current was studied in single voltage-clamped ventricular myocytes isolated from guinea pig hearts. Like forward-mode Na-Ca exchange, this early inward tail current required [Na+]o and [Ca2+]i and is thought to follow earlier reverse-mode Na-Ca exchange that triggers Ca2+ release from sarcoplasmic reticulum. The dependence of the early inward tail current on [Ca2+]i was supported by the ability of small (+10 mV) and large (+80 mV) voltage jumps from -40 mV to decrease and increase, respectively, the size of early inward tail currents evoked by subsequent voltage steps from -80 to -40 mV. As expected, tetrodotoxin selectively inhibited the early inward tail current but not the late inward tail current that followed voltage jumps to +40 mV test potentials. Although tetrodotoxin also blocked the fast Na+ current, replacement of extracellular Na+ by Li+ sustained the fast Na+ current. However, Li+, which does not support Na-Ca exchange, reversibly suppressed both the early and late inward tail currents. Inhibitors (ryanodine and caffeine) and promoters (intracellularly dialyzed inositol 1,4,5-trisphosphate) of sarcoplasmic reticulum Ca2+ release decreased and increased, respectively, the magnitude of the early inward tail current. The results substantiate the hypothesis that Ca2+ release from the sarcoplasmic reticulum participates in early Na-Ca exchange current and demonstrate that inositol 1,4,5-trisphosphate, by releasing Ca2+ from the sarcoplasmic reticulum, can promote Na-Ca exchange across the plasma membrane.     

G protein-dependent presynaptic inhibition mediated by AMPA receptors at the calyx of Held

The alpha-amino-3-5-methyl-4-isoxazolepropionic acid receptor (AMPAR) is an ionotropic receptor mediating excitatory synaptic transmission, but it can also interact with intracellular messengers. Here we report that, at the calyx of Held in the rat auditory brainstem, activation of AMPARs induced inward currents in the nerve terminal and inhibited presynaptic Ca2+ currents (I(pCa)), thereby attenuating glutamatergic synaptic transmission. The AMPAR-mediated I(pCa) inhibition was disinhibited by a strong depolarizing pulse and occluded by the nonhydrolyzable GTP analog GTPgammaS loaded into the terminal. We conclude that functional AMPARs are expressed at the calyx of Held nerve terminal and that their activation inhibits voltage-gated Ca2+ channels by an interaction with heterotrimeric GTP-binding proteins (G proteins). Thus, at a central glutamatergic synapse, presynaptic AMPARs have a metabotropic nature and regulate transmitter release by means of G proteins.     

Receptors of the serotonin 1C subtype expressed from cloned DNA mediate the closing of K+ membrane channels encoded by brain mRNA.

The modulation of K+ channels by serotonin (5-HT) receptors was studied by coinjecting Xenopus oocytes with mRNA transcribed in vitro from a cloned 5-HT 1C subtype (5-HT1C) receptor gene, together with size-fractionated mRNA isolated from rat cerebral cortex that expresses K+ channels. After intracellular loading with EGTA to block Ca2(+)-dependent chloride currents, these oocytes responded to 5-HT with an inward current associated with a decrease in membrane conductance. Membrane current responses were small or absent in oocytes injected with either mRNA alone. We conclude that 5-HT1C receptors are able to cause the closing of a class of K+ channels expressed by cortex mRNA in a Ca2(+)-independent manner. The coupling between the receptors and channels appears to be mediated by the inositol phospholipid second messenger pathway, since activation of this pathway by application of serum evoked a similar closing current.     

Current fluctuations and oscillations in smooth muscle cells from hog carotid artery. Role of the sarcoplasmic reticulum

Electrical activity of enzymatically isolated, smooth muscle cells from hog carotid arteries was recorded under current clamp and voltage clamp. Under the experimental conditions, membrane potential usually was not stable, and spontaneous hyperpolarizing transients of approximately 100-msec duration were recorded. The amplitude of the transients was markedly voltage dependent and ranged from about 20 mV at a membrane potential of 0 mV to undetectable at membrane potentials negative to -60 mV. Under voltage clamp, transient outward currents displayed a similar voltage dependency. These fluctuations reflect a K+ current; they were abolished by 10 mM tetraethylammonium chloride, a K+ channel blocker, and the current fluctuations reversed direction in high extracellular K+ concentration. Modulators of intracellular Ca2+ concentration also affected electrical activity. Lowering intracellular Ca2+ concentration by addition of 10 mM EGTA to the pipette solution or suppressing sarcoplasmic reticulum function by superfusion with caffeine (10 mM), ryanodine (1 microM), or histamine (3-10 microM) blocked the rapid voltage and current spikes. However, caffeine and histamine induced a much slower hump of outward current before blocking the rapid spikes. This slower transient outward current could be elicited only once after external Ca2+ was removed and is consistent with an activation of K+ channels by Ca2+ released from internal stores. In contrast, removal of external Ca2+ alone failed to abolish the rapid spikes. These results suggest that 1) a Ca2+-dependent K+ conductance can markedly affect the electrical behavior of arterial smooth muscle cells and 2) internal Ca2+ stores, probably the sarcoplasmic reticulum, can support rapid and frequent releases of Ca2+. Exposure to a low concentration of histamine (3 microM) caused synchronization of the irregular, rapid fluctuations giving rise to slow, periodic oscillations of Ca2+-activated K+ conductance with a frequency of 0.1-0.3 Hz. These regular oscillations are reminiscent of periodic Ca2+-induced Ca2+ release, were inhibited by 10 mM caffeine, and point to a modulation of sarcoplasmic reticulum Ca2+ release by histamine.