Protein kinase C is not involved in regulating the short-term cholinoreceptor plasticity of the PPa3 and LPa3 neurons of the edible snail

A voltage clamp technique on identified Helix lucorum's RPa3 and LPa3 neurons has been used to negate the effect of protein kinase C on extinction of response to repeated iontophoretic applications of acetylcholine to soma. Extracellular influence of phorbol ether, protein kinase C activator (12-O-tetradecanoylphorbol-13-acetate, 0.1-10 mumol/l), or polymyxin B, its blocker (100-500 mumol/l), do not affect the extinction of acetylcholine-induced neuronal response. The data show that protein kinase C is not involved into molecular mechanisms responsible for the regulation of short-term plasticity of RPa3 and LPa3 neuronal cholinoreceptors in Helix lucorum.     

Ionic currents in the soma of an identified cockroach motoneurone recorded under voltage-clamp

1. Membrane currents have been recorded from the soma of a bifunctional basalar/coxal depressor motoneurone in the metathoracic ganglion of the cockroach (Periplaneta americana) using a two-electrode voltage-clamp technique. 2. This motoneurone cell body is normally inexcitable when studied under current-clamp. Appropriate depolarizing command steps evoke rapid transient outward currents and late outward currents. 3. Late outward currents are dominated by a Ca-dependent component that confers an N-shaped I-V relationship on the neurone. 4. The Ca-dependent outward current is suppressed by Cd2+ (1 mM), Mn2+ (5 mM) or verapamil (50 microM). 5. Externally applied tetraethylammonium ions (TEA+) (25 mM) block the Ca-dependent current, but also appear to suppress a component of the late outward current that is independent of Ca2+. 6. Aminopyridines cause only minor suppression of late outward currents, but shift the peak in the N-shaped I-V relationship to more negative potentials. 7. The reversal potential of tail currents recorded following pre-pulses to +50 mV were dependent upon the pre-pulse duration; increasing the duration from 10 to 50 msec caused a +17 mV shift in tail current reversal potential. 8. A five-fold increase in the K+ concentration of the solution bathing the preparation only produced small and inconsistent changes in the reversal potential of tail currents. 9. Five-fold reduction in external Cl- caused no change. 10. The dependence of tail current reversal potential upon pre-pulse duration and the limited effect of alterations in the composition of the bathing solution are discussed in the context of restricted ion movements near the external surface of the cell membrane.     

Ionic mechanisms underlying modulating effects of serotonin on acetylcholine-induced responses in Helix pomatia neurons

The ionic mechanisms underlying modulatory effects of serotonin on acetylcholine-response in identified and nonidentifiedHelix pomatia neurons were investigated using voltage-clamping techniques at the neuronal membrane. External application of 10^–5–10^–4 M serotonin to the membrane of neurons responding to application of acetylcholine depending on Na⁺ depolarization (D_Na response) reduced membrane conductivity during response to acetylcholine without changing reversal potential of acetylcholine-induced current. Acetylcholine (10^–6–10^–4 M) administration took place 1–3 min later. Neurons with response to acetylcholine application dependent on Cl⁺ depolarization (D_Cl response) or hyperpolarization (H_Cl response) behaved similarly. Analogous effects could be produced by external application of theophylline which, together with the latency and residual effect characteristic of serotonin action points to the participation of intracellular processes associated with the cellular cyclase system in the changes produced by serotonin in acetylcholineinduced response. Serotonin brought about a shift in reversal potential and an increase in the acetylcholine-induced current in those neurons where this response was associated with changed permeability at the membrane to certain types of ions. During two-stage acetylcholine-induced response of the D_Na-H_K type, serotonin inhibited the inward current stage. Mechanisms underlying modulatory serotonin action on acetylcholine-induced response in test neurons are discussed in the light of our findings.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 57–64, January–February, 1988.     

Transmembrane outward hydrogen current in intracellularly perfused neurones of the snail Helix pomatia

The ionic nature and pharmacological properties of the outward current activated by membrane depolarization were studied on isolated neurones of the snail Helix pomatia, placed in Na+- and Ca2+-free extracellular solutions and intracellularly perfused with K+-free solution ("nonspecific outward current"). It was shown that the amplitude and reversal potential of this current (estimated from instantaneous current-voltage characteristics) are determined mainly by the transmembrane gradient for H+ ions. Lowering of pHi induced an increase in the current amplitude and a shift of the reversal potential to more negative values; the shift magnitude was comparable with that predicted for the hydrogen electrode. Raising pHi, as well as lowering pHo, induced a decrease in the current amplitude and a displacement of the current activation curve to more positive potentials. Addition of EGTA (8 mmol/l) to the intracellular perfusate did not affect the current amplitude. Extracellular 4-aminopyridine (10 mmol/l), verapamil (0.25 mmol/l) or Cd2+ (0.5 mmol/l) blocked the current. It is concluded that the current studied is carried mainly by H+ ions. In the same neurones the nature of the fast decay of the calcium inward current was also studied (in the presence of extracellular Ca2+ ions). This decay considerably slowed when pHi was raised or pHo was lowered, and it became less pronounced upon extracellular application of 4-aminopyridine or upon intracellular introduction of phenobarbital (4 mmol/l) and tolbutamide (3 mmol/l). It is suggested that the fast decay of the calcium inward current is due to activation of a Ca-sensitive component of the hydrogen current which depends on accumulation of Ca2+ ions. The possible physiological role of the transmembrane hydrogen currents is discussed.     

Synaptic transmission: ion concentration changes in the synaptic cleft.

Currents flowing through the postsynaptic membrane of an active synapse will tend to change the concentrations of ions in the synaptic cleft. Published experimental data are used to predict (a) the sodium and potassium concentration changes in the cleft at the frog neuromuscular junction, and (b) the sodium depletion in the cleft under a Ia synaptic bouton on a cat motoneuron. Significant concentration changes are predicted at both synapses. These changes will contribute to the time dependence of the observed current and will cause the reversal potential of the current to be time dependent. At the frog neuromuscular junction, the time course of the endplate current has been shown previously to depend on the magnitude of the current flowing (at a given potential). We attribute this to changes of the cleft ion concentration. The time dependent changes of the endplate current reversal potential that we predict for the neuromuscular junction are probably too small to be detected. This is because the effects of sodium depletion and potassium accumulation on the reversal potential almost cancel. We predict that near the reversal potential small currents of complex time course will remain, i.e. no true reversl potential exists. Such currents have previously been experimentally. At the cat Ia synapse, the synaptic current is predicted to deplete a significant fraction of the available extracellular sodium ions. Consequently, the magnitude of the synaptic current should be relatively independent of the number of postsynaptic channels activated, and of the membrane potental, as has previously been found experimentally.     

Ionic mechanisms of the transmembrane current evoked by injection of cyclic amp into identified Helix pomatia neurons

Ionic mechanisms of the transmembrane current evoked by injection of cyclic AMP into identified neurons ofHelix pomatia were investigated by the voltage clamp method. Injection of cyclic AMP into neurons RPa3, LPa2, LPa3, and LPl1 was shown to cause the development of a two-component transmembrane (cyclic AMP) current. The current-voltage characteristic curve of the early component is linear in the region from –40 to –90 mV; the reversal potential of the early component, determined by extrapolation, lies between –5 and +20 mV; the current-voltage characteristic curve of the late component also is linear and has a reversal potential between –55 and –60 mV. A decrease in the sodium concentration in the external medium from 100 to 25 mM led to a decrease in amplitude of the cyclic AMP current and to a shift of the reversal potential for the early component by 30–32 mV toward hyperpolarization. It is suggested that the early component of the cyclic AMP current in neurons RPa3, LPa2, LPa3, and LPl1 is associated with an increase in permeability of the neuron membrane chiefly for sodium ions, whereas the late component is correspondingly connected with permeability for potassium ions. Injection of cyclic AMP also caused the appearance of a transmembrane inward current in neuron LPa8, but it was independent of the holding potential and was unaccompanied by any change in membrane permeability. It is suggested that this current may be due to a change in the activity of the electrogenic ion pump.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 5, pp. 526–532, September–October, 1980.     

Effect of 3-isobutyl-1-methylxanthine on HCO3- transport in turtle bladder. Evidence for electrogenic HCO3- secretion

Ouabain-treated turtle bladders bathed on both surfaces by identical HCO3-/CO2-containing, Cl- -free Na+ media exhibit a short-circuit current (Isc) and transepithelial potential (p.d.) serosa electronegative to mucosa. Addition of 3-isobutyl-1-methylxanthine (IBMX), an inhibitor of cyclic nucleotide phosphodiesterase, rapidly reverses the direction of the Isc and p.d. The IBMX-induced reversal of Isc and p.d. is (1) dependent on the presence of HCO3- (and CO2) in the serosal bathing fluid, (2) independent of Na+ and other ions in the bathing medium, (3) decreased by inhibitors of carbonic anhydrase or oxidative metabolism, (4) increased by the serosal addition of cyclic AMP or the disulfonic stilbene, SITS. The results constitute evidence that the reversed Isc elicited by IBMX represents electrogenic secretion of HCO3-.     

Calcium currents in squid giant axon.

Voltage-clamp experiments were carried out on intracellularly perfused squid giant axons in a Na-free solution of 100 mM CaCl2+sucrose. The internal solution was 25 mM CsF+sucrose or 100 mM RbF+50mM tetraethylammonium chloride+sucrose. Depolarizing voltage clamp steps produced small inward currents; at large depolarizations the inward current reversed into an outward current. Tetrodotoxin completely blocked the inward current and part of the outward current. No inward current was seen with 100 mM MgCl2+sucrose as internal solution. It is concluded that the inward current is carried by Ca ions moving through the sodium channel. The reversal potential of the tetrodotoxin-sensitive current was +54mV with 25 mM CsF+sucrose inside and +10 mV with 100 mM RbF+50 mM tetraethylammonium chloride+sucrose inside. From the reversal potentials measured with varying external and internal solutions the relative permeabilities of the sodium channel for Ca, Cs and Na were calculated by means of the constant field equations. The results of the voltage-clamp experiments are compared with measurements of the Ca entry in intact axons.     

Calcium regulation of the short-term plasticity of the cholinoreceptors in neurons RPa3 and LPa3 of the edible snail]

Pharmacological influences, changing intracellular content of Ca2+, reversibly change the speed and depth of extinction of the input current of the Helix RPa3 and LPa3 neurones, elicited by a repeated iontophoretic application of acetylcholine to the soma. Suppression by extracellular medium, devoid of Ca2+ and by verapamyl (100-150 mumol/l) of Ca2+ input to the cell, induced by cholinoreceptors activation, reversibly weakens the extinction. Raise of intracellular Ca2+ level by blockade with ruthenium red (5-10 mumol/l) of specific Ca2+ transport by mitochondria and by mobilization with caffeine (1-4 mmol/l) of Ca2+, deposited by endoplasmic reticulum, accelerates and intensifies the extinction. The obtained results testify that the short-term cholinoreceptors plasticity of the above neurones is positively controlled by Ca2+ entering the cell by chemically controlled ion channels and mobilized from intracellular Ca-depot.     

Calcium specificity of the antigen-induced channels in rat basophilic leukemia cells

Ion channels, activated upon IgE-Fc epsilon receptor aggregation by specific antigen, were studied in micropipet-supported lipid bilayers. These bilayers were reconstituted with purified IgE-Fc epsilon receptor complex and the intact 110-kDa channel-forming protein, both isolated from plasma membranes of rat basophilic leukemia cells (line RBL-2H3). In order to identify the current carrier through these ion channels and to determine their ion selectivity, we investigated the currents flowing through the IgE-Fc epsilon receptor gated channels in the presence of a gradient of Ca2+ ions. Thus, the solution in which the micropipet-supported bilayer was immersed contained 1.8 mM CaCl2, while the interior of the micropipet contained 0.1 microM Ca2+ (buffered with EGTA). Both solutions also contained 150 mM of a monovalent cation chloride salt (either K+ or Na+). The currents induced upon specific aggregation of the IgE (by either antigen or anti-IgE antibodies) were examined over a range of potentials imposed on the bilayer. The type of conductance event most frequently observed under the employed experimental conditions was a channel that has a slope conductance of 3 pS and a reversal potential practically identical with the calculated value for the reversal potential of calcium (134 +/- 11 mV in the presence of sodium, 125 +/- 13 mV in the presence of potassium). These results indicate that this channel is highly selective for calcium against the monovalent cations sodium and potassium. This same channel has a conductance of 4-5 pS in the presence of symmetrical solutions containing only 100 mM CaCl2 and 8 pS in the presence of 0.5 M NaCl with no calcium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Permeation of both cations and anions through a single class of ATP-activated ion channels in developing chick skeletal muscle.

Micromolar concentrations of extracellular adenosine 5'-triphosphate (ATP) elicit a rapid excitatory response in developing chick skeletal muscle. Excitation is the result of a simultaneous increase in membrane permeability to sodium, potassium, and chloride ions. In the present study we quantify the selectivity of the ATP response, and provide evidence that a single class of ATP-activated ion channels conducts both cations and anions. Experiments were performed on myoballs using the whole-cell patch-clamp technique. We estimated permeability ratios by measuring the shift in reversal potential when one ion was substituted for another. We found that monovalent cations, divalent cations, and monovalent anions all permeate the membrane during the ATP response, and that there was only moderate selectivity between many of these ions. Calcium was the most permeant ion tested. To determine if ATP activates a single class of channels that conducts both cations and anions, or if ATP activates separate classes of cation and anion channels, we analyzed the fluctuations about the mean current induced by ATP. Ionic conditions were arranged so that the reversal potential for cations was +50 mV and the reversal potential for anions was -50 mV. Under these conditions, if ATP activates a single class of channels, ATP should not evoke an increase in noise at the reversal potential of the ATP current. However, if ATP activates separate classes of cation and anion channels, ATP should evoke a significant increase in noise at the reversal potential of the ATP current. At both +40 and -50 mV ATP elicited a clear increase in noise, but at the reversal potential of the ATP current (-5 mV), no increase in noise above background was seen. These results indicate that there is only a single class of excitatory ATP-activated channels, which do not select by charge. Based on analysis of the noise spectrum, the conductance of individual channels is estimated to be 0.2-0.4 pS.     

A simple model for multi-ion permeation. Single-vacancy conduction in a simple pore model.

Recent experimental evidence suggests that certain membrane channels operate in a nearly ion-saturated state. We therefore consider a "single-vacancy" model of ion permeation: if a channel has n conducting sites, it will contain either n or n-1 ions. Simple analytical expressions for the current, conductance, and reversal potential under bi-ionic conditions are derived. The results are compared with those of single ion models and recent experiments on Ca2(+)-activated K+ channels.     

K(+)-channel blockers do not decrease acetylcholine depolarizations in canine trachealis.

Using the double sucrose gap, we have examined the role of K+ channels in the cholinergic depolarizations in response to field stimulation and acetylcholine (Ach) in canine trachealis. Acetylcholine-like depolarization per se decreased electrotonic potentials from hyperpolarizing currents. The net effect of acetylcholine (10(-6) M) depolarization on membrane conductance was a small increase after the depolarization was compensated by current clamp. Reversal potentials for acetylcholine depolarization and for the excitatory junction potential (EJP) were determined by extrapolation to be 20-30 mV positive to the resting potential, previously shown to be approximately -55 mV. They were shifted positively by tetraethylammonium ion (TEA) at 20 mM or Ba2+ at 1 mM. TEA or Ba2+ initially depolarized the membrane and increased membrane resistance. Repolarization of the membrane restored any reductions in EJP amplitudes associated with depolarization. After 15 min, the membrane potential partially repolarized, and acetylcholine-induced depolarization and contractions were then increased by TEA. 4-Aminopyridine depolarized the membrane but decreased membrane resistance. Apamin (10(-6) M), charybdotoxin (10(-7) M), and glybenclamide (10(-5) M) each failed to significantly depolarize membranes, increase membrane resistance, or reduce EJP amplitudes or depolarization to 10(-6) M Ach. Glybenclamide reduced depolarizations to added acetylcholine slightly. TEA occasionally reduced the EJP markedly, but this was shown to be most likely a prejunctional effect mediated by norepinephrine release. TEA alone among K(+)-channel blockers slowed the onset and the time courses of the EJP as well as the acetylcholine-induced depolarization. K(+)-channel closure cannot be a complete explanation of acetylcholine-induced membrane effects on this tissue. Acetylcholine must have increased the conductance of an ion with a reversal potential positive to the resting potential in addition to any effect to close K+ channels.     

Effects of internal Na+ on the Ca channel outward current in mouse neoplastic B lymphocytes

The whole-cell configuration of the patch-clamp technique was used to study the outward Na+ current through Ca channels in hybridoma cell lines (202B and 206), constructed by fusion of S194 myeloma cells with murine splenic B lymphocytes. The concentration of Na+ in the electrode solution, [Na+]p, was changed by isosmotic replacement of Na+ with N-methyl-D-glucamine+ ions. When 2.5 mM calcium was present in the bath, neither the current nor the reversal potential was significantly altered by changes in the level of external Na+ [( Na+]o. By contrast, both of those properties were strongly affected by [Na+]p. At fixed depolarizing potentials, the outward current increased approximately as the square power of [Na+]p, a feature that cannot be easily explained by one-ion models for a channel or by "continuum" theories based on electrodiffusion. Instead, all the data could be well described by a "single-file" model for a two-site pore that admits up to two ions. Although double occupancy of the Ca channel by divalent cations has been proposed previously (Hess and Tsien. 1984. Nature. 309: 453-456; Almers et al., 1984. J. Physiol. 353: 585-608), this study indicates that, in our system, states of the channel with two Na+ ions must also be considered in order to explain the dependence of the outward current on [Na+]p. A good fit to the data could be obtained by assuming that both sites in the channel are "electrically" close to its cytoplasmic end and that most of the voltage dependence pertains to the rates for ion exit to the external medium. The values of the parameters suggest that: (a) Ca2+ is bound most strongly by the site nearest to the cytoplasm (in both singly and doubly occupied channels); (b) in channels with two Ca2+ ions, the dissociation constant of the site close to the external mouth must be greater than 2.5 mM; and (c) in pores occupied by two Na+ ions, the rate constant for Na+ exit to the external solution is larger than the rate constant for Na+ exit to the cytoplasm.     

Electrophysiological Control of Reversed Ciliary Beating in Paramecium

Quantitative relations between ciliary reversal and membrane responses were examined in electrically stimulated paramecia. Specimens bathed in 1 mM CaCl₂, 1 mM KCl, and 1 mM Tris-HCl, pH 7.2, were filmed at 250 frames per second while depolarizing current pulses were injected. At current intensities producing only electrotonic shifts the cilia failed to respond. Stimuli which elicited a regenerative response were followed by a period of reversed ciliary beating. With increasing stimulus intensities the latency of ciliary reversal dropped from 30 to 4 ms or less, and the duration of reversal increased from 50 ms to 2.4 s or more; the corresponding regenerative responses increased in amplitude and rate of rise. With progressively larger intracellular positive pulses, electric stimulation became less effective, producing responses with a progressive increase in latency and decrease in duration of reversed beating of the cilia. When 100-ms pulses shifted the membrane potential to +70 mV or more, ciliary reversal was suppressed until the end of the pulse. "Off" responses then occurred with a latency of 2–4 ms independent of further increases in positive potential displacement. These results suggest that ciliary reversal is coupled to membrane depolarization by the influx of ions which produces the regenerative depolarization of the surface membrane. According to this view suppression of the ciliary response during stimulation occurs when the membrane potential approaches the equilibrium potential of the coupling ion, thereby retarding its influx. Previous data together with the present findings suggest that this ion is Ca²⁺.     

Regulation of Ca2+-dependent K+ current by alphavbeta3 integrin engagement in vascular endothelium

Interactions between endothelial cells and extracellular matrix proteins are important determinants of endothelial cell signaling. Endothelial adhesion to fibronectin through alpha(v)beta(3) integrins or the engagement and aggregation of luminal alpha(v)beta(3) receptors by vitronectin triggers Ca2+ influx. However, the underlying signaling mechanisms are unknown. The electrophysiological basis of alpha(v)beta(3) integrin-mediated changes in endothelial cell Ca2+ signaling was studied using whole cell patch clamp and microfluorimetry. The resting membrane potential of bovine pulmonary artery endothelial cells averaged -60 +/- 3 mV. In the absence of intracellular Ca2+ buffering, the application of soluble vitronectin (200 microg/ml) resulted in activation of an outwardly rectifying K+ current at holding potentials from -50 to +50 mV. Neither a significant shift in reversal potential (in voltage clamp mode) nor a change in membrane potential (in current clamp mode) occurred in response to vitronectin. Vitronectin-activated current was significantly inhibited by pretreatment with the alpha(v)beta(3) integrin antibody LM609 by exchanging extracellular K+ with Cs+ or by the application of iberiotoxin, a selective inhibitor of large-conductance, Ca2+-activated K+ channels. With intracellular Ca2+ buffered by EGTA in the recording pipette, vitronectin-activated K+ current was abolished. Fura-2 microfluorimetry revealed that vitronectin induced a significant and sustained increase in intracellular Ca2+ concentration, although vitronectin-induced Ca2+ current could not be detected. This is the first report to show that an endothelial cell ion channel is regulated by integrin activation, and this K+ current likely plays a crucial role in maintaining membrane potential and a Ca2+ driving force during engagement and activation of endothelial cell alpha(v)beta(3) integrin.     

Stoichiometry of the Cardiac Na+/Ca2+ exchanger NCX1.1 measured in transfected HEK cells

The stoichiometry with which the Na+/Ca2+ exchanger, NCX1, binds and transports Na+ and Ca2+ has dramatic consequences for ionic homeostasis and cellular function of heart mycocytes and brain neurons, where the exchanger is highly expressed. Previous studies have examined this question using native NCX1 in its endogenous environment. We describe here whole-cell voltage clamp studies using recombinant rat heart NCX1.1 expressed heterologously in HEK-293 cells. This system provides the advantages of a high level of NCX1 protein expression, very low background ion transport levels, and excellent control over clamped voltage and ionic composition. Using ionic conditions that allowed bi-directional currents, voltage ramps were employed to determine the reversal potential for NCX1.1-mediated currents. Analysis of the relation between reversal potential and external [Na+] or [Ca2+], under a variety of intracellular conditions, yielded coupling ratios for Na+ of 1.9-2.3 ions per net charge and for Ca2+ of 0.45 +/- 0.03 ions per net charge. These data are consistent with a stoichiometry for the NCX1.1 protein of 4 Na+ to 1 Ca2+ to 2 charges moved per transport cycle.     

Characterization of the inward-rectifying potassium current in cat ventricular myocytes

Whole-cell membrane currents were measured in isolated cat ventricular myocytes using a suction-electrode voltage-clamp technique. An inward-rectifying current was identified that exhibited a time-dependent activation. The peak current appeared to have a linear voltage dependence at membrane potentials negative to the reversal potential. Inward current was sensitive to K channel blockers. In addition, varying the extracellular K+ concentration caused changes in the reversal potential and slope conductance expected for a K+ current. The voltage dependence of the chord conductance exhibited a sigmoidal relationship, increasing at more negative membrane potentials. Increasing the extracellular K+ concentration increased the maximal level of conductance and caused a shift in the relationship that was directly proportional to the change in reversal potential. Activation of the current followed a monoexponential time course, and the time constant of activation exhibited a monoexponential dependence on membrane potential. Increasing the extracellular K+ concentration caused a shift of this relationship that was directly proportional to the change in reversal potential. Inactivation of inward current became evident at more negative potentials, resulting in a negative slope region of the steady state current-voltage relationship between -140 and -180 mV. Steady state inactivation exhibited a sigmoidal voltage dependence, and recovery from inactivation followed a monoexponential time course. Removing extracellular Na+ caused a decrease in the slope of the steady state current-voltage relationship at potentials negative to -140 mV, as well as a decrease of the conductance of inward current. It was concluded that this current was IK1, the inward-rectifying K+ current found in multicellular cardiac preparations. The K+ and voltage sensitivity of IK1 activation resembled that found for the inward-rectifying K+ currents in frog skeletal muscle and various egg cell preparations. Inactivation of IK1 in isolated ventricular myocytes was viewed as being the result of two processes: the first involves a voltage-dependent change in conductance; the second involves depletion of K+ from extracellular spaces. The voltage-dependent component of inactivation was associated with the presence of extracellular Na+.     

Potassium and calcium currents activated by foetal calf serum in Balb-c 3T3 fibroblasts.

In quiescent Balb-c mouse 3T3 fibroblasts, the application of whole or dialyzed 10% foetal calf serum elicits a biphasic electrical response, consisting of a transient outward current, flowing through Ca(2+)-activated K+ channels, followed by an inward one, lasting up to 15 min. On the basis of experiments with ion substitutions and blockers, the inward current can be attributed to the opening of cationic channels permeable to Na+ and Ca2+ ions. This current could mediate the calcium influx involved in the sustained elevation of [Ca2+]i that has been observed in many preparations in response to mitogen stimulation and that is involved in triggering cell proliferation.