Voltage-dependent calcium and potassium conductances in striated muscle fibers from the scorpion,Centruroides sculpturatus

Ionic currents responsible for the action potential in scorpion muscle fibers were characterized using a three-intracellular microelectrode voltage clamp applied at the fiber ends (8–12°C). Large calcium currents (I _Ca) trigger contractile activation in physiological saline (5 mm Ca) but can be studied in the absence of contractile activation in a low Ca saline (2.5 mm). Barium (Ba) ions (1.5–3 mm) support inward current but not contractile activation.Ca conductance kinetics are fast (time constant of 3 msec at 0 mV) and very voltage dependent, with steady-state conductance increasing e-fold in approximately 4 mV. Half-activation occurs at –25 mV. Neither I _Ca nor I _Ba show rapid inactivation, but a slow, voltage-dependent inactivation eliminates I _Ca at voltages positive to –40 mV. Kinetically, scorpion channels are more similar to L-type Ca channels in vertebrate cardiac muscle than to those in skeletal muscle.Outward K currents turn on more slowly and with a longer delay than do Ca currents, and K conductance rises less steeply with voltage (e-fold change in 10 mV; half-maximal level at 0 mV). K channels are blocked by externally applied tetraethylammonium and 3,4 diaminopyridine.This work was supported by a grant from the NIH (NS-17510) to W.F.G. and a NRSA award to T.S. (GM-09921).     

Forskolin and phorbol esters decrease the same K+ conductance in cultured oligodendrocytes

Summary Cultured ovine oligodendrocytes (OLGs) express a number of voltage-dependent potassium currents after they attach to a substratum and as they begin to develop processes. At 24–48 hours following plating, an outward potassium current can be identified that represents a composite response of a rapidly inactivating component and a steady-state or noninactivating component. After 4–7 days in culture, OLGs also develop an inward rectifier current. We studied the effects of forskolin and phorbol 12-myristate 13-acetate (PMA) on OLG outward currents. These compounds are known to alter the myelinogenic metabolism of OLGs. PMA, an activator of protein kinase C (PK-C), has been shown to enhance myelin basic protein phosphorylation while forskolin acting on adenylate cyclase, and thereby increasing cAMP, inhibits it. Both forskolin and PMA increase the phosphorylation of 23-cyclic nucleotide phosphodiesterase, an OLG/myelin protein. We found that forskolin decreased the steady-state outward current at 120 mV by 10% at 100nm, and by 72% at 25 m from a holding potential of –80 mV. The time course of inactivation of the peak currents was decreased, affecting both the fast and slow time constants. There was no significant change in the steady-state parameters of current activation and inactivation. The effect of forskolin was attenuated when the adenylate cyclase inhibitor adenosine (2mm) was present in the intracellular/pipette filling solution. The results of PMA experiments were similar to those obtained with forskolin. Whereas the amplitude of the currents in the presence of PMA was reduced by 28% at 1.5nm and 60% and 600nm, the decay phase of the peak currents was less affected. The PMA effect could still be seen when the intracellular Ca²⁺ was reduced to 10nm with 5mm BAPTA, but was inhibited when the cells were pre-exposed to 50 m psychosine, a PK-C inhibitor. It is postulated that the potassium currents in OLG can be physiologically modulated by two distinct second-messenger systems, perhaps converging at the level of a common phosphorylated enzyme or regulatory protein.     

Patch-clamp study of isolated taste receptor cells of the frog

Summary Taste discs were dissected from the tongue ofR. ridibunda and their cells dissociated by a collagenase/low Ca/mechanical agitation protocol. The resulting cell suspension contained globular epithelial cells and, in smaller number, taste receptor cells. These were identified by staining properties and by their preserved apical process, the tip of which often remained attached to an epithelial (associated) cell. When the patch pipette contained 110mm KCl and the cells were superfused with NaCl Ringer's during whole-cell recording, the mean zero-current potential of 22 taste receptor cells was –65.2 mV and the slope resistance 150 to 750 M. Pulse-depolarization from a holding voltage of –80 mV activated a transient TTX-blockable inward Na current. Activation became noticeable at –25 mV and was half-maximal at –8 mV. Steady-state inactivation was half-maximal at –67 mV and complete at –50 mV. Peak Na current averaged –0.5 nA/cell. The Ca-ionophore A23187 shifted the activation and inactivation curve to more negative voltages. Similar shifts occurred when the pipette Ca was raised. External Ni (5mm) shifted the activation curve towards positive voltages by 10 mV. Pulse depolarization also activated outward K currents. Activation was slower than that of Na current and inactivation slower still. External TEA (7.5mm) and 4-aminopyridine (1mm) did not block, but 5mm Ba blocked the K currents. K-tail currents were seen on termination of depolarizing voltage pulses. A23187 shifted theI _K(V)-curve to more negative voltages. Action potentials were recorded when passing pulses of depolarizing outward current. Of the frog gustatory stimulants, 10mm Ca caused a reversible 5-to 10-mV depolarization in the current-clamp mode. Quinine (0.1mm, bitter) produced a reversible depolarization accompanied by a full block of Na current and, with slower time-course, a partial block of K currents. Cyclic AMP (5mm in the external solution or 0.5 m in the pipette) caused reversible depolarization (to –40 to –20 mV) due to partial blockage of K currents, but only if ATP was added to the pipette solution. Similar responses were elicited by stimulating the adenylate cyclase with forskolin. Blockage of cAMP-phosphodiesterase enhanced the response to cAMP. These results suggest that cAMP may be one of the cytosolic messengers in taste receptor cells. Replacement of ATP by AMP-PNP in the pipette abolished the depolarizing response to cAMP. Inclusion of ATP--S in the pipette caused slow depolarization to –40 to –20 mV, due to partial blockage of K currents. Subsequently, cAMP was without effect. The remaining K currents were blockable by Ba. These results suggest that cAMP initiates phosphorylation of one set of K channels to a nonconducting conformation.     

Electrophysiological and Theoretical Analysis of Depolarization-Dependent Outward Currents in the Dendritic Membrane of an Identified Nonspiking Interneuron in Crayfish

Depolarization-dependent outward currents were analyzed using the single-electrode voltage clamp technique in the dendritic membrane of an identified nonspiking interneuron (LDS interneuron) in situ in the terminal abdominal ganglion of crayfish. When the membrane was depolarized by more than 20 mV from the resting potential (65.0 ± 5.7 mV), a transient outward current was observed to be followed by a sustained outward current. Pharmacological experiments revealed that these outward currents were composed of 3 distinct components. A sustained component (I _s) was activated slowly (half rise time > 5 msec) and blocked by 20 mM TEA. A transient component (I _t1) that was activated and inactivated very rapidly (peak time < 2.5 msec, half decay time < 1.2 msec) was also blocked by 20 mM TEA. Another transient component (I _t2) was blocked by 100 M 4AP, activated rapidly (peak time < 10.0 msec) and inactivated slowly (half decay time > 131.8 msec). Two-step pulse experiments have revealed that both sustained and transient components are not inactivated at the resting potential: the half-maximal inactivation was attained at –21.0 mV in I _t1, and –38.0 mV in I _t2. I _s showed no noticeable inactivation. When the membrane was initially held at the resting potential level and clamped to varying potential levels, the half-maximal activation was attained at –36.0 mV in I _s, –31.0 mV in I _t1 and –40.0 mV in I _t2. The activation and inactivation time constants were both voltage dependent. A mathematical model of the LDS interneuron was constructed based on the present electrophysiological records to simulate the dynamic interaction of outward currents during membrane depolarization. The results suggest that those membrane conductances found in this study underlie the outward rectification of the interneuron membrane as well as depolarization-dependent shaping of the excitatory synaptic potential observed in current-clamp experiments.     

Electrophysiology of cultured human lens epithelial cells

Summary The lens epithelial K⁺ conductance plays a key role in maintaining the lens ionic steady state. The specific channels responsible for this conductance are unknown. We used cultured lens epithelia and patch-clamp technology to address this problem. Human lens epithelial explants were cultured and after 1–4 passages were dissociated and used in this study. The cells from which we measured had a mean diameter of 31±1 m (sem,n=26). The resting voltage was –19±4 mV (sem,n=10) and the input resistance was 2.5±0.5 G (sem,n=17) at –60 mV. Two currents were prominent in whole-cell recordings. An outwardly rectifying current was seen in nearly every cell. The magnitude of this current was a function of K⁺ concentration and was blocked by 3mm tetraethylammonium. The instantaneous current-voltage relationship was linear in symmetric K⁺, implying that the outward rectificiation was due to gating. The current showed complex activation and inactivation kinetics. The second current seen was a transient inward current. This current had kinetics very similar to the traditional Na⁺ current of excitable cells and was blocked by 0.1 m tetrodotoxin. In single-channel recordings, a 150-pS K⁺ channel and a 35-pS nonselective cation channel were seen but neither account for the macroscopic currents measured.     

Single calcium channels in neurons of rat spinal ganglia

Using a refined patch clamp technique, a study was made of single calcium channels of spinal ganglia neurons on a cell-attached membrane site in newborn rats; these convey the basic (high threshold) component of calcium current. Findings show that currents carried by calcium ions at a concentration of 60 mM in the recording pipet changes from 0.58±0.05 to 0.43±0.05 pA with a change in potential of 20 mV. This corresponds to a channel conductance of 7±0.5 pS. The distribution of open time was monoexponential with a time constant of about 0.75 msec, independent of membrane potential. Distribution of closed time approached a biexponential time course. The fast component (0.8 msec) was voltage-dependent, while the slow component decreased from 22 to 4 msec when depolarization increased by 20 mV. Using experimentally obtained time parameters which describe single calcium channel function, and assuming a three-tier model of the channel, the numerical values of the constants of transition rates between individual states were determined.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 673–682, September–October, 1985.     

Ca2+-activated K+ currents inNecturus choroid plexus

Summary The tight-seal whole-cell recording method has been used to studyNecturus choroid plexus epithelium. A cell potential of –59±2 mV and a whole cell resistance of 56±6 M were measured using this technique. Application of depolarizing step potentials activated voltage-dependent outward currents that developed with time. For example, when the cell was bathed in 110mm NaCl Ringer solution and the interior of the cell contained a solution of 110mm KCl and 5nm Ca²⁺, stepping the membrane potential from a holding value of –50 to –10 mV evoked outward currents which, after a delay of greater than 50 msec, increased to a steady state in 500 msec. The voltage dependence of the delayed currents suggests that they may be currents through Ca²⁺-activated K^_ channels. Based on the voltage dependence of the activation of Ca²⁺-activated K⁺ channels, we have devised a general method to isolate the delayed currents. The delayed currents were highly selective for K⁺ as their reversal potential at different K⁺ concentration gradients followed the Nernst potential for K⁺. These currents were reduced by the addition of TEA⁺ to the bath solution and were eliminated when Cs⁺ or Na⁺ replaced intracellular K⁺. Increasing the membrane potential to more positive values decreased both the delay and the half-times (t _1/2) to the steady value. Increasing the pipette Ca²⁺ also decreased the delay and decreasedt _1/2. For instance, when pipette Ca²⁺ was increased from 5 to 500nm, the delay andt _1/2 decreased from values greater than 50 and 150 msec to values less than 10 and 50 msec. We conclude that the delayed currents are K⁺ currents through Ca²⁺-activated K⁺ channels.At the resting membrane potential of –60 mV, Ca²⁺-activated K⁺ channels contribute between 13 to 25% of the total conductance of the cell. The contribution of these channels to cell conductance nearly doubles with membrane depolarization of 20–30 mV. Such depolarizations have been observed when cerebrospinal fluid (CSF) secretion is stimulated by cAMP and with intracellular Ca²⁺. Thus the Ca²⁺-activated K⁺ channels may play a specific role in maintaining intracellular K⁺ concentrations during CSF secretion.     

Voltage dependence of calcium current deactivation in the somatic membrane of mouse sensory neurons

Voltage dependence of the deactivation kinetics of calcium inward currents was investigated in the somatic membrane of murine spinal ganglia neurons. It was found that deactivation of high threshold calcium current has a slower component (=0.80–0.85 msec at a repolarizing potential of –80 mV) as well as the principal transient exponential component (130 sec at the same potential repolarizing level). A dissimilar relationship exists between amplitudes of the transient and slower exponential components, describing deactivation of high threshold calcium current and degree of activation of the depolarizing shift in membrane potential; the former dependence is expressed by a sigmoid and the latter by a V-shaped curve. The slower component of deactivation of high threshold current was inhibited substantially by perfusing the cell with a Tris-PO₄-containing solution. Low-threshold calcium tail current undergoes slower deactivation (=1.1–1.2 msec) at a repolarizing potential of –160 mV. A relationship between the time constant of low threshold current deactivation and the type of penetrating cation used was observed. A kinetic model of calcium current deactivation is suggested, taking account of the three different types of calcium channels, (one low and two high threshold) present in the somatic membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 2, pp. 185–193, March–April, 1988.     

Separation of sodium and calcium channels in the surface membrane of molluscan nerve cells

By intracellular dialysis of isolated neurons of the mollusksHelix pomatia andLimnaea stagnalis and by a voltage clamp technique the characteristics of transmembrane ionic currents were studied during controlled changes in the ionic composition of the extracellular and intracellular medium. By replacing the intracellular potassium ions by Tris ions, functional blocking of the outward potassium currents was achieved and the inward current distinguished in a pure form. Replacement of Ringer's solution in the extracellular medium with sodium-free or calcium-free solution enabled the inward current to be separated into two additive components, one carried by sodium ions, the other by calcium ions. Sodium and calcium inward currents were found to have different kinetics and different potential-dependence: _mNa=1±0.5 msec, _mCa=3±1 msec, _hNa=8±2 msec, _hCa=115±10 msec (V_m=0), G_Na=0.5 (V_m=–21±2 mV), G_Ca=0.5 (V_m=–8±2 mV). Both currents remained unchanged by tetrodotoxin, but the calcium current was specifically blocked by cadmium ions (2·10^–3 M), verapamil, and D=600, and also by fluorine ions if injected intracellularly. All these results are regarded as evidence that the soma membrane of the neurons tested possesses separate systems of sodium and calcium ion-conducting channels. Quantitative differences are observed in the relative importance of the systems of sodium and calcium channels in different species of mollusks.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 8, No. 2, pp. 183–191, March–April, 1976.     

GABA-Mediated Inhibition in Cultured Neurons of the Rat Brain Cortex

In cultured pyramidal neurons of the rat brain cortex, we recorded (in the whole-cell configuration) postsynaptic currents (PSC) evoked by direct electrical microstimulation of an axon of the interneuron adjacent to the pyramidal cell. Application of 5 M bicuculline rapidly, entirely, and reversibly blocked these currents. Linear changes in the holding potential on the membrane of the postsynaptic cell resulted in linear changes in the amplitude of averaged currents. The currents underwent reversion when the holding potential was –16 mV, which was close to the reversal potential for Cl^- ions at their respective concentrations in the extra- and intracellular solutions. We conclude that the recorded currents are inhibitory PSC (IPSC) mediated by GABA release. The amplitudes of the recorded currents varied from a measurable minimum (8 pA) to more than 150 pA at a holding potential on the postsynaptic cell membrane of –80 mV. Times to peak of the high- and low-amplitude currents showed no significant differences, being about 6.4 msec on average. Decays of the current could be satisfactorily approximated by a monoexponential function with a mean time constant of 17 msec. The time constants of IPSC decay were distributed accordingly to the Gaussian law. In some cases, the amplitude distributions of IPSC were unimodal ((with a rightward asymmetry), but in most cases they were clearly polymodal. The amplitude distribution can be described by the sum of several Gaussian distributions; the distance between modes of the Gaussians was 25 ± 6 pA, on average. The obtained estimates of the amplitude of monoquantal GABA-induced IPSC in neurons of the brain cortex allow us to conclude that in various CNS regions the dimension of the vesicles in GABA-ergic synapses formed by inhibitory interneurons is identical.     

Sodium channels in cultured chick dorsal root ganglion neurons

Isolated Na currents were studied in cultured chick sensory neurons using the patch clamp technique. On membrane depolarization, whole cell currents showed the typical transient and voltage-dependent time course as in nerve fibres. Na currents appeared at about-40 mV and reached maximum amplitude at around-10 mV. At low voltages (-30 to 0 mV), their turning-on was sigmoidal and inactivation developed exponentially. The ratio of inactivation time constants was found to be smaller than in squid axons and comparable to that of mammalian nodes of Ranvier. Peak conductance and steady-state inactivation were strongly voltage-dependent, with maximum slopes at-17 and-40 mV, respectively. The reversal potential was close to the Nernst equilibrium potential, indicating a high degree of ion-selectivity for the channel. Addition of 3M TTX, or replacement of Na by Choline in the external bath, abolished these currents. Internal pronase (1 mg/ml) and N-bromoacetamide (0.4 mM) made inactivation incomplete, with little effect on its rate of decay.Single Na channel currents were studied in outside-out membrane patches, at potentials between-50 and-20 mV. Their activation required large negative holding potentials (-90 mV). They were fully blocked by addition of TTX (3 M) to the external bath. At-40 mV their mean open time was about 2ms and the amplitude distribution could be fitted by a single Gaussian curve, indicating the presence of a homogeneous population of channels with a conductance of 11±2 pS. Probability of opening increased and latency to first opening decreased with increasing depolarization. Inactivation of the channel became faster with stronger depolarizations, as measured from the inactivation time course of sample averages. Internal pronase (0.1 mg/ml) produced effects on inactivation comparable to those on whole cell currents. Openings of the channel had a tendency to occur in bursts and showed little inactivation during pulses of 250 ms duration. The open lifetime of the channel at low potentials (-50,-40 mV) was only three times larger than in control patches, suggesting that Na channels in chick sensory neurons can close several times before entering an inactivating absorbing state.     

Effects of (±)-kavain on inactivation of voltage-operated Na+ channels

Effects of a kava-pyrone (±)-kavain on fast inactivation of Na⁺ channels were studied in experiments on isolated neurons from the rat hippocampus. (±)-Kavain was found to block Na⁺ channels, and its effect was voltage-dependent. At the holding potentials of –100 and –80 mV, IC₅₀ for (±)-kavain was 744.9 and 178.8 µM, respectively. The inactivation characteristic of Na⁺ channels was satisfactorily described with the Boltzmann's equation both in the control and under (±)-kavain application. (±)-Kavain at a 330 µM concentration shifted theV _1/2 toward more negative values by 14.4 mV and concurrently modified the slope factor: the latter was 5.7 mV in the control, while under the influence of 330 µM (±)-kavain it reached 6.7 mV. In agreement with Hille's hypothesis of a modulated receptor, inactivated Na⁺ channels demonstrated an increased sensitivity to kavain. (±)-Kavain effects resulted in an increase in the rate of depolarization-related fast inactivation, while the process of recovery from inactivation became slower when the membrane was hyperpolarized. Our data show that under the (±)-kavain effect the probability of the inactivated state of Na⁺ channels increases, and the state of fast inactivation is stabilized.Neirofiziologiya/Neurophysiology, Vol. 28, No. 4/5, pp. 218–224, July–October, 1996.     

Voltage-gated chloride currents in cultured canine tracheal epithelial cells

Summary Chloride ions (Cl^–) are concentrated in airway epithelial cells and subsequently secreted into the tracheal lumen by downhill flux through apical Cl^– channels. We have studied Cl^– currents in cultured canine tracheal cells using the whole-cell voltage-clamp technique. Ultrastructural techniques demonstrated that the cells used in the electrophysiological experiments possessed apical membrane specializations known to be present in the intact, transporting cell type. Cultured cells 2–6 days old were characterized by an input resistance of 3.4±0.8 G (n=11) and a capacitance of 63.8±10.8 pF (n=26). A comparison of 3 and 4 day-old cells with 5 and 6 day-old cells showed that the input resistance decreased almost 50%, and the cell capacitance and the inward and outward currents increased concomitantly approximately 200%. Cultured cells 3–4 days old held at –40 mV produced currents of 196±22 pA at 50 mV and –246±27 pA at –90 mV (n=212) with pipette and bath solutions containing primarily 140 KCl and 140 NaCl, respectively. The chloride channel blocker diphenylamine-2-carboxylate (DPC, 100 m) suppressed whole-cell currents by 76.8% at 60 mV; however, currents were unaffected by the stilbenes SITS (1mm) and DNDS (1–30 m). Replacement of K⁺ with Cs⁺ in the pipette solution did not affect the outward current, the current reversal potential, or the input resistance of the cells, indicating that the current was not significantly K⁺ dependent when the intrapipette solution was buffered to a Ca²⁺ concentration of 20nm. The Cl^–/Na⁺ permeability ratio was estimated to be greater than 11 as calculated from reversal potential measurements in the presence of an internal to external NaCl concentration ratio of 12. Current equilibrium permeabilities, relative to Cl^– were: I^– (2.9)NO ₃ ^– (1.1)Br^– (1.1)Cl^– (1.0)F^– (0.93)MeSO ₄ ^– (0.19)gluconate (0.18)aspartate (0.14). Depolarizations to potentials greater than 20 mV elicited a time-dependent component in the outward current in 71% of the cells studied. Currents inactivated with a double exponential time course at the most depolarized voltages. Recovery from inactivation was fast, holding potential-dependent, and followed a double exponential time course. Current amplitude was increased via a cAMP-dependent pathway as has been demonstrated for single Cl-selective channels in cell-attached patches from cultured canine and human tracheal epithelial cells. Forskolin, an activator of adenylate cyclase, produced a 260% increase in the outward current at +50 mV. In summary, cultured canine tracheal cells have a single resting conductance that is Cl^– selective, voltage-dependent, and modulated by a cAMP-dependent mechanism. This preparation appears to be appropriate for analysis of cellular modulation of airway Cl^– channels and Cl^– secretion.     

Voltage dependence of Na/K pump current inXenopus oocytes

Summary Stage V and VI (Dumont, J.N., 1972.J. Morphol. 136:153–180) oocytes ofXenopus laevis were treated with collagenase to remove follicular cells and were placed in K-free solution for 2 to 4 days to elevate internal [Na]. Na/K pump activity was studied by restoring the eggs to normal 3mm K Barth's solution and measuring membrane current-voltage (I–V) relationships before and after the addition of 10 m dihydroouabain (DHO) using a two-microelectrode voltage clamp. Two pulse protocols were used to measure membraneI–V relationships, both allowing membrane currents to be determined twice at each of a series of membrane potentials: (i) a down-up-down sequence of 5 mV, 1-sec stair steps and (ii) a similar sequence of 1-sec voltage pulses but with consecutive pulses separated by 4-sec recovery periods at the holding potential (–40 mV). The resulting membraneI–V relationships determined both before and during exposure to DHO showed significant hysteresis between the first and second current measurements at each voltage. DHO difference curves also usually showed hysteresis indicating that DHO caused a change in a component of current that varied with time. Since, by definition, the steady-state Na/K pumpI–V relationship must be free of hysteresis, the presence of hysteresis in DHO differenceI–V curves can be used as a criterion for excluding such data from consideration as a valid measure of the Na/K pumpI–V relationship. DHO differenceI–V relationships that did not show hysteresis were sigmoid functions of membrane potential when measured in normal (90mm) external Na solution. The Na/K pump current magnitude saturated near 0 mV at a value of 1.0–1.5 A cm^–2, without evidence of negative slope conductance for potentials up to +55 mV. The Na/K pump current magnitude in Na-free external solution was approximately voltage independent. Since these forward-going Na/K pumpI–V relationships do not show a region of negative slope over the voltage range –110 to +55 mV, it is not necessary to postulate the existence of more than one voltage-dependent step in the reaction cycle of the forward-going Na/K pump.     

The influence of membrane potential on chloride channels activated by GABA in rat cultured hippocampal neurons

Chloride currents were activated by a low concentration of GABA (0.5 m) in neonatal rat hippocampal neurons cultured for up to 14 days. Currents elicited by 0.5 m GABA in neurons, voltage-clamped using the whole-cell technique with pipettes containing 149 mm Cl^–, reversed close to 0 mV whether pipettes contained 144 mm Na⁺ or 140 mm Cs⁺, and were blocked by 100 m bicuculline. Current-voltage curves showed outward rectification. Single channel currents appeared in cell-attached patches when the pipette tip was perfused with pipette solution containing 0.5 m GABA and disappeared when a solution containing 100 m bicuculline plus 0.5 m GABA was injected into the pipette tip. The channels showed outward rectification and, in some patches, had a much lower probability of opening at hyperpolarized potentials. The average chord conductance in 10 patches hyperpolarized by 80 mV was 7.8±1.6 pS (sem) compared with a chord conductance of 34.1±3.5 pS (sem) in the same patches depolarized by 80 mV. Similar single channel currents were also activated in cell-free, inside-out patches in symmetrical chloride solutions when 0.5 m GABA was injected into the pipette tip. The channels showed outward rectification similar to that seen in cell-attached patches, and some channels had a lower probability of opening at hyperpolarized potentials. The average chord conductance in 13 patches hyperpolarized by 80 mV was 11.8±2.3 pS (sem) compared with 42.1±3.1 pS (sem) in the same patches depolarized by 80 mV.We are grateful to B. McLachlan and M. Robertson for their general assistance, to C. McCulloch and M. Smith for writing computer programs and to W. O'Hare for making the pipette injection device.     

Pharmacology of the SV channel in the vacuolar membrane of chenopodium rubrum suspension cells

Single channel performance and deactivation currents have been analyzed in the presence of cation channel blockers to reveal pharmacological properties of the slow-activating (SV) cation-selective ion channel in the vacuolar membrane (tonoplast) isolated from suspension cells of Chenopodium rubrum L. At a holding potential of –100 mV, the SV channel showed half-maximal inhibition with 20mm tetraethylammonium (TEA), 7 m 9amino-acridine, 6 m (+)-tubocurarine, 300nm quinacrine, and 35 m quinine, respectively. The SV channel is also blocked by charybdotoxin (20nm at –80 mV) but not by apamine. 9-Amino-acridine, (+)-tubocurarine and quinacrine act in a voltage-dependent fashion, binding to the open channel and to different sites along the transmembrane voltage profile according to Woodhull (J. Gen. Physiol. 61:687–708, 1973). No binding site could be specified for charybdotoxin, which binds to the closed channel, and for quinine. Except for quinine, all tested blockers were effective only if added to the cytoplasmic side of the tonoplast. A structural relationship between the SV channel and Maxi-K channels in animal systems is inferred.We are grateful to Prof. F. Dreyer and Dr. J. Beise from the Pharmacology Department of the Justus-Liebig-Universität Giessen for continuous interest and helpful suggestions. This work was supported by a grant from the Deutsche Forschungsgemeinschaft (Be 466/21-5) and the Bundesminister für Forschung und Technologie, Bonn.     

Characterization of sodium currents in mammalian sensory neurons cultured in serum-free defined medium with and without nerve growth factor

Summary The influence of nerve growth factor (NGF) on Na currents of rat dorsal root ganglia (DRG) was studied in neurons obtained from newborns and cultured for 2–30 hr inserum-free defined medium (SFM). Cell survival for the period studied was 78–87% both with and without NGF. Na currents were detected in all cells cultured for 6–9 hr. They were also detected after 2 hr in culture in 21.5% of the cells cultured without NGF (–NGF cells), and in 91.5% of the cells cultured with NGF (+NGF cells). Current density of the -NGF cells was 2.3 and 2 pA/m² after growth for 2 and 6–9 hr, respectively, compared to 3.0 and 3.9 pA/m² for the +NGF cells. The +NGF cells were separated into fast (F), Intermediate (I) and slow (S) cells, based on the Na current they expressed, while -NGF cells were all of theI type.F, I andS currents differed in their voltage-dependent inactivation (Vh ₅₀=–79, –28 and –20 mV), kinetics of inactivation (tau _h =0.55, 1.3 and 7.75 msec), and TTX sensitivity (K _i=60, 550 and 1100nm). All currents were depressed by [Ca] _o with aKd _Ca of 22, 17 and 8mm forF, I andS currents, respectively. Current density ofF andS currents was 5.5 and 5 pA/m² for theI current. The concentration-dependent curve ofI currentvs. TTX indicated thatI current has two sites: one withF-like and another withS-likeK _i for TTX. Hybridization ofF andS currents yieldI-like currents. Thus, the major effect of NGF on Na currents in SFM is the accleration of Na current acquisition and diversity, reflected in an increase of either theS orF type in a cell.     

Excitation-calcium release uncoupling in aged single human skeletal muscle fibers

The biological mechanisms underlying decline in muscle power and fatigue with age are not completely understood. The contribution of alterations in the excitation-calcium release coupling in single muscle fibers was explored in this work. Single muscle fibers were voltage-clamped using the double Vaseline gap technique. The samples were obtained by needle biopsy of the vastus lateralis (quadriceps) from 9 young (25–35 years; 25.9 ± 9.1; 5 female and 4 male) and 11 old subjects (65–75 years; 70.5 ± 2.3; 6 f, 5 m). Data were obtained from 36 and 39 fibers from young and old subjects, respectively. Subjects included in this study had similar physical activity. Denervated and slow-twitch muscle fibers were excluded from this study. A significant reduction of maximum charge movement (Q_max) and DHP-sensitive Ca current were recorded in muscle fibers from the 65–75 group. Q_max values were 7.6 ± 0.9 and 3.2 ± 0.3 nC/F for young and old muscle fibers, respectively (P < 0.01). No evidences of charge inactivation or interconversion (charge 1 to charge 2) were found. The peak Ca current was (–)4.7 ± 0.08 and (–)2.15 ± 0.11 A/F for young and old fibers, respectively (P < 0.01). The peak calcium transient studied with mag-fura-2 (400 m) was 6.3 ± 0.4 m and 4.2 ± 0.3 m for young and old muscle fibers, respectively. Caffeine (0.5 mm) induced potentiation of the peak calcium transient in both groups. The decrease in the voltage-/ Ca-dependent Ca release ratio in old fibers (0.18 ± 0.02) compared to young fibers (0.47 ± 0.03) (P < 0.01), was recorded in the absence of sarcoplasmic reticulum calcium depletion. These data support a significant reduction of the amount of Ca available for triggering mechanical responses in aged skeletal muscle and, the reduction of Ca release is due to DHPR-ryanodine receptor uncoupling in fast-twitch fibers. These alterations can account, at least partially for the skeletal muscle function impairment associated with aging.This work was supported by Grant-in-Aid from the American Heart Association (National) and Muscular Dystrophy Association, and National Institutes of Health (2-P60AG18484-06)     

Action of ω-conotoxin on calcium currents of rat pituitary GH3 cells

The effect of -conotoxin (-CgTX) on calcium currents of rat pituitary GH3 cells was studied by the voltage clamp method on a whole cell, under tight junction conditions. Two different components of the inward calcium current were observed in a solution containing 15 mM Ca²⁺. The first was activated with a holding potential of –80 mV and by testing pulses more positive than –55 mV. A shift of holding potential to –40 mV led to steady-state inactivation of this low-threshold component of the current. -CgTX at the initial moment after its application had an activating action on both components of the calcium current: low-threshold and high-threshold, but the increase in the first was much greater. In the present experiments the currents increased as early as 30 sec after replacement of the external solution; later the drop of current took place with temporal parameters characteristic of the spontaneous current drop in the control solution during cell dialysis. Incubation of the cells in growth medium containing 5 µM -CgTX for 2 h led to an increase in the density of both types of calcium currents in the GH3 cells, which was reduced after incubation for 2 h in the same medium. Thus -CgTX was found to have an activating action on calcium currents of GH3 cells at the initial moment after application of the toxin. The absence of a marked blocking action of -CgTX on the calcium currents of the test cells confirms the high tissue specificity of action of the toxin as a blocker of high-threshold calcium channels in the nerve cell membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 2, pp. 199–205, March–April, 1991.