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.     

Inwardly rectifying whole-cell and single-channel K currents in the murine macrophage cell line J774.1

Summary Inward currents in the murine macrophage-like cell line J774.1 were studied using the whole-cell and cell-attached variations of the patch-clamp technique. When cells were bathed in Na Hanks' (KCl=4.5mm, NaCl=145mm), and the electrode contained Na-free K Hanks' (KCl=145mm) single-channel currents were observed at potentials below –40 mV which showed inward rectification, were K-selective, and were blocked by 2.5mm Ba in the pipette. Single-channel conductance was 29 pS, and was proportional to the square root of [K] _o . Channels manifested complex kinetics, with multiple open and closed states. The steady-state open probability of the channel was voltage dependent, and declined from 0.9 to 0.45 between –40 and –140 mV. When hyperpolarizing voltage pulses were repetitively applied in the cell-attached patch mode, averaged single-channel currents showed inactivation. Inactivation of inwardly rectifying whole-cell current was measured in Na Hanks' and in two types of Na-free Hanks': one with a normal K concentration (4.5mm) and the other containing 145mm K. Inactivation was shown to have Na-dependent and Na-independent components. Properties of single-channel current were found to be sufficient to account for the behavior of the macroscopic current, except that single-channel current showed a greater degree of Na-independent inactivation than whole-cell current.     

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.     

Ionic basis of methacholine-induced shrinkage of dissociated eccrine clear cells

Summary Apical membrane currents were recorded from the taste pore of single taste buds maintained in the tongue of the rat, using a novel approach. Under a dissection microscope, the 150-m opening of a saline-filled glass pipette was positioned onto single fungiform papillae, while the mucosal surface outside the pipette was kept dry. Electrical responses of receptor cells to chemical stimuli, delivered from the pipette, were recorded through the pipette while the cells remained undamaged in their natural environment. We observed monophasic transient currents of 10-msec duration and 10–100 pA amplitude, apparently driven by action potentials arising spontaneously in the receptor cells. When perfusing the pipette with a solution of increased Na but unchanged Cl concentration, a stationary inward current (from pipette to taste cell) of 50–900 pA developed and the collective spike rate of the receptor cells increased. At a mucosal Na concentration of 250mm, the maximal collective spike rate of a bud was in the range of 6–10 sec^–1. In a phasic/tonic response, the high initial rate was followed by an adaptive decrease to 0.5–2 sec^–1. Buds of pure phasic response were also observed. Amiloride (30 m) present in the pipette solution reversibly and completely blocked the increase in spike rate induced by mucosal Na. Amiloride also decreased reversibly the stationary current which depended on the presence of mucosal Na (inhibition constant near 1 m). During washout of amiloride, spike amplitudes were first small, then increased, but always remained smaller than the amiloride-blockable stationary current of the bud. This is understandable since the stationary current of a bud arises from a multitude of taste cells, while each current spike is presumably generated by just one taste cell. We suggest that, in a Na-sensitive receptor cell, (i) the apical amiloride-blockable Na inward current serves as a generator current causing cell depolarization and firing of action potentials, and (ii) each current spike recorded from the taste pore arises mainly from a modulation of the apical Na inward current of this cell, because the action potential generated by the taste cell will transiently decrease or abolish the driving force for the apical Na inward current. The transients are indicators of receptor cell action potentials, which appear to be physiological responses of taste cellsin situ.     

Effects of the anion transport inhibitor,SITS, on the proximal straight tubule of the rabbit perfusedin vitro

Summary Conventional microelectrodes were used to study the effects of SITS (4-acetamido-4-isothiocyanostilbene-2,2-disulfonate) on the basolateral membrane potentialVbl of the superficial proximal straight tubule (PST) of the rabbit kidney perfusedin vitro. Addition of 0.1mm SITS to the bathing solution resulted in a slow and irreversible hyperpolarization ofVbl from –42.5±1.17 (37) mV to –77.3±0.83 (52) mV. The new steady-state potential was reached in 10 to 15 min and was accompanied by visible cell swelling. Associated with thisVbl hyperpolarization was: 1) an increased steady-state depolarization (from 6.2±0.77 (17) mV to 25.7±0.83 (29) mV) in response to increasing bath potassium concentration from 5 to 16.7mm (HK); 2) a decreased transient depolarization (from 19.8±1.88 (8) mV to 0.43±0.37 (8) mV) in response to decreasing bath bicarbonate concentration from 22 to 6.6mm at constant bath pH (L-HCO₃); and 3) inhibition of a depolarizing overshoot and a decreased steady-state depolarization (from 35.9±1.84 (12) mV to 4.7±1.37 (13) mV) in response to reducing bath sodium concentration from 144 to zero (0-Na). Sodium, chloride and NMDG (N-methyl-d-glucamine) were used as the substituting ions, respectively. These results are consistent with the presence of a coupled sodium-bicarbonate carrier in the basolateral membrane which is electrogenic and SITS inhibitable. Comparison of the time course of SITS effects on these ion-substitution responses suggests that the inhibition of the bicarbonate exit pathway(s) is the primary event and that the changes inVbl and in the steady-stateVbl responses to HK and 0-Na are secondary events which may be related to changes in intracellular composition and/or basolateral membrane properties.     

Voltage dependence of current through the Na,K-exchange pump ofRana oocytes

Summary We have studied current (I _Str) through the Na, K pump in amphibian oocytes under conditions designed to minimize parallel undesired currents. Specifically,I _Str was measured as the strophanthidin-sensitive current in the presence of Ba^2–, Cd²⁺ and gluconate (in place of external Cl^–). In addition,I _Str was studied only after the difference currents from successive applications and washouts of strophanthidin (Str) were reproducible. The dose-response relationship to Str in four oocytes displayed a meanK _0.5 of 0.4 m, with 2–5 m producing 84–93% pump' block. From baseline data with 12 Na⁺-preloaded oocytes, voltage clamped in the range [–170, +50 mV] with and without 2–5 m Str, the averageI _Str depended directly onV _m up to a plateau at 0 mV with interpolated zero current at –165 mV. In three oocytes, lowering the external [Na⁺] markedly decreased the voltage sensitivity ofI _p , while producing only a small change in the maximal outwardI _Str. In contrast, decreasing the external [K⁺] from 25 to 2.5mm reducedI _Str at 0 mV without substantially affecting its voltage dependence. At K⁺ concentrations of 1mm, both the absolute value ofI _Str at 0 mV and the slope conductance were reduced. In eight oocytes, the activation of the averagedI _Str by [K⁺] _o over the voltage interval [–30, +30 mV] was well fit by the Hill equation, with K=1.7±0.4mm andnH (the minimum number of K⁺ binding sites) =1.7±0.4. The results unequivocally establish that the cardiotonic-sensitive current ofRana oocytes displays only a positive slope conductance for [K⁺] _o >1mm. There is therefore no need to postulate more than one voltage-sensitive step in the cycling of the Na, K pump under physiologic conditions. The effects of varying external Na⁺ and K⁺ are consistent with results obtained in other tissues and may reflect an ion-well effect.     

Amiloride-blockable sodium currents in isolated taste receptor cells

Summary Isolated taste receptor cells from the frog tongue were investigated under whole-cell patch-clamp conditions. With the cytosolic potential head at –80 mV, more than 50% of the cells had a stationary inward Na current of 10 to 700 pA in Ringer's solution. This current was in some cells partially, in others completely, blockable by low concentrations of amiloride. With 110mm Na in the external and 10mm Na in the internal solution, the inhibition constant of amiloride was (at –80 mV) near 0.3 m. In some cells the amiloride-sensitive conductance was Na specific; in others it passed both Na and K. The Na/K selectivity (estimated from reversal potentials) varied between 1 and 100. The blockability bysmall concentrations of amiloride resembled that of channels found in some Na-absorbing epithelia, but the channels of taste cells showed a surprisingly large range of ionic specificities. Receptor cells, whichin situ express these channels in their apical membrane, may be competent to detect the taste quality salty. The same cells also express TTX-blockable voltage-gated Na channels.     

Cell K activity in frog skin in the presence and absence of cell current

Summary Cell K activity,a _k, was measured in the short-circuited frog skin by simultaneous cell punctures from the apical surface with open-tip and K-selective microelectrodes. Strict criteria for acceptance of impalements included constancy of the open-tip microelectrode resistance, agreement within 3% of the fractional apical voltage measured with open-tip and K-selective microelectrodes, and constancy of the differential voltage recorded between the open-tip and the K microelectrodes 30–60 sec after application of amiloride or substitution of apical Na. Skins were bathed on the serosal surface with NaCl Ringer and, to reduce paracellular Cl conductance and effects of amiloride on paracellular conductance, with NaNO₃ Ringer on the apical surface.Under control conditionsa _k ^r was nearly constant among skins (mean±SD=92±8mM, 14 skins) in spite of a wide range of cellular currents (5 to 70 A/cm²). Cell current (and transcellular Na transport) was inhibited by either apical addition of amiloride or substitution of Na by other cations. Although in some experiments the expected small increase ina _k ^r after inhibition of cell current was observed, on the average the change was not significant (98±11mM after amiloride, 101±12mM after Na substitution), even 30 min after the inhibition of cell current. The membrane potential, which in the control state ranged from –42 to –77 mV, hyperpolarized after inhibition of cell current, initially to –109±5mV, then depolarizing to a stable value (–88±5mV) after 15–25 min. At this time K was above equilibrium (E _k=98±2mV), indicating that the active pump mechanism is still operating after inhibition of transcellular Na transport.The measurement ofa _k ^r permitted the calculation of the passive K current and pump current under control conditions. assuming a constant current source with almost all of the basolateral conductance attributable to K. We found a significant correlation between pump current and cell current with a slope of 0.31, indicating that about one-third of the cell current is carried by the pump, i.e., a pump stoichiometry of 3Na/2K.     

Functional domains of bovine β-1,4 galactosyltransferase

A number of N- and C-terminal deletion and point mutants of bovine -1,4 galactosyltransferase (-1,4GT) were expressed inE. coli to determine the binding regions of the enzyme that interact withN-acetylglucosamine (NAG) and UDP-galactose. The N-terminal truncated forms of the enzyme between residues 1–129, do not show any significant difference in the apparentK _ms toward NAG or linear oligosaccharide acceptors e.g. for chitobiose and chitotriose, or for the nucleotide donor UDP-galactose. Deletion or mutation of Cys 134 results in the loss of enzymatic activity, but does not affect the binding properties of the protein either to NAG- or UDP-agarose. From these columns the protein can be eluted with 15mm NAG and 50mm EDTA, like the enzymatically active protein, TL-GT129, that contains residues 130–402 of bovine -1,4GT. Also the N-terminus fragment, TL-GT129NAG, that contains residues 130–257 of the -1,4GT, binds to, and elutes with 15mm NAG and 50mm EDTA from the NAG-agarose column as efficiently as the enzymatically active TL-GT129. Unlike TL-GT129, the TL-GT129NAG binds to UDP-columns less efficiently and can be eluted from the column with only 15mm NAG. The C-terminus fragment GT-257UDP, containing residues 258–402 of -1,4GT, binds tightly to both NAG- and UDP-agarose columns. A small fraction, 5–10% of the bound protein, can be eluted from the UDP-agarose column with 50mm EDTA alone. The results show that the binding behaviour of N- and C-terminal fragments of -1,4GT towards the NAG- and UDP-agarose columns differ, the former binds preferentially to NAG-columns, while the latter binds to UDP-agarose columns via Mn²⁺.     

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).     

Angiotensin II,vasopressin and GTP[γ-S] inhibit inward-rectifying K+ channels in porcine cerebral capillary endothelial cells

Summary Cerebral capillaries from porcine brain were isolated. and endothelial cells were grown in primary culture. The whole-cell tight seal patch-clamp method was applied to freshly isolated single endothelial cells, and cells which were held in culture up to one week. With high K⁺ solution in the patch pipette and in the bath we observed inward-rectifying K⁺ currents, showing a time-dependent decay in part of the experiments. Ba²⁺ (1–10mm) in the bath blocked this current, whereas outside tetraethylammonium (10mm) decreased the peak current but increased the steady-state current. Addition of 1 m of angiotensin II or of arginine-vasopressin to the extracellular side caused a time-dependent inhibition of the inward-rectifying K⁺ current in part of the experiments. Addition of 100 m GTP[-S] to the patch pipette blocked the K⁺ inward rectifier. In cell-attached membrane patches two types of single inward-rectifying K⁺ channels were observed, with single channel conductances of 7 and 35 pS. Cell-attached patches were also obtained at the antiluminal membrane of intact isolated cerebral capillaries. Only one type of K⁺ channel withg=30 pS was recorded. In conclusion, inwardly rectifying K⁺ channels, which can be inhibited by extracellular angiotensin II and arginine-vasopressin, are present in cerebral capillary endothelial cells. The inhibition of this K⁺ conductance by GTP[-S] indicates that G-proteins are involved in channel regulation. It is suggested that angiotensin II and vasopressin regulate K⁺ transport across the blood-brain barrier, mediating their effects via G-proteins.     

Effects of calcium and bay K-8644 on calcium currents in adrenal medullary chromaffin cells

Summary The kinetic and steady-state characteristics of calcium currents in cultured bovine adrenal chromaffin cells were analyzed by the patch-clamp technique. Whole cell inward Ca²⁺ currents, recorded in the presence of either 5.2 or 2.6mm Ca²⁺ exhibited a single, noninactivating component. To analyze the effects of Ca²⁺ and Bay K-8644 on the kinetics of the Ca²⁺ currents, we used a modified version of the Hodgkin-Huxley empirical model. At physiological [Ca²⁺] (2.5mm) the midpoint of the steady-state Ca²⁺-channel activation curve lay at –6.9 mV. Increasing the [Ca²⁺] to 5.2mm shifted the midpoint by –4.3 mV along the voltage axis. At the midpoint, changes in potential of 7.8 mV (for 5.2mm Ca²⁺) and 9.2 mV (for 2.5mm Ca²⁺) induced ane-fold change in the activation of the current. Increasing [Ca²⁺]₀ from 2.5 to 5.2mm induced a marked increase in the rate constant for turning on the Ca²⁺ permeability. Conductances were estimated from the slope of the linear part of the currentvoltage relationships as 8.7 and 4.2 nS in the presence of 5.2 and 2.5mm Ca²⁺, respectively. Incubation of the cells in the presence of Bay K-8644 at increasing concentrations from 0.001 to 0.1 m increased the slope conductance from 4.2 to 9.6 nS. Further increases in the concentration of Bay K-8644 from 1 to 100 m induced a marked reduction in the conductance to 1.1 nS. In the presence of Bay K-8644 (0.1 m) the midpoint of the activation curve was shifted by 6.1 mV towards more negative potentials, i.e., from –6.9 to –13 mV. At the midpoint potential of –13 mV, a change in potential of 6.9 mV caused ane-fold change in Ca²⁺ permeability. The kinetic analysis showed that Bay K-8644 significantly reduced the size of the rate constant for turning off the Ca²⁺ permeability.     

Intracellular potassium activity in mammalian proximal tubule: Effect of perturbations in transepithelial sodium transport

Summary Intracellular potassium activity (a _{K i} ) was measured in control conditions in mid-cortical rabbit proximal convoluted tubule using two methods: (i) by determination of the K⁺ equilibrium potential (E _K) using Ba²⁺-induced variations in the basolateral membrane potential (V _BL) during transepithelial current injections and (ii) with double-barrel K-selective microelectrodes. Using the first method, the meanV _BL was –48.5±3.2 mV (n=16) and the meanE _K was –78.4±4.1 mV corresponding to aa _{K i} of 68.7mm. With K-selective microelectrodes,V _BL was –36.6±1.1 mV (n=19),E _K was –64.0±1.1 mV anda _{K i} averaged 40.6±1.7mm. While these lastE _K andV _BL values are significantly lower than the corresponding values obtained with the first method (P<0.001 andP<0.01, respectively), the electrochemical driving force for K transport across the basolateral membrane ( _K =V _BL –E _K) is not significantly different for both techniques (30.1±3.3 mV for the first technique and 27.6±1.8 mV for ion-selective electrodes). This suggests an adequate functioning of the selective barrel but an underestimation ofV _BL by the reference barrel of the double-barrel microelectrode. Such double-barrel microelectrodes were used to measure temporal changes ina _{K i} and _K in different experimental conditions where Na reabsorption rate (J _Na) was reduced.a _{K i} was shown to increase by 12.2±2.7 (n=5) and 14.1±4.4mm (n=5), respectively, whenJ _Na was reduced by omitting in the luminal perfusate: (i) 5.5mm glucose and 6mm alanine and (ii) glucose, alanine, other Na-cotransported solutes and 110mm Na. In terms of the electrochemical driving force for K exit across the basolateral membrane, _K, a decrease of 5.4±2.0 mV (P<0.05,n=5) was measured when glucose and alanine were omitted in the luminal perfusate while _K remained unchanged whenJ _Na was more severely reduced (mean change =–1.7±2.1 mV, NS,n=5). In the latter case, this means that the electrochemical driving force for K efflux across the basolateral membrane has not changed while both the active influx through the Na–K pump and the passive efflux in steady state are certainly reduced. If the main pathway for K transport is through the basolateral K conductance, this implies that this conductance must have decreased in the same proportion as that of the reduction in the Na–K pump activity.     

Apical membrane K conductance in the toad urinary bladder

Summary The conductance of the apical membrane of the toad urinary bladder was studied under voltage-clamp conditions at hyperpolarizing potentials (mucosa negative to serosa). The serosal medium contained high KCl concentrations to reduce the voltage and electrical resistance across the basal-lateral membrane, and the mucosal solution was Na free, or contained amiloride, to eliminate the conductance of the apical Na channels. As the mucosal potential (V _m) was made more negative the slope conductance of the epithelium increased, reaching a maximum at conductance of the epithelium increased, reaching a maximum atV _m=–100 mV. This rectifying conductance activated with a time constant of 2 msec whenV _m was changed abruptly from 0 to –100 mV, and remained elevated for at least 10 min, although some decrease of current was observed. ReturningV _m to+100 mV deactivated the conductance within 1 msec. Ion substitution experiments showed that the rectified current was carried mostly by cations moving from cell to mucosa. Measurement of K flux showed that the current could be accounted for by net movement of K across the apical membrane, implying a voltage-dependent conductance to K (G _K). Mucosal addition of the K channel blockers TEA and Cs had no effect onG _K, while 29mm Ba diminished it slightly. Mucosal Mg (29mm) also reducedG _K, while Ca (29mm) stimulated it.G _K was blocked by lowering the mucosal pH with an apparent pK₁ of 4.5. Quinidine (0.5mm in the serosal bath) reducedG _K by 80%.G _K was stimulated by ADH (20 mU/ml), 8-Br-cAMP (1mm), carbachol (100 m), aldosterone (5×10^–7 m for 18 hr), intracellular Li and extracellular CO₂.     

Electrophysiological studies of forskolin-induced changes in ion transport in the human colon carcinoma cell line HT-29 cl.19A: Lack of evidence for a cAMP-activated basolateral K+ conductance

Summary Forskolin (i.e, cAMP)-modulation of ion transport pathways in filter-grown monolayers of the Cl^–-secreting subclone (19A) of the human colon carcinoma cell line HT29 was studied by combined Ussing chamber and microimpalement experiments.Changes in electrophysiological parameters provoked by serosal addition of 10^–5 m forskolin included: (i) a sustained increase in the transepithelial potential difference (3.9±0.4 mV). (ii) a transient decrease in transepithelial resistance with 26±3 · cm² from a mean value of 138±13 · cm² before forskolin addition, (iii) a depolarization of the cell membrane potential by 24±1 mV from a resting value of –50±1 mV and (iv) a decrease in the fractional resistance of the apical membrane from 0.80±0.02 to 0.22±0.01. Both, the changes in cell potential and the fractional resistance, persisted for at least 10 min and were dependent on the presence of Cl^– in the medium. Subsequent addition of bumetanide (10^–4 m), an inhibitor of Na/K/2Cl cotransport, reduced the transepithelial potential, induced a repolarization of the cell potential and provoked a small increase of the transepithelial resistance and fractional apical resistance. Serosal Ba²⁺ (1mm), a known inhibitor of basolateral K⁺ conductance, strongly reduced the electrical effects of forskolin. No evidence was found for a forskolin (cAMP)-induced modulation of basolateral K⁺ conductance.The results suggest that forskolin-induced Cl^– secretion in the HT-29 cl.19A colonic cell line results mainly from a cAMP-provoked increase in the Cl^– conductance of the apical membrane but does not affect K⁺ or Cl^– conductance pathways at the basolateral pole of the cell. The sustained potential changes indicate that the capacity of the basolateral transport mechanism for Cl^– and the basal Ba²⁺-sensitive K⁺ conductance are sufficiently large to maintain the Cl^– efflux across the apical membrane. Furthermore, evidence is presented for an anomalous inhibitory action of the putative Cl^– channel blockers NPPB and DPC on basolateral conductance rather than apical Cl^– conductance.     

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.     

Effect of membrane potential on furosemide-inhibitable sodium influxes in human red blood cells

Summary Furosemide-inhibitable Na influx (a measure of Na/K/Cl cotransport) was determined as a function of membrane potential in human red blood cells. The membrane potential was varied from –42 to +118 mV using valinomycin and gradients of K. The furosemide-inhibitable, unidirectional Na influx was independent of membrane potential over the entire range of potentials. The change in flux per mV, 0.443 mol/(liter cells·hr· mV), was not significantly different from zero. The mean flux was 153±16mol/(liter cells·hr) (±sem,n=71). The ouabain and furosemide-resistant influexes of Na and K were also measured as functions of membrane potential using either valinomycin and K or a chloride-free, tartrate flux medium to vary membrane potential. The unidirectional Na influx decreased slightly as the membrane potential was increased from negative potentials to about +10 mV. At higher membrane potentials Na influx rose dramatically with potential. This increase was not reversible and was also observed with K influx.     

Voltage-gated K+ channels in the mouse interleukin 3-dependent cell line,FDC-P2

Summary The electrical properties of a mouse interleukin (IL)-3-dependent cell line, FDC-P2, were examined using the tightseal whole-cell clamp technique. Under current clamp conditions with 140mM K⁺ in the pipette, the cells had a resting potential of –30 mV. Under voltage-clamp conditions, a transient outward current was elicited upon depolarization from a holding potential of –80 mV. The current was activated at potentials more positive than –10 mV and had a delayed-rectifying property. It showed rapid activation and slow inactivation during command steps. The current was abolished by Cs⁺ in the pipette, indicating that K⁺ is the charge carrier. The K⁺ current was suppressed by tetraethylammonium withK _i of <0.1mM and was not affected by scorpion toxin. Recovery from inactivation was steeply voltage dependent: As the holding potential was more hyperpolarized, the recovery became faster. Thus, with a holding potential of –80 mV, the current showed slight use-dependent inactivation, while the current decreased prominently by repetitive depolarization at a holding potential of –40 mV. These properties of the K⁺ current are similar to those of thel-type K⁺ channel current in mature T lymphocytes. The K⁺ current in FDC-P2 cells was dramatically reduced after culture in the IL-3-free medium for 1–2 days. When IL-3 was re-added to the medium, the current was re-expressed. These observations suggest that expression of the K⁺ current depends on extracellular IL-3, and that the current may play some roles in proliferation of these cells.     

Excitatory action of γ-aminobutyric acid (GABA) on crustacean neurosecretory cells

Summary 1. Intracellular and voltage-clamp recordings were obtained from a selected population of neuroscretory (ns) cells in the X organ of the crayfish isolated eyestalk. Pulses of -aminobutyric acid (GABA) elicited depolarizing responses and bursts of action potentials in a dose-dependent manner. These effects were blocked by picrotoxin (50 µM) but not by bicuculline. Picrotoxin also suppressed spontaneous synaptic activity.2. The responses to GABA were abolished by severing the neurite of X organ cells, at about 150 µm from the cell body. Responses were larger when the application was made at the neuropil level.3. Topical application of Cd²⁺ (2 mM), while suppressing synaptic activity, was incapable of affecting the responses to GABA.4. Under whole-cell voltage-clamp, GABA elicited an inward current with a reversal potential dependent on the chloride equilibrium potential. The GABA effect was accompanied by an input resistance reduction up to 33% at a –50 mV holding potential. No effect of GABA was detected on potassium, calcium, and sodium currents present in X organ cells.5. The effect of GABA on steady-state currents was dependent on the intracellular calcium concentration. At 10^–6 M [Ca²⁺]_i, GABA (50 µM) increased the membrane conductance more than threefold and shifted the zero-current potential from–25 to–10 mV. At 10^–9 M [Ca²⁺]_i, GABA induced only a 1.3-fold increase in membrane conductance, without shifting the zero-current potential.6. These results support the notion that in the population of X organ cells sampled in this study, GABA acts as an excitatory neurotransmitter, opening chloride channels.     

Electrical characteristics of stomatal guard cells: The contribution of ATP-dependent, “Electrogenic” transport revealed by current-voltage and difference-current-voltage analysis

Summary The steady-state, current-voltage (I–V) characteristics of stomatal guard cells fromVicia faba L. were explored by voltage clamp using conventional electrophysiological techniques, but with double-barrelled microelectrodes containing 50mm K⁺-acetate. Attention was focused, primarily, on guard cell response to metabolic blockade. Exposures to 0.3–1.0mm NaCN and 0.4mm salicylhydroxamic acid (SHAM) lead consistently to depolarizing (positive-going) shifts in guard cell potentials (V _m ), as large as +103 mV, which were generally complete within 60–90 sec (mean response half-time, 10.3±1.7 sec); values forV _m in NaCN plus SHAM were close or positive to –100 mV and well removed from the K⁺ equilibrium potential. Guard cell ATP content, which was followed in parallel experiments, showed a mean half-time for decay of 10.8±1.9 ([ATP] _t=0, 1.32±0.28mm; [ATP] _{t=60–180sec}, 0.29±0.40mm). In respiring cells, theI–V relations were commonly sigmoid aboutV _m or gently concave to the voltage axis positive toV _m . Inward- and outward-rectifying currents were also observed, especially near the voltage extremes (nominally –350 and +50 mV). Short-circuit currents (atV=0 mV) were typically about 200–500 mA m^–2. The principal effect of cyanide early on was to linearize theI–V characteristic while shifting it to the right along the voltage axis, to decrease the membrane conductance, and to reduce the short-circuit current by approx. 50–75%. The resulting difference-current-voltage (dI–V) curves (±cyanide) showed a marked sensitivity to voltages negative from –100 mV and, when clamp scans had been extended sufficiently, they revealed a distinct minimum near –300 mV before rising at still more negative potentials. The difference currents, along with changes in guard cell potential, conductance and ATP content are interpreted in context of a primary, ATP-consuming ion pump. FittingdI–V curves to reaction kinetic model for the pump [Hansen, U.-P., et al. (1981)J. Membrane Biol. 63:165; Blatt, M.R. (1986)J. Membrane Biol. 92:91] implicates a stoichiometry of one (+) charge transported outward for each ATP hydrolyzed, with pump currents as high as 200 mA m^–2 at the free-running potential. The analysis indicates that the pump can comprise more than half of the total membrane conductance and argues against modulations of pump activity alone, as an effective means to controlling K⁺ transport for stomatal movements.