Ba2+-sensitive potassium permeability of the apical membrane in newt kidney proximal tubule

Summary The apical membrane K⁺ permeability of the newt proximal tubular cells was examined in the doubly perfused isolated kidney by measuring the apical membrane potential change (V _a change) during alteration of luminal K⁺ concentration and resultant voltage deflections caused by current pulse injection into the lumen.V _a change/decade for K⁺ was 50 mV at K⁺ concentration higher than 25mm, and the resistance of the apical membrane decreased bt 58% of control when luminal K⁺ concentration was increased from 2.5 to 25mm. Ba²⁺ (1mm in the lumen) reducedV _a change/decade to 24 mV and increased the apical membrane resistance by 70%. These data support the view that Ba²⁺-sensitive K⁺ conductance exists in the apical membrane of the newt proximal tubule. Furthermore, intracellular K⁺ activity measured by K⁺-selective electrode was 82.4 ± 3.6 meq/liter, which was higher than that predicted from the Nernst equation for K⁺ across both cell membranes. Thus, it is concluded that cell K⁺ passively diffuses, at least in part, through the K⁺ conductive pathway of the apical membrane.     

An Amiloride-sensitive Na+ conductance in the basolateral membrane of toad urinary bladder

Summary Exposing the apical membrane of toad urinary bladder to the ionophore nystatin lowers its resistance to less than 100 cm². The basolateral membrane can then be studied by means of transepithelial measurements. If the mucosal solution contains more than 5mm Na⁺, and serosal Na⁺ is substituted by K⁺, Cs⁺, or N-methyl-d-glucamine, the basolateral membrane expresses what appears to be a large Na⁺ conductance, passing strong currents out of the cell. This pathway is insensitive to ouabain or vanadate and does not require serosal or mucosal Ca²⁺. In Cl-free SO ₄ ^2– Ringer's solution it is the major conductive pathway in the basolateral membrane even though the serosal side has 60mm K⁺. This pathway can be blocked by serosal amiloride (K _i=13.1 m) or serosal Na⁺ ions (K _i 10 to 20mm). It also conducts Li⁺ and shows a voltage-dependent relaxation with characteristic rates of 10 to 20 rad sec^–1 at 0 mV.     

Ion transport by mitochondria-rich cells in toad skin

Summary The optical sectioning video imaging technique was used for measurements of the volume of mitochondria-rich (m.r.) cells of the isolated epithelium of toad skin. Under short-circuit conditions, cell volume decreased by about 14% in response to bilateral exposure to Cl-free (gluconate substitution) solutions, apical exposure to ouabain resulted in a large increase in volume, which could be prevented either by the simultaneous application of amiloride in the apical solution or by the exposure of the epithelium to bilateral Cl-free solutions. Unilateral exposure to a Cl-free solution did not prevent ouabain-induced cell swelling. It is concluded that m.r. cells have an amiloride-blockable Na conductance in the apical membrane, a ouabain-sensitive Na pump in the basolateral membrane, and a passive Cl permeability in both membranes. From the initial rate of ouabain-induced cell volume increase the active Na current carried by a single m.r. cell was estimated to be 9.9±1.3 pA. Voltage clamping of the preparation in the physiological range of potentials (0 to –100 mV, serosa grounded) resulted in a cell volume increase with a time course similar to that of the stimulation of the voltage-dependent activation were prevented by exposure of the tissue to a Cl-free apical solution. The steady-state volume of the m.r. cells increased with the clamping voltage, and at –100 mV the volume was about 1.15 times that under short-circuit conditions. The rate of volume increase during current passage was significantly decreased by lowering the serosal K concentration (K _i ) to 0.5mm, but was independent of whether K _i was 2.4, 5, or 10mm. This indicates that the K conductance of the serosal membrane becomes rate limiting for the uptake of KCl when K _i is significantly lower than its physiological value. It is concluded that the voltage-activated Cl currents flow through the m.r. cells and that swelling is caused by an uptake of Cl ions from the apical bath and K ions from the serosal bath. Bilateral exposure of the tissue to hypo- or hypertonic bathing solutions changed cell volume without detectable changes in the Cl conductance. The volume response to external osmotic perturbations followed that of an osmometer with an osmotically inactive volume of 21%. Using this value and the change in cell volume in response to bilateral Cl-free solutions, we calculated an intracellular steady-state Cl concentration of 19.8±1.7mm (n=6) of the short-circuited cell.     

Implications of an anomalous intracellular electrical response in bullfrog corneal epithelium

Summary The ionic dependencies of the transepithelial and intracellular electrical parameters were measured in the isolated frog cornea. In NaCl Ringer's the intracellular potential differenceV _sc measured under short-circuit conditions depolarized by nearly the same amount after either increasing the stromal-side KCl concentration from 2.5 to 25mm or exposure to 2mm BaCl₂ (K⁺ channel blocker). With Ba²⁺ the depolarization of theV _sc by 25mm K⁺ was reduced to one-quarter of the control change. If the Cl-permselective apical membrane resistanceR _o remained unchanged, the relative basolateral membrane resistanceR _i, which includes the lateral intercellular space, increased at the most by less than twofold after Ba²⁺. These effects in conjunction with the depolarization of theV _sc by 62 mV after increasing the stromal-side K⁺ from 2.5 to 100mm in Cl-free Ringer's as well as the increase of the apparent ratio of membrane resistances (a=R _o/R_i) from 13 to 32 are all indicative of an appreciable basolateral membrane K⁺ conductance. This ratio decreased significantly after exposure to either 25mm K⁺ or Ba²⁺. The decline ofR _o/R_i with 25mm K⁺ appears to be anomalous since this decrease is not consistent with just an increase of basolateral membrane conductance by 25mm K⁺, but rather perhaps a larger decrease ofR _o thanR _iAlso an increase of lateral space resistance may offset the effect of decreasingR _i with 25mm K⁺. In contrast,R _o/R_i did transiently increase during voltage clamping of the apical membrane potential differenceV _o and exposure to 25mm K⁺ on the stromal side. This increase and subsequent decrease ofR _o/R_i supports the idea that increases in stromal K⁺ concentration may produce secondary membrane resistance changes. These effects onR _o/R_i show that the presence of asymmetric ionic conductance properties in the apical and basolateral membranes can limit the interpretative value of this parameter. The complete substitution of Na⁺ withn-methyl-glucamine in Cl-free Ringer's on the stromal side hyperpolarized theV _sc by 6 mV whereas 10^–4 m ouabain depolarized theV _sc by 7 mV. Thus the basolateral membrane contains K⁺, Na⁺ and perhaps Cl^– pathways in parallel with the Na/K pump component.     

Electrical effects of potassium and bicarbonate on proximal tubule cells ofNecturus

Summary The effects of stepwise concentration changes of K⁺ and HCO ₃ ^– in the basolateral solution on the basolateral membrane potential (V _bl) of proximal tubule cells of the doubly-perfusedNecturus kidney were examined using conventional microelectrodes. Apparent transference numbers were calculated from changes inV _bl after alterations in external K⁺ concentration from 1.0 to 2.5mm (t _{K, 1.0–2.5}), 2.5 to 10, and in external HCO ₃ ^– concentration (at constant pH) from 5 to 10mm (t _{HCO3, 5–10}), 10 to 20, or 10 to 50.t _{K, 2.5–10} was 0.38±0.02 under control conditions but was sharply reduced to 0.08±0.03 (P>0.001) by 4mm Ba⁺⁺. This concentration of Ba⁺⁺ reducedV _bl by 9±1 mV (at 2.5 external K⁺). Perfusion with SITS (5×10^–4 m) for 1 hr hyperpolarizedV _bl by 10±3 mV and increasedt _{K, 2.5–10} significantly to 0.52±0.01 (P<0.001). Ba⁺⁺ application in the presence of SITS depolarizedV _bl by 22±3 mV. In control conditionst _{HCO3, 10–50} was 0.63±0.05 and was increased to 0.89±0.07 (P<0.01) by Ba⁺⁺ but was decreased to 0.14±0.02 (P<0.001) by SITS. In the absence of apical and basolateral chloride, the response ofV _bl to bicarbonate was diminished but still present (t _{HCO3, 10–20} was 0.35±0.03). Intracellular pH, measured with liquid ion-exchange microelectrodes, increased from 7.42±0.19 to 7.57±0.17 (P<0.02) when basolateral bicarbonate was increased from 10 to 20mm at constant pH. These data show that the effects of bicarbonate onV _bl are largely independent of effects on the K⁺ conductance and that there is a significant current-carrying bicarbonate pathway in the basolateral membrane. Hence, both K⁺ and HCO ₃ ^– gradients are important in the generation ofV _bl, and their relative effects vary reciprocally.     

Saturable K+ pathway across the outer border of frog skin (Rana temporaria): Kinetics and inhibition by Cs+ and other cations

Summary The reaction of abdominal skins of the frog speciesRana temporaria on mucosal K⁺-containing solutions was studied in an Ussing-type chamber by recording transepithelial potential difference (PD), short-circuit current (SCC) and conductance (G). With Na-Ringer's as serosal medium, a linear correlation between PD and the logarithm of the mucosal K⁺-concentration ([K] _o ) was obtained. The K⁺-dependent SCC saturated with increasing [K] _o , and could quickly and reversibly be depressed by addition of Rb⁺, Cs⁺, and H⁺, Li⁺, Na⁺, and NH ₄ ⁺ did not influence K⁺ current. A large scatter was obtained for kinetic parameters like the slope of the PD-log [K] _o -line (18–36.5 mV/decade), the apparent Michaelis constant (13–200mm), and the maximal current of the saturable SCC (6–50 A·cm^–2), as well as for the degree of inhibition by Cs⁺ ions. This seemed to be caused by a time-dependent change during long time exposure to high [K] _o (more than 30 sec), thereby inducing a selectivity loss of K⁺-transporting structures, together with an increase in SCC andG and a decrease in PD. Short time exposure to K⁺-containing solutions showed a competitive inhibition of K⁺ current by Cs⁺ ions, and a Michaelis constant of 6.6mm for the inhibitory action of Cs⁺. Proton titration resulted in a decrease of K⁺ current at pH<3. An acidic membrane component (apparent dissociation constant 2.5×10^–3 m) is virtually controlling K⁺ transfer. Reducing the transepithelial K⁺-concentration gradient by raising the serosal potassium concentration was accompanied by the disappearance of SCC and PD.     

Microelectrode characterization of the basolateral membrane of rabbit S3 proximal tubule

Summary The purpose of this study was to characterize the basolateral membrane of the S3 segment of the rabbit proximal tubule using conventional and ion-selective microelectrodes. When compared with results from S1 and S2 segments, S3 cells under control conditions have a more negative basolateral membrane potential (V _bl=–69 mV), a higher relative potassium conductance (t _K=0.6), lower intracellular Na⁺ activity (A _Na=18.4mm), and higher intracellular K⁺ activity (A _K=67.8mm). No evidence for a conductive sodium-dependent or sodium-independent HCO ₃ ^– pathway could be demonstrated. The basolateral Na–K pump is inhibited by 10^–4 m ouabain and bath perfusion with a potassium-free (0-K) solution. 0-K perfusion results inA _Na=64.8mm,A _K=18.5mm, andV _bl=–28 mV. Basolateral potassium channels are blocked by barium and by acidification of the bathing medium. The relative K⁺ conductance, as evaluated by increasing bath K⁺ to 17mm, is dependent upon the restingV _bl in both S2 and S3 cells. In summary, the basolateral membrane of S3 cells contains a pump-leak system with similar properties to S1 and S2 proximal tubule cells. The absence of conductive bicarbonate pathways results in a hyperpolarized cell and larger Na⁺ and K⁺ gradients across the cell borders, which will influence the transport properties and intracellular ion activities in this tubule segment.     

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.     

Effect of adherence,cell morphology,and lipopolysaccharide on potassium conductance and passive membrane properties of murine macrophage J774.1 cells

Summary The effects of adherence, cell morphology, and lipopolysaccharide on electrical membrane properties and on the expression of the inwardly rectifying K conductance in J774.1 cells were investigated. Whole-cell inwardly rectifying K currents (K _i), membrane capacitance (C _m), and membrane potential (V _m) were measured using the patch-clamp technique. SpecificK _i conductance (G _K i, whole-cell Ki conductance corrected for leak and normalized to membrane capacitance) was measured as a function of time after adherence, and was found to increase almost twofold one day after plating. Membrane potential (V _m) also increased from –42±4 mV (n=32) to –58±2 mV (n=47) over the same time period.G _K i andV _m were correlated with each other;G _L (leak conductance normalized to membrane capacitance) andV _m were not. The magnitudes ofG _K i andV _m 15 min to 2 hr after adherence were unaffected by the presence of 100 m cycloheximide, but the increase inG _K iandV _m that normally occurred between 2 and 8 hr after adherence was abolished by cycloheximide treatment. Membrane properties were analyzed as a function of cell morphology, by dividing cells into three categories ranging from small round cells to large, extremely spread cells. The capacitance of spread cells increased more than twofold within one day after adherence, which indicates that spread cells inserted new membrane. Spread cells had more negative resting membrane potentials than round cells, butG _K i andG _L were not significantly different. Lipopolysaccharide-(LPS; 1 or 10 g/ml) treated cells showed increasedC _m compared to control cells plated for comparable times. In contrast to the effect of adherence, LPS-treated cells exhibited a significantly lowerG _K i than control cells, indicating that the additional membrane did not have as high a density of functionalG _K i channels. We conclude that both adherence and LPS treatment increase the total surface membrane area of J774 cells and change the density of Ki channels. In addition, this study demonstrates that membrane area and density of Ki channels can vary independently of one another.     

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.     

X-ray microanalysis of elements in frozen-hydrated sections of an electrogenic K+ transport system: The posterior midgut of tobacco hornworm (Manduca sexta) in vivo andin vitro

Summary The lepidopteran midgut is a model for the oxygendependent, electrogenic K⁺ transport found in both alimentary and sensory tissues of many economically important insects. Structural and biochemical evidence places the K⁺ pump on the portasome-studded apical plasma membrane which borders the extracellular goblet cavity. However, electrochemical evidence implies that the goblet cell K⁺ concentration is less than 50mm. We used electron probe X-ray microanalysis of frozenhydrated cryosections to measure the concentration of Na, Mg, P, S, Cl, K, Ca and H₂O in several subcellular sites in the larval midgut ofManduca sexta under several experimental regimes. Na is undetectable at any site. K is at least 100mm in the cytoplasm of all cells. Typicalin vivo values (mm) for K were: blood, 25; goblet and columnar cytoplasm, 120; goblet cavity, 190; and gut lumen, 180. The high K concentration in the apically located goblet cavity declined by 100mm under anoxia. Both cavity and gut fluid are Cl deficient, but fixed negative charges may be present in the cavity. We conclude that the K⁺ pump is sited on the goblet cell apical membrane and that K⁺ follows a nonmixing pathway via only part of the goblet cell cytoplasm. The cavity appears to be electrically isolated in alimentary tissues, as it is in sensory sensilla, thereby allowing a PD exceeding 180 mV (lumen positive) to develop across the apical plasma membrane. This PD appears to couple K⁺ pump energy to nutrient absorption and pH regulation.     

Effects of NEM on Voltage-activated Chloride Conductance in Toad Skin

The regulation of the voltage-activated chloride current conductance (G _Cl ) in toad skin was investigated by the use of the SH reagents N-ethylmaleimide (NEM) and p-chloro-mercuricbenzenesulfonic acid PCMBS. This anion pathway is controlled by a voltage-sensitive gating regulator. Mucosal application of NEM decreased the voltage-activation in a time and concentration dependent manner, half-maximal inhibition being exerted at a concentration of 30 μm within 20 min. At concentrations higher than 100 μm, the voltage-activated G _Cl was near-completely and irreversibly inhibited in less than 10 min. Resting, deactivated conductance was essentially unaffected. NEM had no effect on active sodium transport (measured as I _sc ) under conditions, which fully dissipated the voltage-activated G _Cl . After complete inhibition of the voltage-activated G _Cl with NEM, chloride conductance could still be stimulated by CPT-cAMP as in control tissues. Under these conditions, NEM at concentrations above 1 mm decreased G _Cl reversibly. Mucosal application of PCMBS at 500 μm inhibited the activated conductance by 35%, which was slightly reversible. Inhibition of voltage-activated G _Cl , which was observed after mucosal addition of the membrane-impermeable NEM analogue, eosin-5-maleimide, was completely reversible after washout. This suggests that the binding site for the maleimide is not accessible from the external face of the apical membrane. Brief application of NEM at lower concentrations (1–3 min, ≤100 μm) led to partial inhibition of G _Cl , followed by occasionally complete recovery upon washout of NEM. Recovery of voltage-activated G _Cl was progressively attenuated and eventually disappeared after subsequent brief applications of NEM. This could reflect recruitment of permeation/control sites from a finite pool. The data are discussed in the frame of a working model for the voltage-activated Cl⁻-pathway, that contains two principle components, i.e., an anion-selective permeation path which is controlled by regulatory protein(s). Received: 18 December 1996/Revised: 28 April 1997     

Ca2+-activated K+ conductance of the human red cell membrane: Voltage-dependent Na+ block of outward-going currents

Summary Human red cells were prepared with various cellular Na⁺ and K⁺ concentrations at a constant sum of 156mm. At maximal activation of the K⁺ conductance,g _K(Ca), the net efflux of K⁺ was determined as a function of the cellular Na⁺ and K⁺ concentrations and the membrane potential,V _m , at a fixed [K⁺]_ex of 3.5mm.V _m was only varied from (V _m –E _K)25 mV and upwards, that is, outside the range of potentials with a steep inward rectifying voltage dependence (Stampe & Vestergaard-Bogind, 1988).g _K(Ca) as a function of cellular Na⁺ and K⁺ concentrations atV _m =–40, 0 and 40 mV indicated a competitive, voltage-dependent block of the outward current conductance by cellular Na⁺. Since the present Ca²⁺-activated K⁺ channels have been shown to be of the multi-ion type, the experimental data from each set of Na⁺ and K⁺ concentrations were fitted separately to a Boltzmann-type equation, assuming that the outward current conductance in the absence of cellular Na⁺ is independent of voltage. The equivalent valence determined in this way was a function of the cellular Na⁺ concentration increasing from 0.5 to 1.5 as this concentration increased from 11 to 101mm. Data from a previous study of voltage dependence as a function of the degree of Ca²⁺ activation of the channel could be accounted for in this way as well. It is therefore suggested that the voltage dependence ofg _K(Ca) for outward currents at (V _m –E _K)>25 25 mV reflects a voltage-dependent Na⁺ block of the Ca²⁺-activated K⁺ channels.     

Potassium-dependent,bipolar gating of K+ channels in guard cells

Summary Guard cells of higher plants control transpirational water loss and gas exchange for photosynthesis by opening and closing pores in the epidermis of the leaf. To power these turgordriven movements, guard cells accumulate (and lose) 200 to 400mm (1 to 3 pmol/cell) K⁺, fluxes thought to pass through K⁺ channels in the guard cells plasma membrane. Steady-state current-voltage (I–V) relations of intactVicia guard cells frequently show large, outward-going currents at potentials approaching 0 mV. Since this current could be carried by K⁺ channels, its pharmacology and dependence on external K⁺ (K _v ⁺ ) has been examined under voltage clamp over an extended potential range. Measurements were carried out on cells which showed little evidence of primary electrogenic transport, thus simplifying analyses. Clamping these cells away from the free-running membrane potential (V _m ) revealed an outward-rectifying current with instantaneous and time-dependent components, and sensitive to the K⁺ channel blocker tetraethylammonium chloride. The current declined also under metabolic blockade with NaCN and in the presence of diethylstilbesterol, responses which were attributed to secondary effects of these inhibitors. The putative K⁺ current rose with voltage positive toV _m but it decayed over two voltage ranges, one negative toV _m and one near +100 mV, to give steady-stateI–V relations with two regions of negative (slope) conductance. Voltage-dependent and kinetic characteristics of the current were affected by K _v ⁺ and followed the K⁺ equilibrium potential. Against a (presumably) low background of primary ion transport, the K⁺ current contributed appreciably to charge balance atV _m in 0.1mm as well as in 1 to 10mm K _v ⁺ . Thus, gating of these K⁺ channels compensates for the prevailing K⁺ conditions to ensure net K⁺ movement out of the cell.     

Modulation of apical Na permeability of the toad urinary bladder by intracellular Na,Ca, and H

Summary The Na conductance of the apical membrane of the toad urinary bladder was measured at different concentrations of Na both in the external medium and in the cell. Bladders were bathed in high K-sucrose medium to reduce basal-lateral resistance and voltage, and the transepithelial currents measured under voltage-clamp conditions. Amiloride was used as a specific blocker of the apical Na channel. At constant external Na, the internal Na concentration was increased by blocking the basallateral Na pump with ouabain. With high Na activity in the mucosal medium (86mm), increases in intracellular Na activity from 10 to over 40mm increased the amiloride-sensitive slope conductance at zero voltage while apical Na permeability, estimated from current-voltage plots using the constant field equation, decreased by less than 20%. Lowering the serosal Ca concentration from 1 to 0.1mm had no effect on the change inP _Na with increasing Na_c, but increasing serosal Ca to 5mm enhanced the reduction inP _Na with increasing Na _c , presumably by increasing Ca influx into the cell.P _Na was also reduced by serosal vanadate (0.5mm), a putative blocker of ATP-dependent Ca extrusion from the cell, and by acute exposure to CO₂, which presumably acidifies the cytoplasm. Current-voltage relationships of the amiloridesensitive transport pathway were also measured in the absence of a Na gradient across the apical membrane. These plots show that outward current passes through the channels somewhat less easily than does inward current. The shape of theI-V relationships was not significantly altered by changes in cellular Na, Ca or H, indicating that the effects of these ions onP _Na are voltage independent.     

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.     

Cyclic AMP-induced changes in membrane conductance ofNecturus gallbladder epithelial cells

Summary Enhanced cellular cAMP levels have been shown to increase apical membrane Cl^– and HCO ₃ ^– conductances in epithelia. We found that the phosphodiesterase inhibitor 3-isobutyl-1-methyl-xanthine (IBMX) increases cAMP levels inNecturus gallbladder. We used conventional open-tip and double-barreled Cl^–-selective microelectrodes to study the effects of IBMX on membrane conductances and intracellular Cl^– activities in gallbladders mounted in a divided chamber and bathed with Ringer's solutions at 23°C and pH 7.4. In HCO ₃ ^– -free media, 0.1mM IBMX added to the mucosal medium depolarized the apical membrane potentialV _a , decreased the fractional resistanceF _R , and significantly reduced intracellular Cl^– activity (a _Cl ⁱ ). Under control conditions,a _Cl ⁱ was above the value corresponding to passive distribution across the apical cell membrane. In media containing 25mM HCO ₃ ^– , IBMX caused a small transient hyperpolarization ofV _a followed by a depolarization not significantly different from that observed in HCO ₃ ^– -free Ringer's. Removal of mucosal Cl^–, Na⁺ or Ca²⁺ did not affect the IBMX-induced depolarization inV _a . The basolateral membrane ofNecturus gallbladder is highly K⁺ permeable. Increasing serosal K⁺ from 2.5 to 80mM, depolarizedV _a . Mucosal IBMX significantly reduced this depolarization. Addition of 10mM Ba²⁺, a K⁺ channel blocker, to the serosal medium depolarizedV _a and, essentially, blocked the depolarization induced by IBMX. These results indicate that mucosal IBMX increases apical HCO ₃ ^– conductance and decreases basolateral K⁺ conductance in gallbladder epithelial cells via a cAMP-dependent mechanism. The latter effect, not previously reported in epithelial tissues, appears to be the major determinant of the IBMX-induced depolarization ofV _a .     

Effects of antidiuretic hormone on cellular conductive pathways in mouse medullary thick ascending limbs of Henle: II. Determinants of the ADH-mediated increases in transepithelial voltage and in net Cl− absorption

Summary Cellular impalements were used in combination with standard transepithelial electrical measurements to evaluate some of the determinants of the spontaneous lumen-positive voltage,V _e , which attends net Cl^– absorption,J _Cl ^net , and to assess how ADH might augment bothJ _Cl ^met andV _e in the mouse medullary thick ascending limb of Henle microperfusedin vitro. Substituting luminal 5mm Ba⁺⁺ for 5mm K⁺ resulted in a tenfold increase in the apical-to-basal membrane resistance ratio,R _c /R _bl , and increasing luminal K⁺ from 5 to 50mm in the presence of luminal 10^–4 m furosemide resulted in a 53-mV depolarization of apical membrane voltage,V _a . Thus K⁺ accounted for at least 85% of apical membrane conductance. Either with or without ADH. 10^–4 m luminal furosemide reducedV _e andJ _Cl ^net to near zero values and hyperpolarized bothV _a andV _bl , the voltage across basolateral membranes; however, the depolarization ofV _bl was greater in the presence than in the absence of hormone while the hormone had no significant effect on the depolarization ofV _a , Thus ADH-dependent increases inV _b were referable to greater depolarizations ofV _bl in the presence of ADH than in the absence of ADH 68% of the furosemide-induced hyperpolarization ofV _a was referable to a decrease in the K⁺ current across apical membranes, but, at a minimum, only 19% of the hyperpolarization ofV _bl could be accounted for by a furosemide-induced reduction in basolateral membrane Cl^– current. Thus an increase in intracellular Cl^– activity may have contributed to the depolarization ofV _bl during net Cl^– absorption, and the intracellular Cl^– activity was likely greater with ADH than without hormone. Since ADH increases apical K⁺ conductance and since the chemical driving force for electroneutral Na⁺,K⁺,2Cl^– cotransport from lumen to cell may have been less in the presence of ADH than in the absence of hormone, the cardinal effects of ADH may have been to increase the functional number of both Ba⁺⁺-sensitive conductance K⁺ channels and electroneutral Na⁺,K⁺,2Cl^– cotransport units in apical plasma membranes.     

Flow-Dependent Activation of Maxi K+ Channels in Apical Membrane of Rabbit Connecting Tubule

The Ca²⁺-activated maxi K⁺ channel was found in the apical membrane of everted rabbit connecting tubule (CNT) with a patch-clamp technique. The mean number of open channels (NP _o ) was markedly increased from 0.007 ± 0.004 to 0.189 ± 0.039 (n= 7) by stretching the patch membrane in a cell-attached configuration. This activation was suggested to be coupled with the stretch-activation of Ca²⁺-permeable cation channels, because the maxi K⁺ channel was not stretch-activated in both the cell-attached configuration using Ca²⁺-free pipette and in the inside-out one in the presence of 10 mm EGTA in the cytoplasmic side. The maxi K⁺ channel was completely blocked by extracellular 1 μm charybdotoxin (CTX), but was not by cytoplasmic 33 μm arachidonic acid (AA). On the other hand, the low-conductance K⁺ channel, which was also found in the same membrane, was completely inhibited by 11 μm AA, but not by 1 μm CTX. The apical K⁺ conductance in the CNT was estimated by the deflection of transepithelial voltage (ΔV _t ) when luminal K⁺ concentration was increased from 5 to 15 mEq. When the tubule was perfused with hydraulic pressure of 0.5 KPa, the ΔV _t was only −0.7 ± 0.4 mV. However, an increase in luminal fluid flow by increasing perfusion pressure to 1.5 KPa markedly enhanced ΔV _t to −9.4 ± 0.9 mV. Luminal application of 1 μm CTX reduced the ΔV _t to −1.3 ± 0.6 mV significantly in 6 tubules, whereas no significant change of ΔV _t was recorded by applying 33 μm AA into the lumen of 5 tubules (ΔV _t =−7.2 ± 0.5 mV in control vs.ΔV _t =−6.7 ± 0.6 mV in AA). These results suggest that the Ca²⁺-activated maxi K⁺ channel is responsible for flow-dependent K⁺ secretion by coupling with the stretch-activated Ca²⁺-permeable cation channel in the rabbit CNT. Received: 21 August 1997/Revised: 20 March 1998     

Basolateral membrane potential and conductance in frog skin exposed to high serosal potassium

Summary In studies of apical membrane current-voltage relationships, in order to avoid laborious intracellular microelectrode techniques, tight epithelia are commonly exposed to high serosal K concentrations. This approach depends on the assumptions that high serosal K reduces the basolateral membrane resistance and potential to insignificantly low levels, so that transepithelial values can be attributed to the apical membrane. We have here examined the validity of these assumptions in frog skins (Rana pipiens pipiens). The skins were equilibrated in NaCl Ringer's solutions, with transepithelial voltageV _t clamped (except for brief perturbations V _t) at zero. The skins were impaled from the outer surface with 1.5m KCl-filled microelectrodes (R _el>30 M). The transepithelial (short-circuit) currentl _i and conductanceg _t=–I _t/V _t, the outer membrane voltageV _o (apical reference) and voltage-divider ratio (F _o=V _o/V _t), and the microelectrode resistanceR _el were recorded continuously. Intermittent brief apical exposure to 20 m amiloride permitted estimation of cellular (c) and paracellular (p) currents and conductances. The basolateral (inner) membrane conductance was estimated by two independent means: either from values ofg _i andF _o before and after amiloride or as the ratio of changes (–I _c/V _i) induced by amiloride. On serosal substitution of Na by K, within about 10 min,I _c declined andg _t increased markedly, mainly as a consequence of increase ing _p. The basolateral membrane voltage (V _i(=–V _o) was depolarized from 75±4 to 2±1 mV [mean±sem (n=6)], and was partially repolarized following amiloride to 5±2 mV. The basolateral conductance increased in high serosal K, as estimated by both methods. Essentially complete depolarization of the basolateral membrane and increase in its conductance in response to high [K] were obtained also when the main serosal anion was SO₄ or NO₃ instead of Cl. On clampingV _t over the range 0 to +125 mV in K₂SO₄-depolarized skins, the quasi-steady-stateV _o V _t relationship was linear, with a mean slope of 0.88±0.03. The above results demonstrate that, in a variety of conditions, exposure to high serosal K results in essentially complete depolarization of the basolateral membrane and a large increase in its conductance.