Noise analysis of the K+ current through the apical membrane of Necturus gallbladder

Tetraethylammonium-sensitive apical K+ channels mediating K+ secretion by turtle colon

1. Apical membrane K+ channels in turtle colon were identified and characterized using current fluctuation analysis. 2. Under short-circuit conditions in NaCl-Ringer solution, the power density spectrum (PDS) of the short-circuit current (Isc) sometimes exhibited a clearly discernible Lorentzian component, indicating spontaneous fluctuations produced by a population of apical ion channels. The Lorentzian component had a characteristic corner frequency (fc) which averaged 10.2 +/- 0.9 Hz (mean +/- S.E.M., n = 20). 3. The power of the spontaneous fluctuations was enhanced (So increased) by manoeuvres that depolarize the apical membrane electrical potential (Va). Discernible fluctuations were enhanced or induced by raising the serosal K+ concentration ([K+]s = 50-115 mM, Na+ replacement), by clamping the transepithelial potential (Vt) to serosa-positive values, or by blocking basolateral K+ channels with Ba2+. 4. Mucosal amiloride (100 microM) attenuated the spontaneous fluctuations observed in NaCl-Ringer solution but had no effect in the presence of serosal high K+, indicating that amiloride did not block the K(+)-permeable channels but these channels resided in the same cells as the amiloride-sensitive Na+ channels. 5. Raising the mucosal K+ concentration attenuated spontaneous fluctuations. 6. In the presence of serosal high K+ and mucosal amiloride, the spontaneous fluctuations were often accompanied by a reversed Isc consistent with K+ secretion. These conditions were used to test the effects of putative channel blockers. 7. Mucosal Ba2+ and tetraethylammonium (TEA+) were effective inhibitors of the spontaneous fluctuations and the reversed Isc. At a concentration of 10 mM, TEA+ was maximally effective but the TEA+ analogues tetramethylammonium (TMA+) and tetrapropylammonium (TPrA+) were much less effective. Mucosal Rb+ or Cs+ did not inhibit at a concentration of 10 mM. 8. Mucosal lidocaine (200 microM), quinidine (200 microM), or diphenylamine-2-carboxylate (DPC, 1 mM) had little or no effect on the spontaneous fluctuations and reversed Isc. Quinine (100 microM), 4-aminopyridine (1 mM), and apamin (100 nM) were also without effect. 9. Mucosal TEA+ (10 mM) abolished the active secretory K+ flux measured in the presence of serosa-positive transepithelial potentials. 10. These experiments identified a population of TEA(+)-sensitive, apical K+ channels which mediate active K+ secretion in turtle colon. Sensitivity to external TEA+ distinguishes these channels from basolateral K+ channels in turtle colon and demonstrates similarity to apical K+ channels in mammalian colon.

A possible relationship between KCl symport and basolateral K+-conductance in Necturus gallbladder epithelial cells

1. Apical membrane potential (Va), transepithelial potential (VT), fractional apical voltage ratio (FVa = delta Va/delta VT), tissue resistance (RT), and intracellular Cl- (aiCl) and K+ (aiK) activities were measured in isolated gallbladders maintained between oxygenated bicarbonate-free physiological media (23 degrees C, pH 7.2 or 8.2) in a divided chamber. The basolateral membrane potential (Vb) was calculated from the measured values of Va and VT. 2. Cl- removal from the serosal medium (which should accelerate coupled basolateral KCl exit) significantly depolarized Vb, decreased aiCl, decreased FVa, increased RT, and attenuated the depolarization of Vb (delta Vb) induced by high K+ added to the serosal side. These changes are consistent with a decrease in the K(+)-conductance of the basolateral membrane (gbK). 3. Addition of furosemide (an inhibitor of KCl cotransport) to the serosal medium induced significant increases in Vb, FVa, and high K(+)-induced delta Vb, indicating an increase in gbK. 4. In the presence of serosal furosemide, Cl- removal from the serosal medium did not significantly alter Vb, aiCl or delta Vb from their corresponding values when serosal Cl- was present. 5. Serosal furosemide had no significant effect on aiK and aiCl measured with double-barreled ion-selective microelectrodes. 6. These results suggest the possibility of a reciprocal relationship between gbK and the rate of basolateral KCl cotransport. This may contribute to the maintenance of aiK in gallbladder epithelial cells.

Maxi K+ channels and their relationship to the apical membrane conductance in Necturus gallbladder epithelium

Using the patch-clamp technique, we have identified large-conductance (maxi) K+ channels in the apical membrane of Necturus gallbladder epithelium, and in dissociated gallbladder epithelial cells. These channels are more than tenfold selective for K+ over Na+, and exhibit unitary conductance of approximately 200 pS in symmetric 100 mM KCl. They are activated by elevation of internal Ca2+ levels and membrane depolarization. The properties of these channels could account for the previously observed voltage and Ca2+ sensitivities of the macroscopic apical membrane conductance (Ga). Ga was determined as a function of apical membrane voltage, using intracellular microelectrode techniques. Its value was 180 microS/cm2 at the control membrane voltage of -68 mV, and increased steeply with membrane depolarization, reaching 650 microS/cm2 at -25 mV. We have related maxi K+ channel properties and Ga quantitatively, relying on the premise that at any apical membrane voltage Ga comprises a leakage conductance and a conductance due to maxi K+ channels. Comparison between Ga and maxi K+ channels reveals that the latter are present at a surface density of 0.09/microns 2, are open approximately 15% of the time under control conditions, and account for 17% of control Ga. Depolarizing the apical membrane voltage leads to a steep increase in channel steady-state open probability. When correlated with patch-clamp studies examining the Ca2+ and voltage dependencies of single maxi K+ channels, results from intracellular microelectrode experiments indicate that maxi K+ channel activity in situ is higher than predicted from the measured apical membrane voltage and estimated bulk cytosolic Ca2+ activity. Mechanisms that could account for this finding are proposed.

Barium blocks cell membrane and tight junction conductances in Necturus gallbladder epithelium. Experiments with an extended impedance analysis technique

The site and concentration dependence of the blocking effect of Ba2+ on Necturus gallbladder epithelium has been investigated. A new approach was used which combines time-dependent electrical cell coupling analysis with intermittently performed measurements of transepithelial and apparent intracellular impedance. From the coupling pulse data the sum of apical and basolateral membrane conductances is obtained, which is then held constant during fitting of the impedance data. This combination technique yields more reliable estimates of apical and basolateral membranes resistances (Ra, Rbl) and of tight junction resistance (Rj) than our previous impedance analysis technique. Using the new approach we have found that luminal Ba2+ concentrations between 0.5 and 1.0 mmol/l increase Ra with saturation-type kinetics without affecting Rbl and Rj, while higher luminal Ba2+ concentrations progressively increase Rj. Corresponding effects were observed under serosal Ba2+. The results validate the new impedance analysis approach and demonstrate that millimolar concentrations of Ba2+ block tight junction conductances. Accordingly, Ba2+ can no longer be considered a tool to exclusively alter cell membrane resistances in epithelia.

Blocking agents of Ca2+-activated K+ channels in cultured medullary thick ascending limb cells

Ca2+-activated K+ channels with estimated single channel conductances of 127 +/- 2 pS were identified in the apical cell membrane of clone A3 of cultured medullary thick ascending limb (MTAL) cells. Both Ba2+ and the scorpion toxin, charybdotoxin (CTX), are slow blockers of the channels. An application of 0.1 microM Ba2+ to the intracellular face caused a 50% reduction in fractional open time (fv). Ba2+ block is both concentration and voltage dependent. Concentrations of CTX as low as 2 nM in the extracellular solution caused a significant reduction in fv. Tetraethylammonium (TEA) and quinine are fast blockers of Ca2+-activated K+ channels in MTAL cells. TEA, 400 microM, in the extracellular solution caused a voltage-dependent reduction in channel amplitude, whereas it takes 10 mM in the intracellular solution to reduce channel amplitude by 30%. Micromolar amounts of quinine applied to the intracellular face caused the channels to flicker rapidly between open and blocked states. These results suggest that K+ channels in MTAL cells are homologous to those found in muscle cells, and that these blocking agents may be used to probe the nature of K+ conductances in several nephron segments.

Ca2+- and voltage activated K+ channel in apical cell membrane of gallbladder epithelium from Triturus

The presence of Ca2+- and voltage-activated K+ channels was directly demonstrated in the apical cell membrane of gallbladder epithelium by patch-clamp single-channel current recording. In K+-depolarized epithelial cells, negative pipette potentials induced outward current steps when the patch-pipette was filled with Na+-rich solution and these current steps were not affected by the presence or absence of Cl-. When K+-rich solution was in the pipette and K+-depolarized cells were examined, the current-voltage relations were linear with a single-channel conductance of 140 pS and polarity was reversed at 0 mV. In excised inside-out membrane patches, raising the free Ca2+ concentration of the medium facing the inner side of the membrane from 10(-7) to 10(-6) M evoked a marked increase in open state probability of the channels without affecting the elementary current steps. This suggests that intracellular Ca2+ as a second messenger plays a crucial role in the regulatory mechanism of the membrane potential by modulating the high-conductance apical K+ channels.

Ca2+-sensitive, spontaneously fluctuating, cation channels in the apical membrane of the adult frog skin epithelium

The fluctuations in transepithelial current through the abdominal skin of bullfrogs (Rana catesbeiana) were analysed while the transepithelial voltage was clamped to zero. A Lorentzian component in the power spectrum was recorded when the skin was bathed with Ca2+ free NaCl Ringer's on both sides. After replacement of all mucosal Na+ by choline the Lorentzian component disappeared. The application of mucosa positive potentials enhanced the plateau of the relaxation noise component while it was depressed by mucosa negative potentials. These observations showed that the current associated with the relaxation noise, was carried by Na+ moving in the inward direction. Divalent cations added to the mucosal solution in micromolar concentrations depressed the relaxation noise immediately, which is indicative for an apical localization of the fluctuating channels. The relaxation noise depended strongly on the pH of the mucosal medium: alkalinization enhanced the relaxation noise while acidification depressed the fluctuations. Micromolar concentrations of the diuretic amiloride, which is known to block the Na+ entry into the cellular compartment, enhanced the Na+-dependent relaxation noise while at higher concentrations an inhibitory effect was observed. From these observations it was concluded that the relaxation noise is caused by inward Na+ movement through fluctuating channels which are localized in the apical membrane. These channels seem to constitute a pathway in parallel with the amiloride-blockable channels. Ionic substitution of Na+ by other monovalent cations showed that these channels are also permeable for K+, Rb+, NH4+, Cs+ and Tl+, but not for Li+. Divalent cations in micromolar concentrations completely occlude these fluctuating channels. Therefore, this pathway will be blocked for monovalent cations when normal Ca2+ containing Ringer's are used as mucosal bathing medium.

Electrophysiology of flounder intestinal mucosa. I. Conductance properties of the cellular and paracellular pathways

We evaluated the conductances for ion flow across the cellular and paracellular pathways of flounder intestine using microelectrode techniques and ion-replacement studies. Apical membrane conductance properties are dominated by the presence of Ba-sensitive K channels. An elevated mucosal solution K concentration, [K]m, depolarized the apical membrane potential (psi a) and, at [K]m less than 40 mM, the K dependence of psi a was abolished by 1-2 mM mucosal Ba. The basolateral membrane displayed Cl conductance behavior, as evidenced by depolarization of the basolateral membrane potential (psi b) with reduced serosal Cl concentrations, [Cl]s. psi b was unaffected by changes in [K]s or [Na]s. From the effect of mucosal Ba on transepithelial K selectivity, we estimated that paracellular conductance (Gp) normally accounts for 96% of transepithelial conductance (Gt). The high Gp attenuates the contribution of the cellular pathway to psi t while permitting the apical K and basolateral Cl conductances to influence the electrical potential differences across both membranes. Thus, psi a and psi b (approximately 60 mV, inside negative) lie between the equilibrium potentials for K (76 mV) and Cl (40 mV), thereby establishing driving forces for K secretion across the apical membrane and Cl absorption across the basolateral membrane. Equivalent circuit analysis suggests that apical conductance (Ga approximately equal to 5 mS/cm2) is sufficient to account for the observed rate of K secretion, but that basolateral conductance (Gb approximately equal to 1.5 mS/cm2) would account for only 50% of net Cl absorption. This, together with our failure to detect a basolateral K conductance, suggests that Cl absorption across this barrier involves KCl co-transport.

Physiological role of apical potassium ion channels in frog skin

The K+ permeability of the apical membrane of frog skin (Rana temporaria) was analysed by recording the short-circuit current and its fluctuations in the presence of a mucosa-to-serosa-oriented K+ concentration gradient. Loading of the animals with KCl resulted in an augmentation of the Ba2+-blockade component of the short-circuit current and the plateau value of the K+-dependent relaxation noise. Poisoning of active transport and exposing both sides of the epithelium to KCl Ringer solution caused an increase of the K+ current and its fluctuations recorded after restoring the inward-oriented K+ gradient. Serosal quinidine (5 X 10(-4) M), which is thought to increase intracellular Ca2+ activity, depressed the K+ current and the relaxation noise. This effect was completely reversible. Removal of Na+ from the serosal solution, which is known to result in an elevation of intracellular Ca2+ by abolishing the driving force for the Na+/Ca2+ exchanger, also reduced the K+ current and the Lorentzian plateau. Both parameters returned to their control values after restoring the Na+ gradient across the basolateral membranes. It is concluded from these experiments that the apical K+ permeability is controlled by factors which depend on the intracellular K+ and Ca2+ concentration and that the apical K+ channels may constitute a pathway for K+ secretion.

Single channel recordings of calcium-activated potassium channels in the apical membrane of rabbit cortical collecting tubules

Recordings of single potassium channels from the apical membrane of rabbit cortical collecting tubule have been achieved using the patch-clamp technique. The conductive properties of the channel have been studied in inside-out patches. The slope conductance of the open channel is approximately equal to 90 pS. The channel is selective to potassium over sodium, with a selectivity ratio of 9:1. Decreasing the calcium concentration of the solution bathing the cytoplasmic face of the patch results in a decrease of the open-channel probability. Decreasing the calcium concentration to 10 nM or less completely inhibited channel activity. The channel is also inhibited by barium in a dose-dependent fashion.

Studies of sodium channels in rabbit urinary bladder by noise analysis

Sodium channels in rabbit urinary bladder were studied by noise analysis. There are two components of short-circuit current (Isc) and correspondingly two components of apical Na+ entry, one amiloride-sensitive (termed IA and the A channel, respectively) and one amiloride-insensitive (IL and the leak pathway, respectively). The leak pathway gives rise to l/f noise, while the A channel in the presence of amiloride gives rise to Lorentzian noise. A two-state model of the A channel accounts well for how the corner frequency and plateau value of Lorentzian noise vary with amiloride concentration. The single-channel current is 0.64 pA, and the conducting channel density is on the order of 40 copies per cell. Triamterene blocks the A channel alone, and increasing external Na+ decreases the number but not the single-channel permeability of the A channel. Hydrostatic pressure pulses ("punching") increase the number of both pathways. Repeated washing of the mucosal surface removes most of the leak pathway without affecting the A channel. Properties of the A channel revealed by noise analysis of various tight epithelia are compared, and the mechanism of l/f noise is discussed. It is suggested that the A channel is synthesized intracellularly, stored in intracellular vesicles, transferred with or from vesicular membrane into apical membrane under the action of microfilaments, and degraded into the leak pathway, which is washed out into urine or destroyed. The A channel starts with PNa/PK approximately 30 and loses selectivity in stages until PNa/PK reaches the free-solution mobility ratio (approximately 0.7) for the leak pathway. This turnover cycle functions as a mechanism of repair and regulation for Na+ channels, analogous to the repair and regulation of most intracellular proteins by turnover. Vesicular delivery of membrane channels may be operating in several other epithelia.

Electrophysiological analysis of bicarbonate permeation across the peritubular cell membrane of rat kidney proximal tubule. II. Exclusion of HCO3(-)-effects on other ion permeabilities and of coupled electroneutral HCO3(-)-transport

Cell membrane potentials of rat kidney proximal tubules were measured in response to peritubular ion substitutions in vivo with conventional and Cl- sensitive microelectrodes in order to test possible alternative explanations of the bicarbonate dependent cell potential transients reported in the preceding paper. Significant direct effects of bicarbonate on peritubular K+, Na+, and Cl- conductances could be largely excluded by blocking K+ permeability with Ba2+ and replacing all Na+ and Cl- by choline or respectively SO4(2-) isethionate, or gluconate. Under those conditions the cell membrane response to HCO3- was essentially preserved. In addition it was observed that peritubular Cl- conductance is negligibly small, that Cl-/HCO3- exchange - if present at all - is insignificant, and that rheogenic HCO3- flow with coupling to Na+ flow is also absent or insignificant. A transient disturbance of the Na+ pump or a transient unspecific increase of the membrane permeability was also excluded by experiments with ouabain and by the observation that SITS (4-acetamido-4'-isothiocyano-2,2' disulphonic stilbene) blocked the HCO3- response instantaneously. The data strongly support the notion that the potential changes in response to peritubular HCO3- concentration changes arise from passive rheogenic bicarbonate transfer across the peritubular cell membrane, and hence that this membrane has a high conductance for bicarbonate buffer.

Turnover, membrane insertion, and degradation of sodium channels in rabbit urinary bladder

Noise analysis of rabbit bladder revealed two components: Lorentzian noise, arising from interaction of amiloride with the Na+ channel, and flicker noise (l/f, where f is frequency), as in other biological membranes. Hydrostatic pressure, which causes exchange between intracellular vesicular membrane and apical membrane, increases the number but not the single-channel current of the amiloride-sensitive channels. Flicker noise arises from degraded channels that have lost amiloride sensitivity and Na+ to K+ selectivity. The degraded channels were selectively removed by washing the mucosal surface. These results imply channel turnover by intracellular synthesis, transfer from vesicular to apical membrane, degradation, and elimination.

Voltage-dependent K conductance at the apical membrane of Necturus gallbladder

The epithelial and cellular effects of clamping the transepithelial potential (Vt, mucosa reference) have been investigated in the Necturus gallbladder. Following initial equilibration at short circuit, tissue conductance gt was 4.1 +/- 1.2 (SD) mS/cm2, the apical potential Va was -76 +/- 8 mV, and the apical fractional voltage on brief voltage perturbation (fa = delta Va/delta Vt, reflecting the ratio of apical membrane to transcellular resistance) was 0.72 +/- 0.11 (21 gallbladders, 34 impalements). On clamping Vt at positive values, Va depolarized and fa decreased; at the same time gt decreased. Clamping Vt at negative values produced converse effects. All of the above changes were related directly to the magnitude of the clamping potential Vt and were reversed on return to the short circuit state. Effects of Vt on fa are not due to changes in the extracellular pathway resistances (which, however, contribute to gt). Furthermore, the effects of Vt on fa were abolished by the mucosal application of TEA or Ba, or acidification of the mucosal solution. Thus, these experiments disclose the presence of a voltage-dependent apical K conductance that increases with apical membrane depolarization. The calculated dose-response curve of TEA inhibition of apical conductance and the values of the apparent dissociation constant were in good agreement with those found for K channels in excitable tissues. Mucosal application of the Ca ionophore A23187 shifted the voltage dependence curve of fa to more negative values of Va without altering its shape. The effect of A23187 suggests a possible role of intracellular Ca in the modulation of the apical K channels.

Noise analysis of inward and outward Na+ currents across the apical border of ouabain-treated frog skin

The passive Na+ transport across the apical membrane of frog skin (Rana catesbeiana) was studied under the following circumstances: (1) control conditions (sulfate Ringer's, K+ depolarised serosal membranes); (2) after blocking the active transport step with ouabain; (3) with an outward oriented Na+ current. The amiloride-induced Na+ current fluctuations were analysed to calculate the density of amiloride blockable channels and the current through one single channel. Despite the large reduction of the macroscopic current by ouabain, the single channel current remained unchanged, while the number of amiloride blockable Na+ channels was reduced by a factor of eight. It is concluded from these observations that the earlier described reduction of the permeability of the apical membrane is caused by a decrease of the number of electrically conductive Na+ channels. The outward oriented single channel currents were less than 50% of the currents in the opposite direction. After ouabain, the number of Na+ channels was independent from the current direction.

Intracellular chloride activity and apical membrane chloride conductance in Necturus gallbladder

Open-tip and Cl--selective microelectrodes were used to study the effect of external pH on apical membrane potential (Va) and intracellular chloride activity (aiCl) in epithelial cells of Necturus gallbladder. Increasing the pH from 7.2 to 8.2 in the mucosal, the serosal, or in both bathing solutions simultaneously, hyperpolarized Va (control value -60 +/- 5 mV) by about -6, -10 and -17 mV, respectively, but did not significantly change the transepithelial potential (VT = 0.3 +/- 0.5 mV). Identical hyperpolarizations were recorded with Cl--selective microelectrodes, even 40 min after changing external pH. Thus, aiCl (12 +/- 2 mM) remained essentially constant. The ratio fVa between the deflections in Va and VT produced by transepithelial current pulses, which is an approximate measure of the fractional resistance of the apical membrane, decreased when mucosal pH was increased, and increased when serosal pH was raised. The changes in Va and fVa are due, in part at least, to the known pH dependence of cell membrane K+ conductance (PK) in this tissue. The constancy of aiCl, despite significant increases in Va, indicates that cell membrane Cl- conductance (PCl) is virtually zero or decreases, with increased external pH, in a way that compensates for the increased driving force for Cl- exit. Experiments in which 90 mM gluconate or 90 mM methylsulfate were substituted for an equivalent amount of luminal Cl- did not provide any evidence for a significant contribution of Cl- ions, per se, to the emf or conductance of the apical membrane. They suggested, rather, a dependence of apical membrane cation permeability on luminal Cl- concentration. Since basolateral membrane PCl is known to be very low, the insensitivity of aiCl to Va is the consequence of a negligible electrodiffusive Cl- permeability at both cell membranes. Thus, overall, transcellular Cl- transport in Necturus gallbladder is, in large measure, effected by electroneutral processes.

Noise analysis reveals K+ channel conductance fluctuations in the apical membrane of rabbit colon

In this paper we describe current fluctuations in the mammalian epithelium, rabbit descending colon. Pieces of isolated colon epithelium bathed in Na+ or K+ Ringer's solutions were studied under short-circuit conditions with the current noise spectra recorded over the range of 1-200 Hz. When the epithelium was bathed on both sides with Na+ Ringer's solution (the mucosal solution contained 50 microM amiloride), no Lorentzian components were found in the power spectrum. After imposition of a potassium gradient across the epithelium by replacement of the mucosal solution by K+ Ringer's (containing 50 microM amiloride), a Lorentzian component appeared with an average corner frequency, fc = 15.6 +/- 0.91 Hz and a mean plateau value So = (7.04 +/- 2.94) x 10(-20) A2 sec/cm2. The Lorentzian component was enhanced by voltage clamping the colon in a direction favorable for K+ entry across the apical membrane. Elimination of the K+ gradient by bathing the colon on both sides with K+ Ringer's solutions abolished the noise signal. The Lorentzian component was also depressed by mucosal addition of Cs+ or tetraethylammonium (TEA) and by serosal addition of Ba2+. The one-sided action of these K+ channel blockers suggests a cellular location for the fluctuating channels. Addition of nystatin to the mucosal solution abolished the Lorentzian component. Serosal nystatin did not affect the Lorentzian noise. This finding indicates an apical membrane location for the fluctuating channels. The data were similar in some respects to K+ channel fluctuations recorded from the apical membranes of amphibian epithelia such as the frog skin and toad gallbladder. The results are relevant to recent reports concerning transcellular potassium secretion in the colon and indicate that the colon possesses spontaneously fluctuating potassium channels in its apical membranes in parallel to the Na+ transport pathway.

Intra- and transepithelial analytical techniques

Epithelia transport a variety of solutes and water. Study of such transport requires a determination of the driving forces responsible for transport, of the pathways through which transport occurs, and of the factors controlling such transport. Transepithelial driving forces are readily determined where the composition of the bathing media can be altered and electrical forces negated. Where substances move only through a paracellular pathway such manipulations may be adequate to define the permeability and selectivity of the pathways. For substances utilizing a cellular pathway, driving forces and permeabilities across the two dissimilar apical and basolateral cellular membranes must be determined. Where a substance can be shown to move across a membrane against its electrochemical potential gradient, the source of the energy for such movement must be assessed. This review focuses on the applicability and validity of a variety of techniques utilized for the study of epithelial transport to answer these questions. These include microelectrode techniques, chemical analyses, microprobe analysis, microscopy, and techniques for assessing the coupling of metabolism to transport.