Effects of antidiuretic hormone on cellular conductive pathways in mouse medullary thick ascending limbs of Henle: I. ADH increases transcellular conductance pathways

Summary This paper reports experiments designed to assess the relations between net salt absorption and transcellular routes for ion conductance in single mouse medullary thick ascending limbs of Henle microperfusedin vitro. The experimental data indicate that ADH significantly increased the transepithelial electrical conductance, and that this conductance increase could be rationalized in terms of transcellular conductance changes. A minimal estimate (G _c ^min ) of the transcellular conductance, estimated from Ba⁺⁺ blockade of apical membrane K⁺ channels, indicated thatG _c ^min was approximately 30–40% of the measured transepithelial conductance. In apical membranes, K⁺ was the major conductive species; and ADH increased the magnitude of a Ba⁺⁺-sensitive K⁺ conductance under conditions where net Cl^– absorption was nearly abolished. In basolateral membranes, ADH increased the magnitude of a Cl^– conductance; this ADH-dependent increase in basal Cl^– conductance depended on a simultaneous hormone-dependent increase in the rate of net Cl^– absorption. Cl^– removal from luminal solutions had no detectable effect onG _e , and net Cl^– absorption was reduced at luminal K⁺ concentrations less than 5mm; thus apical Cl^– entry may have been a Na⁺,K⁺,2Cl^– cotransport process having a negligible conductance. The net rate of K⁺ secretion was approximately 10% of the net rate of Cl^– absorption, while the chemical rate of net Cl^– absorption was virtually equal to the equivalent short-circuit current. Thus net Cl^– absorption was rheogenic; and approximately half of net Na⁺ absorption could be rationalized in terms of dissipative flux through the paracellular pathway. These findings, coupled with the observation that K⁺ was the principal conductive species in apical plasma membranes, support the view that the majority of K⁺ efflux from cell to lumen through the Ba⁺⁺-sensitive apical K⁺ conductance pathway was recycled into cells by Na⁺,K⁺,2Cl^– cotransport.     

Effect of K+ channels in the apical plasma membrane on epithelial secretion based on secondary active Cl− transport

Summary Models of epithelial salt secretion, involving secondary active transport of Cl^– [9], locate the K⁺ conductance of the plasma membrane exclusively in the basolateral membrane, although there is considerable experimental evidence to show that many secretory epithelia do have a significant apical K⁺ conductance. We have used an equivalent circuit model to examine the effect of an apical K⁺ conductance on the composition and flow rate of the fluid secreted by an epithelium in which secretion is driven by the secondary active transport of Cl^–. The parameters of the model were chosen to be similar to those measured in the dog tracheal mucosa when stimulated with adrenaline to secrete. We find that placing a K⁺ conductance in the apical membrane can actually enhance secretion provided that proportion of the total cell K⁺ conductance in the apical membrane is not greater than about 60%, the enabling effect on secretion being maximal when the proportion is around 10–20%. We also find that even when the entire cell K⁺ conductance is located in the apical membrane, the secreted fluid remains relatively Na⁺ rich. Analysis of the sensitivity of model behavior to the choice of values for the parameters shows that the effects of an apical K⁺ conductance are enhanced by increasing the ratio of the paracellular resistance to the transcellular resistance.     

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.     

Electrical properties of chloride transport across theNecturus proximal tubule

Summary The chloride conductance of the basolateral cell membrane of theNecturus proximal tubule was studied using conventional and chloride-sensitive liquid ion exchange microelectrodes. Individual apical and basolateral cell membrane and shunt resistances, transepithelial and basolateral, cell membrane potential differences, and electromotive forces were determined in control and after reductions in extracellular Cl^–. When extracellular Cl^– activity is reduced in both apical and basolateral solutions the resistance of the shunt increases about 2.8 times over control without any significant change in cell membrane resistances. This suggests a high Cl^– conductance of the paracellular shunt but a low Cl^– conductance of the cell membranes. Reduction of Cl^– in both bathing solutions or only on the basolateral side hyperpolarizes both the basolateral cell membrane potential difference and electromotive force. Hyperpolarization of the basolateral cell membrane potential difference after low Cl^– perfusion was abolished by exposure to HCO ₃ ^– -free solutions and SITS treatment. In control conditions, intracellular Cl^– activity was significantly higher than predicted from the equilibrium distribution across both the apical and basolateral cell membranes. Reducing Cl^– in only the basolateral solution caused a decrease in intracellular Cl^–. From an estimate of the net Cl^– flux across the basolateral cell membrane and the electrochemical driving force, a Cl^– conductance of the basolateral cell membrane was predicted and compared to measured values. It was concluded that the Cl^– conductance of the basolateral cell membrane was not large enough to account for the measured flux of Cl^– by electrodiffusion alone. Therefore these results suggest the presence of an electroneutral mechanism for Cl^– transport across the basolateral cell membrane of theNecturus proximal tubule cell.     

Membrane electrical parameters in turtle bladder measured using impedance-analysis techniques

Summary Equivalent-circuit impedance analysis experiments were performed on the urinary bladders of freshwater turtles in order to quantify membrane ionic conductances and areas, and to investigate how changes in these parameters are associated with changes in the rate of proton secretion in this tissue. In all experiments, sodium reabsorption was inhibited thereby unmasking the electrogenic proton secretion process. We report the following: (1) transepithelial impedance is represented exceptionally well by a simple equivalent-circuit model, which results in estimates of the apical and basolateral membrane ionic conductances and capacitances; (2) when sodium transport is inhibited with mucosal amiloride and serosal ouabain, the apical and basolateral membrane conductances and capacitances exhibit a continual decline with time; (3) this decline in the membrane parameters is most likely caused by subtle time-dependent changes in cell volume, resulting in changes in the areas of the apical and basolateral membranes; (4) stable membrane parameters are obtained if the tissue is not treated with ouabain, and if the oncotic pressure of the serosal solution is increased by the addition of 2% albumin; (5) inhibition of proton secretion using acetazolamide in CO₂ and HCO ₃ ^– -free bathing solutions results in a decrease in the area of the apical membrane, with no significant change in its specific conductance; (6) stimulation of proton transport with CO₂ and HCO ₃ ^– -containing serosal solution results in an increase in the apical membrane area and specific conductance. These results show that our methods can be used to measure changes in the membrane electrophysiological parameters that are related to changes in the rate of proton transport. Notably, they can be used to quantify in the live tissue, changes in membrane area resulting from changes in the net rates of endocytosis and exocytosis which are postulated to be intimately involved in the regulation of proton transport.     

Biphasic increase of apical Cl− conductance by muscarinic stimulation of ht-29cl.19a human colon carcinoma cell line: Evidence for activation of different cl− conductances by carbachol and forskolin

Summary The modulation of ion transport pathways in filtergrown monolayers of the Cl^–-secreting subclone (19A) of the human colon carcinoma cell line HT-29 by muscarinic stimulation was studied by combined Ussing chamber and microimpalement experiments.Basolateral addition of 10^–4 m carbachol induced a complex poly-phasic change of the cell potential consisting of (i) a fast and short (30-sec) depolarization of 15±1 mV from a resting value of –52±1 mV and an increase of the fractional resistance of the apical membrane (first phase), (ii) a repolarization of 22±1 mV leading to a hyperpolarization of the cell (second phase), (iii) a depolarization of 11±1 mV and a decrease of the fractional resistance of the apical membrane (the third phase), (iv) and sometimes, a hyperpolarization of 6±1 mV and an increase of the fractional resistance of the apical membrane (fourth phase). The transepithelial potential increased with a peak value of 2.4±0.3 mV (basolateral side positive). The transepithelial PD started to increase (serosa positive), coinciding with the start of the second phase of the intracellular potential change, and continued to increase during the third phase. Ion replacements and electrical circuit analyses indicate that the first phase is caused by increase of the Cl^– conductance in the apical and basolateral membrane, the second phase by increased K⁺ conductance of the basolateral membrane, and the third phase and the fourth phase by increase and decrease, respectively, of an apical Cl^– conductance. The first and second phase of the carbachol effect could be elicited also by ionomycin. They were strongly reduced by EGTA. Phorbol dibutyrate (PDB) induced a sustained depolarization of the cell and a decrease of the apical fractional resistance. The results suggest that two different types of Cl^– channels are involved in the carbachol response: one Ca²⁺ dependent and a second which may be PKC sensitive.In the presence of a supramaximal concentration of forskolin, carbachol evoked a further increase of the apical Cl^– conductance.It is concluded that the short-lasting carbachol/Ca²⁺-dependent Cl^– conductance is different from the forskolin-activated conductance. The increase of the Cl^– conductance in the presence of forskolin by carbachol may be due to activation of different Cl^– channels or to modulation of the PKA-activated Cl^– channels by activated PKC.The authors are grateful to Drs. Laboisse and Augeron for providing the cell clone, and we thank Prof. Dr. F.H. Lopes da Silva for his comments. This work was supported by a grant from the Dutch Organization for Scientific Research, NWO.     

Effects of anions on cellular volume and transepithelial Na+ transport across toad urinary bladder

Summary The effects of complete substitution of gluconate for mucosal and/or serosal medium Cl^– on transepithelial Na⁺ transport have been studied using toad urinary bladder. With mucosal gluconate, transepithelial potential difference (V _T) decreased rapidly, transepithelial resistance (R _T) increased, and calculated short-circuit current (I _sc) decreased. CalculatedE _Na was unaffected, indicating that the inhibition of Na⁺ transport was a consequence of a decreased apical membrane Na⁺ conductance. This conclusion was supported by the finding that a higher amiloride concentration was required to inhibit the residual transport. With serosal gluconateV _T decreased,R _T increased andI _sc fell to a new steady-state value following an initial and variable transient increase in transport. Epithelial cells were shrunken markedly as judged histologically. CalculatedE _Na fell substantially (from 130 to 68 mV on average). Ba²⁺ (3mm) reduced calculatedE _Na in Cl^– Ringer's but not in gluconate Ringer's. With replacement of serosal Cl^– by acetate, transepithelial transport was stimulated, the decrease in cellular volume was prevented andE _Na did not fall. Replacement of serosal isosmotic Cl^– medium by a hypo-osmotic gluconate medium (one-half normal) also prevented cell shrinkage and did not result in inhibition of Na⁺ transport. Thus the inhibition of Na⁺ transport can be correlated with changes in cell volume rather than with the change in Cl^– per se. Nystatin virtually abolished the resistance of the apical plasma membrane as judged by measurement of tissue capacitance. With K⁺ gluconate mucosa, Na⁺ gluconate serosa, calculated basolateral membrane resistance was much greater, estimated basolateral emf was much lower, and the Na⁺/K⁺ basolateral permeability ratio was much higher than with acetate media. It is concluded the decrease in cellular volume associated with substitution of serosal gluconate for Cl^– results in a loss of highly specific Ba²⁺-sensitive K⁺ conductance channels from the basolateral plasma membrane. It is possible that the number of Na⁺ pump sites in this membrane is also decreased.     

Identification and regulation of whole-cell Cl− and Ca2+-activated K+ currents in cultured medullary thick ascending limb cells

The whole-cell patch-clamp technique has been used to study membrane currents in cultured rabbit medullary thick ascending limb (MTAL) epithelial cells. A Ca²⁺-activated K⁺ current was characterized by its voltage-dependent and Ca²⁺-dependent properties. When the extracellular K⁺ ion concentration was increased from 2 to 140 mm, the rereversal potential (E_k) was shifted from –85 to 0 mV with a slope of 46 mV per e-fold change. The Ca²⁺-activated K⁺ current is blocked by charybdotoxin (CTX) in a manner similar to the apical membrane Ca²⁺-activated K⁺ channel studied with the single channel patch-clamp technique. The results suggest that the Ca²⁺-activated K⁺ current is the predominant, large conductance and Ca²⁺-dependent K⁺ pathway in the cultured MTAL cell apical membrane. The biophysical properties and physiological regulation of a Cl^– current were also investigated. This current was activated by stimulation of intracellular cAMP using forskolin and isobutyl-1-methylxanthine (IBMX). The current-voltage (I–V) relationship of the Cl^– current showed an outward-rectifying pattern in symmetrical Cl^– solution. The Cl^– selectivity of the whole-cell current was confirmed by tail current analysis in different Cl^– concentration bath solutions. Several Cl^– channel blockers were found to be effective in blocking the outward-rectifying Cl^– current in MTAL cells. The cAMP-dependent Cl^– transport in MTAL cells was further confirmed by measuring changes in the intensity of Cl^– sensitive dye using fluorescence microscopy. These results suggest that the Cl^– channel in the apical or basolateral membrane of MTAL cells may be regulated by cAMP-dependent protein-kinase-induced phosphorylation.This study was supported by the National Institutes of Health grants GM46834 to L.L. and DK32753 to W.B.G., and by a Grant-in-Aid from the American Heart Association of Ohio to L.L.     

Hydrochlorothiazide action on the apical Cl−, Ca2+ and K+ conductances in rabbit gallbladder epithelium. Presence of an apamin-sensitive,Ca2+-activated K+ conductance

In the rabbit gallbladder epithelium, hydrochlorothiazide (HCTZ) was shown to inhibit the transepithelial NaCl transport and the apical Na⁺-Cl^– symport, to depolarize the apical membrane potential and to enhance the cell-to-lumen Cl^– backflux (radiochemically measured), this increase being SITS-sensitive. To better investigate the causes of the depolarization and the Cl^– backflux increase, cells were punctured with conventional microelectrodes on the luminal side (incubation in bicarbonate-free saline at 27°C) and the apical membrane potential (V _m) was studied either with prolonged single impalements or with a set of short multiple impalements. The maximal depolarization was of 3–4 mV and was reached with 2.5 × 10^–4 m HCTZ. It was significantly enhanced by reducing luminal Cl^– concentration to 30 mm; it was abolished by SCN^–, furosemide, SITS; it was insensitive to DPC. SITS converted the depolarization into a hyperpolarization of about 4 mV; this latter was apamin, nifedipine and verapamil sensitive. It was concluded that HCTZ concomitantly opens apical Cl^– and (probably) Ca²⁺ conductances and, indirectly, a Ca²⁺-sensitive, apamin inhibitable K⁺ conductance: since the intracellular Cl^– activity is maintained above the value predicted at the electrochemical equilibrium, the opening of the apical Cl^– conductance depolarizes V _mand enhances Cl^– backflux. In the presence of apamin or verapamil, to avoid the hyperpolarizing effects due to HCTZ, the depolarization elicited by this drug was fully developed (7–10 mV) and proved to be Ca²⁺ insensitive. On this basis and measuring the transepithelial resistance and the apical/basolateral resistance ratio, the Cl^– conductance opened by HCTZ has been estimated and the Cl^– backflux increase calculated: it proved to be in the order of that observed radiochemically. The importance of this Cl^– leak to the lumen in the overall inhibition of the transepithelial NaCl transport by HCTZ has been evaluated.This research was supported by Ministero dell'Università e della Ricerca Scientifica e Tecnologica, Rome, Italy. We are very grateful to prof. G. Meyer and dr. G. Bottà for helpful discussion and criticism.     

Separate,Ca2+-activated K+ and Cl− transport pathways in Ehrlich ascites tumor cells

Summary The net loss of KCl observed in Ehrlich ascites cells during regulatory volume decrease (RVD) following hypotonic exposure involves activation of separate conductive K⁺ and Cl^– transport pathways. RVD is accelerated when a parallel K⁺ transport pathway is provided by addition of gramicidin, indicating that the K⁺ conductance is rate limiting. Addition of ionophore A23187 plus Ca²⁺ also activates separate K⁺ and Cl^– transport pathways, resulting in a hyperpolarization of the cell membrane. A calculation shows that the K⁺ and Cl^– conductance is increased 14-and 10-fold, respectively. Gramicidin fails to accelerate the A23187-induced cell shrinkage, indicating that the Cl^– conductance is rate limiting. An A23187-induced activation of⁴²K and³⁶Cl tracer fluxes is directly demonstrated. RVD and the A23187-induced cell shrinkage both are: (i) inhibited by quinine which blocks the Ca²⁺-activated K⁺ channel. (ii) unaffected by substitution of NO ₃ ^– or SCN^– for Cl^–, and (iii) inhibited by the anti-calmodulin drug pimozide. When the K⁺ channel is blocked by quinine but bypassed by addition of gramicidin, the rate of cell shrinkage can be used to monitor the Cl^– conductance. The Cl^– conductance is increased about 60-fold during RVD. The volume-induced activation of the Cl^– transport pathway is transient, with inactivation within about 10 min. The activation induced by ionophore A23187 in Ca²⁺-free media (probably by release of Ca²⁺ from internal stores) is also transient, whereas the activation is persistent in Ca²⁺-containing media. In the latter case, addition of excess EGTA is followed by inactivation of the Cl^– transport pathway. These findings suggest that a transient increase in free cytosolic Ca²⁺ may account for the transient activation of the Cl^– transport pathway. The activated anion transport pathway is unselective, carrying both Cl^–, Br^–, NO ₃ ^– , and SCN^–. The anti-calmodulin drug pimozide blocks the volume- or A23187-induced Cl^– transport pathway and also blocks the activation of the K⁺ transport pathway. This is demonstrated directly by⁴²K flux experiments and indirectly in media where the dominating anion (SCN^–) has a high ground permeability. A comparison of the A23187-induced K⁺ conductance estimated from⁴²K flux measurements at high external K⁺, and from net K^– flux measurements suggests single-file behavior of the Ca²⁺-activated K⁺ channel. The number of Ca²⁺-activated K⁺ channels is estimated at about 100 per cell.     

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 Ag+ on ion transport by the corneal epithelium of the rabbit

Summary Exposure of thein vitro rabbit corneal epithelium to Ag⁺ by the addition of AgNO₃ (10^–7–10^–5)m) to the apical surface or by the use of imperfectly chlorided Ag/AgCl half-cells in Ussing-style membrane chambers, greatly increases short-circuit current and transepithelial potential. The early phase (the first 30 min) of the short-circuit current stimulation by Ag⁺ is linearly dependent on tear-side sodium concentration, is largely a result of a tenfold increase in net Na⁺ uptake and is incompletely inhibited by ouabain, suggesting that Ag⁺ increases cation (primarily Na⁺) conductance of the apical membrane. This mechanism for the Ag⁺ effect is supported by microelectrode experiments, wherein Ag⁺ depolarizes specifically the apical barrier potential and increases apical barrier conductance. A later phase in the effect (0.5–3 hr) is characterized by a gradual increase in³⁶Cl^– and¹⁴C-mannitol unidirectional fluxes, by a decline in epithelial resting potential and short-circuit current, by complete ouabain inhibition and by fit to saturation kinetics with respect to Na⁺ concentration in the bathing media. This pahse of the effect apparently reflects a nonselective opening of the paracellular pathway in the epithelium and is rate-limited by Na⁺ pump activity at the basolateral membrane. Both phases are associated with swelling of the corneal stroma and may be rapidly reversed using thiol agents (reduced glutathione and dithiothreitol). The results suggest that Ag⁺ may be useful in the study of cation transport by epithelia and the work provides basic physiological information that is pertinent to the prophylactic use of AgNO₃ in clinical ophthalmology.     

Active potassium transport by rabbit descending colon epithelium

Summary Previous studies of rabbit descending colon have disagreed concerning potassium transport across this epithelium. Some authors reported active K⁺ secretion underin vitro short-circuited conditions, while others suggested that K⁺ transport occurs by passive diffusion through a highly potassium-selective paracellular route. For this reason, we re-examined potassium fluxes across the colon in the presence of specific and general metabolic inhibitors. In addition, electrochemical driving forces for potassium across the apical and basolateral membranes were measured using conventional and ion-sensitive microelectrodes. Under normal conditions a significant net K⁺ secretion was observed (J _net ^K =–0.39±0.081 eq/cm²hr) with⁴²K fluxes, usually reaching steady-state within approximately 50 min following isotope addition. In colons treated with serosal addition of 10^–4 m ouabain,J _sm ^K was lowered by nearly 70% andJ _ms ^K was elevated by approximately 50%. Thus a small but significant net absorption was present (J _net ^K =0.12±0.027 eq/cm²hr). Under control conditions, the net cellular electrochemical driving force for K⁺ was 17 mV, favoring K⁺ exit from the cell. Cell potential measurements indicated that potassium remained above equilibrium after ouabain, assuming that passive membrane permeabilities are not altered by this drug. Net K⁺ fluxes were abolished by low temperature.The results indicate that potassium transport by the colon may occur via transcellular mechanisms and is not solely restricted to a paracellular pathway. These findings are consistent with our previous electrical results which indicated a nonselective paracellular pathway. Thus potassium transport across the colon can be modeled as a paracellular shunt pathway in parallel with pump-leak systems on the apical and basolateral membranes.     

Chloride movement across the basolateral membrane of proximal tubule cells

Summary Electrophysiologic and tracer experiments have shown that Cl^– entersNecturus proximal tubule cells from the tubule lumen by a process coupled to the flow of Na⁺, and that Cl^– entry is electrically silent. The mechanism of Cl^– exit from the cell across the basolateral membrane has not been directly studied. To evaluate the importance of the movement of Cl^– ions across the basolateral membrane, the relative conductance of Cl^– to K⁺ was determined by a new method. Single-barrel ion-selective microelectrodes were used to measure intracellular Cl^– and K⁺ as a function of basolateral membrane PD as it varied normally from tubule to tubule. Basolateral membrane Cl^– conductance was about 10% of K⁺ conductance by this method. A second approach was to voltage clamp the basolateral PD to 20 mV above and below the spontaneous PD, while sensing intracellular Cl^– activity with the second barrel of a double-barrel microelectrode. An axial wire electrode in the tubule lumen was used to pass current across the tubular wall and thereby vary the basolateral membrane PD. Cell Cl^– activity was virtually unaffected by the PD changes. We conclude that Cl^– leavesNecturus proximal tubule cells by a neutral mechanism, possibly coupled to the efflux of Na⁺ or K⁺.     

Basolateral membrane potential of a tight epithelium: Ionic diffusion and electrogenic pumps

Summary The contribution of specific ions to the conductance and potential of the basolateral membrane of the rabbit urinary bladder has been studied with both conventional and ion-specific microelectrode techniques. In addition, the possibility of an electrogenic active transport process located at the basolateral membrane was studied using the polyene antibiotic nystatin. The effect of ion-specific microelectrode impalement damage on intracellular ion activities was examined and a criterion set for acceptance or rejection of intracellular activity measurements. Using this criterion, we found (K⁺)=72mm and (Cl^–)=15.8mm. Cl^– but not K⁺ was in electrochemical equilibrium across the basolateral membrane. The selective permeability of the basolateral membrane was measured using microelectrodes, and the data analyzed using the Goldman, Hodgkin-Katz equation. The sodium to potassium permeability ratio (P _Na/P _K) was 0.044, and the chloride to potassium permeability ratio (P _Cl/P _K) was 1.17. Since K⁺ was not in electrochemical equilibrium, intracellular (K⁺) is maintained by active metabolic processes, and the basolateral membrane potential is a diffusion potential with K⁺ and Cl^– the most permeable ions. After depolarizing the basolateral membrane with high serosal potassium bathing solutions and eliminating the apical membrane as a rate limiting step for ion movement using the polyene antibiotic nystatin, we found that the addition of equal aliquots of NaCl to both solutions caused the basolateral membrane potential to hyperpolarize by up to 20 mV (cell interior negative). This popential was reduced by 80% within 3 min of the addition of ouabain to the serosal solution. This hyperpolarization most probably represents a ouabain sensitive active transport process sensitive to intracellular Na⁺. An equivalent electrical circuit for Na⁺ transport across rabbit urinary bladder is derived, tested, and compared to previous results. This circuit is also used to predict the effects that microelectrode impalement damage will have on individual membrane potentials as well as time-dependent phenomena; e.g., effect of amiloride on apical and basolateral membrane potentials.     

Cellular and paracellular pathway resistances in the “tight” Cl−-secreting epithelium of rabbit cornea

Summary The high transverse resistance of the isolated rabbit cornea (6–12 k·cm²) is associated with the corneal epithelium, a Cl^–-secreting tissue which is modulated by -adrenergic and serotonergic receptors. Three methods were employed to determine the resistances for the apical membrane, basolateral membrane, and paracellular conductive pathways in the epithelium. In the first method, the specific resistance of the apical membrane was selectively and reversibly changed. Epinephrine was used to increase apical Cl^– conductance and Ag⁺ was used to increase apical cation permeability. The second method utilized a direct measure of the spontaneous cellular ionic current. The third method obtained estimates of shunt resistance using transepithelial electrophysiological responses to changes in apical membrane resistance. The results of the first method were largely independent of the agent used. In addition, the three methods were in general agreement, and the ranges of mean values for apical membrane, basolateral membrane, and shunt resistances were 23–33, 3–4, and 12–16 k·cm², respectively, for the normal cornea. The apical membrane was the major, physiologically-modulated barrier to ion permeation. The shunt resistance of the corneal epithelium was comparable to that found previously for other tight epithelia. Experiments using Ag⁺ in tissues that were bathed in Cl^– and HCO₃-free solutions indicated that under resting conditions the apical membrane is anion-selective.     

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.     

Regulation of K+ channels in the basolateral membrane ofNecturus oxyntic cells

Summary Patch-clamp methods were used to study single-channel events in isolated oxyntic cells and gastric glands fromNecturus maculosa. Cell-attached, excised inside-out and outside-out patches from the basolateral membrane frequently contained channels which had conductances of 67±21 pS in 24% of the patches and channels of smaller conductance, 33±6 pS in 56% of the patches. Channels in both classes were highly selective for K⁺ over Na⁺ and Cl^–, and shared linear current-voltage relations. The 67-pS channel was activated by membrane depolarization, whereas the activity of the 33-pS channel was relatively voltage independent. The larger conductance channels were activated by intracellular Ca²⁺ in the range between 5 and 500nm, but unaffected by cAMP. The smaller conductance channels were activated by cAMP, but not Ca²⁺. The presence of K⁺ channels in the basolateral membrane which are regulated by these known second messengers can account for the increase in conductance and the hyperpolarization of the membrane observed upon secretagogue stimulation.     

Na+ and Cl− conductances are controlled by cytosolic Cl− concentration in the intralobular duct cells of mouse mandibular glands

Our previously published whole-cell patch-clamp studies on the cells of the intralobular (granular) ducts of the mandibular glands of male mice revealed the presence of an amiloride-sensitive Na⁺ conductance in the plasma membrane. In this study we demonstrate the presence also of a Cl^– conductance and we show that the sizes of both conductances vary with the Cl^– concentration of the fluid bathing the cytosolic surface of the plasma membrane. As the cytosolic Cl^– concentration rises from 5 to 150 mmol/liter, the size of the inward Na⁺ current declines, the decline being half-maximal when the Cl^– concentration is approximately 50 mmol/liter. In contrast, as cytosolic Cl^– concentration increases, the inward Cl^– current remains at a constant low level until the Cl^– concentration exceeds 80 mmol/liter, when it begins to increase. Studies in which Cl^– in the pipette solution was replaced by other anions indicate that the Na⁺ current is suppressed by intracellular Br^-, Cl^– and NO ₃ ^- but not by intracellular I^-, glutamate or gluconate. Our studies also show that the Cl^– conductance allows passage of Cl^– and Br^- equally well, I-less well, and NO ₃ ^- , glutamate and gluconate poorly, if at all. The findings with NO ₃ ^- are of particular interest because they show that suppression of the Na⁺ current by a high intracellular concentration of a particular anion does not depend on actual passage of that anion through the Cl^– conductance. In mouse granular duct cells there is, thus, a reciprocal regulation of Na⁺ and Cl^– conductances by the cytosolic Cl^– concentration. Since the cytosolic Cl^– concentration is closely correlated with cell volume in many epithelia, this reciprocal regulation of Na⁺ and Cl^– conductances may provide a mechanism by which ductal Na⁺ and Cl transport rates are adjusted so as to maintain a stable cell volume.This project was supported by the National Health and Medical Research Council of Australia. We thank Professor P. Barry (University of New South Wales) for assistance with the junction potential measurements.