Modes of Cl− transport across the mucosal and serosal membranes of urodele intestinal cells

Summary The characteristics of Cl^– movement across luminal and basolateral membranes ofAmphiuma intestinal absorptive cells were studied using Cl^–-sensitive microelectrodes and tracer³⁶Cl techniques. Intracellular Cl^– activity (a _Cl ⁱ ) was unchanged when serosal Cl^– was replaced; when luminal Cl^– was replaced cell Cl^– was rapidly lost. Accordingly, the steady statea _Cl ⁱ could be varied by changing the luminal [Cl]. As luminal [Cl] was raised from 1 to 86mM,a _Cl ⁱ rose in a linear manner, the mucosal membrane hyperpolarized, and the transepithelial voltage became serosa negative. In contrast, the rate of Cl^– transport from the cell into the serosal medium, measured as the SITS-inhibitable portion of the Cl^– absorptive flux, attained a maximum whena _Cl ⁱ reached an apparent value of 17mm, indicating the presence of a saturable, serosal transport step. The stilbeneinsensitive absorptive flux was linear with luminal [Cl], suggestive of a paracellular route of movement. Intracellulara _Cl was near electrochemical equilibrium at all but the lowest values of luminal [Cl] after interference produced by other anions was taken into account.a _Cl ⁱ was unaffected by Na replacement, removal of medium K, or elevation of medium HCO ₃ ^– . Mucosae labeled with³⁶Cl lost isotope into both luminal and serosal media at the same rate and from compartments of equal capacity. Lowering luminal [Cl] or addition of theophylline enhanced luminal Cl^– efflux. It is concluded that a conductive Cl leak pathway is present in the luminal membrane. Serosal transfer is by a saturable, stilbene-inhibitable pathway. Luminal Cl^– entry appears to be passive, but an electrogenic uptake cannot be discounted.     

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 .     

Electrical properties of the cellular transepithelial pathway inNecturus gallbladder: III. Ionic permeability of the basolateral cell membrane

Summary The ionic permeability of the basolateral membrane ofNecturus gallbladder epithelium was studied with intracellular microelectrode techniques. After removal of most of the subepithelial tissue (to reduce unstirred layer thickness), impalements were performed from the serosal side, and ionic substitutions were made in the serosal solution while a microelectrode was kept in a cell. Thus, it was possible to obtain continuous (and reversible) records of transepithelial and cell membrane potentials and to measure intermittently the transepithelial resistance and the ratio of cell membrane resistances. From these data and the mean value of the equivalent resistance of the cell membranes in parallel (obtained from cable analysis in a different group of tissues), absolute cell membrane and shunt resistances and equivalent electromotive forces (emf's) were calculated. From the changes of basolateral membrane emf (E _b ) produced by the substitutions, the conductance (G) and permeability (P) of the membrane for K, Cl and Na were estimated. Potassium-for-sodium substitutions produced large reductions of both cell membrane potentials, ofE _b , and of the resistance of the basolateral membrane (R _b ), indicating highG _K andP _K . Chloride substitution with isethionate or sulfate resulted in smaller changes of cell membrane potentials andE _b and in no significant change ofR _b , indicating small but measurable values ofG _Cl andP _Cl . Sodium substitutions with N-methyl-d-glucamine (NMDG) resulted in cell potential changes entirely attributable to the biionic potential produced in the shunt pathway (P _Na >P _NMDG ), and in no significant changes ofP _b orE _b , indicating thatG _Na andP _Na are undetectable. The question of the mechanism of Cl transport across the basolateral membrane was addressed by comparing the mean rate of transepithelial Cl transport (J _Cl ^net ) and the predicted passive Cl flux across the basolateral membrane (from the membrane Cl conductance, potential, and Cl equilibrium potential). The conclusion is that only a very small fraction of the Cl flux across the basolateral membrane can be electrodiffusional. Since the paracellular Cl conductance is also too low to account forJ _Cl ^net , these results suggest the presence of a neutral mechanism of Cl extrusion from the cells. This could be a NaCl pump, a downhill KCl transport mechanism, or a Cl–HCO₃ exchange mechanism.     

Transcellular Chloride Pathways in Ambystoma Proximal Tubule

The transport mechanisms of Ambystoma proximal tubule that mediate transcellular Cl⁻ absorption linked to Na⁺ were investigated in isolated perfused tubules using Cl⁻-selective and voltage-recording microelectrodes. In control solutions intracellular activity of Cl⁻ (a _i ^Cl ) is 11.3 ± 0.5 mm, the basolateral (V ₁ ), apical (V ₂ ), and transepithelial (V ₃ ) potential differences are −68 ± 1.2 mV, +62 ± 1.2 mV and −6.4 ± 0.3 mV, respectively. When Na⁺ absorption is decreased by removal of organic substrates from the lumen, a _i ^Cl falls by 1.3 ± 0.3 mm and V ₂ hyperpolarizes by +11.4 ± 1.7 mV. Subsequent removal of Na⁺ from the lumen causes a _i ^Cl to fall further by 2.3 ± 0.4 mm and V ₂ to hyperpolarize further by +15.3 ± 2.4 mV. The contribution of transporters and channels to the observed changes of a _i ^Cl was examined using ion substitutions and inhibitors. Apical Na/Cl or Na/K/2Cl symport is excluded because bumetanide, furosemide or hydrochlorothiazide have no effect on a _i ^Cl . The effects of luminal HCO⁻ ₃ removal and/or of disulfonic stilbenes argue against the presence of apical Cl-base exchange such as Cl-HCO₃ or Cl-OH. The effects of basolateral HCO⁻ ₃ removal, of basolateral Na⁺ removal and/or of disulfonic stilbenes are compatible with presence of basolateral Na-independent Cl-base exchange and Na-driven Cl-HCO₃ exchange. Several lines of evidence favor conductive Cl⁻ transport across both the apical and basolateral membrane. Addition of the chloride-channel blocker diphenylamine-2-carboxylate to the lumen or bath, increases the a _i ^Cl by 2.4 ± 0.6 mm or 2.9 ± 1.0 mm respectively. Moreover, following inhibition by DIDS of all anion exchangers in HCO⁻ ₃-free Ringer, the equilibrium potential for Cl⁻ does not differ from the membrane potential V ₂ . Finally, the logarithmic changes in a _i ^Cl in various experimental conditions correlate well with the simultaneous changes in either basolateral or apical membrane potential. These findings strongly support the presence of Cl⁻ channels at the apical and basolateral cell membranes of the proximal tubule. Received: 14 November 1997/Revised: 6 July 1998     

The steady-state relationship between sodium and chloride transmembrane electrochemical potential differences inNecturus gallbladder

Summary Intracellular C1, K and Na activities (a _Cl ⁱ ,a _k ⁱ anda _Na ⁱ ) and transmucosal membrane potential (E _m) in epithelial cells ofNecturus gallbladder were measured at different external Na concentrations ([Na]_o), with liquid ion-exchanger and conventional microelectrodes. Bladders were mounted in a divided chamber at 23°C between identical HCO₃-free Ringer solutions containing 5mm K. The pH was 7.2. Tris was substituted for Na. Measurements were made under steady-state conditions as determined by the constancy of the transepithelial potential difference. Both,a _Cl ⁱ anda _Na ⁱ increased in a saturable fashion with [Na]_o.E _m did not change significantly. Average values (±sem) under normal conditions ([Na]_o=100mm) fora _Cl ⁱ ,a _Na ⁱ andE _m were 16.8±0.8mm (n=9), 9.7±0.6mm (n=10) and –52.6±0.6 mV (n=26), respectively. In Na-free mediaa _Cl ⁱ declined to its equilibrium value.a _K ⁱ (96±2mm;n=7) did not change when [Na]_o was varied between 100 and 10mm but decreased to 80±3mm (n=4) in Na-free media.Transmembrane electrochemical potential differences, , for Cl and Na were calculated at four different [Na]_o levels. A highly significant linear relation between and was found, indicating that Cl and Na transport are energetically linked. The results support the view that the energy necessary for intracellular Cl accumulation is derived from the simultaneous dissipation of the chemical potential gradient of Na across the apical membrane and that the coupled entry mechanism is electroneutral.     

Cellular and transepithelial responses of goldfish intestinal epithelium to chloride substitutions

Summary In goldfish intestine chloride was substituted by large inorganic anions (gluconate or glucuronate) either mucosally, serosally or bilaterally. Changes in intracellular activities of chloride (a _i Cl^–), sodium (a _i Na⁺) and potassium (a _i K⁺), pH_i, relative volume, membrane and transepithelial potentials, transepithelial resistance and voltage divider ratio were measured. Control values were:a _i Cl^–=35 meq/liter, a _i Na⁺=11 meq/liter and a _i K⁺=95 meq/liter. During bilateral substitution the latter two did not change while a _i Cl^– dropped to virtually zero.Mucosal membrane potentials (_ms) were: control,-53 mV; serosal substitution,-51 mV; bilateral substitution,-66 mV; while during mucosal substitution a transient depolarization occurred and the final steady state _ms was-66 mV.During control and bilateral substitution the transepithelial potentials (_ms) did not differ from zero. During unilateral substitutions _ms was small, in the order of magnitude of the errors in the liquid junction potentials near the measuring salt bridges.During bilateral substitution pH _i increased 0.4 pH units. Cellular volume decreased during mucosal substitution to 88% in 40 min; after serosal substitution it transiently increased, but the new steady-state value was not significantly above its control value.Three minutes after mucosal substitution ana _i Cl^– of approx. 10 meq/liter was measured.Chemical concentrations of Na, K and Cl were determined under control conditions and bilateral substitution. Cl concentrations were also measured as a function of time after unilateral substitutions.The data indicate an electrically silent chloride influx mechanism in the brush border membrane and an electrodiffusional chloride efflux in the basolateral membrane. A substantial bicarbonate permeability is present in the basolateral membrane. The results are in agreement with the observed changes in membrane resistances, volume changes and pH changes.     

Cyclic AMP and intracellular ionic activities innecturus gallbladder

Summary Open-tip and liquid ion-exchanger microelectrodes were used to study the effects of cAMP (6mm, added to the serosal medium) on apical membrane potential (E _m ) and intracellular sodium, potassium, and chloride activities (a _Na ⁱ ,a _K ⁱ ,a _Cl ⁱ ) inNecturus gallbladder under open-circuit conditions. Transepithelial potential difference (E _Tr ) was also measured. In the presence of cAMP,a _Cl ⁱ fell from about 1.5 times its equilibrium value to a level that corresponded to electrochemical equilibrium across the apical and basolateral cell membranes. Under these conditionsa _Na ⁱ decreased anda _K ⁱ increased,E _m was unchanged andE _Tr increased from virtually zero to a small but significant serosal positive value. The cAMP-induced increase ina _K ⁱ was abolished when Cl^–-free incubation media were used. Addition of the Ca⁺⁺-ionophore A23187 (0.5 g/ml) to the serosal medium had no effect onE _m ,E _Tr , ora _Cl ⁱ . When A23187 was added to the mucosal medium,E _m and the basolateral membrane potential hyperpolarized by about 20 mV and an increase in the outwardly directed electrochemical driving force for Cl^– was observed. These results indicate that cAMP inhibits coupled transapical Na–Cl entry into epithelial cells ofNecturus gallbladder and suggest that this inhibition may not be mediated by an increase in intracellular Ca⁺⁺ concentration.     

Regulation of intracellular chloride activity during perfusion with hypertonic solutions in theNecturus proximal tubule

Summary In a previous study we presented evidence that chloride transport across the basolateral membrane inNecturus proximal tubule cells occurs predominantly via exchange for both Na⁺ and HCO ₃ ^– . In this study the regulation of intracellular chloride was further examined in the doubly-perfused kidney preparation using conventional and chloride-sensitive microelectrodes. Application of hypertonic basolateral solutions containing 80mm raffinose stimulated an efflux of chloride such that chloride activity remained unchanged at control levels. Membrane potential did not change in these experiments. Inhibition of Cl^– exit across the basolateral cell membrane by removal of either HCO ₃ ^– or Na⁺ from the perfusion solution resulted in a significant increase in intracellular chloride activity,a _Cl ⁱ , when basolateral osmolarity was raised. Hypertonic basolateral solutions also produced a significant rise ina _Cl ⁱ in the presence of SITS.This study provides further evidence that chloride is transported across the basolateral cell membrane in exchange for both Na⁺ and HCO ₃ ^– . Since this exchange mechanism is activated in response to hypertonic solutions, these studies suggest a functional role for this exchanger in the regulation ofa _Cl ⁱ in theNecturus proximal tubule cell during volume changes.     

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.     

Mechanism of Cl secretion in canine trachea: Changes in intracellular chloride activity with secretion

Summary Cl-sensitive microelectrodes were employed to investigate the mechanism of Cl secretion by canine tracheal epithelium. In control tissues with a mean calculated short-circuit current (I _sc) of 18.1 A/cm², the intracellular Cl activity (a _Cl ⁱ ) was 47.2mm. This value is 30.1mm (or 27.0 mV) above the electrochemical equilibrium for Cl across the apical membrane. Epinephrine, which stimulates Cl secretion, increased the calculatedI _sc to 160 A/cm² and decreaseda _Cl ⁱ to 32.2mm, a value only 11.2mm (or 10.9 mV) above equilibrium for the apical membrane. These results indicate a secretagogue induced decrease in the impedance to Cl exit from the cell via the apical membrane. From these and prior measurements we calculate that epinephrine-induced Cl efflux from the cell can occur by simple diffusion across the apical membrane. Further implications of these calculations are also discussed.     

Mechanism of stimulation by epinephrine of active transepithelial Cl transport in isolated frog cornea

Summary In the isolated frog cornea, the effects of 0.1mm epinephrine were measured on both the transepithelial and intracellular electrical parameters. Epinephrine increased the short-circuit current (I _sc) and transepithelial electrical conductance (g _t) by 176 and 96%, respectively. The effective electromotive driving force for active transepithelial Cl transport (E _Cl) was 45 mV and agrees with the value forE _Cl calculated by a different technique in the isolated rabbit corneal epithelium (Klyce, S.D., Wong, R.K.S., 1977,J. Physiol. (London) 266: 777). With respect to the tear-side bathing solution, epinephrine caused the intracellular potential difference of shortcircuited frog corneas to decrease from –54 to –50 mV (P>0.05). The fractional resistance of the apical membrane {F(R _o)=(R_o/R_o+R_i)} whereR _o andR _i represent the resistances of the apical and basolateral membranes, respectively, decreased from 0.38±0.06 to 0.23±0.03. Using these values ofF(R _o) and the cellular conductances, the calculated Cl resistances ofR _o andR _i decreased 4.3- and 2.3-fold, respectively. However, the value forE _Cl calculated from the intracellular electrical measurements (48 mV) did not appear to change since this value was in close agreement with the value forE _Cl calculated from the effects of epinephrine on the transepithelial electrical parameters. Thus, the effects of epinephrine onI _sc andg _t can be accounted for by increases in the Cl conductance of both the apical and basolateral membranes. Epinephrine caused the potential difference across the basolateral membrane to hyperpolarize by 9 mV. All of these results are consistent with the notion that the steps in transepithelial Cl transport include uphill movement into the cell across the basolateral membrane followed by downhill movement across the apical membrane into the tear-side bathing solution.     

Chloride secretion by canine tracheal epithelium: II. The cellular electrical potential profile

Summary We used intracellular microelectrode techniques to study the mechanisms responsible for Cl secretion by canine tracheal epithelium. Tissues were treated with indomethacin (10^–6 m, added to the mucosal solution) to reduce the baseline rate of Cl secretion and then stimulated by addition of epinephrine (10^–6 m) or prostaglandin E₁ (10^–6 m) to the submucosal solution.Three conclusions emerged from our findings: First, secretagogues enhance the rate of transepithelial Cl transport primarily by increasing apical membrane Cl permeability, since: (i) stimulation of secretion produced parallel decreases in transepithelial resistance (R _t) and the membrane resistance ratioR _a/R_b, whereR _a andR _b refer to the resistances of the apical and basolateral membranes; (ii) there was an inverse relation between the short-circuit current andR _a/R_b; (iii) secretagogues depolarized the electrical potential difference across the apical membrane (_a) and produced an equivalent hyperpolarization of the transepithelial electrical potential difference (₁) so that, in the steady-state, the basolateral membrane potential (_b) was unchanged; and (iv) substitution of sulfate or gluconate for Cl in the bathing solutions prevented secretagogue-induced changes inR _t, R_a/R_b, (_a) and (₁).Second, Cl entry into the cell across the basolateral membrane appears to be electrically-neutral since omission of Cl from the submucosal solution had no effect on (_b) and did not decreaseR _a/R_b as would be expected if Cl entered the cell by a conductive process.Third, secretagogues decreaseR _b. Approximately 20 sec after the onset of the secretory responseR _a/R_b underwent a secondary increase whileR _t continued to fall. The decrease inR _b may reflect an increase in basolateral membrane K permeability.     

Role of Apical H-K Exchange and Basolateral K Channel in the Regulation of Intracellular pH in Rat Distal Colon Crypt Cells

An apical membrane ouabain-sensitive H-K exchange and a barium-sensitive basolateral membrane potassium channel are present in colonic crypt cells and may play a role in both K absorption and intracellular pH (pH_i) regulation. To examine the possible interrelationship between apical membrane H-K exchange and basolateral membrane K movement in rat distal colon in the regulation of pH_i, experiments were designed to assess whether changes in extracellular potassium can alter pH_i. pH_i in isolated rat crypts was determined using microspectrofluorimetric measurements of the pH-sensitive dye BCECF-AM (2′,7′-bis(carboxyethyl-5(6)-carboxy-fluorescein acetoxy methylester). After loading with the dye, crypts were superfused with a Na-free solution which resulted in a rapid and reversible fall in pH_i (7.36 ± 0.02 to 6.98 ± 0.03). Following an increase in extracellular [K] to 20 mm, in the continued absence of Na, there was a further decrease in pH_i (0.20 ± 0.02, P < 0.01). K-induced acidification was blocked both by 2 mm bath barium, a K channel blocker, and by 0.5 mm lumen ouabain. K-induced acidification was also observed when intracellular acidification was induced by a NH₄Cl prepulse. These observations suggest that increased basolateral K movement increases intracellular [K] resulting in a decrease in pH_i that is mediated by a ouabain-sensitive apical membrane H,K-ATPase. Our results demonstrate an interrelationship between basolateral K movement and apical H-K exchange in the regulation of pH_i and apical K entry in rat distal colon. Received: 31 March 1998/Revised: 8 September 1998     

Roles of external and cellular Cl− ions on the activation of an apical electrodiffusional Cl− pathway in toad skin

Summary This study is concerned with the short-circuit current,I _sc, responses of the Cl^–-transporting cells of toad skin submitted to sudden changes of the external Cl^– concentration. [Cl]₀. Sudden changes of [Cl]₀, carried out under apical membrane depolarization, allowed comparison of the roles of [Cl]₀ and [Cl]_cell on the activation of the apical Cl^– pathways. Equilibration of shortcircuited skins symmetrically in K-Ringer's solutions of different Cl^– concentrations permitted adjustment of [Cl]_cell to different levels. For a given Cl^– concentration (in the range of 11.7 to 117mm) on both sides of a depolarized apical membrane, this structure exhibits a high Cl^– permeability,P _(Cl)apical. On the other hand, for the same range of [Cl]_cell but with [Cl]₀=0,P _(Cl)apical is reduced to negligible values. These observations indicate that when the apical membrane is depolarizedP _(Cl)apical is modulated by [Cl]₀; in the absence of external Cl^– ions, intracellular Cl^– is not sufficient to activateP _(Cl)apical. Computer simulation shows that the fast Cl^– currents induced across the apical membrane by sudden shifts of [Cl]₀ from a control equilibrium value strictly follow the laws of electrodiffusion. For each experimental group, the computer-generatedI _sc versus ([Cl]_cell–[Cl]₀) curve which best fits the experimental data can only be obtained by a unique pair ofP _(Cl)apical andR _b (resistance of the basolateral membrane), thus allowing the calculation of these parameters. The electrodiffusional behavior of the net Cl^– flux across the apical membrane supports the channel nature of the apical Cl^– pathways in the Cl^–-transporting cell. Cl^– ions contribute significantly to the overall conductance of the basolateral membrane even in the presence of a high K concentration in the internal solution.     

Aldosterone control of the density of sodium channels in the toad urinary bladder

Summary Near-instantaneous current-voltage relationships and shot-noise analysis of amiloride-induced current fluctuations were used to estimate apical membrane permeability to Na (P _Na), intraepithelial Na activity (Na _c ), single-channel Na currents (i) and the number of open (conducting) apical Na channels (N₀), in the urinary bladder of the toad (Bufo marinus). To facilitate voltageclamping of the apical membrane, the serosal plasma membranes were depolarized by substitution of a high KCl (85mm) sucrose (50mm) medium for the conventional Na-Ringer's solution on the serosal side.Aldosterone (5×10^–7 m, serosal side only) elicited proportionate increases in the Na-specific current (I _Na and inP _Na, with no significant change in the dependence ofP _Na on mucosal Na (Na _o ).P _Na and the control ofP _Na by aldosterone were substrate-dependent: In substrate-depleted bladders, pretreatment with aldosterone markedly augmented the response to pyruvate (7.5×10^–3 m) which evoked coordinate and equivalent increases inI _Na andP _Na.The aldosterone-dependent increase inP _Na was a result of an equivalent increase in the area density of conducting apical Na channels. The computed single-channel current did not change. We propose that, following aldosterone-induced protein synthesis, there is a reversible metabolically-dependent recruitment of preexisting Na channels from a reservoir of electrically undetectable channels. The results do not exclude the possibility of a complementary induction of Na-channel synthesis.     

Chloride transport in apical membrane vesicles from bovine tracheal epithelium: Characterization using a fluorescent indicator

Summary Cl transport in apical membrane vesicles derived from bovine tracheal epithelial cells was studied using the Cl-sensitive fluorescent indicator 6-methoxy-N-(3-sulfopropyl) quinolinium. With an inwardly directed 50 mM Cl gradient at 23°C, the initial rate of Cl entry (J _Cl) was increased significantly from 0.32±0.12 nmol · sec^–1 · mg protein^–1 (mean±sem) to 0.50±0.07 nmol · sec^–1 · mg protein^–1 when membrane potential was changed from 0 to +60 mV with K/valinomycin. At 37°C, with membrane potential clamped at 0 mV, there was a 34±7% (n=5) decrease inJ _Cl from a control value of 0.37±0.03 nmol · sec^–1 · mg protein^–1 upon addition of 0.2mm diphenylamine-2-carboxylate. The following did not alterJ _Cl significantly (J _Cl values gives as percent change from control): 50mm cis Na (–1±5%), 0.1mm furosemide (–3±4%), 0.1mm furosemide in the presence of 50mm cis Na (–5±2%), 0.1mm H₂DIDS (–18±9%), a 1.5 pH unit inwardly directed H gradient (–7±7%), and 0.1mm H₂DIDS in the presence of a 1.5 unit pH gradient (4±18%). With inward 50mm anion gradients, the initial rates of Br and I entry (J _Br andJ ₁, respectively) were not significantly different fromJ _Cl.J _Cl was a saturable function of Cl concentration with apparentK _d of 24mm and apparentV _max of 0.54 nmol · sec^–1 · mg protein^–1. Measurement of the temperature dependence ofJ _Cl yielded an activation energy of 5.0 kcal/mol (16–37°C). These results demonstrate that Cl transport in tracheal apical membrane vesicles is voltage-dependent and inhibited by diphenylamine-2-carboxylate. There is no significant contribution from the Na/K/2Cl, Na/Cl, or Cl/OH(H) transporters. The conductive pathway does not discriminate between Cl, Br, and I and is saturable. The low activation energy supports a pore-type mechanism for the conductance.     

Electrogenic Cl− absorption byAmphiuma small intestine: Dependence on serosal Na+ from tracer and Cl− microelectrode studies

Summary The Na⁺ requirement for active, electrogenic Cl^– absorption byAmphiuma small intestine was studied by tracer techniques and double-barreled Cl^–-sensitive microelectrodes. Addition of Cl^– to a Cl^–-free medium bathingin vitro intestinal segments produced a saturable (K _m =5.4mm) increase in shortcircuit current (I _sc) which was inhibitable by 1mm SITS. The selectivity sequence for the anion-evoked current was Cl^–=Br^–>SCN^–>NO ₃ ^– >F^–=I^–. Current evoked by Cl^– reached a maximum with increasing medium Na concentration (K _m =12.4mm). Addition of Na⁺, as Na gluconate (10mm), to mucosal and serosal Na⁺-free media stimulated the Cl^– current and simultaneously increased the absorptive Cl^– flux (J _ms ^Cl ) and net flux (J _net ^Cl ) without changing the secretory Cl^– flux (J _sm ^Cl ). Addition of Na⁺ only to the serosal fluid stimulatedJ _ms ^Cl much more than Na⁺ addition only to the mucosal fluid in paired tissues. Serosal DIDS (1mm) blocked the stimulation. Serosal 10mm Tris gluconate or choline gluconate failed to stimulateJ _ms ^Cl . Intracellular Cl^– activity (a _Cl ⁱ ) in villus epithelial cells was above electrochemical equilibrium indicating active Cl^– uptake. Ouabain (1mm) eliminated Cl^– accumulation and reduced the mucosal membrane potential _m over 2 to 3 hr. In contrast, SITS had no effect on Cl^– accumulation and hyperpolarized the mucosal membrane. Replacement of serosal Na⁺ with choline eliminated Cl^– accumulation while replacement of mucosal Na⁺ had no effect. In conclusion by two independent methods active electrogenic Cl^– absorption depends on serosal rather than mucosal Na⁺. It is concluded that Cl^– enters the cell via a primary (rheogenic) transport mechanism. At the serosal membrane the Na⁺ gradient most likely energizes H⁺ export and regulates mucosal Cl^– accumulation perhaps by influencing cell pH or HCO ₃ ^– concentration.     

Effects of amphotericin B on the electrical properties ofNecturus gallbladder: Intracellular microelectrode studies

Summary Intracellular microelectrode techniques were employed to study the mechanism by which amphotericin B induces a transient mucosa-negative transepithelial potential (V _ms) in the gallbladder ofNecturus. When the tissue was incubated in standard Na-Ringer's solution, the antibiotic reduced the apical membrane potential by about 40 mV, and the basolateral membrane potential by about 35 mV whereas the transepithelial potential increased by about 5 mV. The electrical resistance of the apical membrane fell by 83%, and that of the basolateral membrane by 40%; the paracellular resistance remained unchanged. Circuit analysis indicated that the equivalent electromotive forces of the apical and basolateral membranes fell by 35 and 11 mV, respectively. Changes in potentials and resistances produced by ionic substitutions in the mucosal bathing medium showed that amphotericin B produces a nonselective increase in apical membrane small monovalent cation conductance (K, Na, Li). In the presence of Na-Ringer's on the mucosal side, this resulted in a reduction of the K permselectivity of the membrane, and thus in a fall of its equivalent emf. During short term exposure to amphotericin B,P _Na/P _Cl across the paracellular pathway did not change significantly, whereasP _K/P _Na doubled. These results indicate that V _ms is due to an increase of g_Na across the luminal membranes of the epithelial cells (Cremaschiet al., 1977,J. Membrane Biol. 34:55); the data do not support the alternative hypothesis (Rose & Nahrwold, 1976.J. Membrane Biol. 29:1) that V _ms results from a reduction in shuntP _Na/P _Cl acting in combination with a rheogenic basolateral Na pump.     

Dependence of cell membrane conductances on bathing solution HCO 3 − /CO2 inNecturus gallbladder

Summary The effects of bathing solution HCO ₃ ^– /CO₂ concentrations on baseline cell membrane voltages and resistances were measured inNecturus gallbladder epithelium with conventional intracellular microelectrode techniques. Gallbladders were bathed in either low HCO ₃ ^– /CO₂ Ringer's solutions (2.4mm HCO ₃ ^– /air or 1mm HEPES/air) or a high HCO ₃ ^– /CO₂ Ringer's (10mm HCO ₃ ^– /1% CO₂). The principal finding of these studies was that the apical membrane fractional resistance (fR _a) was higher in tissues bathed in the 10mm HCO ₃ ^– /CO₂ Ringer's, averaging 0.87±0.06, whereasfR _a averaged 0.63±0.07 and 0.48±0.08 in 2.4mm HCO ₃ ^– and 1mm HEPES, respectively. Intraepithelial cable analysis was employed to obtain estimates of the individual apical (R _a) and basolateral membrane (R _b) resistances in tissues bathed in 10mm HCO ₃ ^– /1% CO₂ Ringer's. Compared to previous resistance measurements obtained in tissues bathed in a low HCO ₃ ^– /CO₂ Ringer's, the higher value offR _a was found to be due to both an increase inR _a and a decrease inR _b. The higher values offR _a and lower values ofR _b confirm the recent observations of others. To ascertain the pathways responsible for these effects, cell membrane voltages were measured during serosal solution K⁺ and Cl^– substitutions. The results of these studies suggest that an electrodiffusive Cl^– transport mechanism exists at the basolateral membrane of tissues bathed in a 10mm HCO ₃ ^– /1% CO₂ Ringer's, which can explain in part the fall inR _b. The above observations are discussed in terms of a stimulatory effect of solution [HCO ₃ ^– /PCO₂ on transepithelial fluid transport, which results in adaptive changes in the conductive properties of the apical and basolateral membranes.     

Evidence for an anion exchanger in the mouse lacrimal gland acinar cell membrane

Summary Anion exchange transport in the mouse lacrimal gland acinar cell membrane was studied by measuring the intracellular H⁺ (pH_i) and Cl^– (aCl_i) activities with double-barreled ion-selective microelectrodes. In a HCO ₃ ^– -free solution of pH 7.4 (HEPES/Tris buffered), pH_i was 7.25 andaCl_i was 33mm. By an exposure to a HCO ₃ ^– (25mm HCO ₃ ^– /5% CO₂, pH 7.4) solution for 15 min,aCl_i was decreased to 25mm and pH_i was transiently decreased to about 7.05 within 1 min, then slowly relaxed to 7.18 in 15 min. Intracellular HCO ₃ ^– concentration [HCO ₃ ^– ]_i, calculated by the Henderson-Hasselbalch's equation, was 11mm at 1 min after the exposure and then slowly increased to 15mm. Readmission of the HCO ₃ ^– -free solution reversed the changes inaCl_i and pH_i. The intracellular buffering power was about 40mm/pH. An addition of DIDS (0.2mm) significantly inhibited the rates of change inaCl_i, pH_i, and [HCO ₃ ^– ]_i caused by admission/withdrawal of the HCO ₃ ^– , solution and decreased the buffer value. Replacement of all Cl^– with gluconate in the HCO ₃ ^– solution increased pH_i, and readmission of Cl^– decreased pH_i. The rates of these changes in pH_i were reduced by DIDS by 32–45% but not by amiloride (0.3mm). In the HCO ₃ ^– solution, a stimulation of intracellular HCO ₃ ^– production by exposing the tissue to 25mm NH ₄ ⁺ increasedaCl_i significantly. While in the HCO ₃ ^– -free solution or in the HCO ₃ ^– , solution containing DIDS, exposure to NH ₄ ⁺ had little effect onaCl_i. All of these findings were consistent with the presence of a reversible, disulfonic stilbene-sensitive Cl^–/HCO ₃ ^– exchanger in the basolateral membrane of the acinar cells. The possibility of anion antiport different from one-for-one Cl^–/HCO ₃ ^– exchange is discussed.