Current-voltage analysis of apical sodium transport in toad urinary bladder: Effects of inhibitors of transport and metabolism

Summary The basal-lateral surface of the epithelium of the urinary bladder of the toad (Bufo marinus) was depolarized by exposure of the serosal surface to 85mm KCL and 50mm sucrose. The extent of depolarization appeared to be virtually complete, as evaluated by the invariance in the transepithelial electrical potential difference and conductance on addition of nystatin (a monovalent cation ionophore) to the serosal medium. The Na-specific current (I _Na) was defined as the current sensitive to the removal of Na from the mucosal medium or inhibitable by addition of amiloride to this medium. In the presence of the high K-sucrose serosal medium, rapid, serial, stepwise clamping of the transepithelial voltage (V) yielded a curvilinear dependence ofI _Na onV; which is taken to represent theI–V curve of the apical Na channels. The constant field equation (Goldman, D.E. 1943;J. Gen. Physiol. 27:37) fits theI–V data points closely, allowing estimates to be made of the permeability to Na of the apical membrane (P _Na) and of the intracellular Na activity (Na _c ). Exposure of the apical surface to amiloride (5×10^–7 m) decreasedP _Na in proportion to the decrease inI _Na (i.e., 70%) but decreased Na _c only 25%. In contrast, an equivalent lent reduction inI _Na elicited by exposure of the basallateral surface to ouabain was accompanied by only a 20% decrease inP _Na and a sixfold increase in Na _c . The effects of amiloride onP _Na and ouabain on Na _c are consistent with the primary pharmacological actions of these drugs. In addition,P _Na appears to be under metabolic control, in that 2-deoxyglucose, a specific inhibitor of glycolysis, decreasedI _Na andP _Na proportionately, and lowered Na _c marginally, effects indistinguishable from those obtained with amiloride.     

Relationships among sodium current,permeability, and Na activities in control and glucocorticoid-stimulated rabbit descending colon

Summary Effects of a potent synthetic glucocorticoid, methylprednisolone (MP), on transepithelial Na transport were examined in rabbit descending colon. Current-voltage (I–V) relations of the amiloride-sensitive apical Na entry pathway were measured in colonic tissues of control and MP-treated (40 mg im for 2 days) animals. Tissues were bathed mucosally by solutions of various Na activities, (Na)_m, ranging from 6.2 to 75.6mm, and serosally by a high K solution. TheseI–V relations conformed to the constant field flux equation permitting determination of the permeability of the apical membrane to Na,P _Na ^m , and the intracellular Na activity, (Na)_c. The following empirical relations were observed for both control and MP-treated tissues: (i) Na transport increases hyperbolically with increasing (Na)_m obeying simple Michaelis-Mentin kinetics; (ii)P _Na ^m decreased hyperbolically with increasing (Na)_m, but was unrelated to individual variations in (Na)_c; (iii) (Na)_c increased hyperbolically with (Na)_m; (iv) both spontaneous and steroid-stimulated variations in Na entry rate could be attributed entirely to parallel variations inP _Na ^m at each mucosal Na activity. Comparison of these empirical, kinetic relations between control and MP-treated tissues revealed: (i) maximal Na current andP _Na ^m were greater in MP tissues, but the (Na)_m's at which current andP _Na ^m were half-maximal were markedly reduced; (ii) (Na)_c was significantly increased in MP tissues at each (Na)_m while the (Na)_m at half-maximal (Na)_c was unchanged. These results provide direct evidence that glucocorticoids cause marked stimulation of Na absorption across rabbit colon primarily by increasing the Na permeability of the apical membrane. While the mechanism for the increased permeability remains to be determined, the altered relation betweenP _Na ^m and (Na)_m suggests possible differences in the conformation or environment of the Na channel in MP-treated tissues.     

Ca-sensitive sodium absorption in the colon of Xenopus laevis

Summary Transepithelial electrogenic Na transport (I_Na) was investigated in the colon of the frog Xenopus laevis with electrophysiological methods in vitro. The short circuit current (I_sc) of the voltage-clamped tissue was 24.2±1.8 A·cm^-2 (n=10). About 60% of this current was generated by electrogenic Na transport. Removal of Ca²⁺ from the mucosal Ringer solution stimulated I_Na by about 120%. I_Na was not blockable by amiloride (0.1 mmol·l^-1), a specific Na-channel blocker in epithelia, but a fully and reversible inhibition was achieved by mucosal application of 1 mmol·l^-1 lanthanum (La^3-). No Na-self-inhibition was found, because I_Na increased linearly with the mucosal Na concentration. A stimulation of I_Na by antidiuretic hormones was not possible. The analysis of fluctuations in the short circuit current (noise analysis) indicated that Na ions pass the apical cell membrane via a Ca-sensitive ion channel. The results clearly demonstrate that in the colon of Xenopus laevis Na ions are absorbed through Ca-sensitive apical ion channels. They differ considerably in their properties and regulation from the amiloride-sensitive Na channel which is typically found in the colon of vertebrates.Abbreviations G _T transepithelial conductance - I _sc short circuit current - I _Na transepithelial Na-current - m mucosal - s serosal - PDS power density spectrum - f frequency - f _c corner frequency of the Lorentzian component of the PDS - S(f) power density of the Lorentzian component of the PDS - S_o plateau value of the Lorentzian component of the PDS     

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

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

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.     

Cell sodium activity and sodium pump function in frog skin

Summary Cell Na activity,a _Na ^c , was measured in the short-circuited frog skin by simulaneous cell punctures from the apical surface with open-tip and Na-selective microelectrodes. Skins were bathed on the serosal surface with NaCl Ringer and, to reduce paracellular conductance, with NaNO₃ Ringer on the apical surface. Under control conditionsa _Na ^c averaged 8±2mm (n=9,sd). Apical addition of amiloride (20 m) or Na replacement reduceda _Na ^c to 3mm in 6–15 min. Sequential decreases in apical [Na] induced parallel reductions ina _Na ^c and cell current,I _c . On restoring Na after several minutes of exposure to apical Na-free solutionI _c rose rapidly to a stable value whilea _Na ^c increased exponentially, with a time constant of 1.8±0.7 min (n=8). Analysis of the time course ofa _Na ^c indicates that the pump Na flux is linearly related toa _Na ^c in the range 2–12mm. These results indicate thata _Na ^c plays an important role in relating apical Na entry to basolateral active Na flux.     

Mode of action of amiloride in toad urinary bladder

Summary The effect of amiloride on the sensitivity to Na of the mucosal border of toad urinary bladder was investigated by recording Na concentration-dependent transepithelial potential difference (V _t ) and the intracellular potential. When mucosal Na concentration was normal, amiloride added to the mucosal solution at 10^–4 m markedly reduced the mucosal membrane potential (V _m ) and altered the potential profile from a two-step type to a well type. Similar changes were observed when Na was totally eliminated from the mucosal medium. The serosal membrane potential was insensitive to amiloride and elimination of mucosal Na. In the absence of amiloride, theV _t could be described by the Goldman-Hodgkin-Katz equation in the range of mucosal Na concentration from 0 to 16mm, and amiloride extended this concentration range. By using the Goldman-Hodgkin-Katz equation, Na permeability was calculated from the data ofV _t 's obtained in the allowed ranges of Na concentration and compared before and after the addition of amiloride. The results show that Na permeability decreases to 1/600 of control when the maximum dose of amiloride (10^–4 m) is applied. The relationship between Na permeability and amiloride concentration is well explained on the basis of assumptions that amiloride binds to the Na site of the mucosal border in one-to-one fashion and in a competitive manner with Na and that Na permeability reduces in proportion to increase in number of the sites bound with amiloride.     

Ion transport by rabbit colon: II. Unidirectional sodium influx and the effects of amphotericin B and amiloride

Summary The unidirectional influx of Na from the mucosal solution into the epithelium ofin vitro descending rabbit colon (J _me ^Na ) determined under short-circuit conditions, is comprised of two components: one represents entry of Na into transporting epithelial cells and is abolished by amiloride which also abolishes Na absorption (J _net ^Na ). The other represents diffusional Na entry into paracellular pathways traversing the epithelium. In all instances, exposure of the mucosal surface to amphotericin B increased tissue conductance andJ _me ^Na and elicited K secretion. Tissues showing a spontaneousI _sc of approximately 4 eq/cm²hr did not respond to amphotericin B with increasedI _sc andJ _net ^Na . However, in tissues characterized by a lowerI _sc under control conditions, amphotericin B increasedI _sc andJ _net ^Na to approximately 4eq/cm²hr. These findings suggest that amphotericin increasesJ _net ^Na and elicits K secretion by disrupting the normal permselectivity of the mucosal membrane. Under these conditions the extrusion of Na from cell-to-serosal solution becomes the rate limiting step in transepithelial Na transport. Finally, a close correlation betweenJ _me ^Na andJ _net ^Na was observed when the rate of Na absorption varied either spontaneously or experimentally with amiloride, suggesting that the backflux of Na from cell-to-mucosal solution is undetectably small.     

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

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

Phenamil: An irreversible inhibitor of sodium channels in the toad urinary bladder

Summary Several new amiloride analogues and two reported photoaffinity analogues were tested for irreversible inhibition of short-circuit current,I _sc, in toad bladder. Bromoamiloride, a photoaffinity analogue, induced 40% irreversible inhibition at 500 m after irradiation with ultraviolet light 320 nm. Iodoamiloride caused no irreversible inhibition. Of the new analogues tested, only 3,5-diamino-6-chloro-N-[(phenylamino) aminomethylene] pyrazinecarboxamide,phenamil, irreversibly inhibitedI _sc at concentrations of 0.05 to 5 m when added to the mucosal solution. Irreversible inhibition ofI _sc by phenamil may be attributed to specific blockage of the mucosal sodium channels, which depended on: 1) time of exposure; 2) mucosal pH: 3) mucosal sodium concentration. For example, 5 m phenamil irreversibly inhibitedI _sc by 38% in 103mm Na at pH 8.6 and nearly 75% in 30mm Na at pH 6.4 after a 40-min exposure. Irreversible inhibition occurred in two phases with time constants of 10 min and approximately 140 min. Due to its irreversible nature, phenamil may be used to measure channel density.     

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

Summary 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 m 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 m amiloride), a Lorentzian component appeared with an average corner frequency,f _c=15.6±0.91 Hz and a mean plateau valueS _o=(7.04±2.94)×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.     

Effects of 2-deoxy-d-glucose,amiloride, vasopressin,and ouabain on active conductance andE Na in the toad bladder

Summary The effects of various agents on active sodium transport were studied in the toad bladder in terms of the equivalent circuit comprising an active conductanceK ^a, an electromotive forceE _Na, and a parallel passive conductanceK ^p. For agents which affectK ^a, but notE _Na orK ^p, the inverse slope of the plot of total conductance against short-circuit currentI ₀ evaluatesE _Na, and the intercept representsK ^p. Studies employing 5×10^–7 m amiloride to depressK ^a indicate a changingE _Na, invalidating the use of the slope technique with this agent. An alternative suitable technique employs 10^–5 m amiloride, which reducesI ₀ reversibly to near zero without effect onK ^p. Despite curvilinearity of the -I₀ plot under these conditions,K ^p may therefore be estimated fairly precisely from the residual conductance. It then becomes possible to follow the dynamic behavior ofK ^a andE _Na (in the absence of 10^–5 m amiloride) by frequent measurements of andI ₀, utilizing the relationshipsK ^a=K-K ^p, andK _Na=I _O/(K-K ^p). 2-deoxy-d-glucose (7.5×10^–3 m) depressedK ^a without affectingE _Na. Amiloride (5×10^–7 m) depressedK ^a and enhancedE _Na. Vasopressin (100 mU/ml) enhancedK ^a markedly and depressedE _Na slightly. Ouabain (10^–4 m) depressed bothK ^a andE _Na. All of the above effects were noted promptly;K ^p was unaffected. The electromotive force of Na transportE _Na appears not to be a pure energetic parameter, but to reflect kinetic factors as well, in accordance with thermodynamic considerations.     

Mechanisms of Na and Cl absorption across the distal colon epithelium of the pig

Summary Porcine distal colon epithelium was mounted in Ussing chambers and bathed in plasma-like Ringer solution. Tissue conductances ranged from 10 to 15 mS and the short-circuit current (I_sc) ranged from-15 to 220 A·cm^-2. Variations in basal I_sc resulted from differences in the amount of amiloride (10M mucosal addition)-sensitive Na⁺ absorption. Ion substitution and transepithelial flux experiments showed that 10 M amiloride produced a decrease in the mucosal-to-serosal (M-S) and net Na flux, and that this effect on I_sc was independent of Cl^- and HCO ₃ ^- replacement. When the concentration of mucosal amiloride was increased from 10 to 100 M, little change in I_sc was observed. However, increasing the concentration to 1 mM produced a further inhibition, which often reversed the polarity of the I_sc. The decrease in I_sc due to 1 mM amiloride was dependent on both Cl^- and HCO ₃ ^- , and was attributed to reductions in the M-S and net Na⁺ fluxes as well as the M-S unidirectional Cl^- flux. Ion replacement experiments demonstrated that Cl^- substitution reduced the M-S and net Na fluxes, while replacement of HCO ₃ ^- with HEPES abolished net Cl^- absorption by reducing the M-S unidirectional Cl^- flux. From these data it can be concluded that: (1) Na⁺ absorption is mediated by two distinct amiloride-sensitive transport pathways, and (2) Cl^- absorption is completely HCO ₃ ^- -dependent (presumably mediated by Cl^-/HCO ₃ ^- exchange) and occurs independently of Na⁺ absorption.Abbreviations G_t tissue conductance - HEPES tris (hydroxymethyl) aminomethane - (tris) N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - I_sc short-circuit current - J_r residual flux - M-S mucosal-to-scrosal - S-M serosal-to-mucosal - TTX tetrodotoxin     

Single-file diffusion through the Ca2+-activated K+ channel of human red cells

Summary We have examined the effect of internal and external pH on Na⁺ transport across toad bladder membrane vesicles. Vesicles prepared and assayed with a recently modified procedure (Garty & Asher, 1985) exhibit large, rheogenic, amiloridesensitive fluxes. Of the total²²Na uptake measured 0.5–2.0 min after introducing tracer, 80±4% (mean±se,n=9) is blocked by the diuretic with aK ₁ of 2×10^–8 m. Thus, this amiloridesensitive flux is mediated by the apical sodium-selective channels. Varying the internal (cytosolic) pH over the physiologic range 7.0–8.0 had no effect on sodium transport; this result suggests that variation of intracellular pHin vivo has no direct apical effect on modulating sodium uptake. On the other hand,²²Na was directly and monotonically dependent on external pH. External acidification also reduced the amiloride-sensitive efflux across the walls of the vesicles. This inhibition of²²Na efflux was noted at external Na⁺ concentrations of both 0.2 m and 53mm.These results are different from those reported with whole toad bladder. A number of possible bases for these differences are considered and discussed. We suggest that the natriferic response induced by mucosal acidification of whole toad urinary bladder appears to operate indirectly through one or more factors, presumably cytosolic, present in whole cells and absent from the vesicles.     

Amiloride-blockable sodium currents in isolated taste receptor cells

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

Effect of amiloride on the apical cell membrane cation channels of a sodium-absorbing,potassium-secreting renal epithelium

Summary The effect of the K-sparing diuretic amiloride was assessed electrophysiologically in the isolated cortical collecting tubule of the rabbit, a segment which absorbs Na and secretes K. Low concentrations of amiloride in the perfusate caused a rapid, reversible, decrease in the magnitude of the lumen negative transepithelial potential difference,V _te, transepithelial conductanceG _te, and equivalent short-circuit current,I _sc, with an apparentK _1/2 of approximately 7×10^–8 m. The effects of a maximum inhibitory concentration of amiloride (10^–5 m) were identical to those observed upon Na removal from lumen and bath (Na removal from the bath alone has no effect). Removal of Na in the presence of 10^–5 m amiloride had no affect onV _te,G _te, orI _sc, and is consistent with the view that amiloride blocks the Na conductive pathways of the apical cell membrane. Further, in the absence of Na, the subsequent addition of amiloride had no influence. In tubules where active Na absorption was either spontaneously low, or abolished by removal of Na from lumen and bath, the elevation of K from 5 to 155 meq/liter in the perfusate caused a marked change of theV _te in the negative direction and an increase in theG _te. These effects could be attributed to a high K permeability of the apical cell membrane and not of the tight junctions. Amiloride (10^–5 m) had no effect on these responses to K. It is concluded that amiloride selectively blocks the apical cell membrane Na channels but has no effect on the K conductive pathways(s). This selective nature of amiloride may indicate that Na and K are transported across the apical cell membrane via separate conductive pathways.     

Amiloride blockable sodium fluxes in toad bladder membrane vesicles

Summary Recently we reported a simple manual assay for the measurements of isotope fluxes through channels in heterogenous vesicle populations (Garty et al.,J. Biol. Chem. 258:13094–13099 (1983)). The present paper describes the application of this method to the assessment of amiloride blockable fluxes in toad bladder microsomes. When²²Na⁺ uptake was monitored in the presence of an opposing Na⁺ gradient, a relatively large and transient amiloride-sensitive flux was observed. Such an amiloride-blockable flux could also be induced by a KCl+valinomycin diffusion potential. The effects of the intra- and extravesicular ionic composition on the rate of²²Na⁺ uptake were examined. It was shown that the amiloride-blockable fluxes occur in particles permeable to Na⁺ and Li⁺ but relatively impermeable to K⁺, Tris⁺ and Cl^–. Analysis of the amiloride dose-response relations revealed a complex non Michaelis-Menten behavior. The data could be accounted for by assuming either a strong negative cooperativity in the amiloride-membrane interaction, or two amiloride-sensitive Na⁺ conducting pathways withK _i values of 0.06 and 6.4 m. Both pathways appear to be electrogenic and therefore the possibility of an electroneutral amiloride-blockable Na/H exchange was excluded. Calcium ions could block the amiloride-sensitive flux from the inner but not from the outer phase of the membrane. It is suggested that although a substantial part of the²²Na⁺ flux is inhibited only by a relatively high concentration of amiloride, this uptake represents transport through the apical Na-specific channels. The data also define the optimal experimental conditions for the study of amiloride-sensitive fluxes in toad bladder microsomes.     

Apical membrane K conductance in the toad urinary bladder

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

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.     

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

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