Passive sodium fluxes across toad bladder in the presence of simultaneous transepithelial gradients of concentration and potential

Summary Bidirectional sodium fluxes were measured across toad bladder sacs after eliminating active transport with ouabain. Transepithelial potential was clamped to 100 mV or the Nernst potential, _eq, at varying sodium concentrations,C _m , in the mucosal medium. Serosal sodium concentration,C _s , was held constant. Equations were derived for permeability, partial ionic conductance, and unidirectional fluxes as functions ofC _m andC _s , based in part on the assumption that the ratio,Q, of bulk sodium permeability to tracer sodium permeability is a constant, independent of concentration and potential. The results conformed closely to these equations.     

Effect of transepithelial concentration gradients on the passive fluxes of sodium across toad bladder

Summary Bidirectional sodium fluxes across toad bladder were measured after eliminating active transport with ouabain. Mucosal sodium concentration,C _m , was progressively reduced (from 114 to 3mm) while serosal sodium remained constant. Potential difference was maintained at zero by current passage. The ratio,Q, of the bulk permeability coefficient for sodium,P, to the tracer sodium permeability coefficientP ^*, was found to remain constant asC _m decreased. Equations were derived on this basis for bidirectional fluxes and forP andP ^* as functions ofC _m , which corresponded closely to the observed data. The explanation for the observed value ofQ and its constancy under these conditions is uncertain.     

Ba2+-inhibitable86Rb+ fluxes across membranes of vesicles from toad urinary bladder

Summary ⁸⁶Rb⁺ fluxes have been measured in suspensions of vesicles prepared from the epithelium of toad urinary bladder. A readily measurable barium-sensitive, ouabain-insensitive component has been identified; the concentration of external Ba²⁺ required for half-maximal inhibition was 0.6mm. The effects of externally added cations on⁸⁶Rb⁺ influx and efflux have established that this pathway is conductive, with a selectivity for K⁺, Rb⁺ and Cs⁺ over Na⁺ and Li⁺. the Rb⁺ uptake is inversely dependent on external pH, but not significantly affected by internal Ca²⁺ or external amiloride, quinine, quinidine or lidocaine. It is likely, albeit not yet certain, that the conductive Rb⁺ pathway is incorporated in basolateral vesicles oriented right-side-out. It is also not yet clear whether this pathway comprises the principle basolateral K⁺ channel in vivo, and that its properties have been unchanged during the preparative procedures. Subject to these caveats, the data suggest that the inhibition by quinidine of Na⁺ transport across toad bladder does not arise primarily from membrane depolarization produced by a direct blockage of the basolateral channels. It now seems more likely that the quinidine-induced elevation of intracellular Ca²⁺ activity directly blocks apical Na⁺ entry.     

Amide transport channels across toad urinary bladder

Summary Urea and other small amides cross the toad urinary bladder by a vasopressinsensitive pathway which is independent of somotic water flow. Amide transport has characteristics of facilitated transport: saturation, mutual inhibition between amides, and selective depression by agents such as phloretin. The present studies were designed to distinguish among several types of transport including (1) movement thought a fixed selective membrane channel and (2) movement via a mobile carrier. The former wold be characterized by co-transport (acceleration of labele amide flow in the direction of net flow in the opposite direction). Mucosal to serosal (MS) and serosal to mucosal (SM) permeabilities of labeled amides were determined in paired bladers. Unlabeled methylurea, a particularly potent inhibitor of amide movement, was added to either the M or S bath, while osmotic water flow was eliminated by addition of ethylene glycol to the opposite bat. Co-transport of labeled methylurea and, to a lesser degree, acetamide and urea with unlabeled methylurea was observed. Co-transport of the nonamides ethylene glycol and ethanol could not be demonstrated. Methylurea did not alter water permeability or transmembrane electrical resistance. The demonstration of co-transport is consistent with the presence of ADH-sensitive amide-selective channcels rather than a mobile carrier.     

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.     

Kinetics of bidirectional active sodium fluxes in the toad bladder

The kinetics of isotopic Na⁺ flows was studied in urinary bladders of toads from the Dominican Republic. Initial studies of the potential dependence of passive serosal to mucosal ²²Na⁺ efflux demonstrated the absence of isotope interaction and/or other coupling with passive Na⁺ flow. The electrical current $\text{I}$ and mucosal to serosal ²²Na⁺ influx were then measured with transmembrane potential clamped at $\text{Δψ = 0, 25, 50, 75 or 100}\text{mV}$. Subsequent elimination of active Na⁺ transport mucosal amiloride permitted calculation of the rates of active Na⁺ transport $\text{J}{}_{\mathrm{<mtext>Na</mtext>}}{}^{\mathrm{<mtext>a</mtext>}}$ and active and passive influx and $\text{J}{}_{\mathrm{<mtext>Na</mtext>}}{}^{\mathrm{<mtext>a</mtext>}}$ and $\text{J}{}_{\mathrm{<mtext>Na</mtext>}}{}^{\mathrm{<mtext>p</mtext>}}$. The results indicate that for Dominican toad bladders mounted in chambers only Na⁺ contributes significantly to transepithelial active ion transport; hence $\text{J}{}_{\mathrm{<mtext>Na</mtext>}}{}^{\mathrm{<mtext>a</mtext>}}\text{= J}{}^{\mathrm{<mtext>a</mtext>}}$. $\text{J}{}^{\mathrm{<mtext>a</mtext>}}$ was abolished at $\text{Δψ = E = 96.3 ± 1.9}\text{(S.E.) mV}$. As Δψ approached $\text{E}$, active efflux $\text{J}{}^{\mathrm{<mtext>a</mtext>}}$ became demonstrable. At $\text{Δ = 100}\text{mV}\text{,}\text{J}{}^{\mathrm{<mtext>a</mtext>}}$ exceeded $\text{J}{}^{\mathrm{<mtext>a</mtext>}}$, so that $\text{J}{}^{\mathrm{<mtext>a</mtext>}}$ was negative. Experimental values of $\text{J}{}^{\mathrm{<mtext>a</mtext>}}$ agreed well with theoretical values predicted by a thermodynamic formulation: $\text{J}{}_{\mathrm{<mtext>exp</mtext>}}{}^{\mathrm{<mtext>a</mtext>}}\text{= 0.985}\text{J}{}_{\mathrm{<mtext>theor</mtext>}}{}^{\mathrm{<mtext>a</mtext>}}\text{(r = 0.993)}$. The dependence of $\text{J}{}^{\mathrm{<mtext>a</mtext>}}$ on Δψ is curvilinear.     

Sodium fluxes through the active transport pathway in toad bladder

Summary To assess the active components of sodium flux across toad bladder as a function of transepithelial potential, unidirectional sodium fluxes between identical media were measured before and after adding sufficient ouabain (1.89×10^–3 m) to eliminate active transport, while clamping transepithelial potential to 0, 100 or 150 mV. Evidence was adduced that ouabain does not alter passive fluxes, and that fluxes remain constant if ouabain is not added. Hence, the ouabain-inhibitable fluxes represent fluxes through the active path. Results were analyzed by a set of equations, previously shown to describe adequately passive fluxes under electrical gradients in this tissue, here modified by the insertion ofE, the potential at which bidirectional sodium fluxes ( ^E and ^E ) through the active pathway are equal. According to these equations, ^E and ^E are the logarithmic mean of bidirectional fluxes through the active path at any potential, and the flux ratio in this path is modified by a constant factorQ _ia, which represents the ratio of the bulk diffusion coefficient to the tracer diffusion coefficient in this pathway. The data are shown to conform closely to these equations.Q _ia averages 2.54. Hence, serosal-to-mucosal flux vanishes rapidly as potential falls belowE. MeanE in these experiments was 158±1 mV. Thus, linear dependence of net flux in both active and passive pathways on potential is present, even though the sodium fluxes in both paths fail to conform to the Ussing flux ratio equation.Q _{i p}<1 in the passive path (qualitatively similar to exchange diffusion) andQ _ia>1 in the active path (as in single file pore diffusion). Both of these features tend to reduce the change in serosal-to-mucosal sodium flux induced by depolarization from spontaneous potential to zero potential (short-circuiting).     

Sodium fluxes through the active transport pathway in toad bladder.

To assess the active components of sodium flux across toad bladder as a function of transepithelial potential, unidirectional sodium fluxes between identical media were measured before and after adding sufficient ouabain (1.89 X 10(-3)M) to eliminate active transport, while clamping transepithelial potential to 0, 100 or 150 mV. Evidence was adduced that ouabain does not alter passive fluxes, and that fluxes remain constant if ouabain is not added. Hence, the ouabain-inhibitable fluxes represent fluxes through the active path. Results were analyzed by a set of equations, previously shown to describe adequately passive fluxes under electrical gradients in this tissue, here modified by the insertion of E, the potential at which bidirectional sodium fluxes (beta E, and theta E) through the active pathway are equal. According to these equations, beta E and theta E are the logarithmic mean of bidirectional fluxes through the active path at any potential, and the flux ratio in this path is modified by a constant factor Qia, which represents the ratio of the bulk diffusion coefficient to the tracer diffusion coefficient in this pathway. The data are shown to conform closely to these equations. Qia averages 2.54. Hence, serosal-to-mucosal flux vanishes rapidly as potential falls below E. Mean E in these experiments was 158 +/- 1 mV. Thus, linear dependence of net flux in both active and passive pathways on potential is present, even though the sodium fluxes in both paths fail to conform to the Ussing flux ratio equation. Qip less than 1 in the passive path (qualitatively similar to exchange diffusion) and Qia greater than 1 in the active path (as in single file pore diffusion). Both of these features tend to reduce the change in serosal-to-mucosal sodium flux induced by depolarization from spontaneous potential to zero potential ("short-circuiting").     

Cellular lithium and transepithelial transport across toad urinary bladder

Summary Toad urinary bladders were exposed on either their mucosal or serosal surfaces, or on both surfaces, to medium in which sodium was replaced completely by lithium. With mucosal lithium Ringer's, serosal sodium Ringer's, short-circuit current (SCC) declined by about 50 percent over the first 60 min and was then maintained over a further 180 min. Cellular lithium content was comparable to the sodium transport pool. With lithium Ringer's serosa, SCC was abolished over 60 to 120 min whether the mucosal cation was sodium or lithium. Measurements of cellular ionic composition revealed that the epithelial cells gained lithium from both the mucosal and serosal media. With lithium Ringer's mucosa and serosa, cells lost potassium and gained lithium and a little chloride and water, but these changes in cellular ions could not account for the current flow across the tissue under these conditions, which must, therefore, have been carried by a transepithelial movement of lithium itself. The inhibition by serosal lithium of SCC was overcome by exposure of the mucosal surface of the bladders to amphotericin B. Thus it reflected, predominantly, an inhibition of lithium entry to the cells across the apical membrane. It is suggested that this inhibition is a consequence of cellular lithium accumulation.     

Dobutamine inhibits vasopressin-mediated water transport across toad bladder epithelium

This study aimed to investigate the effect of dobutamine on water transport across toad bladder epithelium. Water flow through the membrane was measured gravimetrically in bladder sac preparations. Dobutamine had no effect on basal water transport, but partially inhibited transport stimulated by vasopressin. Similarly, dobutamine exerted no influence on the hydrosmotic response to 8-chlorophenylthio-cAMP, but interfered with the response to phosphodiesterase inhibitor 1-methyl-3-isobutyl-xanthine. These results demonstrate that this catecholamine may inhibit vasopressin-stimulated water transport at a site prior to cAMP formation. The use of propranolol was ineffective in blocking the effect of dobutamine on transport stimulated by vasopressin, indicating that beta-adrenoceptors play no role in this effect. On the other hand, phentolamine significantly reduced the effect of dobutamine, indicating the involvement of alpha-adrenoceptors in such event. Rauwolscine also inhibited the effect of dobutamine, pointing to the specific contribution of the alpha(2)-adrenoceptors to this effect. Taken together, the results of this study demonstrate that dobutamine inhibits vasopressin-stimulated water transport in toad bladders through a mechanism mediated by the stimulation of alpha(2)-adrenoceptors, thus suggesting that such a drug may exert a direct cellular effect on membrane permeability to water in transporting epithelia. The current study may provide a better understanding of the effects of dobutamine on renal function by contributing towards the elucidation of its action mechanism.     

Kinetics of bidirectional active sodium fluxes in the toad bladder.

The kinetics of isotopic Na+ flows was studied in urinary bladders of toads from the Dominican Republic. Initial studies of the potential dependence of passive serosal to mucosal 22Na+ efflux demonstrated the absence of isotope interaction and/or other coupling with passive Na+ flow. The electrical current I and mucosal to serosal 22Na+ influx were then measured with transmembrane potential clamped at deltapsi=0, 25, 50, 75 or 100 mV. Subsequent elimination of active Na+ transport with mucosal amiloride permitted calculation of the rates of active Na+ transport JaNa and active and passive influx leads to JaNa and leads to JpNa. The results indicate that for Dominican toad bladders mounted in chambers only Na+ contributes significantly to transepithelial active ion transport; hence JaNa=Ja. Ja was abolished at deltapsi=E=96.3+/-1.9 (S.E.) mV. As deltapsi approached E, active efflux comes from Ja became demonstrable. At deltapsi=100 mV, comes from Ja exceeded leads to Ja, so that Ja was negative. Experimental values of leads to Ja agreed well with theoretical values predicted by a thermodynamic formulation: leads to Jaexp=0.985 leads to Jatheor (r=0.993). The dependence of leads to Ja on deltapsi is curvilinear.     

Barium inhibition of sodium ion transport in toad bladder

The effect of Ba²⁺ on Na⁺ transport and electrical characteristics of toad bladder was determined from change produced in short circuit current (I_sc, epithelial, apical and basal-lateral potentials (ψ_t, ψ_a, ψ_b), epithelial and membrane resistances (R_t, R_a, R_b) and shunt resistance (R_s). Mucosal Ba²⁺ had no effect. Serosal Ba²⁺ reduced I_sc, ψ_t, ψ_a, and ψ_b, but had no effect on R_t, R_a, R_b and R_s. Minimal effective Ba²⁺ concentration was 5 · 10^?5 M. The phenomenon was reversed by Ba²⁺ removal, but not by 86 mM serosal K⁺. Ba²⁺ inhibition of I_sc did not impair the response to vasopressin which was quantitatively the same as controls. ψ_a with Ba²⁺ equalled ψ_b. After Ba²⁺ inhibition, ouabain produced no further decrease in ψ_t and I_sc. Ba²⁺ exposure after ouabain did not decrease ψ_t and I_sc. The results suggest that Ba²⁺ inhibits the basal-lateral electrogenic Na⁺ pump.     

Thermodynamic analysis of nonelectrolyte permeation across the toad urinary bladder

Summary Permeability coefficients (P's) and apparent activation energies (E _a s) for nonelectrolyte permeation across the toad urinary bladder have been analyzed in terms of the thermodynamics of partition between membrane lipids and water. Particular attention has been paid to the contributions made by –CH₂– and –OH groups: on the average, the addition of one –CH₂– group to a molecule increasesP fourfold, while the addition of one –OH group reducesP 500-fold. Using these changes inP, we have calculated the incremental free energies (F), enthalpies (H), and entropies (S) for partition, hydration, and solution in membrane lipids. The results for toad bladder have been compared and contrasted with those extracted from the literature for red blood cells, lecithin liposomes, and bulk phase lipid solvents. The partition of –CH₂– groups into toad bladder and red cell membranes is dominated by entropy effects, i.e., a decrease in entropy of the aqueous phase that pushes the group out of water, and an increase in entropy of the membrane lipid that pulls the group into the membrane. This process resembles that in frozen liposome membranes. In melted liposomes and bulk lipid solvents the free energy of solution in the lipid is controlled by enthalpy of solution. Partition of –OH groups in all systems is governed by hydrogen bonding between the –OH group and water. However, the solution of the –OH group in toad bladder membranes is complex, and processes such as dimer and tetramer formation in the lipid phase may be involved. The results presented in this and the previous paper are discussed in terms of the structure of phospholipid bilayer membranes. Attention is drawn to the possible role of structural defects in the quasi-crystalline structure of the lipid (so-called 2gl kinks) in the permeation of small molecules such as water, urea, methanol and acetamide.     

Ethanol and silver effects on ion transport across toad skin

Silver stimulated short-circuit current and transepithelial potential difference. Ethanol inhibited transpithelial potential difference. Ethanol had no effect on short-circuit current. Ethanol stimulated unidirectional movements of chloride from outside to inside and from inside to outside.     

Calcium ion fluxes across the external surface ofPhysarum polycephalum

Summary There is no significant change in Ca⁺⁺ efflux rate from plasmodia during chemotactic responses to several sugars, whereas substantially increased Ca⁺⁺ efflux caused by EDTA does not significantly affect movement. Evidently the Ca⁺⁺ fluxes controlling movement take place inside the organism, and chemotaxis probably involves a second messenger.     

Catecholamine stimulation of ion transport in the toad urinary bladder

We have observed that serosal catecholamines increase the amplitude of the short-circuit current (Isc) in the toad urinary bladder by as much as 450%. Chemical sympathectomy with 10(-6) M 6-hydroxydopamine and the sympathomimetic effects of 10(-5) M tyramine indicate a reservoir of amines in the serosal stroma of the tissue. The urinary epithelium from the toad responds to six adrenoceptor agonists: (-)-epinephrine, (-)-norepinephrine, (-)-phenylephrine, clonidine, methoxamine and oxymetazoline. The alpha 2-adrenoceptor agonist clonidine is most potent for stimulating Isc. Some agonists were found to diminish Isc. Apparently this is related to a simultaneous increase in the transepithelial flux of both chloride and sodium. The Isc response to the catecholamines is also inhibited by several adrenoceptor antagonists. The alpha 2-adrenoceptor antagonist yohimbine is more effective than the alpha 1-antagonist prazosin for blocking the stimulation of epithelial transport. As a result of these studies, we have tentatively classified the serosal adrenoceptor of the toad urinary bladder as alpha 2.