Gaspar Carrasquer

Anomalous potential response and (Na+ + K+)-ATPase in in vitro frog gastric mucosa

In general, increasing K+ on the nutrient side decreases the transmucosal PD (nutrient becomes more negative) but after bathing the mucosa in zero K+ media for about 30 min, or longer, elevation of K+ on the nutrient side increases the PD, an anomalous effect. In Cl- media, increasing nutrient K+ from zero to 4 mM produces an increase in PD (an anomalous response) of 3.1 and 5.3 mV in 2 and 5 min, respectively. Ouabain (10(-3) M) to the nutrient side abolished the anomalous response as did removal of Na+ (choline for Na+) from bathing media. In SO4(2-) media (SO4(2-) for Cl-), a significant anomalous PD response was observed when K+ on the nutrient side was increased from zero to 1, 2 or 3 mM but not to higher K+ concentrations. In this case, ouabain also abolished the anomalous response. It is postulated, on the basis of the effects of ouabain and the use of choline media, that an electrogenic (Na+ + K+)-ATPase pump is present on the nutrient-facing membrane in which more Na+ than K+ are transported per cycle.

Evidence for HCO3− conductance pathways in nutrient membrane of resting frog fundus

Abstract The effect on potential difference (PD) and resistance in Cl − media bathing the resting fundus of Rana pipiens was determined for nutrient HCO 3 − changes from 25 mM to several lower concentrations and back to 25 mM. The graph of |vbΔPD|vb versus log[HCO 3 − ] was linear for changes from 25 down to 3.1 mM and also back to 25 mM, but deviated considerably for changes to 1.6 mM. The fact that changes from higher to lower HCO 3 − gave a less rapid initial PD response than the reverse direction eliminated H + conductance pathways as being predominant. Experiments were done in which in the first part changes were made in the nutrient solution from 5% CO 2 and 25 mM HCO 3 − to 0.6% CO 2 and 3 mM HCO 3 − and in the second part, the same changes with the simultaneous change of secretory solution from 5% to 10% CO 2 . The magnitude of the PD decrease was greater by 4.0 mV in the second part. This result indicated that HCO 3 − rather than OH − conductance pathways predominated. On the secretory side, the change from 25 to 3.1 mM HCO 3 − gave a small but significant change in PD. The latter effect was too small to determine whether HCO 3 − pathways existed in the secretory membrane.

Potential difference responses due to K+, Na+ and Cl− changes in Bullfrog antrum with and without HCO3−

The effect of changing [K+], [Na+] and [Cl-] in nutrient solution was studied in bullfrog antrum with and without HCO3- in nutrient. In 25 mM HCO3- (95% O2/5% CO2) and in zero HCO3- (100% O2), nutrient pH was maintained at 7.3. Changing from 4 to 40 mM K+ or from 81 to 8.1 mM Cl- gave a decrease 10 min later in transmucosal PD (nutrient became more negative)--a normal response. These responses were less in zero than in 25 mM HCO3-. A decrease from 102 to 8 mM Na+ decreased PD (anomalous response of electrogenic NaCl symport). This effect was attenuated or eliminated in zero HCO3-. In contrast, change from 4 to 40 mM K+ gave initial anomalous PD response and change from 102 to 8 mM Na+, initial normal PD response with either zero or 25 mM HCO3-. Both responses were associated with (Na+ + K+)-ATPase pump and were greater in zero than in 25 mM HCO3-. Initial PD increases in zero HCO3- are explained as due to increase in the resistance of passive conductance and/or NaCl symport pathways. Thus, removal of HCO3- modifies conductance pathways of nutrient membrane.

Effect of melittin on PD, resistance and short-circuit current in the frog gastric mucosa.

In an in-vitro preparation of gastric mucosae of Rana pipiens, the effect of adding melittin to a concentration of 5x10-6 M in the secretory solution on the transepithelial potential difference (PD), resistance (R) and short-circuit current (Isc) was studied. In 20 min, melittin decreased the PD by 9.3 mV and R by 148 ohm cm2. These changes can be explained by a decrease in the resistance, RP, of the paracellular pathway. To determine whether specific-ion pathways were responsible for the decrease in R, the effect of melittin on the partial conductances of Cl-, K+ and Na+ was also studied using the ion substitution method. Melittin decreased the PD response to changes in nutrient Na+, K+ and Cl- and the PD response to changes in secretory Cl-, but did not affect PD responses to changes in secretory Na+ or K+. Therefore, melittin decreased the nutrient membrane partial conductances of Cl-, K+ and Na+ and secretory membrane partial conductance of Cl-, without affecting the secretory partial conductances of Na+ or K+. Initially, melittin increased Isc in regular and Cl--free but not in Na+-free solutions. There was a delayed decrease in Isc. The results indicate that melittin decreases RP, increases the Na+ conductance of the secretory membrane and inhibits, eventually, the Na+/K+-ATPase pump.

Amphotericin B enhanced anomalous potential difference response to changes in aqueous K+ in frog cornea

An increase in aqueous K+ from 0 to 4 mM increased the potential difference (anomalous response of electrogenic (Na+ + K+)-ATPase antiport) by 1.1 mV in Cl(-)-free solutions compared to 6.8 mV in Cl- solutions. With amphotericin B added to the tear solution in Cl(-)-free solutions, the anomalous PD response for the addition of 4 mM K+ to the aqueous solution was about 20 mV, significantly greater than in Cl- solutions. This anomalous response was inhibited by ouabain. These data support the electrogenicity of the (Na+ + K+)-ATPase pump. It is also evident that, for the pump to respond, Na+ should readily enter the cell. This may be accomplished experimentally, either across the basolateral membrane in Cl- solutions or across the apical membrane in Cl(-)-free solutions with amphotericin B present in the tear solution.

Effects of ouabain on frog gastric mucosa in vitro

The effect of the addition of ouabain to the nutrient solution was determined on resistance, potential difference (p.d.) and H+ secretion rate. In NaCl media, 10(-3) M ouabain decreased significantly the p.d. from 25.6 mV to 16.1 mV in 30 min and to 11.0 mV in 60 min. No significant changes occurred in resistance and H+ secretion rate. In Na2SO4 (Cl(-)-free) media, ouabain produced a biphasic effect on p.d. The p.d. changed from -28.0 mV (nutrient-negative) to a nadir of -37.4 mV in 7 min and then increased to -16.4 mV in 60 min. At the nadir there was no significant change in resistance or H+ secretion rate but at 60 min, unlike Cl- media, resistance increased by 36% and H+ secretion rate decreased by 43%. To decide whether the ouabain-caused decrease in H+ rate in Na2SO4 media was due to an effect on the H+ pump or on resistance of the return pathways, the voltage was clamped at 0 and 40 mV. Clamping the voltage showed that in the case of a marked decrease in the H+ secretion rate, the H+ transport mechanism itself was inhibited (and not the parallel pathway). The decrease in p.d. due to ouabain in Cl- and SO42- media indicates that the (Na+ + K+)-ATPase mechanism may be electrogenic.

Normal and anomalous potential responses due to K+ changes in bullfrog antrum

The effect of changing the K+ concentration in the bathing media was studied in the bullfrog antrum. Usually increasing K+ on the nutrient side in standard Cl- -containing and Cl- -free solutions decreased the transmucosal potential difference (nutrient became more negative) - a normal effect. Similar results were obtained on the secretory side. Moreover, for K+ changes on the nutrient side in Cl- media, a plot of magnitude of delta V vs. log [K+] was linear for [K+] greater than 20 mM with slope of 27 mV per 10-fold change in [K+]. However, after bathing the mucosa in Cl- media with zero K+ for about 20 min, elevating the nutrient [K+] to 4 mM increased the potential difference (V) by 4.8 mV in 5 min and repeating the same sequence increased V by 6.9 mV in 5 min - both anomalous effects. Beyond 20 mM K+ the response was normal. In SO2-4 media, an anomalous potential difference of about 1 mV was obtained for changes from 0 to 3 or 6 mM nutrient K+. Ouabain (1 X 10(-3) M) in the nutrient solution abolished the anomalous response in Cl- and SO2-4 media. The normal response is attributed to passive, conductance pathways and the anomalous response because of the effect of ouabain, to a (Na+ + K+)-ATPase pump on the nutrient-facing membrane in which more Na+ than K+ ions are transported per cycle.

Microelectrode studies of amphotericin B on Na+ and K+ conductance in bullfrog cornea

Addition of 10(-5) M amphotericin B to the tear solution of an in vitro preparation of the frog cornea increased the transepithelial conductance, gt, and decreased the apical membrane fractional resistance, f(R0), in the presence or absence of tear Na+ and Cl-. In the presence of tear Na+ and Cl-, amphotericin B increased the short-circuit current, Isc, from 3.9 to 8.8 microA.cm-2 and changed the intracellular potential, V0, from -48.5 to -17.9 mV probably due to a higher increase in the Na+ than in the K+ conductance. In the absence of tear Na+ and Cl-, amphotericin B decreased Isc from 5.5 to about 0 microA.cm-2 due to K+ (and possibly Na+) flux from cell to tear and changed V0 from -35.4 to -63.6 mV due to the increase in conductance of both ions. Increase in the tear K+ from 4 to 79 mM (in exchange for choline), in the presence of amphotericin B and absence of tear Na+ and Cl-, decreased f(R0) from 0.09 to 0.06, increased gt from 0.23 to 0.31 mS, increased Isc from 0.63 to 7.3 microA.cm-2, and changed V0 from -65.5 to -17.3 mV due to the change in EK in the presence of a high conductance in the tear membrane. Similar effects were observed with an increase of tear Na+. Results support the concept that the Na+ conductance opened by amphotericin B in the apical membrane is greater than the K+ conductance. Previously observed transepithelial effects of the ionophore may be explained mostly on the basis of its effect on the apical membrane.

Evidence for HCO3- conductance pathways in nutrient membrane of bullfrog antrum.

The effect of changing the nutrient HCO3- concentration on potential difference (PD) and resistance in bullfrog antrum bathing in CI- media was determined. Changes in HCO3- concentration were from 25 mM to several lower concentrations and back to 25 mM. A plot of /delta PD/ versus log [HCO3-] gave a linear relation for changes of HCO3- concentration from 25 down to 3.1 mM and back to 25 mM but deviated to some extent for changes to 1.6 mM. In these experiments, changes from higher to lower HCO3- concentrations gave a less rapid initial PD response than those in the reverse direction. This result eliminated H+ conductance pathways as being predominant. Experiments were done in which in the first part changes were made in nutrient solution from 5 percent CO2 and 25 mM HCO3- to 0.6 percent CO2 and 3 mM HCO3- and in the second part the same changes with a simultaneous changes of secretory solution from 5 percent to 10 percent CO2. The magnitude of PD decrease was greater by 4.5 mV in the second part. This result indicated that HCO3- conductance pathways rather than OH- conductance pathways are predominated . There was no evidence of HCO3-, OH-, and H+ conductance pathways in secretory membranes.

FURTHER EVIDENCE FOR A SIMPLE CL CONDUCTANCE PATHWAY IN NUTRIENT MEMBRANE OF FROG STOMACH

A decrease in nutrient Cl- increases the negativity of the nutrient relative to the secretory side. It seemed possible that Cl- transport could result from a neutral Cl- mechanism in the nutrient membrane coupled to a simple Cl- conductance pathway in the secretory membrane. Experiments in HCO3(-)-free, K(+)-free and Na(+)-free solutions in both bathing media gave for a 10-fold change in nutrient Cl- a PD change of 9.5 mV. Similar experiments with 0.5 mM DIDS in the nutrient solution gave for a 10-fold change in nutrient Cl- a PD change of 7.9 mV. These experiments eliminated a neutral Cl(-)-HCO3- exchanger, a NaCl and a KCl symport. Thus the change in PD could best be explained by a simple Cl- conductance in the nutrient membrane.