Ion Transport in Isolated Rabbit Ileum : I. Short-circuit current and Na fluxes

The transmural potential difference, short-circuit current, and Na fluxes have been investigated in an in vitro preparation of isolated rabbit ileum. When the tissue is perfused with a physiological buffer, the serosal surface is electrically positive with respect to the mucosal surface and the initial potential difference in the presence of glucose averages 9 mv. Unidirectional and net Na fluxes have been determined under a variety of conditions, and in each instance, most if not all of the simultaneously measured short-circuit current could be attributed to the active transport of Na from mucosa to serosa. Active Na transport is dependent upon the presence of intact aerobic metabolic pathways and is inhibited by low concentrations of ouabain in the serosal medium. A method is described for determining whether a unidirectional ionic flux is the result of passive diffusion alone, in the presence of active transport of that ion in the opposite direction. Using this method we have demonstrated that the serosa-to-mucosa flux of Na may be attributed to passive diffusion with no evidence for the presence of carrier-mediated exchange diffusion or the influence of solvent-drag.     

Sodium-Sulfate Symport by Aplysia californica Gut

Sulfate transport across plasma membranes has been described in a wide variety of organisms and cell types including gastrointestinal epithelia. Sulfate transport can be coupled to proton, sodium symport or antiport processes involving chloride or bicarbonate. It had previously been observed in Aplysia gut that sulfate was actively absorbed. To understand the mechanism for this transport, short-circuited Aplysia californica gut was used. Bidirectional transepithelial fluxes of both sodium and sulfate were measured to see whether there was interaction between the fluxes. The net mucosal-to-serosal flux of Na(+) was enhanced by the presence of sulfate and it was abolished by the presence of serosal ouabain. Similarly, the net mucosal-to-serosal flux of sulfate was dependent upon the presence of Na(+) and was abolished by the presence of serosal ouabain. Theophylline, DIDS and bumetanide, added to either side, had no effect on transepithelial potential difference or short-circuit current in the Aplysia gut bathed in a Na2SO4 seawater medium. However, mucosal thiosulfate inhibited the net mucosal-to-serosal fluxes of both sulfate and Na(+) and the thiosulfate-sensitive Na(+) flux to that of sulfate was 2:1. These results suggest the presence of a Na-SO4 symporter in the mucosal membrane of the Aplysia californica foregut absorptive cell.     

Sodium transport by isolated bullfrog small intestine. Effect of prostaglandin E1.

Addition of 446 micron prostaglandin E1 (PGE1) to the serosal medium of isolated short-circuited bullfrog small intestine elicited small increases transmural potential difference and short-circuit current while addition of PGE1 to the mucosal medium caused no change in the electrical parameters. Addition of 100 micron indomethacin to the mucosal medium inhibited both potential difference and short-circuit current with a resultant increase in steady-state tissue resistance. In the presence of mucosal 100 micron indomethacin, serosal 60 micron PGE1 markedly stimulated transmural potential difference and short-circuit current with a resultant decrease in steady-state tissue resistance. Serosal arachidonic acid (330 micron) stimulated transmural potential difference and short-circuit current and this effect was abolished by the addition of 100 micron indomethacin to the mucosal medium. Serosal 60 micron PGE1 only stimulated the M (mucosa) leads to S (serosa) unidirectional flux of sodium. These results strongly suggest that the PGE1 action is mediated either via a series of metabolic reactions which possibly increase the permeability of the mucosal membrane to sodium or via direct stimulation of rheogenic sodium pump activity.     

Sodium-phosphate symport by Aplysia californica gut

Phosphate transport across plasma membranes has been described in a wide variety of organisms and cell types including gastrointestinal epithelia. Phosphate transport across apical membranes of vertebrate gastrointestinal epithelia requires sodium; whereas, its transport across the basolateral membrane requires antiport processes involving primarily chloride or bicarbonate. To decipher the phosphate transport mechanism in the foregut apical membrane of the mollusc, Aplysia californica, in vitro short-circuited Aplysia californica gut was used. Bidirectional transepithelial fluxes of both sodium and phosphate were measured to see whether there was interaction between the fluxes. The net mucosal-to-serosal flux of Na+ was enhanced by the presence of phosphate and it was abolished by the presence of serosal ouabain. Similarly, the net mucosal-to-serosal flux of phosphate was dependent upon the presence of Na+ and was abolished by the presence of serosal ouabain. Theophylline, DIDS and bumetande, added to either side, had no effect on transepithelial difference or short-circuit current in the Aplysia gut bathed in a Na2HPO4 seawater medium. However, mucosal arsenate inhibited the net mucosal-to-serosal fluxes of both phosphate and Na+ and the arsenate-sensitive Na+ flux to that of phosphate was 2:1. These results suggest the presence of a Na-PO4 symporter in the mucosal membrane of the Aplysia californica foregut absorptive cell.     

The inhibitory effect of strophanthidin on secretion by the isolated gastric mucosa

The unidirectional fluxes of Na⁺ and Cl^- were measured across the isolated gastric mucosa of the bullfrog (R. catesbiana). The addition of strophanthidin, a cardiac aglycone, resulted in marked reductions of the spontaneous potential and short-circuit current. Associated with these changes, the isolated gastric mucosa ceased secreting chloride and hydrogen ion. Although the active component of chloride transfer was inhibited, the exchange diffusion component seemed to increase. No significant changes in membrane conductance or sodium flux were noted. Possible mechanisms of strophanthidin inhibition were discussed in view of its effect on chloride transport across the gastric mucosa and on sodium and potassium transfer in other tissues. It was concluded that the cardiac glycosides may not be specific inhibitors of sodium and potassium transport. This non-specific inhibition suggests that active chloride transport is affected by strophanthidin directly and/or anion secretion is dependent upon normal functioning of cation transport systems in the tissue.     

Active sodium transport by the isolated toad bladder

Studies were made of the active ion transport by the isolated urinary bladder of the European toad, Bufo bufo, and the large American toad, Bufo marinus. The urinary bladder of the toad is a thin membrane consisting of a single layer of mucosal cells supported on a small amount of connective tissue. The bladder exhibits a characteristic transmembrane potential with the serosal surface electrically positive to the mucosal surface. Active sodium transport was demonstrated by the isolated bladder under both aerobic and anaerobic conditions. Aerobically the mean net sodium flux across the bladder wall measured with radioactive isotopes, Na²⁴ and Na²², just equalled the simultaneous short-circuit current in 42 periods each of 1 hour's duration. The electrical phenomenon exhibited by the isolated membrane was thus quantitatively accounted for solely by active transport of sodium. Anaerobically the mean net sodium flux was found to be slightly less than the short-circuit current in 21 periods of observation. The cause of this discrepancy is not known. The short-circuit current of the isolated toad bladder was regularly stimulated with pure oxytocin and vasopressin when applied to the serosal surface under aerobic and anaerobic conditions. Adrenaline failed to stimulate the short-circuit current of the toad bladder.     

Transport of butyrate across the isolated bovine rumen epithelium--interaction with sodium, chloride and bicarbonate

The Ussing chamber technique was used for studying unidirectional fluxes of 14C-butyrate across the bovine rumen epithelium in vitro. Significant amounts of butyrate were absorbed across the bovine rumen epithelium in vitro, without any external driving force. The paracellular pathway was quantitatively insignificant. The transcellular pathway was predominately voltage-insensitive. The serosal to mucosal (SM) pathway was regulated by mass action, whereas the mucosal to serosal (MS) pathway further includes a saturable process, which accounted for 30 to 55% of the MS flux. The studied transport process for 14C-butyrate across the epithelium could include metabolic processes and transport of 14C-labelled butyrate metabolites. The transport of butyrate interacted with Na+, Cl- and HCO3-, and there was a linear relationship between butyrate and sodium net transport. Lowering the sodium concentration from 140 to 10 mmol l-1 decreased the butyrate MS flux significantly. Amiloride (1 mmol l-1) did, however, not reduce the butyrate flux significantly. Chloride concentration in itself did not seem to influence the transport of butyrate, but chloride-free conditions tended to increase the MS and SM flux of butyrate by a DIDS-sensitive pathway. DIDS (bilateral 0.5 mmol l-1) did further decrease the butyrate SM flux significantly at all chloride concentrations. Removing bicarbonate from the experimental solutions decreased the MS and increased the SM flux of butyrate significantly, and abolished net butyrate flux. There were no significant effects of the carbonic anhydrase inhibitor Acetazolamide (bilateral 1.0 mmol l-1). The results can be explained by a model where butyrate and butyrate metabolites are transported both by passive diffusion and by an electroneutral anion-exchange with bicarbonate. The model couples sodium and butyrate via CO2 from metabolism of butyrate, and intracellular pH.     

Sodium transport by isolated bullfrog small intestine. Effect of Prostaglandin E1

Addition of 446 μM prostaglandin E₁ (PGE₁) to the serosal medium of isolated short-circuited bullfrog small intestine elicited small increases in transmural potential difference and short-circuit current while addition of PGE₁ to the mucosal medium caused no change in the electrical parameters. Addition of 100 μM indomethacin to the mucosal medium inhibited both potential difference and short-circuit current with a resultant increase in steady-state tissue resistance. In the presence of mucosal 100 μM indomethacin, serosal 60 μM PGE₁ markedly stimulated transmural potential difference and short-circuit current with a resultant decrease in steady-state tissue resistance. Serosal arachidonic acid (330μM) stimulated transmural potential difference and short-circuit current and this effect was abolished by the addition of 100 μM indomethacin to the mucosal medium. Serosal 60 μM PGE₁ only stimulated the M (mucosa) → S (serosa) unidirectional flux of sodium. These results strongly suggest that the PGE₁ action is mediated either via a series of metabolic reactions which possibly increase the permeability of the mucosal membrane to sodium or via direct stimulation of rheogenic sodium pump activity.     

Electrical characteristics of isolated Aplysia californica intestine

• 1.1. Transmural potential difference and short-circuit current of intestinal sheets of Aplysia califonica were stable up to 5 hr.
• 2.2. Transmural potential difference was serosa negative relative to the mucosa and the short-circuit current was consistent with a net active anion transport from mucosa to serosa.
• 3.3. Transmural potential difference and short-circuit current were dependent upon the presence of sodium and chloride in the bathing medium.
• 4.4. Transmural potential difference and short-circuit current were predominantly dependent upon aerobic metabolism, however a finite residual electrical component was dependent upon glycolytic energy.
• 5.5. The major portion of the short-circuit current is carried by a net active chloride transfer from the mucosal to serosal compartments while the minor portion is carried by a net active sodium transfer in the same direction.

     

Responses of frog skin Na(+) and Cl(-) transport to guanylin

A possible role for the peptide hormone guanylin was investigated in frog skin (Rana pipiens) epithelium. Sodium and chloride fluxes in response to this peptide were evaluated in Ussing-type chambers. Net and unidirectional Na(+) fluxes were measured by using (22)Na(+) and atomic absorption analysis of total [Na(+)], whereas net Cl(-) fluxes were measured by using electrometric titration for [Cl(-)]. Mucosal application of guanylin (0.5-2.0 micromol/l) caused marked increases in serosal to mucosal net flux and efflux of Na(+). Serosal application of guanylin over the same dose range caused similar large increases in net serosal to mucosal (S-->M) Na(+) and Cl(-) flux as well as Na(+) efflux. Responses of Na(+) influx were small and inconsistent. When frog skin was bathed on the serosal side with Cl(-)-free Ringer's solution mucosal application of guanylin stimulated large efflux and S-->M net fluxes of Na(+). Serosal treatment yielded large Na(+) effluxes and S-->M Na(+) and Cl(-) net fluxes. When frog skin serosal surfaces were bathed with Na(+)- free Ringer's solution mucosal guanylin treatment had no effect but serosal treatment produced large S-->M Cl(-) net fluxes.     

Intestinal glucose and galactose transport in the cultured gilthead bream (Sparus aurata)

1. Electrical parameters and transepithelial glucose and galactose transport were determined in vitro across anterior and posterior intestine of the culture fish Sparus aurata. 2. Electrical potential difference (PD) and short-circuit current (Isc) were serosa-positive in anterior intestine, while they were serosa-negative or near zero in posterior intestine. 3. Tissue conductance (Gt) was higher in posterior than in anterior intestine. In both parts it was decreased when the Na ion was omitted in mucosal and serosal reservoirs. 4. Addition of glucose or galactose to the mucosal side of intestine caused an increase in PD and Isc in posterior intestine but did not significantly change PD and Isc in anterior intestine. 5. Isotopic flux of glucose and galactose measurements in short-circuit conditions showed a net active glucose and galactose absorption in posterior intestine, while in anterior intestine active transport of glucose or galactose was not observed. 6. The net transport of glucose and galactose in posterior intestine was decreased to zero in the absence of Na in mucosal and serosal reservoirs or in the presence of ouabain (1 mM) in serosal solution.     

Benzodiazepines stimulate sodium ion transport in frog skin epithelium

Benzodiazepine binding sites are present in a variety of non-neuronal tissues including the kidney where they are localized to distal nephron segments. It is postulated that renal binding sites are involved in modulating ion transport. This study examined the effects of two benzodiazepines on sodium transport in frog skin epithelium, a model system for sodium transport in renal collecting duct. Treatment of short-circuited frog skin with diazepam (a non-selective benzodiazepine agonist) stimulated amiloride-sensitive short-circuit current, reflecting stimulation of active sodium transport. The diazepam response was equally effective with either serosal or mucosal application of the drug. Maximal stimulation of the current (42 +/- 8%) was achieved with 10 microM diazepam (serosal). Short-circuit current was similarly augmented by serosal or mucosal addition of Ro5-4864, a benzodiazepine agonist with selective activity at peripheral (non-neuronal) receptors. The natriferic response to diazepam was additive to that of vasopressin or cyclic AMP suggesting that the mode of action of benzodiazepines is probably distinct from the cyclic AMP pathway. Thus, frog skin appears to be a useful model to examine the epithelial effects of benzodiazepines. Whether stimulation of sodium transport, however, involves peripheral-type benzodiazepine receptors in this tissue requires further studies.     

Potential, Current, and Ionic Fluxes across the Isolated Retinal Pigment Epithelium and Choroid

A flux chamber was utilized for in vitro studies of a membrane formed by the retinal pigment epithelium and choroid of the eye of the toad (Bufo arenarum and Bufo marinus). A transmembrane potential of 20 to 30 mv was found, the pigment epithelium surface positive with respect to the choroidal surface. Unidirectional fluxes of chloride, sodium, potassium, and calcium were determined in the absence of an electrochemical potential difference. A net transfer of chloride from pigment epithelium to choroid accounted for a major fraction of the mean short-circuit current. A small net flux of sodium from choroid to pigment epithelium was detected in Bufo marinus. In both species of toads, however, about one-third of the mean short-circuit current remained unaccounted for. Manometric determinations of bicarbonate suggested an uptake of this ion at the epithelial surface of the membrane but did not provide evidence of a relationship between this process and the short-circuit current.     

p-Aminohippurate transport in canine tracheal epithelium

The unidirectional fluxes of 20, 100, 500, and 2,000 microM rho-aminohippurate (PAH) were measured under open- and short-circuit conditions in canine tracheal epithelium mounted as flat sheets in Ussing chambers. In tissues pretreated with mucosal indomethacin (10(-6) M) and amiloride (10(-4) M), unidirectional PAH fluxes under short-circuit conditions increased with increasing bath concentrations but there was no significant net PAH transport. After stimulation of chloride secretion by mucosal cyclic adenosine 3',5' -cyclic monophosphate (cAMP 10(-3) M), there was a significant increase in the secretory flux of PAH and a significant decrease in the absorptive flux of PAH. This resulted in net PAH secretion that demonstrated saturation kinetics with an apparent Michaelis-Menten constant of 754 microM by Lineweaver-Burk analysis. Intracellular concentrations of PAH were 0.4-1.2 times bath concentrations after pretreatment with indomethacin and amiloride and increased to 2.6-3.3 times bath concentrations after cAMP. Under open-circuit conditions, secretory PAH flux decreased and absorptive flux increased resulting in net PAH absorption. We conclude from these early studies that the canine tracheal epithelium possesses a specialized system for the transport of organic anions in the airways and that this transport system may share many similarities with organic anion transport in the kidney.     

Model of ionic transport for bovine ciliary epithelium: effects of acetazolamide and HCO

The possible existence of transepithelial bicarbonate transport across the isolated bovine ciliary body was investigated by employing a chamber that allows for the measurement of unidirectional, radiolabeled fluxes of CO2 + HCO. No net flux of HCO was detected. However, acetazolamide (0.1 mM) reduced the simultaneously measured short-circuit current (I(sc)). In other experiments in which (36)Cl- was used, a net Cl- flux of 1.12 microeq. h(-1). cm(-2) (30 microA/cm(2)) in the blood-to-aqueous direction was detected. Acetazolamide, as well as removal of HCO from the aqueous bathing solution, inhibited the net Cl- flux and I(sc). Because such removal should increase HCO diffusion toward the aqueous compartment and increase the I(sc), this paradoxical effect could result from cell acidification and partial closure of Cl- channels. The acetazolamide effect on Cl- fluxes can be explained by a reduction of cellular H+ and HCO (generated from metabolic CO2 production), which exchange with Na+ and Cl- via Na+/H+ and Cl-/HCO exchangers, contributing to the net Cl- transport. The fact that the net Cl- flux is about three times larger than the I(sc) is explained with a vectorial model in which there is a secretion of Na+ and K+ into the aqueous humor that partially subtracts from the net Cl- flux. These transport characteristics of the bovine ciliary epithelium suggest how acetazolamide reduces intraocular pressure in the absence of HCO transport as a driving force for fluid secretion.     

Thiocyanate inhibition of active chloride absortion in Aplysia intestine

This investigation was principally undertaken to examine the mechanism of active chloride absorption across the Aplysia californica intestine by using various inhibitors of ion transport. Isolated intestine, mounted between identical oxygenated sodium-free seawater solutions, maintained stable transmural potential differences (serosa negative) and short-circuit currents for several hours at 25°C. The metabolic inhibitors, 2,4-dinitrophenol and flouride, reduced both transmural potential difference and short-circuit current; however, the electrical characteristics were predominantly dependent upon glycolytic energy. The addition of thiocyanate to the mucosal solution inhibited both electrical characteristics in parallel, and this inhibition could be titrated according to the thiocyanate concentration. The short-circuit current was carried wholly by a net active chloride transfer from mucosa to serosa as determined by flux measurements. These results suggest that active chloride absorption may be mediated by a primary active transport process.     

D-galactose accumulation in rabbit ileum. Effects of theophylline on serosal permeability.

The effects of theophylline and dibutyryl cyclic AMP, on in vitro unidirectional galactose fluxes across the mucosal and serosal borders of rabbit ileum have been studied. 1. When Ringer [galactose] = 2mM, theophylline and dibutyryl cyclic AMP reduce both mucosal-serosal and serosal-mucosal galactose flux by approx. 50%. The K1 for theophylline inhibition of flux in both directions is 2 mM. 1 mM dibutyryl cyclic AMP elicits a maximal inhibitory response. Concurrent with the inhibition in transmural galactose fluxes, theophylline and dibutyryl cyclic AMP increase the tissue accumulation of [galactose] and the specific-activity ratio R of 3H : 14C-labelled galactose coming from the mucosal and serosal solutions respectively. It is deduced that theophylline and dibutyryl cyclic AMP are without effect on the mucosal unidirectional permeability to galactose but cause a symmetrical reduction in serosal entry and exit permeability. 2. Reduction in the asymmetry of the mucosal border to galactose by reducing Ringer [Na], raising Ringer [galctose] or adding ouabain reduces the theophylline-dependent increase in galactose accumulation. 3. Hypertonicity in the serosal solution increases the permeability of the serosal border to galactose and reduces tissue galactose accumulation. Serosal hypertonicity partially reverses the theophylline-depedent effects on galactose transport. Replacing Ringer chloride by sulphate abolishes the theophylline-dependent effects on galactose transport. 4. It is considered that the theophylline-dependent increase in galactose accumulation results from the reduction in serosal permeability. This is shown to be a quantitatively consistent inference. 5. Further support for the view that the asymmetric transport of galactose in rabbit ileum results from convective-diffusion is presented.     

Electrogenic anion absorption in rabbit distal colon.

The mechanisms of anion transport in the rabbit distal colon were investigated in vitro under short-circuit conditions by examining the effects of transport inhibitors (the stilbene derivatives SITS and DIDS) under a variety of conditions. These agents consistently inhibited Jm-sCl: SITS (10(-3) M) reduced both unidirectional chloride fluxes to the same degree and did not alter JnetCl. In contrast, 10(-4) M DIDS had no effect on Js-mCl and had a significant chloride antiabsorptive effect. DIDS had no effect on either tissue cyclic AMP levels or on basal flux of potassium. The effects of SITS and the cyclic AMP-related secretagogue theophylline on Isc were independent. Additionally, there was no significant alteration of intracellular potential difference or apical membrane fractional resistance elicited by SITS during microelectrode impalement of colonic surface epithelial cells. These results suggest a complex mechanism of anion transport in the distal colon, with a component of electrogenic anion absorption inhibited by the stilbenes. The subsequent changes in current, conductance, and chloride fluxes are dependent upon additional, independent anion transport processes. These pharmacologic agents exhibit an antiabsorptive effect, rather than a stimulation of electrogenic chloride secretion.     

Thiocyanate inhibition of active chloride absorption in Aplysia intestine

This investigation was principally undertaken to examine the mechanism of active chloride absorption across the Aplysia californica intestine by using various inhibitors of ion transport. Isolated intestine, mounted between identical oxygenated sodium-free seawater solutions, maintained stable transmural potential differences (serosa negative) and short-circuit currents for several hours at 25 degrees C. The metabolic inhibitors, 2,4-dinitrophenol and fluoride, reduced both transmural potential difference and short-circuit current; however, the electrical characteristics were predominantly dependent upon glycolytic energy. The addition of thiocyanate to the mucosal solution inhibited both electrical characteristics in parallel, and this inhibition could be titrated according to the thiocyanate concentration. The short-circuit current was carried wholly by a net active chloride transfer from mucosa to serosa as determined by flux measurements. These results suggest that active chloride absorption may be mediated by a primary active transport process.     

Procaine effects on the sodium transport in frog skin

A study on the influence of procaine on the sodium transport properties in frog skin was carried out. The application of procaine hydrochloride on either the mucosal or the serosal sides of the isolated frog skin has opposite effects. When added to the mucosal compartment, the procaine (as well as two procaine based drugs: Gerovital H3 and Aslavital) biphasically increase the short-circuit current (Isc) with a noticeable "recline" phenomenon, and decrease the slope resistance, as given by the I-V curves. When applied in the serosal compartment, Isc is decreased and the slope resistance of the epithelium is increased. The procaine effect on the apical membranes shows a pronounced dependence on the external sodium concentration. The shift of the E2 inflection point (which indicates the critical intensity of the electric field at which the epithelial conductance changes), with respect to the transepithelial open-circuit potential, shows a rapid and quasi-exponential increase following the application of 25 mM procaine in addition to the different mucosal Na concentrations.