Na+-coupled Cl− transport in the gastric mucosa of the guinea pig

The Cl^–/HCO ₃ ^– exchange mechanism usually postulated to occur in gastric mucosa cannot account for the Na⁺-dependent electrogenic serosal to mucosal Cl^– transport often observed. It was recently suggested that an additional Cl^– transport mechanism driven by the Na⁺ electrochemical potential gradient may be present on the serosal side of the tissue. To verify this, we have studied Cl^– transport in guinea pig gastric mucosa. Inhibiting the (Na⁺, K⁺) ATPase either by serosal addition of ouabain or by establishing K⁺-free mucosal and serosal conditions abolished net Cl^– transport. Depolarizing the cell membrane potential with triphenylmethylphosphonium (a lipid-soluble cation), and hence reducing both the Na⁺ and Cl^– electrochemical potential gradients, resulted in inhibition of net Cl^– flux. Reduction of short-circuit current on replacing Na⁺ by choline in the serosal bathing solution was shown to be due to inhibition of Cl^– transport. Serosal addition of diisothiocyanodisulfonic acid stilbene (an inhibitor of anion transport systems) abolished net Cl^– flux but not net Na⁺ flux. These results are compatible with the proposed model of a Cl^–/Na⁺ cotransport mechanism governing serosal Cl^– entry into the secreting cells. We suggest that the same mechanism may well facilitate both coupled Cl^–/Na⁺ entry and coupled HCO ₃ ^– /Na⁺ exit on the serosal side of the tissue.     

Vasopressin alters the mechanism of apical Cl− entry from Na+:Cl− to Na+:K+:2Cl− cotransport in mouse medullary thick ascending limb

Summary Experiments were performed usingin vitro perfused medullary thick ascending limbs of Henle (MTAL) and in suspensions of MTAL tubules isolated from mouse kidney to evaluate the effects of arginine vasopressin (AVP) on the K⁺ dependence of the apical, furosemide-sensitive Na⁺:Cl^– cotransporter and on transport-related oxygen consumption (QO₂). In isolated perfused MTAL segments, the rate of cell swelling induced by removing K⁺ from, and adding onemm ouabain to, the basolateral solution [ouabain(zero-K⁺)] provided an index to apical cotransporter activity and was used to evaluated the ionic requirements of the apical cotransporter in the presence and absence of AVP. In the absence of AVP cotransporter activity required Na⁺ and Cl^–, but not K⁺, while in the presence of AVP the apical cotransporter required all three ions.⁸⁶Rb⁺ uptake into MTAL tubules in suspension was significant only after exposure of tubules to AVP. Moreover,²²Na⁺ uptake was unaffected by extracellular K⁺ in the absence of AVP while after AVP exposure²²Na⁺ uptake was strictly K⁺-dependent. The AVP-induced coupling of K⁺ to the Na⁺:Cl^– cotransporter resulted in a doubling in the rate of NaCl absorption without a parallel increase in the rate of cellular²²Na⁺ uptake or transport-related oxygen consumption. These results indicate that arginine vasopressin alters the mode of a loop diuretic-sensitive transporter from Na⁺:Cl^– cotransport to Na⁺:K⁺:2Cl^– cotransport in the mouse MTAL with the latter providing a distinct metabolic advantage for sodium transport. A model for AVP action on NaCl absorption by the MTAL is presented and the physiological significance of the coupling of K⁺ to the apical Na⁺:Cl^– cotransporter in the MTAL and of the enhanced metabolic efficiency are discussed.     

Studies on chloride permeability of the skin ofLeptodactylus ocellatus: II. Na+ and Cl− effect of inward movements of Cl−

Summary At low concentration (1mm) of Cl^– in the outer solution, the influx of chloride through the isolated skin (J ₁₃ ^Cl ) of the South American frogLeptodactylus ocellatus (L.) seems to be carried by two mechanisms: (i) a passive one that exhibits the characteristics of an exchange diffusion process, and (ii) an active penetration. Studies of the influx and efflux of chloride (J ₁₃ ^Cl andJ ₃₁ ^Cl ) indicate, that the presence of a high (107mm) concentration of Cl^– in the outer solution activates the translocation of this ion through the cells. Studies of the unidirectional flux of Cl^– across the outer barrier (J ₁₂ ^Cl ) indicate that Na⁺ out stimulates the penetration of Cl^– at this level. Cl^– out, in turn, stimulates, theJ ₁₂ ^Na , but this effect is only detected at low concentrations of Na⁺ out.     

Na+ and Cl− conductances are controlled by cytosolic Cl− concentration in the intralobular duct cells of mouse mandibular glands

Our previously published whole-cell patch-clamp studies on the cells of the intralobular (granular) ducts of the mandibular glands of male mice revealed the presence of an amiloride-sensitive Na⁺ conductance in the plasma membrane. In this study we demonstrate the presence also of a Cl^– conductance and we show that the sizes of both conductances vary with the Cl^– concentration of the fluid bathing the cytosolic surface of the plasma membrane. As the cytosolic Cl^– concentration rises from 5 to 150 mmol/liter, the size of the inward Na⁺ current declines, the decline being half-maximal when the Cl^– concentration is approximately 50 mmol/liter. In contrast, as cytosolic Cl^– concentration increases, the inward Cl^– current remains at a constant low level until the Cl^– concentration exceeds 80 mmol/liter, when it begins to increase. Studies in which Cl^– in the pipette solution was replaced by other anions indicate that the Na⁺ current is suppressed by intracellular Br^-, Cl^– and NO ₃ ^- but not by intracellular I^-, glutamate or gluconate. Our studies also show that the Cl^– conductance allows passage of Cl^– and Br^- equally well, I-less well, and NO ₃ ^- , glutamate and gluconate poorly, if at all. The findings with NO ₃ ^- are of particular interest because they show that suppression of the Na⁺ current by a high intracellular concentration of a particular anion does not depend on actual passage of that anion through the Cl^– conductance. In mouse granular duct cells there is, thus, a reciprocal regulation of Na⁺ and Cl^– conductances by the cytosolic Cl^– concentration. Since the cytosolic Cl^– concentration is closely correlated with cell volume in many epithelia, this reciprocal regulation of Na⁺ and Cl^– conductances may provide a mechanism by which ductal Na⁺ and Cl transport rates are adjusted so as to maintain a stable cell volume.This project was supported by the National Health and Medical Research Council of Australia. We thank Professor P. Barry (University of New South Wales) for assistance with the junction potential measurements.     

The nature of the neutral Na+−Cl−-coupled entry at the apical membrane of rabbit gallbladder epithelium: II. Na+−Cl− symport is independent of K+

Summary In the epithelium of rabbit gallbladder, in the nominal absence of bicarbonate, intracellular Cl^– activity is about 25mm, about 4 times higher than intracellular Cl^– activity at the electrochemical equilibrium. It is essentially not affected by 10^–4 m acetazolamide and 10^–4 m 4-acetamido-4-isothiocyanostilbene-2,2-disulfonate (SITS) even during prolonged exposures; it falls to the equilibrium value by removal of Na⁺ from the lumen without significant changes of the apical membrane potential difference. Both intracellular Cl^– and Na⁺ activities are decreased by luminal treatment with 25mm SCN^–; the initial rates of change are not significantly different. In addition, the initial rates of change of intracellular Cl^– activity are not significantly different upon Na⁺ or Cl^– entry block by the appropriate reduction of the concentration of either ion in the luminal solution. Luminal K⁺ removal or 10^–5 m bumetanide do not affect intracellular Cl^– and Na⁺ activities or Cl^– influx through the apical membrane. It is concluded that in the absence of bicarbonate NaCl entry is entirely due to a Na⁺–Cl^– symport on a single carrier which, at least under the conditions tested, does not cotransport K⁺.     

Apical Na+ permeability of frog skin during serosal Cl− replacement

Summary Gluconate substitution for serosal Cl^– reduces the transepithelial short-circuit current (I _sc) and depolarizes shortcircuited frog skins. These effects could result either from inhibition of basolateral K⁺ conductance, or from two actions to inhibit both apical Na⁺ permeability (P _Na ^ap ) and basolateral pump activity. We have addressed this question by studying whole-and split-thickness frog skins. Intracellular Na⁺ concentration (C _Na ^c ) andP _Na ^ap have been monitored by measuring the currentvoltage relationship for apical Na⁺ entry. This analysis was conducted by applying trains of voltage pulses, with pulse durations of 16 to 32 msec. Estimates ofP _Na ^ap ) and CNa/c were not detectably dependent on pulse duration over the range 16 to 80 msec. Serosal Cl^– replacement uniformly depolarized short-circuited tissues. The depolarization was associated with inhibition ofI _sc across each split skin, but only occasionally across the whole-thickness preparations. This difference may reflect the better ionic exchange between the bulk medium and the extracellular fluid in contact with the basolateral membranes, following removal of the underlying dermis in the split-skin preparations.P _Na ^ap was either unchanged or increased, and CNa/c either unchanged or reduced after the anionic replacement. These data are incompatible with the concept that serosal Cl^– replacement inhibitsP _Na ^ap and Na, K-pump activity. Gluconate substutition likely reduces cell volume, triggering inhibition of the basolateral K⁺ channels, consistent with the data and conclusions of S.A. Lewis, A.G. Butt, M.J. Bowler, J.P. Leader and A.D.C Macknight (J. Membrane Biol. 83:119–137, 1985) for toad bladder. The resulting depolarization reduces the electrical force favoring apical Na⁺ entry. The volume-conductance coupling serves to conserve volume by reducing K⁺ solute loss. Its molecular basis remains to be identified.     

Requirement of Cl− and Na+ for the ouabain-resistant control of cell volume in slices of rat liver

Summary The ability of liver cells to control their volume in the presence of ouabain has been studied in tissue slices that were recovering at 38°C from a period of swelling at 1°C. Morphological observations were made in conjunction with measurements of the net movements of water and ions. Extrusion of water in the presence of ouabain (2mm) was accompanied by a net loss of Na⁺ and Cl^– and by the formation of characteristic, rounded vesicles in the peri-canalicular regions of the hepatocytes; bile canaliculi were patent. When incubation was carried out in a medium in which either NO ₃ ^– or SO ₄ ^2– replaced Cl^–, ouabain-resistant water extrusion was prevented and the cytoplasmic vesicles normally found with ouabain were almost totally absent. When these slices were subsequently transferred to Cl^– medium with oubain, extrusion of intracellular water was initiated and cytoplasmic vesicles reappeared. Replacement of medium Na⁺ by Li⁺ mimicked the effects of ouabain on water and ion movements and ultrastructure. In addition, the ouabain-resistant extrusion of water and Cl^– was reduced and there was some diminution in the number of vesicles induced by ouabain. Furosemide (2mm) had little effect on water movement or ultrastructure in the absence of ouabain, but it slowed the net water loss and substantially reduced the formation of cytoplasmic vesicles in the presence of ouabain. The results show a close relationship between ouabain-resistant water extrusion and the formation of the cytoplasmic vesicles that are characteristic of treatment with ouabain. They further suggest that a cotransport of Na⁺ and Cl^– forms an important part of the mechanism underlying ouabain-resistant water extrusion and, specifically, that this cotransport may take place across the membranes of the cytoplasmic vesicles.     

The nature of the neutral Na+−Cl−-coupled entry at the apical membrane of rabbit gallbladder epithelium: I. Na+/H+, Cl−/HCO 3 − double exchange and Na+−Cl− symport

Summary Cl^– influx at the luminal border of the epithelium of rabbit gallbladder was measured by 45-sec exposures to³⁶Cl^– and³H-sucrose (as extracellular marker). Its paracellular component was evaluated by the use of 25mm SCN^– which immediately and completely inhibits Cl^– entry into the cell. Cellular influx was equal to 16.7eq cm^–2 hr^–1 and decreased to 8.5eq cm^–2 hr^–1 upon removal of HCO ₃ ^– from the bathing media and by bubbling 100% O₂ for 45 min. When HCO ₃ ^– was present, cellular influx was again about halved by the action of 10^–4 m acetazolamide, 10^–5 to 10^–4 m furosemide, 10^–5 to 10^–4 m 4-acetamido-4-isothiocyanostilbene-2,2-disulfonate (SITS), 10^–3 m amiloride. The effects of furosemide and SITS were tested at different concentrations of the inhibitor and with different exposure times: they were maximal at the concentrations reported above and nonadditive. In turn, the effects of amiloride and SITS were not additive. Acetazolamide reached its maximal action after an exposure of about 2 min. When exogenous HCO ₃ ^– was absent, the residual cellular influx was insensitive to acetazolamide, furosemide and SITS. When exogenous HCO ₃ ^– was present in the salines, Na⁺ removal from the mucosal side caused a slow decline of cellular Cl^– influx; conversely, it immediately abolished cellular Cl^– influx in the absence of HCO ₃ ^– . In conclusion, about 50% of cellular influx is sensitive to HCO ₃ ^– , inhibitable by SCN^–, acetazolamide, furosemide, SITS and amiloride and furthermore slowly dependent on Na⁺. The residual cellular influx is insensitive to bicarbonate, inhibitable by SCN^–, resistant to acetazolamide, furosemide, SITS and amiloride, and immediately dependent on Na⁺. Thus, about 50% of apical membrane NaCl influx appears to result from a Na⁺/H⁺ and Cl^–/HCO ₃ ^– exchange, whereas the residual influx seems to be due to Na⁺–Cl^– contranport on a single carrier. Whether both components are simultaneously present or the latter represents a cellular homeostatic counterreaction to the inhibition of the former is not clear.     

Role of F-actin in the activation of Na+-K+-Cl− cotransport by forskolin and vasopressin in mouse kidney cultured thick ascending limb cells

The influence of microtubules and F-actin on Na⁺-K⁺-Cl^? cotransport was investigated in cultured cells derived from outer-medullary thick ascending limb tubules microdissected from the mouse kidney. The cultured cells contained Tamm-Horsfall protein, produced cAMP in response to dD-arginine vasopressin (dD-AVP), isoproterenol, prostaglandin E2 and forskolin (FK), and exhibited an ouabain-resistant furosemidesensitive (Or-Fs) component of ⁸⁶Rb⁺ influx mediated by the Na⁺-K⁺-Cl^? cotransporter. Both FK and dD-AVP stimulated the Or-Fs component of Rb⁺ influx. Neither agent altered the tubulin and cytokeratin networks nor the shape of the tight junction using a specific anti-ZO-1 antibody. In contrast, they did induce a marked redistribution of F-actin to the periphery of the cells delineating the tight junctions. Preincubation of the cells with nocodazole, to disrupt microtubules, did not alter the FK-or dD-AVP-elicited Or-Fs Rb⁺ influx. In contrast, phalloidin and NBD-phallicidin, which stabilize F-actin, markedly impaired the stimulation of Na⁺-K⁺-Cl^? cotransport by FK or dD-AVP, without affecting the Na⁺-K⁺ ATPase pumps and the rate constant of ³⁶Cl^? and ⁸⁶Rb⁺ efflux. These results strongly suggested that cAMP-stimulated Na⁺-K⁺-Cl^? cotransport is linked to F-actin in renal TAL cells.     

Stoichiometry and ion affinities of the Na−K−Cl cotransport system in the intestine of the winter flounder (Pseudopleuronectes americanus)

Summary Na–K–Cl cotransport stoichiometry and affinities for Na, K and Cl were determined in flounder intestine. Measurement of simultaneous NaCl and RbCl influxes resulted in ratios of 2.2 for Cl/Na and 1.8 for Cl/Rb. The effect of Na and Rb on Rb influx showed first order kinetics withK _1/2 values of 5 and 4.5mm and Hill coefficients of 0.9 and 1.2, respectively. The effect of Cl on rubidium influx showed a sigmoidal relationship withK _1/2 of 20mm and a Hill coefficient of 2.0. The effects of variations in Na and Cl concentration on short-circuit current (I _sc) were also determined. TheK _1/2 for Na was 7mm with a Hill coefficient of 0.9 and theK _1/2 for Cl was 46mm with a Hill coefficient of 1.9. Based on the simultaneous influx measurements, a cotransport stoichiometry of 1Na1K2Cl is concluded. The Hill coefficients for Cl suggest a high degree of cooperativity between Cl binding sites. Measurements of the ratio of net Na and Cl transepithelial fluxes under short-circuit conditions (using a low Na Ringer solution to minimize the passive Na flux) indicate that the Cl/Na flux ratio is approximately 21. Therefore Na recycling from serosa to mucosa does not significantly contribute to theI _sc. Addition of serosal ouabain (100 m) inhibited Rb influx, indicating that Na–K–Cl cotransport is inhibited by ouabain. This finding suggests that a feedback mechanism exists between the Na–K-ATPase on the basolateral membrane and the apical Na–K–2Cl cotransporter.     

Elektronenmikroskopische Lokalisation von Na+ und Cl− in Zellen und Geweben

Ohne Zusammenfassung     

Intracellular compartmentation of Na+, K+ and Cl− in the Ehrlich ascites tumor cell: Correlation with the membrane potential

Summary The intracellular distribution of Na⁺, K⁺, Cl^– and water has been studied in the Ehrlich ascites tumor cell. Comparison of the ion and water contents of whole cells with those of cells exposed to La³⁺ and mechanical stress indicated that La³⁺ treatment results in selective damage to the cell membrane and permits evaluation of cytoplasmic and nuclear ion concentrations. The results show that Na⁺ is sequestered within the nucleus, while K⁺ and Cl^– are more highly concentrated in the cell cytoplasm. Reduction of the [Na⁺] of the incubation medium by replacement with K⁺ results in reduced cytoplasmic [Na⁺], increased [Cl^–] and no change in [K⁺]. Nuclear concentrations of these ions are virtually insensitive to the cation composition of the medium. Concomitant measurements of the membrane potential were made. The potential in control cells was –13.7 mV. Reduction of [Na⁺] in the medium caused significant depolarization. The measured potential is describable by the Cl^– equilibrium potential and can be accounted for in terms of cation distributions and permeabilities. The energetic implications of the intracellular compartmentation of ions are discussed.     

Intestinal HCO 3 − secretion inAmphiuma: Stimulation by mucosal Cl− and serosal Na+

Summary The requirement for Na⁺ and Cl^– in the bathing media to obtain a maximal HCO ₃ ^– secretory flux ( ) across isolated short-circuitedAmphiuma duodenum was investigated using titration techniques and ion substitution. Upon substitution of media Na⁺ with choline, HCO ₃ ^– secretion was markedly reduced. Replacement of media Cl^– produced a smaller reduction of . The presence of Cl^– enhanced HCO ₃ ^– secretion only if Na⁺ was also in the media. Elevation of media Na⁺ or Cl^– in the presence of the other ion produced a saturable increase of . In the presence of Na⁺, Cl^– stimulated when added to the mucosal but not the serosal medium. In the presence of Cl^–, Na⁺ elevated when added to the serosal but not the mucosal medium. The ability of mucosal Cl^– to stimulate was not apparently dependent on mucosal Na⁺. Simultaneous addition of 10mm Cl^– to the Na⁺-free mucosal medium and 10mm Na⁺ to the Cl^–-free serosal medium stimulated above levels produced by serosal Na⁺ alone. In conclusion, intestinal HCO ₃ ^– secretion required mucosal Cl^– and serosal Na⁺ and did not involve mucosal NaCl cotransport. The results are consistent with a mucosal Cl^– absorptive mechanism in series with parallel basolateral Na⁺–H⁺ and Cl^––HCO ₃ ^– exchange mechanisms.     

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.     

PIKfyve-dependent regulation of the Cl− channel ClC-2

The widely expressed chloride channel ClC-2 is stimulated by the serum and glucocorticoid inducible kinase SGK1. The SGK1-dependent regulation of several carriers involves the mammalian phosphatidylinositol-3-phosphate-5-kinase PIKfyve (PIP5K3). The present experiments explored whether SGK1-dependent regulation of ClC-2 similarly involves PIKfyve. The conductance of Xenopus oocytes is increased more than eightfold by ClC-2 expression. In ClC-2-expressing oocytes, but not in water-injected oocytes, the current was further enhanced by coexpression of either, PIKfyve or constitutively active ^S422DSGK1. Coexpression of the inactive SGK1 mutant ^K127NSGK1 did not significantly alter the current in ClC-2-expressing oocytes and abrogated the stimulation of the current by PIKfyve-coexpression. The stimulating effect of PIKfyve was abolished by replacement of the serine with alanine in the SGK1 consensus sequence (^S318APIKfyve). Coexpression of ^S318APIKfyve significantly blunted the stimulating effect of ^S422DSGK1 on ClC-2-activity. In conclusion, PIKfyve is a potent stimulator of ClC-2-activity and contributes to SGK1-dependent regulation of ClC-2.     

Studies on chloride permeability of the skin ofLeptodactylus ocellatus: III. Na+ and Cl− effect on electrical phenomena

Summary During their flux through the skin of the frogLeptodactylus ocellatus, Na⁺ and Cl^– interact with each other. This interaction gives rise to electrical phenomena which are studied in the present paper. The skin is mounted in Na₂SO₄ Ringer's with 115 mM Na⁺ on the inside, and a variety of outer solutions,. The osmolarity of all solutions is kept constant at 237.8 mosmol by adding sucrose. When the main anion used on the outside is SO ₄ ⁼ the electrical potential difference () rises steadily with the concentration of sodium (Na⁺)_o up to 87 mV, which is reached at about 20mm. Thereafter remains constant. When the main anion is Cl^– it is observed that rises steadily with (NaCl)_o with a slope similar to the curve obtained with SO ₄ ⁼ (37 mV per decade), but with a lower intercept attributed to an inward Cl pumping which is characteristic of this frog species. At 2–9 mM (NaCl)_o a Cl-specific channel is activated. Further increases of (NaCl)_o produce a decrease of . The specificity of the activation of this site by monovalent cations and its use by monovalent anions is also studied.