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.     

Passive sodium movements across the opercular epithelium: The paracellular shunt pathway and ionic conductance

Summary The unidirectional Na⁺, Cl^–, and urea fluxes across isolated opercular epithelia from seawater-adaptedFundulus heteroclitus were measured under different experimental conditions. The mean Na⁺, Cl^–, and urea permeabilities were 9.30×10^–6 cm·sec^–1, 1.24×10^–6 cm·sec^–1, and 5.05×10^–7 cm·sec^–1, respectively. The responses of the unidirectional Na⁺ fluxes and the Cl^– influx (mucosa to serosa) to voltage clamping were characteristic of passively moving ions traversing only one rate-limiting barrier. The Na⁺ conductance varied linearly with, and comprised a mean 54% of, the total tissue ionic conductance. The Cl^– influx and the urea fluxes were independent of the tissue conductance. Triaminopyrimidine (TAP) reduced the Na⁺ fluxes and tissue conductance over 70%, while having no effect on the Cl^– influx or urea fluxes. Mucosal Na⁺ substitution reduced the Na⁺ permeability 60% and the tissue conductance 76%, but had no effect on the Cl^– influx or the urea fluxes. Both the Na⁺ and Cl^– influxes were unaffected by respective serosal substitutions, indicating the lack of any Na⁺/Na⁺ and Cl^–/Cl^– exchange diffusion.The results suggest that the unidirectional Na⁺ fluxes are simple passive fluxes proceeding extracellularly (i.e., movement through a cation-selective paracellular shunt). This pathway is dependent on mucosal (external) Na⁺, independent of serosal (internal) Na⁺, and may be distinct from the transepithelial Cl^– and urea pathways.     

The Nature of the In Vivo Sodium and Chloride Uptake Mechanisms through the Epithelium of the Chilean Frog Calyptocephalella gayi (Dum. et Bibr., 1841) : Exchanges of hydrogen against sodium and of bicarbonate against chloride

The Chilean frog, Calyptocephallela gayi, placed in dilute NaCl solutions may pump Na⁺ and Cl^- at very different rates depending on the kind of bath solutions in which it was preadapted. Furthermore, Na⁺ and Cl^- may be absorbed from solutions in which the accompanying coion, such as sulfate and choline, respectively, is impermeant. In all these cases it is obligatory to postulate the existence of two ionic exchange mechanisms, Cl^- and Na⁺, being exchanged against endogenous anions and cations, respectively. It has been determined that Na⁺ is exchanged against endogenous H⁺ and that Cl^- is exchanged against HCO₃^-. In animals pumping Na⁺ and Cl^- from dilute NaCl solutions Na⁺ or Cl^- uptake may be selectively inhibited, while the flux of the accompanying ion remains unchanged. This is considered to be an additional proof that both Na⁺ and Cl^- fluxes are always independent. The role of the ionic exchange mechanisms in the direct regulation of the Na⁺ and Cl^- levels in the internal medium is discussed as well as their relationship in the regulation of the acid-base equilibrium; other physioecological considerations have been treated.     

Characterization of esophageal desalination in the seawater eel,Anguilla japonica

To characterize mechanisms of esophageal desalination, osmotic water permeability and ion fluxes were measured in the isolated esophagus of the seawater eel. The osmotic permeability coefficient in the seawater eel esophagus was 2·10^-4 cm·s^-1. This value was much lower than those in tight epithelial, although the eel esophagus is a leaky epithelium with a tissue resistance of 77 ohm·cm^-2. When the esophagus was bathed in normal Ringer solutions on both sides no net ion and water fluxes were observed. However, when mucosal NaCl concentration was increased by a factor of 3, Na⁺ und Cl^- ions were transferred from mucosa to serosa (desalination). If only Na⁺ or Cl^- concentration in the mucosal fluid was increased by a factor of 3, net Na⁺ and Cl^- fluxes were reduced to 30–40%, indicating that 60–70% of the net Na⁺ and Cl^- fluxes are coupled mutually. The coupled NaCl transport seems to be effective in desalting the luminal high NaCl. The remaining 30–40% of the total Na⁺ and Cl^- fluxes seems to be due to a simple diffusion, because these components are independent of each other and follow their electrochemical gradients, and also because these fluxes remain even after treatment with NaCN or ouabain. A half of the coupled NaCl transport could be explained by a Na⁺/H⁺–Cl^-/HCO ₃ ^- double exchanger on the apical membrane of the esophageal epithelium, because mucosal amiloride and 4.4-diisothiocyanatostilbene-2,2-disulphonic acid inhibited the net Na⁺ and Cl^- fluxes by approximately 30%. The other half of the coupled NaCl transport, which follows their electrochemical gradients, still remains to be explained.Abbreviations DIDS 4,4-diisothiocyanatostilbene-2,2-disulphonic acid - NMDG N-methyl-d-glucosamine - P _Cl Cl^- permeability coefficient - PD transepithelial potential difference - P _Na Na⁺ permeability coefficient - P _osm osinotic permeability coefficient - TALH thick ascending limb of Henle's loop     

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     

Microbodies and glyoxylate-cycle enzyme activities in filamentous fungi

Summary From compartmental analysis of radioisotope elution measurements, concentrations and fluxes of K⁺, Na⁺ and Cl^- were estimated for cortical cells in root segments of onion, Allium cepa L., relative to a complete nutrient solution. The transported fraction of the total efflux was estimated separately. With the Ussing-Teorell flux ratio equation as the criterion, it was concluded that all three ions were actively accumulated from the outside medium into the cytoplasm and that only Na⁺ was actively accumulated into the vacuole. K⁺ and Cl^- moved passively, in both directions across the tonoplast. Failure to account for leakage from the stele via the segment cut ends resulted in an over-estimate of exchange across the tonoplast but did not alter the conclusions qualitatively. The consequences of changing the assumed value of the tonoplast electrical potential (from 0 to+10- mV), and the effects of different experimental procedures, were also assessed, and found not to affect the main conclusions significantly. Separate measurement of ions leaking from the segment ends revealed that Na⁺ was transported almost exclusively in an acropetal direction in the stele. Cl^- appeared at both ends of the segments in similar amounts and K⁺ was transported mainly in the basipetal direction. The implications of these findings for the mechanism and site of ion selectivity are discussed.     

The effect of ethanol on ion transport in frog skin

Frog skin has been used as a model epithelial sodium-transporting system to study the effect of ethanol on ion transport. Treatment of the outside of frog skin with ethanol decreased the net sodium transport due to inhibition of ²²Na⁺ influx. Ethanol did not alter sodium outflux when bathing the outside of the skin. The inhibition was in proportion to the concentration of ethanol, 0.25 M resulting in 50% inhibition. The chloride permeability of the skin was increased several-fold when the skin was exposed to ethanol in either bathing solution. With 0.4 M ethanol in the inner bathing solution, all the unidirectional fluxes of Na⁺ and Cl^? were increased. The movement of Cl^? was evaluated by comparison of Cl^? flux with urea flux, since urea is thought to move passively across frog skin via an extracellular (shunt) pathway. Chloride flux was increased to a greater extent than urea flux. These experiments indicate that ethanol affects chloride permeability beyond an increase in extracellular ion flow and independent of its effect on Na⁺ transport.     

Short circuit current in tight and leaky epithelia

The effect of short circuit current on the unidirectional fluxes of ions transported across tight and leaky epithelia was investigated. It was found that short circuiting of the frog gastric mucosa (classified as a tight epithelium) caused a decrease of the passive J_ms^C1 and a significant increase of the net Cl^? secretion. However, no significant change of H⁺ secretory rate was observed. On the other hand, short circuiting of the mouse intestine (a known leaky membrane) caused a simultaneous increase of both J_ms and J_sm fluxes of Na⁺ while the net fluxes of Na⁺ and Cl^? remained unchanged. Also, short circuiting did not change the water permeability of the mouse intestine. To explain some of these results a theoretical model is presented to demonstrate that while short circuiting can block the passive ionic movement, it will cause an increase in the energy consumption of the system and introduce certain important changes in the ionic barriers and e.m.fs. The simultaneous increase in the unidirectional fluxes of Na⁺ under short circuit conditions can best be explained by a decrease in the polarized nature of the transepithelial shunt, thereby increasing the diffusion coefficient of the ion(s). Such an increase is specially favorable to the Na⁺ rather than an anion.     

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.     

Relationship between coupled Na+−K+−Cl− transport and water absorption across the seawater eel intestine

Summary Simultaneous measurements of net ion and water fluxes were made in the stripped intestine of the seawater eel, and the relationship between Na⁺, K⁺, Cl^– and water transport were examined in the presence of mucosal KCl and serosal NaCl Ringer (standard condition). When Cl^– was removed from both sides of the intestine, net K⁺ flux from mucosa to serosa was reduced, accompanied by complete blockage of water absorption. Since it has been shown that net Cl^– and water fluxes depend on K⁺ transport under the standard condition (Ando 1983), the interdependence of K⁺ and Cl^– transport suggests the existence of a coupled KCl transport system, while the parallelism between the net Cl^– and water fluxes suggests that water absorption is linked to the coupled KCl transport. The coupled KCl and water transport were inhibited by treatment with ouabain or with Na⁺-free Ringer solutions, suggesting the existence of a Na⁺-dependent KCl transport system and linkage of water absorption to the coupled Na⁺–K⁺–Cl^– transport. Since ouabain blocked the active Na⁺–K⁺–Cl^– transport almost completely, the permeability coefficients for K⁺ and Na⁺ through the paracellular shunt pathway were estimated as P_K=0.076 and P_Na=0.058 cm/h, and P_Cl was calculated as 0.005 cm/h. Although Na⁺-independent K⁺ and Cl^tt- fluxes were observed again in the present study, these fluxes were not inhibited by CN^–, ouabain or diuretics, and evoked even after blocking the Na⁺–K⁺–Cl^– transport completely with ouabain. These results indicate that the Na⁺-independent K⁺ and Cl^– fluxes are distinct from the active Na⁺–K⁺–Cl^– transport and are not themselves active.     

Calculations of K+, Na+, and Cl? fluxes across cell membrane with Na+/K+ pump, NKCC, NC cotransport and ionic channels with non-Goldman rectification in K+-channels: Normal and apoptotic cells

The balance of K⁺, Na⁺, and Cl⁻ fluxes across the cell membrane with the Na⁺/K⁺ pump, ion channels, and Na⁺K⁺2Cl⁻ (NKCC) and Na⁺-Cl⁻ (NC) cotransport was calculated to determine the mechanism of cell shrinkage in apoptosis. It is shown that all unidirectional K⁺, Na⁺, and Cl⁻ fluxes; the ion channel permeability; and the membrane potential can be found using the principle of the flux balance if the following experimental data are known: K⁺, Na⁺, and Cl⁻ concentrations in cell water; total Cl⁻ flux; total K⁺ influx; and the ouabain-inhibited pump component of the Rb⁺(K⁺) influx. The change in different ionic pathways during apoptosis was estimated by calculations based on the data reported in the preceded paper (Yurinskaya et al., 2010). It is found that cell shrinkage and the shift in ion balance in U937 cells induced to apoptosis with 1 μM staurosporine occur due to the coupling of reduced pump activity with a decrease in the integral permeability of Na⁺ channels, whereas K⁺ and Cl⁻ channel permeability remains almost unchanged. Calculations show that only a small part of the total fluxes of K⁺, Na⁺, and Cl⁻ account for the fluxes mediated by NKCC and NC cotransporters. Despite the importance of cotransport fluxes for maintaining the nonequilibrium steady-state distribution of Cl⁻, they cannot play a significant role in apoptotic cell shrinkage because of their minority and cannot be revealed by inhibitors.     

Effects of cholera toxin on cellular and paracellular sodium fluxes in rabbit ileum

The diarrhea observed in patients which cholera is known to be related to secretion of water and electrolytes into the intestinal lumen. However, the exact mechanisms involved in these secretory processes have remained unclear. Although it is clear that purified toxin acts on epithelial cell metabolism, its activity on Na⁺ transport across intestinal mucosa is equivocal: reported either to prevent net Na⁺ absorption or to cause net secretion of Na⁺ from serosa to mucosa. Since total transmural Na⁺ fluxes across “leaky” epithelia involve very significant movement via a paracellular shunt pathway, we studied the effects of cholera toxin on the cellular and paracellular pathways of Na⁺ movement. Unidirectional Na⁺ fluxes were examined as functions of applied potential in control tissues and in tissues from the same animal treated with purified cholera toxin. Treatment of rabbit ileum in vitro with toxin stimulated the cellular component of serosa-to-mucosa Na⁺ flux (from $\text{2.41 ± 0.49 μ}\text{equiv./h}$ per cm² under control conditions to $\text{4.71 ± 0.43 μ}\text{equiv./h}$ per cm² after treatment with toxin, $\text{P < 0.01}$). The effect of cholera toxin on Na⁺ movement through the cells from mucosa to serosa appeared to be insignificant. Finally, a marked decrease in the Na⁺ permeability ($\text{P < 0.01}$) and no detectable significant changes in transference number for Na⁺ of the paracellular shunt pathway were observed following treatment with cholera toxin. These results provide direct evidence for the hypothesis that purified cholera toxin stimulates active sodium secretion but has minimal effect on sodium absorption.     

Fluxes and compartmentation of potassium and chloride in the green alga Mougeotia

Summary Some ionic relations of the filamentous green alga Mougeotia sp. have been analyzed under different light conditions. Data from influx and efflux measurements using ⁸⁶Rb⁺ and ³⁶Cl^- fit the model of three cellular compartments (cell wall, cytoplasm, vacuole) in series. This result is remarkable, since in a Mougeotia cell at least two thirds of the cytoplasmic compartment are occupied by the cell-filling, flat and nearly rectangular chloroplast which is axially oriented. The chloroplast is concluded to be part of the cytoplasmic flux compartment.Photosynthetically saturating irradiances of continuous white light enhance the active and passive fluxes of K⁺ and Cl^- at the plasmalemma by a factor of 3. Photosystem II is responsible for the light-dependent increase of the uptake of Cl^- (³⁶Cl^-) whereas the uptake of K⁺ (⁸⁶Rb⁺) depends additionally on energy from photosystem I.Ion flux measurements performed after irradiations with red and far-red, respectively, show that the fluxes of K⁺ and Cl^- across the plasmalemma are not affected by the state of phytochrome.     

Two-substrate kinetic analysis: a novel approach linking ion and acid-base transport at the gills of freshwater trout,Oncorhynchus mykiss

Summary The novel application of a two-substrate model (Florini and Vestling 1957) from enzymology to transport kinetics at the gills of freshwater trout indicated that Na⁺/acidic equivalent and Cl^-/basic equivalent flux rates are normally limited by the availability of the internal acidic and basic counterions, as well as by external Na⁺ and Cl^- levels. Adult rainbow trout fitted with dorsal aortic and bladder catheters were chronically infused (10–16 h) with isosmotic HCl to induce a persistent metabolic acidosis. Acid-base neutral infusions of isosmotic NaCl and non-infused controls were also performed. Results were compared to previous data on metabolic alkalosis in trout induced by either isosmotic NaHCO₃ infusion or recovery from environmental hyperoxia (Goss and Wood 1990a, b). Metabolic acidosis resulted in a marked stimulation of Na⁺ influx, no change in Cl^- influx, positive Na⁺ balance, negative Cl^- balance, and net H⁺ excretion at the gills. Metabolic alkalosis caused a marked inhibition of Na⁺ influx and stimulation of Cl^- influx, negative Na⁺ balance, positive Cl^- balance, and net H⁺ uptake (=base excretion). Mean gill intracellular pH qualitatively followed extracellular pH. Classical one-substrate Michaelis-Menten analysis of kinetic data indicated that changes in Na⁺ and Cl^- transport during acid-base disturbance are achieved by large increases and decreases in J_max, and by increases in K_m. However, one-substrate analysis considers only external substrate concentration and cannot account for transport limitations by the internal substrate. The kinetic data were fitted successfully to a two-substrate model, using extracellular acid-base data as a measure of internal HCO ₃ ^- and H⁺ availability. This analysis indicated that true J_max values for Na⁺/acidic equivalent and Cl^-/basic equivalent transport are 4–5 times higher than apparent J_max values by one-substrate analysis. Flux rates are limited by the availability of the internal counterions; transport K_m values for HCO ₃ ^- and H⁺ are far above their normal internal concentrations. Therefore, small changes in acid-base status will have large effects on transport rates, and on apparent J_max values, without alterations in the number of transport sites. This system provides an automatic, negative feedback control for clearance or retention of acidic/basic equivalents when acid-base status is changing.Abbreviations Amm total ammonia in water - DMO 55-dimethyl-24-oxyzolidine-dione - J_in unidirectional inward ion movement across the gill - J_out unidirectional outward ion movement across the gill - J_net net transfer of ions (sum of J_in and J_out) across the gill - J_max maximal transport rate for ion - K_m inverse of affinity of transporter for ion - PIO₂ partial pressure of oxygen in inspired water - P_aCO₂ partial pressure of carbon dixide in arterial blood - TAlk titratable alkalinity of the water - PEG polyethylene glycol - NEN New England Nuclear     

Evidence for a simple Cl conductance pathway in nutrient membrane of frog stomach

A decrease in nutrient Cl⁻ results in an increased negativity of the nutrient relative to the secretory side. The possibility emerged that Cl⁻ transport could be attributed to a neutral mechanism involving Cl⁻ in the nutrient membrane coupled to a simple Cl⁻ conductance pathway in the secretory membrane. The decrease in PD (potential difference) with a decrease in nutrient Cl⁻ could arise from a decrease in cellular Cl⁻ so that the ratio of Cl⁻ in cell to Cl⁻ in secretory solution was decreased. Experiments were designed to determine whether there was a need to assume a simple Cl⁻ conductance pathway. A 10-fold decrease in Cl⁻ gave in HCO₃⁻-containing nutrient solutions a PD decrease of 20 mV, in HCO₃⁻-free nutrient solutions, a PD decrease of 13.5 mV, and in HCO₃⁻-free and Na⁺-free solutions, a PD decrease of 6.7 mV. The decrease of 6.7 mV could not be attributed to a neutral Cl⁻HCO₃⁻ exchanger or a NaCl symport. Also there was no evidence for a KCl symport from changes in Cl⁻ in presence and absence of K⁺. It followed that the decrease of 6.7 mV provided evidence for a simple Cl⁻ conductance pathway in the nutrient membrane.     

Antiabsorptive effects of 16, 16 dimethyl prostaglandin E2 and isolated rat colon

Ulcerative colitis is distinguished by abundant prostaglandin E₂ (PGE₂) in the stools and by severe diarrhea. To determine whether luminal PGE₂ alters normal colonic absorption, Na⁺ and Cl⁻transport across isolated rat proximal colon were studied before and after 16, 16 dimethyl PGE₂ (dmPGE₂) addition to flux chambers. Luminal administration of dmPGE₂ significantly reduced the net mucosal to serosal fluxes of Na⁺ and Cl⁻. These antiabsorptive tive effects of dmPGE₂ on Na⁺ and Cl⁻ active transport were reflected by a reduced metabolic rate of colonic tissue slices incubated with dmPGE₂. Addition of dmPGE₂ significantly reduced oxidation of glucose by the colon. Structurally, dmPGE₂ reduced the length of colonic mucosal microvilli, thereby decreasing absorptive surface area. These results suggest that PGE₂ released into the colonic lumen of patients with ulcerative colitis exerts antiabsorptive effects on the colon and in this way contributes to the associated diarrhea.     

Prostaglandin E2 enhances the sodium conductance of exocrine glands in isolated frog skin (Rana esculenta)

Summary Prostaglandins are known to stimulate the active transepithelial Na⁺ uptake and the active secretion of Cl^– from the glands of isolated frog skin. In the present work the effect of prostaglandin E₂ (PGE₂) on the glandular Na⁺ conductance was examined. In order to avoid interference from the Na⁺ uptake and the glandular Cl^– secretion the experiments were carried out on skins where the Cl^– secretion was inhibited (the skins were bathed in Cl^– Ringer's solution in the presence of furosemide, or in NO ₃ ^– Ringer's solution), and the active Na⁺ uptake was blocked by the addition of amiloride. Transepithelial current, water flow and ion fluxes were measured. A negative current was passed across the skins (the skins were clamped at –100 mV, basolateral solution was taken as reference). When PGE₂, was added to the skins under these experimental conditions, the current became more negative; this was mainly due to an increase in the Na⁺ efflux. Together with the increase in Na⁺ efflux a significant increase of the water secretion was observed. The water secretion was coupled to the efflux of Na⁺, and when one Na⁺ was pulled from the basolateral to the apical solution via this pathway 230 molecules of water follwed. From the data presented it is suggested that this pathway for Na⁺ is confined to the exocrine glands.     

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.     

Ouabain switches Na+ transport to Na+/Na+ equivalent exchange in normal and apoptotic lymphoid cells

A theory of change of the ionic fluxes in the lymphoid cells in their transition from normal to apoptosis we have developed previously is applied to the analysis of Na⁺/Na⁺ exchange fluxes in human lymphoid cells U937 exposed to ouabain. We solve a system of equations describing changes in the intracellular concentrations of Na⁺, K⁺ and Cl^?, membrane potential and cell volume. It is shown that the Na⁺ influx (I _Na/Na) and output flux through the Na⁺/Na⁺ tract increased 4 times in 8 h after disconnecting Na⁺/K⁺-ATPase for normal cell U937. These fluxes increased 2.6 times for apoptotic cells. The value of I _Na/Na after 8 h off pump by ouabain is 97% of the total Na⁺ input for both cell types. It is concluded that ouabain not only inhibits the Na⁺/K⁺-ATPase, but also increases Na⁺ exchange fluxes through the Na⁺/Na⁺ tract, thereby switching sodium transport across the membrane of lymphoid cells to Na⁺/Na⁺ equivalent exchange.