Development of Na+ transport in the chicken colon

To evaluate the developmental changes in colonic Na⁺ transport, Na, K-ATPase activity and the sensitivity of the short-circuit current to amiloride were investigated. The amiloride-sensitive short-circuit current which represents the electrogenic, amiloride-sensitive Na⁺ transport through Na⁺ channels, was not present in chicken embryos but rose significantly after hatching in chicks which were kept on a low-salt diet. Amiloride-sensitive short-circuit current increased gradually but the plateau was not reached during the first 15 days of life. Drinking of 0.9% NaCl totally inhibited the induction of amiloride-sensitive Na⁺ transport. Na⁺, K⁺-ATPase activity increased during development but was not influenced by changes in salt intake. Na⁺ transport in chicken colon therefore undergoes profound developmental changes. The increase of Na⁺ transport refleets not only the adaptation of colonocytes to low salt intake but also the maturation of Na⁺ absorption in colon. The possible role of aldosterone in the adaptation to low-salt intake is discussed.Abbreviations LS low-salt - HS high-salt - I _sc short-circuit current     

Regulation of Epithelial Na+ Permeability by Protein Kinase C is Tissue Specific

Protein kinase C (PKC) is a major regulator of a broad range of cellular functions. Activation of PKC has been reported to stimulate Na⁺ transport across frog skin epithelium by increasing the apical Na⁺ permeability. This positive natriferic response has not been observed with other epithelial preparations, and could reflect the specific experimental conditions of different laboratories, or species or organ specificity of the response to PKC. In the present study, measurements were conducted with skins and urinary bladders from the same animals of two different species. The PKC activator TPA uniformly increased the transepithelial Na⁺ transport (measured as amiloride-sensitive short-circuit current, I _SC, across skins from Rana temporaria and Bufo marinus, and inhibited I _SC across bladders from the same animals. Inhibitors of PKC (staurosporine, H-7 and chelerythrine) partially blocked the TPA-induced stimulation of I _SC across frog skin. The specificity of the PKC response by amphibian skin could have reflected an induction of moulting, similar to that observed with aldosterone. However, light micrographs of paired areas of frog skin revealed no evidence of the putative moulting. Separation of stratum corneum from the underlying stratum granulosum could be detected following application of aldosterone. We conclude that the effect of PKC on epithelial Na⁺ channels is organ, and not species specific. The stimulation of Na⁺ permeability in amphibian skin does not arise from sloughing of the stratum corneum. These observations are consistent with the hypothesis that the natriferic action arises from the calcium-independent isozyme of PKC previously detected in frog skin. Received: 19 January 1996/Revised: 10 April 1996     

Involvement of Protein Tyrosine Kinase in Osmoregulation of Na+ Transport and Membrane Capacitance in Renal A6 Cells

Renal A6 cells have been reported in which hyposmolality stimulates Na⁺ transport by increasing the number of conducting amiloride-sensitive 4-pS Na⁺ channels at the apical membrane. To study a possible role of protein tyrosine kinase (PTK) in the hyposmolality-induced signaling, we investigated effects of PTK inhibitors on the hyposmolality-induced Na⁺ transport in A6 cells. Tyrphostin A23 (a PTK inhibitor) blocked the stimulatory action of hyposmolality on a number of the conducting Na⁺ channels. Tyrphostin A23 also abolished macroscopic Na⁺ currents (amiloride-sensitive short-circuit current, I _Na ) by decreasing the elevating rate of the hyposmolality-increased I _Na . Genistein (another type of PTK inhibitor) also showed an effect similar to tyrphostin A23. Brefeldin A (BFA), which is an inhibitor of intracellular translocation of protein, blocked the action of hyposmolality on I _Na by diminishing the elevating rate of the hyposmolality-increased I _Na , mimicking the inhibitory action of PTK inhibitor. Further, hyposmolality increased the activity of PTK. These observations suggest that hyposmolality would stimulate Na⁺ transport by translocating the Na⁺ channel protein (or regulatory protein) to the apical membrane via a PTK-dependent pathway. Further, hyposmolality also caused an increase in the plasma (apical) membrane capacitance, which was remarkably blocked by treatment with tyrphostin A23 or BFA. These observations also suggest that a PTK-dependent pathway would be involved in the hyposmolality-stimulated membrane fusion in A6 cells. Received: 6 October 1999/Revised: 4 February 2000     

Sodium and potassium uptake in primary cultures of rat astroglial cells induced by long-term exposure to the basic astroglial growth factor (AGF2)

Astroglial cell cultures were derived from newborn rat forebrain and cultured for 5 days in serum containing-, and for an additional 4 days in a serum-free, defined medium. At the end of this 9-day-long period, basic astroglial growth factor (AGF2) was administered to the culture medium (10 ng per ml). Cells were subsequently cultured in AGF2 containing serum-free, defined medium for further two weeks. At definite intervals of culturing, unidirectional influx of both Na⁺ and K⁺ (I_Na and I_K, respectively) was determined by applying²²Na and⁴²K. The AGF2-treated cultures showed highly increased, amiloride-sensitive I_Na at the early exposure period (2–8 hours), similar to that we have reported about cultured astroglia exposed to AGF2 for minutes. They also exhibited significant furosemide-sensitive-, while relatively poor ouabain-sensitive component of I_Na. However, at later periods of exposure to AGF2, I_Na was significantly reduced, particularly due to the decrease of its amiloride-sensitive component, while its furosemide-sensitive component further increased with the time of AGF2 treatment. In contrast to I_Na, the I_K in the cultures exposed to AGF2 increased significantly in the course of the long-term exposure period, particularly the ouabain-, and furosemide-sensitive-components, while its amiloride-sensitive component, similarly to that of I_Na, decreased. Our findings show that the initial activation of the Na⁺/H⁺ (or K⁺/H⁺) exchange, what characterized the cation transport changes by short-term exposure of astroglial cells to AGF2 in our previous study, comes relatively soon to a cessation but activation of the Na⁺, K⁺-pump and the furosemide-sensitive Na⁺ and K⁺ influxes further increases. Thus, they suggest the possibility that furosemide-sensitive cation movements play a role, besides the Na⁺, K⁺-pump, in the control of glial cell differentiation.Cente de Neurochimie du CNRS.Special issue dedicated to Dr. Paola S. Timiras.     

Self-Inhibition in Amiloride-sensitive Sodium Channels in Taste Receptor Cells

Electrophysiological recording techniques were used to study the Na⁺ dependence of currents through amiloride-sensitive sodium channels (ASSCs) in rat taste cells from the fungiform and vallate papillae. Perforated patch voltage clamp recordings were made from isolated fungiform and vallate taste receptor cells (TRCs) and Na⁺ transport was measured across lingual epithelia containing fungiform or vallate taste buds in a modified Ussing chamber. In isolated fungiform TRCs that contain Na⁺ currents sensitive to the diuretic amiloride, Na⁺ ions inhibit their own influx through ASSCs, a process known as sodium self-inhibition. Due to the interaction between self-inhibition and the driving force for Na⁺ entry, self-inhibition is most evident in whole-cell recordings at Na⁺ concentrations from 50 to 75 mM. In amiloride-sensitive cells, the Na permeability is significantly higher in extracellular solutions containing 35 mM Na⁺ than in 70 or 140 mM Na⁺. Compared with the block by amiloride, the development of self-inhibition is slow, taking up to 15 s to become maximally inhibited. Approximately one third of fungiform TRCs and all vallate TRCs lack functional ASSCs. These amiloride-insensitive TRCs show no signs of self-inhibition, tying this phenomenon to the presence of ASSCs. The sulfhydryl reagent, p-hydroxymercuribenzoate (p-HMB; 200 μM), reversibly removed self-inhibition from amiloride-sensitive Na⁺ currents, apparently by modifying cysteine residues in the ASSC. Na⁺ currents in amiloride-insensitive TRCs were unaffected by p-HMB. In sodium transport studies in fungiform taste bud–containing lingual epithelia, ∼40% of the change in short-circuit current (I_sc) after addition of 500 mM NaCl to the mucosal chamber is amiloride sensitive (0.5 mM). p-HMB significantly enhanced mucosal NaCl-induced changes in these epithelia at mucosal Na⁺ concentrations of 50 mM and above. In contrast, the vallate-containing epithelia, which are insensitive to amiloride, showed no enhancement of I_sc during p-HMB treatment. These findings suggest that sodium self-inhibition is present in ASSCs in taste receptor cells where it may play a crucial role in performance of salt-sensitive pathways in taste tissue during sodium stimulation. This phenomenon may be important in the process of TRC adaptation, in the conservation of cellular resources during chronic sodium exposure, or in the gustatory response to water.     

Stimulation of Transepithelial Na<Superscript>+</Superscript> Current by Extracellular Gd<Superscript>3+</Superscript> in <Emphasis Type="Italic">Xenopus laevis</Emphasis> Alveolar Epithelium

In the present study we investigated the effect of extracellular gadolinium on amiloride-sensitive Na⁺ current across Xenopus alveolar epithelium by Ussing chamber experiments and studied its direct effect on epithelial Na⁺ channels with the patch-clamp method. As observed in various epithelia, the short-circuit current (I _sc) and the amiloride-sensitive Na⁺ current (I _ami) across Xenopus alveolar epithelium was downregulated by high apical Na⁺ concentrations. Apical application of gadolinium (Gd³⁺) increased I _sc in a dose-dependent manner (EC ₅₀ = 23.5 µM). The effect of Gd³⁺ was sensitive to amiloride, which indicated the amiloride-sensitive transcellular Na⁺ transport to be upregulated. Benz-imidazolyl-guanidin (BIG) and p-hydroxy-mercuribenzonic-acid (PHMB) probably release apical Na⁺ channels from Na⁺-dependent autoregulating mechanisms. BIG did not stimulate transepithelial Na⁺ currents across Xenopus lung epithelium but, interestingly, it prevented the stimulating effect of Gd³⁺ on transepithelial Na⁺ transport. PHMB increased I _sc and this stimulation was similar to the effect of Gd³⁺. Co-application of PHMB and Gd³⁺ had no additive effects on I _sc. In cell-attached patches on Xenopus oocytes extracellular Gd³⁺ increased the open probability (NP _o) of Xenopus epithelial sodium channels (ENaC) from 0.72 to 1.79 and decreased the single-channel conductance from 5.5 to 4.6 pS. Our data indicate that Xenopus alveolar epithelium exhibits Na⁺-dependent non-hormonal control of transepithelial Na⁺ transport and that the earth metal gadolinium interferes with these mechanisms. The patch-clamp experiments indicate that Gd³⁺ directly modulates the activity of ENaCs.     

Chloroquine Stimulates Cl? Secretion by Ca2+ Activated Cl? Channels in Rat Ileum

Chloroquine (CQ), a bitter tasting drug widely used in treatment of malaria, is associated gastrointestinal side effects including nausea or diarrhea. In the present study, we investigated the effect of CQ on electrolyte transport in rat ileum using the Ussing chamber technique. The results showed that CQ evoked an increase in short circuit current (I_SC) in rat ileum at lower concentration (≤5×10⁻⁴ M ) but induced a decrease at higher concentrations (≥10⁻³ M). These responses were not affected by tetrodotoxin (TTX). Other bitter compounds, such as denatoniumbenzoate and quinine, exhibited similar effects. CQ-evoked increase in I_SC was partly reduced by amiloride(10⁻⁴ M), a blocker of epithelial Na⁺ channels. Furosemide (10⁻⁴ M), an inhibitor of Na⁺-K⁺ -2Cl⁻ co-transporter, also inhibited the increased I_SC response to CQ, whereas another Cl⁻ channel inhibitor, CFTR(inh)-172(10⁻⁵M), had no effect. Intriguingly, CQ-evoked increases were almost completely abolished by niflumic acid (10⁻⁴M), a relatively specific Ca²⁺-activated Cl⁻ channel (CaCC) inhibitor. Furthermore, other CaCC inhibitors, such as DIDS and NPPB, also exhibited similar effects. CQ-induced increases in I_SC were also abolished by thapsigargin(10⁻⁶M), a Ca²⁺ pump inhibitor and in the absence of either Cl⁻ or Ca²⁺ from bathing solutions. Further studies demonstrated that T2R and CaCC-TMEM16A were colocalized in small intestinal epithelial cells and the T2R agonist CQ evoked an increase of intracelluar Ca²⁺ in small intestinal epithelial cells. Taken together, these results demonstrate that CQ induces Cl⁻ secretion in rat ileum through CaCC at low concentrations, suggesting a novel explanation for CQ-associated gastrointestinal side-effects during the treatment of malaria.     

Methyl mercury inhibits short-circuit current and Cl− influx across isolated epipodite of European lobster (Homarus gammarus)

The effect of methyl mercuric chloride (MeHg) on short-circuit current (I_SC) was studied in the isolated perfused epipodite preparation from the branchial chamber of European lobster (Homarus gammarus) acclimated to dilute seawater. When applied at the apical surface, 0.2, 1.0 and 3.0 μM MeHg depressed I_SC by a 26%, 81% and 98%, respectively. The half-maximal inhibitory concentration (IC₅₀) of apically applied MeHg was 0.6 μM. Basolaterally added MeHg (3.0 μM) had no effect on I_SC, whereas addition of the specific Na⁺,K⁺-ATPase inhibitor ouabain (1.5 mM) reduced I_SC by ～ 90%. Ouabain effects were reversible, and I_SC fully recovered upon removal of ouabain. The MeHg-induced block of I_SC was partially reversed by the reducing agent, 1,4-dithiothreitol, suggesting that the formation of S–Hg–S bridges is important in the inhibitory mechanism. A significant reduction of I_SC and conductance occurred when low Na⁺ and Cl^? salines were substituted. Furthermore, in the low Na⁺ saline, J^Cl_A → B fluxes were reduced by about 50%. In the highly conductive epipodite epithelium, coupling of Na⁺ and Cl^? fluxes was suggested. The effects of MeHg on I_SC in the lobster epipodite are attributed to inhibition of an apical Cl^? influx.     

Na,K-ATPase and the development of Na+ transport in rat distal colon

Summary Na, K-ATPase function was studied in order to evaluate the mechanism of increased colonic Na⁺ transport during early postnatal development. The maximum Na⁺-pumping activity that was represented by the equivalent short-circuit current after addition of nystatin (I _sc ^N ) did not change during postnatal life or after adrenalectomy performed in 16-day-old rats.I _sc ^N was entirely inhibited by ouabain; the inhibitory constant was 0.1mm in 10-day-old (young) and 0.4mm in 90-day-old (adult) rats. The affinity of the Na, K pump for Na⁺ was higher in young (11mm) than in adult animals (19mm). The Na, K-ATPase activity (measured after unmasking of latent activity by treatment with sodium dodecylsulfate) increased during development and was also not influenced by adrenalectomy of 16-day-old rats. The inhibitory constant for ouabain (K _I ) was not changed during development (0.1–0.3mm). Specific [³H]ouabain binding to isolated colonocytes increased during development (19 and 82 pmol/mg protein), the dissociation constant (K _D ) was 8 and 21 m in young and adult rats, respectively. The Na⁺ turnover rate per single Na, K pump, which was calculated fromI _sc ^N and estimated density of binding sites per cm² of tissue was 500 in adult and 6400 Na⁺/min·site in young rats. These data indicate that the very high Na⁺ transport during early postnatal life reflects an elevated turnover rate and increased affinity for Na⁺ of a single isoform of the Na, K pump. The development of Na⁺ extrusion across the basolateral membrane is not directly regulated by corticosteroids.     

Na+ channel activity in cultured renal (A6) epithelium: Regulation by solution osmolarity

Summary Solution osmolarity is known to affect Na⁺ transport rates across tight epithelia but this variable has been relatively ignored in studies of cultured renal epithelia. Using electrophysiological methods to study A6 epithelial monolayers, we observed a marked effect of solution tonicity on amiloride-sensitive Na⁺ currents (I _sc).I _sc for tissues bathed in symmetrical hyposmotic (170 mOsm), isosmotic (200 mOsm), and hyperosmotic (230 or 290 mOsm) NaCl Ringer's solutions averaged 25±2, 9±2, 3±0.4, and 0.6±0.5 A/cm², respectively. Similar results were obtained following changes in the serosal tonicity; mucosal changes did not significantly affectI _sc. The changes inI _sc were slow and reached steady-state within 30 min. Current fluctuation analysis measurements indicated that single-channel currents and Na⁺ channel blocker kinetics were similar for isosmotic and hyposmotic conditions. However, the number of conducting Na⁺ channels was approximately threefold higher for tissues bathed in hyposmotic solutions. No channel activity was detected during hyperosmotic conditions. The results suggest that Na⁺ channels in A6 epithelia are highly sensitive to relatively small changes in serosal solution tonicity. Consequently, osmotic effects may partly account for the large variability in Na⁺ transport rates for A6 epithelia reported in the literature.     

Kinetic properties of sodium transport pathways in the river lamprey <Emphasis Type="Italic">Lampetra fluviatilis</Emphasis> erythrocytes

To activate Na⁺/H⁺ exchange, intracellular pH (pH_i) of erythrocytes of the river lamprey Lampetra fluviatilis were changed from 6 and 8 using nigericin. The Na⁺/H⁺ exchanger activity was estimated from the values of amiloride-sensitive components of Na⁺ (²²Na) inflow or of H⁺ outflow from erythrocytes. Kinetic parameters of the carrier functioning were determined by using Hill equation. Dependence of Na⁺ and H⁺ transport on pH_i value is described by hyperbolic function with the Hill coefficient value (n) close to 1. Maximal rate of ion transport was within the limits of 9–10 mmol/l cells/min, and the H⁺ concentration producing the exchanger 50% activation amounted to 0.6–1.0 μM. Stimulation of H⁺ outcome from acidified erythrocytes (pH_i 5.9) with increase of H⁺ concentration in the incubation medium is described by Hill equation with n value of 1.6. Concentration Na⁺ for the semimaximal stimulation of H⁺ outcome amounted to 10 mM. The obtained results indicate the presence in lamprey erythrocytes of only binding site for H⁺ from the cytoplasm side and the presence of positive cooperativity in Na⁺-binding from the extracellular side of the Na⁺/H⁺ exchanger. Na⁺ efflux from cells in the Na⁺-free medium did not change at a 10-fold increase of H⁺ concentration in the incubation medium. The presented data indicate differences of kinetic properties of the lamprey erythrocyte Na⁺/H⁺ exchanger and of this carrier isoforms in mammalian cells. In intact erythrocytes the dependence of the amiloride-sensitive Na⁺ inflow on its concentration in the medium is described by Hill equitation with n 1.6. The Na⁺ concentration producing the 50% transport activation amounted to 39 mM and was essentially higher as compared with that in acidified erythrocytes. These data confirm conception of the presence of two amiloride-sensitive pathways of Na+ transport in lamprey erythrocytes.     

Sodium transport through the amiloride-sensitive Na-Mg pathway of hamster red cells

Previous work showed that in hamster red cells the amiloride-sensitive (AS) Na⁺ influx of 0.8 mmol/liter cells/hr is not mediated by Na-H exchange as in other red cells, but depends upon intracellular Mg²⁺ and can be increased by 40-fold by loading cells with Mg²⁺ to 10 mm. The purpose of this study was to verify the connection of AS Na⁺ influx with Na-dependent, amiloride-sensitive Mg²⁺ efflux and to utilize AS Na⁺ influx to explore that pathway.Determination of unidirectional influx of Na⁺ and net loss of Mg²⁺ in parallel sets of cells showed that activation by extracellular [Na⁺] follows a simple Michaelis-Menten relationship for both processes with a K _m of 105–107 mm and that activation of both processes is sigmoidally dependent upon cytoplasmic [Mg²⁺] with a [Mg²⁺]_0.5 of 2.1–2.3 mm and a Hill coefficient of 1.8. Comparison of V_max for both sets of experiments indicated a stoichiometry of 2 Na: l Mg. Amiloride inhibits Na⁺ influx and Mg²⁺ extrusion in parallel (K _i = 0.3 mm). Like Mg²⁺ extrusion, amiloride-sensitive Na⁺ influx shows an absolute requirement for cytoplasmic ATP and is increased by cell swelling. Hence, amiloride-sensitive Na⁺ influx in hamster red cells appears to be through the Na-Mg exchange pathway.There was no amiloride-sensitive Na⁺ efflux in hamster red cells loaded with Na⁺ and incubated with high [Mg²⁺] in the medium with or without external Na⁺, nor with ATP depletion. Hence, this is not a simple Na-Mg exchange carrier.     

l-Arginine Effects on Na+ Transport in M-1 Mouse Cortical Collecting Duct Cells—A Cationic Amino Acid Absorbing Epithelium

The effect of l-arginine on transepithelial ion transport was examined in cultured M-1 mouse renal cortical collecting duct (CCD) cells using continuous short circuit current (I _SC ) measurements in HCO₃ ⁻/CO₂ buffered solution. Steady state I _SC averaged 73.8 ± 3.2 μA/cm² (n= 126) and was reduced by 94 ± 0.6% (n= 16) by the apical addition of 100 μm amiloride. This confirms that the predominant electrogenic ion transport in M-1 cells is Na⁺ absorption via the epithelial sodium channel (ENaC). Experiments using the cationic amino acid l-lysine (radiolabeled) as a stable arginine analogue show that the combined activity of an apical system y⁺ and a basal amino acid transport system y⁺L are responsible for most cationic amino acid transport across M-1 cells. Together they generate net absorptive cationic amino acid flux. Application of l-arginine (10 mm) either apically or basolaterally induced a transient peak increase in I _SC averaging 36.6 ± 5.4 μA/cm² (n= 19) and 32.0 ± 7.2 μA/cm² (n= 8), respectively. The response was preserved in the absence of bath Cl⁻ (n= 4), but was abolished either in the absence of apical Na⁺ (n= 4) or by apical addition of 100 μm amiloride (n= 6). l-lysine, which cannot serve as a precursor of NO, caused a response similar to that of l-arginine (n= 4); neither L-NMMA (100 μm; n= 3) nor L-NAME (1 mm; n= 4) (both NO-synthase inhibitors) affected the I _SC response to l-arginine. The effects of arginine or lysine were replicated by alkalinization that mimicked the transient alkalinization of the bath solution upon addition of these amino acids. We conclude that in M-1 cells l-arginine stimulates Na⁺ absorption via a pH-dependent, but NO-independent mechanism. The observed net cationic amino acid absorption will counteract passive cationic amino acid leak into the CCD in the presence of electrogenic Na⁺ transport, consistent with reports of stimulated expression of Na⁺ and cationic amino acid transporters by aldosterone. Received: 11 September 2000/Revised: 6 December 2000     

Electrogenic cation transport across leech caecal epithelium

 Electrogenic cation transport across the caecal epithelium of the leech Hirudo medicinalis was investigated using modified Ussing chambers. Transepithelial resistance (R _T ) and potential difference (V _T ) were 61.0±3.5 Ω ⋅ cm² and −1.1±0.2 mV (n=149), respectively, indicating that leech caecal epithelium is a “leaky” epithelium. Under control conditions short circuit current (I _SC ) and transepithelial Na⁺ transport rate (I _Na ) averaged at 22.1±1.5 μA ⋅ cm^-2 and 49.7±2.6 μA ⋅ cm^-2, respectively. Mucosal application of amiloride (100 μmol ⋅ l^-1) or benzamil (50 μmol ⋅ l^-1) influenced neither I _SC nor I _Na . The transport system in the apical membrane showed no pronounced cation selectivity and a linear dependence on mucosal Na⁺ concentration. Removal of mucosal Ca²⁺ increased I _SC by about 50% due to an increase of transepithelial Na⁺ transport. Trivalent cations (La³⁺ and Tb³⁺, 1 mmol ⋅ l^-1 both) added to the mucosal Ringer solution reduced I _Na by more than 40%. Serosal ouabain (1 mmol ⋅ l^-1) almost halved I _SC and I _Na while 0.1% (=5.4 mmol ⋅ l^-1) DNP decreased I _Na to 11.8±5.1% of initial values. Serosal addition of cAMP increased both I _SC and I _Na whereas the neurotransmitters FMRFamide, acetylcholine, GABA, L-dopa, serotonin and dopamine failed to show any effects; octopamine, glycine and L-glutamate reduced I _Na markedly. On the basis of these results we conclude that in leech caecal epithelium apical uptake of monovalent cations is mediated by non-selective cation conductances which are sensitive to extracellular Ca²⁺ but insensitive to amiloride. Basolaterally Na⁺ is extruded via ouabain-sensitive and -insensitive ATPases. cAMP activates Na⁺ transport across leech caecal epithelium, although the physiological stimulus for cAMP-production remains unknown. Accepted: 20 May 1996     

Sodium transport in red blood cells of lamprey LAmpetra fluviatilis

• 1.1. Unidirectional Na⁺ influx in lamprey red blood cells was determined using ²²Na as a tracer.
• 2.2. Total Na⁺ uptake and amiloride-inhibitable Na⁺ influx increased in a saturable fashion as a function of external Na⁺ concentration (Na_e).
• 3.3. At 141 mM Na_e, the average value of net Na⁺ influx was 13 ± 1.1 and the amiloride-sensitive Na⁺ influx was 5.3±1.1 mmol/l cells per hr (±SE).
• 4.4. The amiloride-sensitive component of Na⁺ influx was significantly activated by 10⁻⁵ M isoproterenol, by 2 × 10⁻⁵ M DNP, and by cell shrinkage.
• 5.5. Furosemide (1 mM) had no effect on the Na⁺ transport in red cells.
• 6.6. The residual amiloride-insensitive component of Na⁺ transport was a linear function of Na_e in the range of 5–141 mM. This transport seems to be accounted for by simple diffusion.

     

The human non-gastric H,K-ATPase has a different cation specificity than the rat enzyme

The primary sequence of non-gastric H,K-ATPase differs much more between species than that of Na,K-ATPase or gastric H,K-ATPase. To investigate whether this causes species-dependent differences in enzymatic properties, we co-expressed the catalytic subunit of human non-gastric H,K-ATPase in Sf9 cells with the β₁ subunit of rat Na,K-ATPase and compared its properties with those of the rat enzyme (Swarts et al., J. Biol. Chem. 280, 33115-33122, 2005). Maximal ATPase activity was obtained with NH₄⁺ as activating cation. The enzyme was also stimulated by Na⁺, but in contrast to the rat enzyme, hardly by K⁺. SCH 28080 inhibited the NH₄⁺-stimulated activity of the human enzyme much more potently than that of the rat enzyme. The steady-state phosphorylation level of the human enzyme decreased with increasing pH, [K⁺], and [Na⁺] and nearly doubled in the presence of oligomycin. Oligomycin increased the sensitivity of the phosphorylated intermediate to ADP, demonstrating that it inhibited the conversion of E₁P to E₂P. All three cations stimulated the dephosphorylation rate dose-dependently. Our studies support a role of the human enzyme in H⁺/Na⁺ and/or H⁺/NH₄⁺ transport but not in Na⁺/K⁺ transport.     

Light-Induced Proton Gradient Formation in Intact Cells of Dunaliella salina

A light-induced proton gradient (ΔpH) increase as exhibited by an increase of 9-aminoacridine fluorescence quenching is demonstrated between the external medium and the interior of the halophytic green alga Dunaliella salina. The formation and maintenance of the ΔpH is sensitive to electron transport inhibitors and to uncouplers. It is inhibited by p-chloromercuribenzenesulfonic acid (50% inhibition at 3 micromolar), which does not affect photosynthetic O₂ evolution. It is concluded that the observed ΔpH is located across the plasmalemma or the chloroplast envelope. The formation and maintenance of the light-induced proton gradient requires the presence of Na⁺. Substitution of NaCl by KCl or glycerol results in inhibition of the ΔpH formation. The proton gradient is also sensitive to ATPase and energy transfer inhibitors. It is suggested that a Na⁺/H⁺ pump mechanism may be involved in the formation of the proton gradient in intact Dunaliella cells.     

Effects of anions on cellular volume and transepithelial Na+ transport across toad urinary bladder

Summary The effects of complete substitution of gluconate for mucosal and/or serosal medium Cl^– on transepithelial Na⁺ transport have been studied using toad urinary bladder. With mucosal gluconate, transepithelial potential difference (V _T) decreased rapidly, transepithelial resistance (R _T) increased, and calculated short-circuit current (I _sc) decreased. CalculatedE _Na was unaffected, indicating that the inhibition of Na⁺ transport was a consequence of a decreased apical membrane Na⁺ conductance. This conclusion was supported by the finding that a higher amiloride concentration was required to inhibit the residual transport. With serosal gluconateV _T decreased,R _T increased andI _sc fell to a new steady-state value following an initial and variable transient increase in transport. Epithelial cells were shrunken markedly as judged histologically. CalculatedE _Na fell substantially (from 130 to 68 mV on average). Ba²⁺ (3mm) reduced calculatedE _Na in Cl^– Ringer's but not in gluconate Ringer's. With replacement of serosal Cl^– by acetate, transepithelial transport was stimulated, the decrease in cellular volume was prevented andE _Na did not fall. Replacement of serosal isosmotic Cl^– medium by a hypo-osmotic gluconate medium (one-half normal) also prevented cell shrinkage and did not result in inhibition of Na⁺ transport. Thus the inhibition of Na⁺ transport can be correlated with changes in cell volume rather than with the change in Cl^– per se. Nystatin virtually abolished the resistance of the apical plasma membrane as judged by measurement of tissue capacitance. With K⁺ gluconate mucosa, Na⁺ gluconate serosa, calculated basolateral membrane resistance was much greater, estimated basolateral emf was much lower, and the Na⁺/K⁺ basolateral permeability ratio was much higher than with acetate media. It is concluded the decrease in cellular volume associated with substitution of serosal gluconate for Cl^– results in a loss of highly specific Ba²⁺-sensitive K⁺ conductance channels from the basolateral plasma membrane. It is possible that the number of Na⁺ pump sites in this membrane is also decreased.     

Ion transport across the skin of a larval salamander

The transport characteristics of the skin of neotenic Ambystoma tigrinum were investigated using ion substitution and circuit analysis. When bathed with sodium Ringer solution on both sides, a transepithelial potential of up to 50 mV (inside positive) and a short-circuit current (I_sc) of up to 10 μA/cm² were observed. When amiloride was added or Na⁺ was replaced by tetramethylammonium in the apical solution, I_sc was decreased from 3.7 ± 0.4 to 1.5 ± 0.2 μA/cm² (n = 10). When K⁺ replaced Na⁺, there was a smaller change in I_sc from 5.8 ± 0.6 to 3.7 ± 0.5 μA/cm² (n = 10). Although barium had no effect when added to 100 K Ringer on normal skin, it inhibited I_sc on skins taken from K⁺-loaded animals. Nystatin caused substantial increases in I_sc with either Na⁺ or K⁺ as the dominant cation in the apical solution. Current voltage analysis using amiloride was used to estimate the resistances and electromotive forces (EMF) associated with ion transport. The EMF for ion transport was partially dependent on K⁺ in the basolateral solution and it was similar to that observed in other epithelia. The resistance of the transport pathway was high, consistent with the low I_sc. These results suggest that there is an amiloride-sensitive Na⁺ channel in parallel with a small K⁺ conductance in the apical membrane of this preparation.     

Regulation of Cl− Secretion by Extracellular ATP in Cultured Mouse Endometrial Epithelium

The present study explored regulation of electrogenic ion transport across cultured mouse endometrial epithelium by extracellular ATP using the short-circuit current (I _SC ) and the patch-clamp techniques. The cultured endometrial monolayers responded to apical application of ATP with an increase in I _SC in a concentration-dependent manner (EC₅₀ at 3 μm). Replacement of Cl⁻ in the bathing solution or treatment of the cells with Cl⁻ channel blockers, DIDS and DPC, markedly reduced the I _SC , indicating that a substantial portion of the ATP-activated I _SC was Cl⁻-dependent. Amiloride at a concentration (10 μm) known to block Na⁺ channels was found to have no effect on the ATP-activated I _SC excluding the involvement of Na⁺ absorption. Adenosine was found to have little effect on the I _SC excluding the involvement of P₁ receptors. The effect of UTP, a potent P_2U receptor agonist on the I _SC was similar to that of ATP while potent P_2X agonist, α-β-Methylene adenosine 5′-triphosphate (α-β-M-ATP) and P_2Y agonist, 2-methylthio-adenosine triphosphate (2-M-ATP), were found to be ineffective. The effect of ATP on I _SC was mimicked by the Ca²⁺ ionophore, ionomycin, indicating a role of intracellular Ca²⁺ in mediating the ATP response. Confocal microscopic study also demonstrated a rise in intracellular Ca²⁺ upon stimulation by extracellular ATP. In voltage-clamped endometrial epithelial cells, ATP elicited a whole-cell Cl⁻ current which exhibited outward rectification and delayed activation and inactivation at depolarizing and hyperpolarizing voltages, respectively. The results of the present study demonstrate the presence of a regulatory mechanism involving extracellular ATP and P_2U purinoceptors for endometrial Cl⁻ secretion.