Phosphate transport in Ehrlich ascites tumor cells: inhibition by H+

The effect of changes in extracellular pH (pHo) and intracellular pH (pHi) on Na+-dependent and Na+-independent inorganic phosphate (Pi) transport in Ehrlich cells was investigated. In the presence of Na+, acutely reducing pHo from 7.30 to 5.50 results first in a transient (approximately 7 min) stimulation of Pi transport. The enhanced rate of transport is a saturable function of the extracellular [H+]; the Ks equals 2.3 X 10(-6) M (pHo 6.68). However, Pi transport is progressively inhibited as pHi falls below 6.50. The effect of pHi on Pi transport measured at various intracellular [Na+] suggests that inhibition develops as a consequence of H+ interaction with an intracellular Na+ site(s) on the Na+-dependent carrier. At pHo 7.4, about 15% of the steady state Pi flux persists in the absence of Na+. However, when pHo is reduced, transport is stimulated to the same extent and with the same time course and kinetic characteristics as in the presence of Na+. Thus, H+ stimulated Pi transport does not require Na+, raising the possibility that the Na+-independent component is mediated by the anion (Cl-) exchanger.     

Evidence for monovalent phosphate transport in Ehrlich ascites tumor cells

In an effort to determine whether the Na+-dependent Pi transport system of Ehrlich ascites tumor cells exhibits specificity for H2PO4- or HPO4(-2), Pi fluxes were determined by measuring 32Pi-Pi self-exchange. Three experimental approaches were employed. First, the effect of pH on steady-state Pi transport at 0.5 and 5 mM was studied. Second, the relationship between Pi transport and Pi concentration (0.25-9.2 mM) at pH 5.6 and 7.9 was determined. Third, the dependence of Pi transport on [H2PO4-] (0.05-4.2 mM) at constant [HPO4(-2)] (0.5 mM), and the converse, [HPO4(-2)] (0.06-4.5 mM) at constant [H2PO4-] (0.5 mM), was evaluated. Ks (apparent half-saturation constant) and Jmax (maximal transport rate) were calculated by two methods: weighted linear regression (WLR) and a nonparametric procedure. The dependence of Pi flux on pH indicates that optimum transport occurs at pH 6.9. Pi transport decreases as pH is reduced when extracellular Pi is either 0.5 or 5 mM. However, at pH 7.9, Pi flux is reduced only in 0.5 mM Pi. At pH 5.6, H2PO4- comprises 93% of the total Pi present, and the calculated Ks is 0.055 +/- 0.026 mM (WLR). This is the same as the Ks determined from the initial phase of the flux vs. [H2PO4-] relationship (0.056 +/- 0.020 mM). However, at pH 7.9 (where 94% of Pi is HPO4(-2)), the measured Ks is 0.58 +/- 0.11 mM (WLR), which is ten times higher than at pH 5.6. This value is also five times greater than the Ks calculated from the flux vs. [HPO4(-20)] curve (0.106 +/- 0.16 mM). Kinetic parameters calculated by the nonparametric method, though somewhat different, gave similar relative results. Taken together, these results support two conclusions: (1) H2PO4- is the substrate for the Na+-dependent Pi transport system of the Ehrlich cell, and (2) H+ can inhibit Pi transport.     

Na(+)-dependent Cl-HCO3 exchange in the squid axon. Dependence on extracellular pH.

Intracellular pH (pHi) in squid giant axons recovers from acid loads by means of a Na(+)-dependent Cl-HCO3 exchanger, the actual mechanism of which might be exchange of: (i) external Na+ and HCO3- for internal Cl- and H+, (ii) Na+ plus two HCO3- for Cl-, (iii) Na+ and CO3= for Cl-, or (iv) the NaCO3- ion pair for Cl-. Here we examine sensitivity of transport to changes of extracellular pH (pHo) in the range 7.1-8.6. We altered pHo in four ways, using: (i) classical "metabolic" disturbances in which we varied [HCO3-]o, [NaCO3-]o, and [CO3=]o at a fixed [CO2]o; (ii) classical "respiratory" disturbances in which we varied [CO2]o, [NaCO3-]o, and [CO3=]o at a fixed [HCO3-]o; (iii) novel mixed-type acid-base disturbances in which we varied [HCO3-]o and [CO2]o at a fixed [CO3=]o and [NaCO3-]o; and (iv) a second series of novel mixed-type disturbances in which we varied [CO2]o, [CO3=]o, and [Na+]o at a fixed [HCO3-]o and [NaCO3-]o. Axons (initial pHi approximately 7.4) were internally dialyzed with a pH 6.5 solution containing 400 mM Cl- but no Na+. After pHi, measured with a glass microelectrode, had fallen to approximately 6.6, dialysis was halted. The equivalent acid extrusion rate (JH) was computed from the rate of pHi recovery (i.e., increase) in the presence of Na+ and HCO3-. When pHo was varied by method (i), which produced the greatest range of [CO3=]o and [NaCO3-]o values, JH increased with pHo in a sigmoidal fashion; the relation was fitted by a pH titration curve with a pK of approximately 7.7 and a Hill coefficient of approximately 3.0. With method (ii), which produced smaller changes in [CO3=]o and [NaCO3-]o, JH also increased with pHo, though less steeply. With method (iii), which involved changes in neither [CO3=]o nor [NaCO3-]o, JH was insensitive to pHo changes. Finally, with method (iv), which involved changes in neither [HCO3-] nor [NaCO3-]o, but reciprocal changes in [CO3=]o and [Na+]o, JH also was insensitive to pHo changes. We found that decreasing pHo from 8.6 to 7.1 caused the apparent Km for external HCO3- ([Na+]o = 425 mM) to increase from 1.0 to 26.7 mM, whereas Jmax was relatively stable. Decreasing pHo from 8.6 to 7.4 caused the apparent Km values for external Na+ ([HCO3-]o = 48 mM) to increase from 8.6 to 81 mM, whereas Jmax was relatively stable.(ABSTRACT TRUNCATED AT 400 WORDS)     

Intracellular pH-regulatory mechanisms in pancreatic acinar cells. I. Characterization of H+ and HCO3- transporters

Rat pancreatic acini loaded with the pH sensitive fluorescent dye 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein were used to characterize intracellular pH (pHi) regulatory mechanisms in these cells. The acini were attached to cover slips and continuously perfused. In 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES)-buffered solutions recovery from acid load (H+ efflux) required extracellular Na+ (Na+out) and was blocked by amiloride. Likewise, H+ influx initiated by removal of Na+out was blocked by amiloride. Hence, in HEPES-buffered medium the major operative pHi regulatory mechanism is a Na+/H+ exchange. In HCO3(-)-buffered medium, amiloride only partially blocked recovery from acid load and acidification due to Na+out removal. The remaining fraction required Na+out, was inhibited by H2-4,4'-diisothiocyanostilbene-2,2'-disulfunic acid (H2DIDS) and was independent of C1-. Hence, a transporter with characteristics of a Na(+)-HCO3- cotransport exists in pancreatic acini. Measurement of pHi changes due to Na(+)-HCO3- cotransport, suggests that the transporter contributes to HCO3- efflux under physiological conditions. Changing the Cl- gradient across the plasma membrane of acini maintained in HCO3(-)-buffered solutions reveals the presence of an H2DIDS-sensitive, Na(+)-independent, Cl(-)-dependent, HCO3- transporter with characteristics of a Cl-/HCO3- exchanger. In pancreatic acini the exchanger transports HCO3- but not OH- and under physiological conditions functions to remove HCO3- from the cytosol. In summary, only the Na+/H+ exchanger is functional in HEPES-buffered medium to maintain pHi at 7.28 +/- 0.03. In the presence of 25 mM HCO3- at pHo of 7.4, all the transporters operate simultaneously to maintain a steady-state pHi of 7.13 +/- 0.04.     

Na/K/Cl cotransport in cultured human fibroblasts

The transport characteristics and regulation of the Na/K/Cl cotransport system were investigated in cultured human fibroblasts (HSWP cells). The existence of the system was documented by the finding that digitoxin-insensitive K+ influx was dependent upon the presence of both Na+ and Cl- in the extracellular milieu. It was found that only Br- could partially substitute for Cl-, with SCN-, I-, acetate, and gluconate being ineffective. Li+ could partially substitute for Na+; however, choline was without effect. The shape of the titration curves for K+ influx versus extracellular Cl- concentration was dependent upon the substituted anion. Furthermore, the apparent Km for Cl- at saturating [K+]o and [Na+]o, was also dependent upon the substituted anion and ranged from 30 mM (gluconate substitution) to 100 mM (acetate substitution). The titration curves for K+ influx versus extracellular Na+ concentration displayed hyperbolic kinetics and the apparent Km = 15 mM at saturating [K+]o. The curve for K+ influx versus extracellular K+ concentration was a hyperbola and the apparent Km for K+ = 3 mM at saturating [Na+]o. The digitoxin-insensitive K+ flux was found to be sensitive to related 5-sulfamoylbenzoic acid derivatives, commonly known as "loop" diuretics and to be insensitive to both: amiloride (3,5-diamino-N-(aminoiminomethyl)-6-chloropyrazinecarboxamide++ +) and 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid. The Na/K/Cl cotransport system was not stimulated by serum, but was slightly stimulated by two peptide mitogens. Furthermore, agents which cause an elevation in cellular cyclic AMP levels were found to be potent inhibitors of cotransport.     

Characterization of oxalate transport by the human erythrocyte band 3 protein

This paper describes characteristics of the transport of oxalate across the human erythrocyte membrane. Treatment of cells with low concentrations of H2DIDS (4,4'-diisothiocyanatostilbene-2,2'- disulfonate) inhibits Cl(-)-Cl- and oxalate-oxalate exchange to the same extent, suggesting that band 3 is the major transport pathway for oxalate. The kinetics of oxalate and Cl- self-exchange fluxes indicate that the two ions compete for a common transport site; the apparent Cl- affinity is two to three times higher than that of oxalate. The net exchange of oxalate for Cl-, in either direction, is accompanied by a flux of H+ with oxalate, as is also true of net Cl(-)-SO4(2-) exchange. The transport of oxalate, however, is much faster than that of SO4(2-) or other divalent anions. Oxalate influx into Cl(-)-containing cells has an extracellular pH optimum of approximately 5.5 at 0 degrees C. At extracellular pH below 5.5 (neutral intracellular pH), net Cl(-)- oxalate exchange is nearly as fast as Cl(-)-Cl- exchange. The rapid Cl(- )-oxalate exchange at acid extracellular pH is not likely to be a consequence of Cl- exchange for monovalent oxalate (HOOC-COO-; pKa = 4.2) because monocarboxylates of similar structure exchange for Cl- much more slowly than does oxalate. The activation energy of Cl(-)- oxalate exchange is about 35 kCal/mol at temperatures between 0 and 15 degrees C; the rapid oxalate influx is therefore not a consequence of a low activation energy. The protein phosphatase inhibitor okadaic acid has no detectable effect on oxalate self-exchange, in contrast to a recent finding in another laboratory (Baggio, B., L. Bordin, G. Clari, G. Gambaro, and V. Moret. 1993. Biochim. Biophys. Acta. 1148:157-160.); our data provide no evidence for physiological regulation of anion exchange in red cells.     

Na+-independent Cl(-)-HCO-3- exchange in Madin-Darby canine kidney cells. Role in intracellular pH regulation

The role of plasma membrane Cl(-)-HCO-3-exchange in regulating intracellular pH (pHi) was examined in Madin-Darby canine kidney cell monolayers. In cells bathed in 25 mM HCO-3, pH 7.4, steady state pHi was 7.10 +/- 0.03 (n = 14) measured with the fluorescent pH probe 2',7'-biscarboxyethyl-5,6-carboxyfluorescein. Following acute alkaline loading, pHi recovered exponentially in approximately 4 min. The recovery rate was significantly decreased by Cl- or HCO-3 removal and in the presence of 50 microM 4,4'-diisothiocyano-2,2'-disulfonic stilbene (DIDS). Na+ removal or 10(-3) M amiloride did not inhibit the pHi recovery rate after an acute alkaline load. Following acute intracellular acidification, the pHi recovery rate was significantly inhibited by 10(-3) M amiloride but was not altered by Cl- removal or 50 microM DIDS. At an extracellular pH (pHo) of 7.4, pHi remained unchanged when the cells were bathed in either Cl- free media, HCO-3 free media, or in the presence of 50 microM DIDS. As pHo was increased to 8.0, steady state pHi was significantly greater than control in Cl(-)-free media and in the presence of 50 microM DIDS. It is concluded that Madin-Darby canine kidney cells possess a Na+-independent Cl(-)-HCO-3 exchanger with a Km for external Cl- of approximately 6 mM. The exchanger plays an important role in pHi regulation following an elevation of pHi above approximately 7.1. Recovery of pHi following intracellular acidification is mediated by the Na+/H+ antiporter and not the anion exchanger.     

Cl(-)-HCO3- exchange in rat renal basolateral membrane vesicles

Pathways for HCO3- transport across the basolateral membrane were investigated using membrane vesicles isolated from rat renal cortex. The presence of Cl(-)-HCO3- exchange was assessed directly by 36Cl- tracer flux measurements and indirectly by determinations of acridine orange absorbance changes. Under 10% CO2/90% N2 the imposition of an outwardly directed HCO3- concentration gradient (pHo 6/pHi 7.5) stimulated Cl- uptake compared to Cl- uptake under 100% N2 in the presence of a pH gradient alone. Mediated exchange of Cl- for HCO3- was suggested by the HCO3- gradient-induced concentrative accumulation of intravesicular Cl-. Maneuvers designed to offset the development of ion-gradient-induced diffusion potentials had no significant effect on the magnitude of HCO3- gradient-driven Cl- uptake further suggesting chemical as opposed to electrical Cl(-)-HCO3- exchange coupling. Although basolateral membrane vesicle Cl- uptake was observed to be voltage sensitive, the DIDS insensitivity of the Cl- conductive pathway served to distinguish this mode of Cl- translocation from HCO3- gradient-driven Cl- uptake. No evidence for K+/Cl- cotransport was obtained. As determined by acridine orange absorbance measurements in the presence of an imposed pH gradient (pHo 7.5/pHi 6), a HCO3- dependent increase in the rate of intravesicular alkalinization was observed in response to an outwardly directed Cl- concentration gradient. The basolateral membrane vesicle origin of the observed Cl(-)-HCO3- exchange activity was verified by experiments performed with purified brush-border membrane vesicles. In contrast to our previous observations of the effect of Cl- on HCO3- gradient-driven Na+ uptake suggesting a basolateral membrane Na+-HCO3- for Cl- exchange mechanism, no effect of Na+ on Cl-HCO3- exchange was observed in the present study.     

Anion-dependent cation transport in erythrocytes

A selective survey of the literature reveals at least three major anion-dependent cation transport systems, defined as Na+ + Cl-, K+ + Cl- and Na+ + K+ + Cl- respectively. In human red cells, kinetic data on the fraction of K+ and Na+ influx inhibitable by bumetanide are presented to indicate an Na+:K+ stoichiometry of 1:2. For LK sheep red cells the large Cl- -dependent K+ leak induced by swelling is shown to share many characteristics with that induced by N-ethylmaleimide (NEM) treatment. NEM has complex effects, both inhibiting and then activating Cl- -dependent K+ fluxes dependent on NEM concentration. The alloantibody anti-L can prevent the action of NEM. In human red cells NEM induces a large Cl- -dependent specific K+ flux, which shows saturation kinetics. Its anion preference is Cl- greater than Br- greater than SCN- greater than I- greater than NO3- greater than MeSO4-. This transport pathway is not inhibited by oligomycin or SITS, although phloretin and high concentrations of furosemide and bumetanide (over 0.3 mM) do inhibit. Quinine (0.5 mM) is also an inhibitor. It is concluded that at least two distinct Cl- -dependent transport pathways for K+ are inducible in mammalian red cells, although the evidence for their separation is not absolute.     

Kinetics of bicarbonate and chloride transport in human red cell membranes

Unidirectional [14C]HCO3- and 36Cl- efflux from human red cells and ghosts was studied under self-exchange conditions at pH 7.8 and 0 degrees C by means of the Millipore-Swinnex filtering technique. Control bicarbonate experiments showed that 14CO2 loss from the cells to the efflux medium was insignificant. The anion flux was determined under (a) symmetric variations of the anion concentration (C(i) = C(o) = 5-700 mM), and (b) asymmetric conditions with CAn constant on one side and varied on the other side of the membrane. Simple Michaelis-Menten-like kinetics (MM fit: J(eff) = J(eff)max.C/(K1/2 + C)) was used to describe anion flux dependence on C for (a) C(i) = C(o) = 5-100 mM, (b) C(i) = 6-100 mM, C(o) = constant, and (c) C(i) = constant, C(o) = 1-25 mM. At higher cellular concentrations noncompetitive self-inhibition by anion binding (inhibition constant Ki mM) to an intracellular site was included in the model (MS fit): J(eff) = J(eff)max.C(i)/[(K1/2 + C(i)).(1 + C(i)/Ki)]. The MM fits show that the external half-saturation constant, Ko1/2 ( = C(o)An for J(eff,o) = 1/2.j(eff,o)max) at C(o) = 1-25 mM is 1.5-2.4 mM (HCO3-) and 1.8-2.6 mM (Cl-). At C(o) = 1-260 mM Ko1/2 is 1.2-1.5 mM (HCO3-) and 1.4-1.8 mM (Cl-). The respective maximum flux, J(eff,o)max (nmol/[cm2.s]), for C(o) = 1-25 mM is 0.41-0.51 (HCO3-) and 0.28-0.38 (Cl-), and for C(o) = 1-260 mM 0.39-0.44 (HCO3-) and 0.27-0.31 (Cl-). The internal half-saturation constant, Ki1/2 mM is: MM fit (C(i) = 6-100 mM, C(o) = 50 mM), 18.0 mM (HCO3-) and 23.8 mM (Cl-); MS fit (C(i) = 6-920 mM, C(o) = 50 mM), 32.0 mM (HCO3-) and 45.1 mM (Cl-). The maximum flux, J(eff,i)max (nmol/[cm2.s]) is: MM fit; 0.50 (HCO3-) and 0.34 (Cl-); MS fit, 0.70 (HCO-3) and 0.50 (Cl-). The half-inhibition constants of the MS fit, Ki, are 393 mM (HCO3-) and 544 mM (Cl-). The MM fit shows that the symmetric half-saturation constant, Ks1/2, is 20.2 (HCO-3) and 23.9 (Cl-) mM, and J(eff,s)max is 0.51 (HCO3-) and 0.32 (Cl-) nmol/(cm2.s). The MS fit shows that for C = 5-700 mM Ks1/2 is 30.4 nM (HCO3-) and 50.1 mM (Cl-), and Ki is 541 mM (HCO3-) and 392 mM (Cl-).(ABSTRACT TRUNCATED AT 400 WORDS)     

Volume regulatory activity of the Ehrlich ascites tumor cell and its relationship to ion transport

The volume regulatory response of the Ehrlich ascites tumor was studied in KCl-depleted, Na+-enriched cells. Subsequent incubation in K+-containing NaCl medium results in the reaccumulation of K+, Cl-, water and the extrusion of Na+. The establishment of the physiological steady state is due primarily to the activity of 2 transport systems. One is the Na/K pump (KM for K+o = 3.5 mM; Jmax = 30.1 mEq/kg dry min), which in these experiments was coupled 1K+/1 Na+. The second is the Cl--dependent (Na+ + K+) cotransport system (KM for K+o = 6.8 mM; Jmax = 20.8 mEq/kg dry min) which mediates, in addition to net ion uptake in the ratio of 1K+:1Na+:2Cl-, the exchange of K+i for K+o. The net passive driving force on the cotransport system is initially inwardly directed but does not decrease to zero at the steady state. This raises the possibility of the involvement of an additional source of energy. Although cell volume increases concomitant with net ion uptake, this change does not appear to be a major factor regulating the activity of the cotransport system.     

Na+, Li+ and Cl− transport by brush border membranes from rabbit jejunum

Na+, Li+, K+, Rb+, Br-, Cl- and SO4(2-) transport were studied in brush border membrane vesicles isolated from rabbit jejunum. Li+ uptakes were measured by flameless atomic absorption spectroscopy, and all others were measured using isotopic flux and liquid scintillation counting. All uptakes were performed with a rapid filtration procedure. A method is presented for separating various components of ion uptake: 1) passive diffusion, 2) mediated transport and 3) binding. It was concluded that a Na+/H+ exchange mechanism exists in the jejunal brush border. The exchanger was inhibited with 300 microM amiloride or harmaline. The kinetic parameters for sodium transport by this mechanism depend on the pH of the intravesicular solution. The application of a pH gradient (pHin = 5.5, pHout = 7.5) causes an increase in Jmax (50 to 125 pmol/mg protein . sec) with no change in Kt (congruent to 4.5 nM). Competition experiments show that other monovalent cations, e.g. Li+ and NH4+, share the Na+/H+ exchanger. This was confirmed with direct measurements of Li+ uptakes. Saturable uptake mechanisms were also observed for K+, Rb+ and SO4(2-), but not for Br-. The Jmax for K+ and Rb+ are similar to the Jmax for Na+, suggesting that they may share a transporter. The SO4(2-) system appears to be a Na+/SO4(2-) cotransport system. There does not appear to be either a Cl-/OH- transport mechanism of the type observed in ileum or a specific Na+/Cl- symporter.     

Cytosolic pH regulation in osteoblasts. Regulation of anion exchange by intracellular pH and Ca2+ ions

Measurements of cytosolic pH (pHi) 36Cl fluxes and free cytosolic Ca2+ concentration ([Ca2+]i) were performed in the clonal osteosarcoma cell line UMR-106 to characterize the kinetic properties of Cl-/HCO3- (OH-) exchange and its regulation by pHi and [Ca2+]i. Suspending cells in Cl(-)-free medium resulted in rapid cytosolic alkalinization from pHi 7.05 to approximately 7.42. Subsequently, the cytosol acidified to pHi 7.31. Extracellular HCO3- increased the rate and extent of cytosolic alkalinization and prevented the secondary acidification. Suspending alkalinized and Cl(-)-depleted cells in Cl(-)-containing solutions resulted in cytosolic acidification. All these pHi changes were inhibited by 4',4',-diisothiocyano-2,2'-stilbene disulfonic acid (DIDS) and H2DIDS, and were not affected by manipulation of the membrane potential. The pattern of extracellular Cl- dependency of the exchange process suggests that Cl- ions interact with a single saturable external site and HCO3- (OH-) complete with Cl- for binding to this site. The dependencies of both net anion exchange and Cl- self-exchange fluxes on pHi did not follow simple saturation kinetics. These findings suggest that the anion exchanger is regulated by intracellular HCO3- (OH-). A rise in [Ca2+]i, whether induced by stimulation of protein kinase C-activated Ca2+ channels, Ca2+ ionophore, or depolarization of the plasma membrane, resulted in cytosolic acidification with subsequent recovery from acidification. The Ca2+-activated acidification required the presence of Cl- in the medium, could be blocked by DIDS, and H2DIDS and was independent of the membrane potential. The subsequent recovery from acidification was absolutely dependent on the initial acidification, required the presence of Na+ in the medium, and was blocked by amiloride. Activation of protein kinase C without a change in [Ca2+]i did not alter pHi. Likewise, in H2DIDS-treated cells and in the absence of Cl-, an increase in [Ca2+]i did not activate the Na+/H+ exchanger in UMR-106 cells. These findings indicate that an increase in [Ca2+]i was sufficient to activate the Cl-/HCO3- exchanger, which results in the acidification of the cytosol. The accumulated H+ in the cytosol activated the Na+/H+ exchanger. Kinetic analysis of the anion exchange showed that at saturating intracellular OH-, a [Ca2+]i increase did not modify the properties of the extracellular site. A rise in [Ca2+]i increased the apparent affinity for intracellular OH- (or HCO3-) of both net anion and Cl- self exchange. These results indicate that [Ca2+]i modifies the interaction of intracellular OH- (or HCO3-) with the proposed regulatory site of the anion exchanger in UMR-106 cells.     

Apical membrane Na+/H+ exchange in Necturus gallbladder epithelium. Its dependence on extracellular and intracellular pH and on external Na+ concentration

Intracellular microelectrode techniques and extracellular pH measurements were used to study the dependence of apical Na+/H+ exchange on mucosal and intracellular pH and on mucosal solution Na+ concentration ([Na+]o). When mucosal solution pH (pHo) was decreased in gallbladders bathed in Na(+)-containing solutions, aNai fell. The effect of pHo is consistent with titration of a single site with an apparent pK of 6.29. In Na(+)-depleted tissues, increasing [Na+]o from 0 to values ranging from 2.5 to 110 mM increased aNai; the relationship was well described by Michaelis-Menten kinetics. The apparent Km was 15 mM at pHo 7.5 and increased to 134 mM at pHo 6.5, without change in Vmax. In Na(+)-depleted gallbladders, elevating [Na+]o from 0 to 25 mM increased aNai and pHi and caused acidification of a poorly buffered mucosal solution upon stopping the superfusion; lowering pHo inhibited both apical Na+ entry and mucosal solution acidification. Both effects can be ascribed to titration of a single site; the apparent pK's were 7.2 and 7.4, respectively. Diethylpyrocarbonate (DEPC), a histidine-specific reagent, reduced mucosal acidification by 58 +/- 4 or 39 +/- 6% when exposure to the drug was at pHo 7.5 or 6.5, respectively. Amiloride (1 mM) did not protect against the DEPC inhibition, but reduced both apical Na+ entry and mucosal acidification by 63 +/- 5 and 65 +/- 9%, respectively. In the Na(+)-depleted tissues mean pHi was 6.7. Cells were alkalinized by exposure to mucosal solutions containing high concentrations of nicotine or methylamine. Estimates of apical Na+ entry at varying pHi, upon increasing [Na+]o from 0 to 25 mM, indicate that Na+/H+ exchange is active at pHi 7.4. Intracellular H+ stimulated apical Na+ entry by titration of more than one site (apparent pK 7.1, Hill coefficient 1.7). The results suggest that external Na+ and H+ interact with one site of the Na+/H+ exchanger and that cytoplasmic H+ acts on at least two sites. The external titratable group seems to be an imidazolium, which is apparently different from the amiloride-binding site. The dependence of Na+ entry on pHi supports the notion that the Na+/H+ exchanger is operational under normal transport conditions.     

Na+, Cl− cotransport in Ehrlich ascites tumor cells activated during volume regulation (regulatory volume increase)

Ehrlich ascites cells were preincubated in hypotonic medium with subsequent restoration of tonicity. After the initial osmotic shrinkage the cells recovered their volume within 5 min with an associated KCl uptake. The volume recovery was inhibited when NO-3 was substituted for Cl-, and when Na+ was replaced by K+, or by choline (at 5 mM external K+). The volume recovery was strongly inhibited by furosemide and bumetanide, but essentially unaffected by DIDS. The net uptake of Cl- was much larger than the value predicted from the conductive Cl- permeability. The undirectional 36Cl flux, which was insensitive to bumetanide under steady-state conditions, was substantially increased during regulatory volume increase, and showed a large bumetanide-sensitive component. During volume recovery the Cl- flux ratio (influx/efflux) for the bumetanide-sensitive component was estimated at 1.85, compatible with a coupled uptake of Na+ and Cl-, or with an uptake via a K+,Na+,2Cl- cotransport system. The latter possibility is unlikely, however, because a net uptake of KCl was found even at low external K+, and because no K+ uptake was found in ouabain-poisoned cells. In the presence of ouabain a bumetanide-sensitive uptake during volume recovery of Na+ and Cl- in nearly equimolar amounts was demonstrated. It is proposed that the primary process during the regulatory volume increase is an activation of an otherwise quiescent, bumetanide-sensitive Na+,Cl- cotransport system with subsequent replacement of Na+ by K+ via the Na+/K+ pump, stimulated by the Na+ influx through the Na+,Cl- cotransport system.     

Mechanism of cis- and trans-substrate interactions at the tetraethylammonium/H+ exchanger of rabbit renal brush-border membrane vesicles

The kinetic basis for trans-effects of intravesicular substrates on the uptake of the organic cation, tetraethylammonium (TEA), into rabbit renal brush-border membrane vesicles (BBMV) was studied. Preloading BBMV with 1, 2, or 4 mM TEA stimulated the initial rate of uptake and the total net accumulation of 0.1 mM [3H]TEA. The stimulatory effect of intravesicular TEA on the initial rate of uptake was a saturable function of the trans-TEA concentration, with a half-maximal effect noted at an intravesicular concentration of 0.28 mM. A 1 mM trans-concentration of TEA increased the Jmax of [3H]TEA uptake (from 4.3 to 6.8 nmol.mg-1.min-1) without affecting the apparent Kt. An outwardly directed H+ gradient also increased Jmax (to 10.7 nmol.mg-1.min-1), although the addition of an outwardly directed TEA gradient did not produce further increases in the rate of TEA uptake. External H+ acted as a competitive inhibitor of TEA uptake, and an increase in external [H+] (from 32 nM to 100 nM) produced an increase in the apparent Kt for TEA transport (from 0.12 to 0.26 mM) without affecting the Jmax. The results suggested that TEA and H+ compete for a common site or set of mutually exclusive sites on the cytoplasmic and luminal aspects of TEA/H+ exchanger in the renal brush border, and that these sites have a similar affinity for TEA.     

Furosemide-sensitive salt transport in the Madin-Darby canine kidney cell line. Evidence for the cotransport of Na+, K+, and Cl-

Confluent monolayer cultures of the Madin-Darby canine kidney (MDCK) cell line have been shown to possess a furosemide and bumetanide-sensitive (Na+,K+)-cotransport system. We have studied the effect of anion substitutions on (Na+,K+)-cotransport. In Na+-depleted cells, bumetanide-sensitive uptake of 22Na+ or 86Rb+ exhibited an absolute requirement for extracellular Cl-. Chloride could be replaced in the buffers by Br-, but not by F-, I-, acetate, nitrate, thiocyanate, sulfate, or gluconate. The effect of Cl- was saturating, and Na+-stimulated 86RB+ uptake as well as K+-stimulated 22Na+ uptake was shown to be dependent on the square of the Cl- concentration. The concentration of Cl- which gave half-maximal stimulation of cation cotransport varied between 58 and 70 mM. There was a small degree of cooperativity between the binding affinities for Cl- and K+ at constant Na+ concentrations. Bumetanide-sensitive 36Cl- uptake could be demonstrated when extracellular Na+ and K+ were present simultaneously. Uptake through this system was unaffected by changes in the membrane potential or by the imposition of pH gradients. Together these data strongly suggest that the bumetanide-sensitive transport system in Madin-Darby canine kidney cells co-transports Na+, K+, and Cl- in a ratio of 1:1:2.     

Effects of halides and bicarbonate on chloride transport in human red blood cells

Chloride self-exchange was determined by measuring the rate of 36Cl efflux from human red blood cells at pH 7.2 (0 degrees C) in the presence of fluoride, bromide, iodide, and bicarbonate. The chloride concentration was varied between 10--400 mM and the concentration of other halides and bicarbonate between 10--300 mM. Chloride equilibrium flux showed saturation kinetics. The half-saturation constant increased and the maximum flux decreased in the presence of halides and bicarbonate: the inhibition kinetics were both competitive and noncompetitive. The competitive and the noncompetitive effects increased proportionately in the sequence: fluoride less than bromide less than iodide. The inhibitory action of bicarbonate was predominantly competitive. The noncompetitive effect of chloride (chloride self-inhibition) on chloride transport was less dominant at high inhibitor concentrations. Similarly, the noncompetitive action of the inhibitors was less dominant at high chloride concentrations. The results can be described by a carrier model with two anion binding sites: a transport site, and a second site which modifies the maximum transport rate. Binding to both types of sites increases proportionately in the sequence: fluoride less than chloride less than bromide less than iodide.     

The regulation of intracellular pH in monkey kidney epithelial cells (BSC-1). Roles of Na+/H+ antiport, Na+-HCO3(-)-(NaCO3-) symport, and Cl-/HCO3- exchange

Using the pH-sensitive absorbance of 5 (and 6)-carboxy-4',5'- dimethylfluorescein, we investigated the regulation of cytoplasmic pH (pHi) in monkey kidney epithelial cells (BSC-1). In the absence of HCO3-, pHi is 7.15 +/- 0.1, which is not significantly different from pHi in 28 mM HCO3-, 5% CO2 (7.21 +/- 0.07). After an acid load, the cells regulate pHi in the absence of HCO3- by a Na+ (or Li+)-dependent, amiloride-inhibitable mechanism (indicative of Na+/H+ antiport). In 28 mM HCO3-, while still dependent on Na+, this regulation is only blocked in part by 1 mM amiloride. A partial block is also observed with 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) (1 mM). With cells pretreated with DIDS, 1 mM amiloride nearly totally inhibits this regulation. Cl- had no effect on pHi regulation in the acidic range. In HCO3(-)-free saline, Na+ removal leads to an amiloride-insensitive acidification, which is dependent on Ca2+. In 28 mM HCO3-, Na+ (and Ca2+) removal led to a pronounced reversible and DIDS-sensitive acidification. When HCO3- was lowered from 46 to 10 mM at constant pCO2 (5%), pHi dropped by a DIDS-sensitive mechanism. Identical changes in pHo (7.6 to 6.9) in the nominal absence of HCO3- led to smaller changes of pHi. In the presence but not in the absence of HCO3-, removal of Cl- led to a DIDS-sensitive alkalinization. This was also observed in the nominal absence of Na+, which leads to a sustained acidification. It is concluded that in nominally bicarbonate-free saline, the amiloride-sensitive Na+/H+ antiport is the predominant mechanism of pHi regulation at acidic pHi, while being relatively inactive at physiological values of pHi. In bicarbonate saline, two other mechanisms effect pHi regulation: a DIDS-sensitive Na+-HCO3- symport, which contributes to cytoplasmic alkalinization, and a DIDS-sensitive Cl-/HCO3- exchange, which is apparently independent of Na+.     

Chloride transport in embryonic cells: effect of ethanol and GABA

Ethanol and GABA (gamma-aminobutyric acid) and their interaction on 36Cl-influx were analyzed in cultured embryonic palate and limb mesenchymal cells in order to determine whether ethanol exerts its teratogenic action through a GABA receptor involved in embryogenesis. Cl- transport in secondary cultures of C57BL/6 palate mesenchymal cells was shown to consist of three systems including the electroneutral Cl-/HCO3- exchange (50%) and Na+/K+/Cl- cotransport (30%) pathways and the voltage-dependent Cl- channel (20%). Treatment with DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonic acid) or SITS (4-acetamido-4'-isocyano-stilbene-2,2' disulfonic acid) in SWV palate cells inhibited the Cl-/HCO3- exchange pathway, while treatment with DIDS and bumetanide inhibited both the exchange and cation cotransport pathways, the residual Cl- influx inferred to be the electrogenic pathway. Inhibition of Cl- transport by anthracene-9-carboxylic acid confirmed the presence of the electrogenic Cl- pathway. It was observed that the rate of Cl- transport was significantly greater in palate cells of C57BL/6 mice than those of SWV mice. Also the rate of Cl- transport was significantly greater in secondary cultures of palate cells from C57BL/6 mice than from primary cultures of limb cells from the same strain. No evidence could be obtained that ethanol (10 to 100 mM) or GABA (3 X 10(-5) M) or their combination stimulated total Cl- influx in either C57BL/6 or SWV palate mesenchymal cells, putative voltage-dependent Cl- influx in C57BL/6 palate cells, or total Cl- influx in primary cultures of C57BL/6 limb mesenchymal cells.