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.     

Intracellular pH regulation in cultured embryonic chick heart cells. Na(+)-dependent Cl-/HCO3- exchange

The contribution of Cl-/HCO3- exchange to intracellular pH (pHi) regulation in cultured chick heart cells was evaluated using ion-selective microelectrodes to monitor pHi, Na+ (aiNa), and Cl- (aiCl) activity. In (HCO3- + CO2)-buffered solution steady-state pHi was 7.12. Removing (HCO3- + CO2) buffer caused a SITS (0.1 mM)-sensitive alkalinization and countergradient increase in aiCl along with a transient DIDS-sensitive countergradient decrease in aiNa. SITS had no effect on the rate of pHi recovery from alkalinization. When (HCO3- + CO2) was reintroduced the cells rapidly acidified, aiNa increased, aiCl decreased, and pHi recovered. The decrease in aiCl and the pHi recovery were SITS sensitive. Cells exposed to 10 mM NH4Cl became transiently alkaline concomitant with an increase in aiCl and a decrease in aiNa. The intracellular acidification induced by NH4Cl removal was accompanied by a decrease in aiCl and an increase in aiNa that led to the recovery of pHi. In the presence of (HCO3- + CO2), addition of either amiloride (1 mM) or DIDS (1 mM) partially reduced pHi recovery, whereas application of amiloride plus DIDS completely inhibited the pHi recovery and the decrease in aiCl. Therefore, after an acid load pHi recovery is HCO3o- and Nao- dependent and DIDS sensitive (but not Ca2+o dependent). Furthermore, SITS inhibition of Na(+)-dependent Cl-/HCO3- exchange caused an increase in aiCl and a decrease in the 36Cl efflux rate constant and pHi. In (HCO3- + CO2)-free solution, amiloride completely blocked the pHi recovery from acidification that was induced by removal of NH4Cl. Thus, both Na+/H+ and Na(+)-dependent Cl-/HCO3- exchange are involved in pHi regulation from acidification. When the cells became alkaline upon removal of (HCO3- + CO2), a SITS-sensitive increase in pHi and aiCl was accompanied by a decrease of aiNa, suggesting that the HCO3- efflux, which can attenuate initial alkalinization, is via a Na(+)-dependent Cl-/HCO3- exchange. However, the mechanism involved in pHi regulation from alkalinization is yet to be established. In conclusion, in cultured chick heart cells the Na(+)-dependent Cl-/HCO3- exchange regulates pHi response to acidification and is involved in the steady-state maintenance of pHi.     

Direct measurement of intracellular pH in identified glial cells and neurones of the leech central nervous system

Neutral carrier pH-sensitive double-barrelled microelectrodes were used to investigate intracellular pH (pHi) in leech neuropile glial cells and in Retzius neurones. The mean pHi of the glial cells was 6.87 +/- 0.13 (+/- SD, n = 27) in HEPES-buffered saline (pHo 7.4) and 7.18 +/- 0.19 (n = 13) in solutions buffered with 2% CO2- 11 mM HCO3-. The distribution of H+ ions in both the glia and neurones was found not to be in electrochemical equilibrium. To investigate pHi regulation, the pHi was decreased by exposure to CO2 or by adding and then removing NH4Cl. Acidification by any method was followed by a recovery to normal pHi values within minutes. The pHi recovery from acidification in neuropile glial cells in HEPES-buffered saline and CO2-HCO3- buffered saline was, however, blocked by removing external Na. In HCO3(-)-free solutions the diuretic amiloride (2 mM) reduced the rate of pHi recovery. In the presence of HCO3-, the rate of acid efflux was stimulated; the stilbene 4-acetamido-4'-isothiocyanatostilbene-2,3'-disulfonic acid (SITS; 0.5 mM) slowed pHi recovery. In HEPES buffered and CO2-HCO3- buffered solutions pHi regulation in neurones was inhibited by removing external Na. In HCO3(-)-free solutions amiloride reduced the rate of pHi recovery considerably. In the presence of HCO3-, SITS or amiloride slowed but did not completely block pHi recovery. We conclude that leech glial cells and neurones have two mechanisms of pHi regulation, one being Na+-H+ exchange and the other Na+ and HCO3- dependent.     

Cl--dependent and Cl--independent Na+/ HCO3- acid extrusion in cultured rat cerebellar astrocytes

It is still uncertain whether the Na+-dependent Cl--HCO3- exchanger (NCBE) is expressed in mammalian astrocytes. Using fluorescent indicators to monitor the intracellular pH (pHi) and intracellular Na+ or Cl- levels, the NCBE in cultured rat cerebellar astrocytes was examined in detail. In nominally bicarbonate-free (Hepes-buffered) medium, a marked pHi recovery from internal acid load was seen which could be blocked completely by 30 microM HOE 694, a specific Na+-H+ exchanger isoform 1(NHE-1) inhibitor, at a pHi above 6.9. These conditions were therefore used to block NHE activity in CO2/HCO3-buffered media when the NCBE was being studied at pHi above 6.9. After internal acid loading in completely Cl--free bicarbonate-buffered medium (containing HOE 694), the rates of pHi recovery and transient Na+ influx were considerably slowed, and the Cl--dependent acid extrusion was both Na+- and 4,4-diisothiocyano-stilbene-disulphonic acid (DIDS)-sensitive. Moreover, a HCO3-dependent Cl- efflux during internal acid injection was seen. These results suggest that the NCBE is present in astrocytes. Following repetitive internal acid loading by addition of 5% CO2 to internal Cl- depleted cells, a similar rate of pHi recovery was consistently seen, suggesting Cl--independent pHi regulation also occurred in astrocytes. Moreover, this pHi recovery was completely blocked in the absence of sodium or on addition of DIDS, confirming that the Na+-HCO3 cotransporter (NBC) is present. Thus, the present study provides evidence that both the NCBE and NBC play important roles in acid extrusion in cultured mammalian astrocytes.     

Intracellular pH-regulatory mechanisms in pancreatic acinar cells. II. Regulation of H+ and HCO3- transporters by Ca2(+)-mobilizing agonists

Pancreatic acini loaded with the pH-sensitive dye 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein were used to examine the effect of Ca2(+)-mobilizing agonists on the activity of acid-base transporters in these cells. In the accompanying article (Muallen, S., and Loessberg, P. A. (1990) J. Biol. Chem. 265, 12813-12819) we showed that in 4-(2-hydroxyethyl)-1-piperazine-ethanesulfonic acid (HEPES)-buffered medium the main pHi regulatory mechanism is the Na+/H+ exchanger, a while in HCO3(-)-buffered medium pHi is determined by the combined activities of a Na+/H+ exchanger, a Na(+)-HCO3- cotransporter and a Cl-/HCO3- exchanger. In this study we found that stimulation of acini with Ca2(+)-mobilizing agonists in HEPES or HCO3(-)-buffered media is followed by an initial acidification which is independent of any identified plasma membrane-located acid-base transporting mechanism, and thus may represent intracellularly produced acid. In HEPES-buffered medium there was a subsequent large alkalinization to pHi above that in resting cells, which could be attributed to the Na+/H+ exchanger. Measurements of the rate of recovery from acid load indicated that the Na+/H+ exchanger was stimulated by the agonists. In HCO3(-)-buffered medium the alkalinization observed after the initial acidification was greatly attenuated. Examination of the activity of each acid-base transporting mechanism in stimulated acini showed that in HCO3(-)-buffered medium: (a) recovery from acid load in the presence of H2-4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (H2DIDS) (Na+/H+ exchange) was stimulated similar to that found in HEPES-buffered medium; (b) recovery from acid load in the presence of amiloride and acidification due to removal of external Na+ in the presence of amiloride (HCO3- influx and efflux, respectively, by Na(+)-HCO3- cotransport) were inhibited; and (c) HCO3- influx and efflux due to Cl-/HCO3- exchange, which was measured by changing the Cl- or HCO3- gradients across the plasma membrane, were stimulated. Furthermore, the rate of Cl-/HCO3- exchange in stimulated acini was higher than the sum of H+ efflux due to Na+/H+ exchange and HCO3- influx due to Na(+)-HCO3- cotransport. Use of H2DIDS showed that the latter accounted for the attenuated changes in pHi in HCO3(-)-buffered medium, as much as treating the acini with H2DIDS resulted in similar agonist-mediated pHi changes in HEPES- and HCO3(-)-buffered media. The effect of agonists on the various acid-base transporting mechanisms is discussed in terms of their possible role in transcellular NaCl transport, cell volume regulation, and cell proliferation in pancreatic acini.     

Regulation of intracellular pH in LLC-PK1 cells studied using 31P-NMR spectroscopy

31P-NMR spectroscopy was used to monitor intracellular pH (pHi) in a suspension of LLC-PK1 cells, a renal epithelial cell line. The regulation of intracellular pH (pHi) was studied during intracellular acidification with 20% CO2 or intracellular alkalinization with 30 mM NH4Cl. The steady-state pHi in bicarbonate-containing Ringer's solution (pHo 7.40) was 7.14 +/- 0.04 and in bicarbonate-free Ringer's solution (pHo 7.40) 7.24 +/- 0.04. When pHo was altered in nominally HCO3(-)-free Ringer's, the intracellular pHi changed to only a small extent between pHo 6.6 and pHo 7.6; beyond this range pHi was linearly related to pHo. Below pHo 6.6 the cell was capable of maintaining a delta pH of 0.2 pH unit (inside more alkaline), above pH 7.6 a delta pH of 0.4 unit could be generated (inside more acid). During exposure to 20% CO2 in HCO3(-)-free Ringer's solution, pHi dropped initially to 6.9 +/- 0.05, the rate of realkalinisation was found to be 0.071 pH unit X min-1. After removal of CO2 the pHi increased by 0.65 and the rate of reacidification was 0.056 pH unit X min-1. Exposure to 30 mM NH4Cl caused a raise of pHi by 0.48 pH unit and an initial rate of re-acidification of 0.063 pH unit X min-1, after removal of NH4Cl the pHi fell by 0.58 pH unit below the steady-state pHi, followed by a subsequent re-alkalinization of 0.083 pH unit X min-1. Under both experimental conditions, the pHi recovery after an intracellular acidification, introduced by exposure to 20% CO2 and by removal of NH4+, was found to be inhibited by 53% and 63%, respectively, in the absence of sodium and 60% and 72%, respectively, by 1 mM amiloride. These studies indicate that 31P-NMR can be used to monitor steady-state intracellular pH as well a pHi transients in suspensions of epithelial cells. The results support the view that LLC-PK1 cells use an Na+-H+ exchange system to readjust their internal pH after acid loading of the cell.     

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.     

Intracellular pH regulation in the S3 segment of the rabbit proximal tubule in HCO3- -free solutions

We used the absorbance spectrum of 4',5'-dimethyl-5-(and 6) carboxyfluorescein to measure intracellular pH (pHi) in the isolated, perfused S3 segment of the rabbit proximal tubule. Experiments were conducted in HCO3- -free solutions. pHi recovered from an acid load imposed by an NH4+ prepulse, indicating the presence of one or more active acid-extrusion mechanisms. Removal of Na+ from bath and lumen caused pHi to decrease by approximately 0.6, whereas Na+ readdition caused complete pHi recovery. Removal of Na+ from the bath caused only a slow pHi decrease that was enhanced about fourfold when Na+ was subsequently removed from the lumen also. Similarly, the pHi recovery produced by the readdition of Na+ to the bath and lumen was about ninefold faster than when Na+ was returned to the bath only. Amiloride (1-2 mM) inhibited the pHi recovery that was elicited by returning 15 or 29 mM Na+ to lumen by only approximately 30%. However, in the absence of external acetate (Ac-), 1 mM amiloride inhibited approximately 66% of the pHi recovery induced by the readdition of 29 mM Na+ to the lumen only. The removal of external Ac- reduced the pHi recovery rate from an NH4+-induced acid load by approximately 47%, and that elicited by Na+ readdition, by approximately 67%. Finally, when bilateral removal of Na+ was maintained for several minutes, pHi recovered from the initial acidification, slowly at first, and then more rapidly, eventually reaching a pHi approximately 0.1 higher than the initial one. This Na+-independent pHi recovery was not significantly affected by lowering [HEPES]o from 32 to 3 mM or by adding N'N'-dicyclohexylcarbodiimide (10(-4) M) to the lumen, but it was reduced approximately 57% by iodoacetate (0.5 mM) plus cyanide (1 mM). We conclude that in the nominal absence of HCO3-, three transport systems contribute to acid extrusion by S3 cells: (a) a Na+-independent mechanism, possibly an H+ pump; (b) a Na-H exchanger, confined primarily to the luminal membrane; and (c) an Ac- and luminal Na+-dependent mechanism. The contribution of these three mechanisms to total acid extrusion, assessed by the rapid readdition of Na+, was approximately 13, approximately 30, and approximately 57%, respectively.     

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+.     

Polarized distribution of Na+/H+ antiport and Na+/HCO3- cotransport in primary cultures of renal inner medullary collecting duct cells.

Primary cultures of rat renal inner medullary collecting duct cells were grown to confluence on glass coverslips and treated permeant supports, and the pH-sensitive fluorescent probe 2,7-biscarboxyethyl-5,6-carboxyfluorescein was employed to delineate the nature of the transport pathways that allowed for recovery from an imposed acid load in a HCO3-/CO2-buffered solution. The H+ efflux rate of acid-loaded cells was 13.44 +/- 0.94 mM/min. Addition of amiloride, 10(-4) M, to the recovery solution reduced the H+ efflux rate to 4.06 +/- 0.63 mM/min. The amiloride-resistant pHi recovery mechanism displayed an absolute requirement for Na+ but was Cl(-)-independent. Studies performed on permeable supports demonstrated that the latter pathway was located primarily on the basolateral-equivalent (BE) cell surface and was inhibited by 50 microM 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). In a Na(+)-replete solution containing DIDS (50 microM) and amiloride (10(-4) M), acid-loaded cells failed to return to basal pHi. To delineate further the amiloride-inhibitable component of pHi recovery, monolayers were studied in the nominal absence of HCO3-/CO2. In 70% of monolayers studied, Na(+)-dependent, amiloride-inhibitable H+ efflux was the sole mechanism whereby acid-loaded cells returned to basal pHi. A Na(+)-independent pathway was observed in 30% of monolayers examined and represented only a minor component of the pHi recovery process. In studies performed on permeable supports, the Na(+)-dependent amiloride-inhibitable pathway was found to be confined exclusively to the BE cell surface. In summary, confluent monolayers of rat renal inner medullary collecting duct cells in primary culture possess two major mechanisms that contribute toward recovery from an imposed acid load, namely, Na+/H+ antiport and Na+/HCO3- cotransport. Na(+)-independent pHi recovery mechanisms represent a minor component of the pHi recovery process in the cultured cell. Both the Na+/H+ antiporter and Na+/HCO3- cotransporter are located primarily on the BE cell surface.     

Regulation of cytoplasmic pH in rat sublingual mucous acini at rest and during muscarinic stimulation

The regulation of intracellular pH (pHi) in rat sublingual mucous acini was monitored using dual-wavelength microfluorometry of the pH-sensitive dye BCECF (2',7'-biscarboxyethyl-5(6)-carboxyfluorescein). Acini attached to coverslips and continuously superfused with HCO3(-)-containing medium (25 mM NaHCO3/5% CO2; pH 7.4) have a steady-state pHi of 7.25 +/- 0.02. Acid loading of acinar cells using the NH4+/NH3 prepulse technique resulted in a Na(+)-dependent, MIBA-inhibitable (5-(N-methyl-N-isobutyl) amiloride, Ki approximately 0.42 microM) pHi recovery, the kinetics of which were not influenced by the absence of extracellular Cl-. The rate and magnitude of the pHi recovery were dependent on the extracellular Na+ concentration, indicating that Na+/H+ exchange plays a critical role in maintaining pHi above the pH predicted for electrochemical equilibrium. When the NH4+/NH3 concentration was varied, the rate of pHi recovery was enhanced as the extent of the intracellular acidification increased, demonstrating that the activity of the Na+/H+ exchanger is regulated by the concentration of intracellular protons. Switching BCECF-loaded acini to a Cl(-)-free medium did not significantly alter resting pHi, suggesting the absence of Cl-/HCO3- exchange activity. Muscarinic stimulation resulted in a rapid and sustained cytosolic acidification (t 1/2 < 30 sec; 0.16 +/- 0.02 pH unit), the magnitude of which was amplified greater than two-fold in the presence of MIBA (0.37 +/- 0.05 pH unit) or in the absence of extracellular Na+ (0.34 +/- 0.03 pH unit). The agonist-induced intracellular acidification was blunted in HCO3(-)-free media and was inhibited by DPC (diphenylamine-2-carboxylate), an anion channel blocker. In contrast, the acidification was not influenced by removal of extracellular Cl-. The Ca2+ ionophore, ionomycin, mimicked the effects of stimulation, whereas preloading acini with BAPTA (bis-(o-aminophenoxy)-ethane-N,N,N',N'-tetra-acetic acid) to chelate intracellular Ca2+ blocked the agonist-induced cytoplasmic acidification. The above results indicate that during muscarinic stimulation an intracellular acidification occurs which: (i) is partially buffered by increased Na+/H+ exchange activity; (ii) is most likely mediated by HCO3- efflux via an anion channel; and (iii) requires an increase in cytosolic free [Ca2+].     

Bicarbonate determines cytoplasmic pH and suppresses mitogen-induced alkalinization in fibroblastic cells

Addition of growth factors to responsive cells in HCO3- -free media results in a rapid rise in cytoplasmic pH (pHi) caused by activation of Na+/H+ exchange. In this paper, we have examined how pHi regulation and growth factor responsiveness are affected by HCO3(-)using quiescent mouse MES-1 fibroblastic cells as a model. When cells are exposed to 25 mM HCO3-, 5% CO2, steady-state pHi reaches a new more alkaline level (by 0.25 unit) within 10 min. This rise in pHi is both Na+- and HCO3- -dependent, does not occur in Cl(-)-depleted cells, and is inhibited by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid, but not by 5-(n,n-dimethyl)-amiloride, indicating the involvement of Na+-dependent HCO3-/Cl- exchange. Furthermore, the recovery of pHi from acute acid loads is accelerated by HCO3- in a Na+-dependent and 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid-sensitive manner and is blocked in Cl(-) -depleted cells. Similar results were obtained for mouse 3T3 cells and human fibroblasts. In the presence of HCO3-/CO2 (pH 7.35), mitogens and phorbol esters fail to induce a detectable rise in pHi. However, when steady-state pHi is artificially lowered by approximately 0.4 unit, growth factors evoke significant increases in pHi due to activation of Na+/H+ exchange. In the absence of HCO3-, mitogen-induced alkalinizations are readily detectable but not when pHi is artificially elevated to the value normally observed in HCO3- media. From these results we conclude that: 1) Na+-dependent HCO3-/Cl- exchange determines steady-state pHi and acts in parallel with Na+/H+ exchange to stimulate pHi recovery from acid loading; 2) Na+-dependent HCO3-/Cl- exchange raises steady-state pHi to a level beyond the operating range of the Na+/H+ exchanger and thereby prevents growth factors from alkalinizing the cytoplasm any further. The results also imply that, unlike Na+/H+ exchange, Na+-dependent HCO3-/Cl- exchange is not activated by mitogens.     

Na/H exchange in cultured chick heart cells. pHi regulation

The purpose of this study was to establish the existence of Na/H exchange in cardiac muscle and to evaluate the contribution of Na/H exchange to pHi regulation. The kinetics of pHi changes in cultured chick heart cells were monitored microfluorometrically with 6-carboxyfluorescein and correlated with Nai content changes analyzed by atomic absorption spectrophotometry; transmembrane H+ movements were evaluated under pH stat conditions. After induction of an intracellular acid load by pretreatment with NH4Cl, a regulatory cytoplasmic alkalinization occurred with a t1/2 of 2.9 min. pHi regulation required external Na+ and was concomitant with transmembrane H+ extrusion as well as a rapid rise in Nai content in an Na/H ratio of 1:1. Microelectrode recordings of membrane potential demonstrated directly the electroneutral character of pHi regulation. Acid-induced net Na+ uptake could be either stimulated by further decreasing pHi or inhibited by decreasing pHo; Na+ uptake was unaffected by tetrodotoxin (10 micrograms/ml), quinidine (10(-3) M), DIDS (10(-4) M), Clo-free solution, or HCO3-free solution. Amiloride (10(-3) M) maximally inhibited both pHi regulation and Na+ uptake; the ID50 for amiloride inhibition of Na+ uptake was 3 microM. Nao-dependent H+ extrusion showed half-maximal activation at 15 mM Nao; Li+, but not K+ or choline+, could substitute for Na+ to support H+ extrusion. Cao-free solution also stimulated acid-induced Na+ uptake. We conclude that pHi regulation following an acid load in cardiac muscle cells is by an amiloride-sensitive, electroneutral Na/H exchange. Stimulation of Na/H exchange up to 54 pmol/cm2 X s indicates the rapidity of this exchange across cardiac cell membranes. Na/H exchange may also participate in steady state maintenance of pHi.     

Regulation of intracellular pH in cultured hippocampal neurons by an amiloride-insensitive Na+/H+ exchanger.

Regulation of intracellular pH (pHi) in single cultured rat hippocampal neurons was investigated using the fluorescent pHi indicator dye bis-carboxyethylcarboxyfluorescein. Resting pHi was dependent on the presence of bicarbonate and external Na+ but was not altered significantly by removal of Cl- or treatment with the anion exchange inhibitor diisothiocyanatostilbene-2,2'-disulfonate. Recovery of pHi from acute acid loading was due, in large part, to a pharmacologically distinct variant of the Na+/H+ antiporter. In nominally HCO3(-)-free solutions, this recovery exhibited a saturable dose dependence on extracellular Na+ (Km = 23-26 mM) or Li+. The antiporter was activated by decreasing pHi and was unaffected by collapse of the membrane potential with valinomycin. Like the Na+/H+ antiporter described in other cell systems, the hippocampal activity was inhibited by harmaline, but in sharp contrast, neither amiloride nor its more potent 5-amino-substituted analogues were able to prevent the recovery from an acid load. These data indicate that Na(+)-dependent mechanisms dominate pHi regulation in hippocampal neurons and suggest a role for a novel variant of the Na+/H+ antiporter.     

Role of a Na+-dependent Cl-/HCO3- exchange in regulation of intracellular pH in fibroblasts

We previously reported that, in a HCO3(-)-free medium, cytoplasmic pH (pHi) of hamster fibroblasts (CCL39) is primarily regulated by an amiloride-sensitive Na+/H+ antiport (L'Allemain, G., Paris, S., and Pouysségur, J. (1984) J. Biol. Chem. 259, 5809-5815). Here we demonstrate the existence of an additional pHi-regulating mechanism in CCL39 cells, namely a Na+-dependent HCO3-/Cl- exchange. Evidence for this system is based on 36Cl- influx studies and on pHi measurements in PS120, a CCL39-derived mutant lacking the Na+/H+ antiport activity. 36Cl- influx rate is a saturable function of external [Cl-] (apparent Km approximately equal to 7 mM), is competitively inhibited by external HCO3- (KI approximately equal to 3 mM), and by stilbene derivatives (KI approximately equal to 20 microM for 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid). Measurements of pHi recovery after an acute acid load indicate that PS120 cells possess an acid-extruding mechanism dependent on external HCO3-, which is inhibited by stilbene derivatives and requires external Na+. Since 22Na+ influx is stimulated upon addition of HCO3- to acid-loaded cells and this effect is completely abolished by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid, we conclude that Na+ is co-transported with HCO3-, in exchange for intracellular Cl-. In a HCO3(-)-containing medium, this pHi-regulating mechanism appears to have two essential physiological functions for the Na+/H+ antiport-deficient mutant: protection of the cells against excessive cytoplasmic acidification and establishment of a steady-state pHi permissive for growth, at neutral or slightly acidic pHo values (6.6-7.2).     

Basolateral regulation of pHi in proximal tubules of avian loopless and long-looped nephrons in bicarbonate.

In isolated, nonperfused chicken proximal tubules from both loopless reptilian-type and long-looped mammalian-type nephrons, resting intracellular pH (pHi), measured with pH-sensitive fluorescent dye 2',7'-bis(2-carboxyethyl)-5,6-carboxyfluorescein (BCECF), was approximately 7.1 under control HCO3- conditions [20 mM N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES)/5 mM HCO3(-)-buffered medium with pH 7.4 at 37 degrees C] and was reduced to approximately 6.8 in response to NH4Cl pulse. The rate of recovery of pHi (dpHi/dt) from this level to the resting level in proximal tubules from both nephron types was (1) significantly reduced by the removal of Na+ or both Na+ and Cl- from the bath, and (2) unaffected by the removal of Cl- from the bath or the presence of a high K+ concentration or Ba2+ in the bath. In proximal tubules from long-looped mammalian-type, but not loopless reptilian-type, nephrons, dpHi/dt was significantly reduced by the addition of either 5-(N-ethyl-N-isopropyl) amiloride (EIPA) or 4,4'-diisothiocyanostilbene-2,2'disulfonate (DIDS) to the bath. These data suggest that a Na+/H+ exchanger and most likely a Na(+)-dependent Cl-/HCO3- exchanger are involved in basolateral regulation of pHi in mammalian-type nephrons whereas none of the commonly identified basolateral acid-base transporters appear to be involved in regulation of pHi in reptilian-type nephrons.     

Electrogenic sodium-dependent bicarbonate secretion by glial cells of the leech central nervous system

The ability to move acid/base equivalents across the membrane of identified glial cells was investigated in isolated segmental ganglia of the leech Hirudo medicinalis. The intracellular pH (pHi) of the glial cells was measured with double-barreled, neutral-ligand, ion-sensitive microelectrodes during step changes of the external pH (pHo 7.4-7.0). The rate of intracellular acidification after the decrease in extracellular pH (pHo) was taken as a measure of the rate of acid/base transport across the glial membrane. Taking into account the total intracellular buffering power, the maximum rate of acid/base flux was 0.4 mM/min in CO2/HCO3-free saline, and 3.92 mM/min in the presence of 5% CO2/10 mM HCO-3, suggesting that the acid/base flux was dependent upon HCO3-. The rate of acid influx/base efflux increased both with the external HCO3- concentration and with increasing pHi (and hence HCO3-i). This suggested that the decrease in pHi was due to HCO3- efflux. The rapid decrease of pHi was accompanied by a HCO3--dependent depolarization of the glial membrane from -74 +/- 5 mV (n = 20) to -54 +/- 7 mV (n = 13). Both this depolarization and the rate of intracellular acidification were greatly reduced by the anion exchange inhibitor 4,4-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS; 0.3-0.5 mM), but were not affected by the removal of external Cl-. Reduction of the external Na+ concentration to one-tenth normal affected the rate of intracellular acidification only in the presence of CO2/HCO3-: the rate increased within the first 3-5 min after lowering external Na+; after longer exposures in low external Na+ the rate decreased, presumably due to depletion of intracellular Na+. Amiloride (1 mM), which inhibits the Na+-H+ exchange in these cells, had no effect on the rate of intracellular acidification. The intracellular Na activity (aNai) of the glial cells was measured to be 5.2 +/- 1.0 mM (n = 8) in CO2/HCO3-free saline; aNai increased to 7.3 +/- 2.2 mM (n = 8) after the addition of 5% CO2/24 mM HCO3-. Upon a change in pHo to 7.0 in the presence of CO2/HCO3-, aNai decreased by an average of 2 +/- 1.1 mM (n = 5); in CO2/HCO3--free saline external acidification produced a transient increase in aNai. It is concluded that, in the presence of CO2/HCO3-, the rate of intracellular acidification in glial cells is dominated by an outwardly directed, electrogenic Na+-HCO3-cotransport. Neurons, which do not possess this cotransporter, acidify at much lower rates under similar conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cl-/HCO3- exchange modulates intracellular pH in rat type II alveolar epithelial cells

The role of an anion exchange pathway in modulating intracellular pH (pHi) under steady-state and alkaline load conditions was investigated in confluent monolayers of rat type II alveolar epithelial cells using the pH-sensitive fluorescent probe 2'-7'-biscarboxy-ethyl-5,6-carboxylfluorescein. Under steady-state conditions in the presence of 25 mM HCO3-, 5% CO2 at pHo 7.4, pHi was 7.32 in a Na+-replete medium and 7.33 in the absence of Na+. Steady-state pHi was 7.19 in a nominally HCO3(-)-free medium at pHo 7.4, and 7.52 in a Cl(-)-free medium, with both values significantly different from that obtained in the presence of both HCO3- and Cl-. Monolayers in which pHi was rapidly elevated by removal of HCO3-/CO2 from the bathing medium demonstrated an absolute requirement for Cl- to recover toward base-line pHi. The Km of Cl- for the external site of the exchange pathway was 11 +/- 1 mM. Recovery of pHi from the alkaline load in the presence of Cl- was inhibited 60% by the stilbene derivative 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid. Removal of Cl- from the medium of cells bathed in HCO3-/CO2 resulted in a rapid increment in pHi which returned to base line when Cl- was reintroduced into the bathing medium. In contrast, pHi was not perturbed by removal or addition of Cl- to monolayers bathed in a 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid-buffered medium, indicating that HCO3- was the preferred species for transport. Recovery of pHi from an alkaline load was not affected by the presence or absence of Na+. These findings define the transport pathway as Na+-independent Cl-/HCO3- exchange. This pathway contributes importantly to determining resting pHi of pneumocytes and enables the cell to recover from an alkaline load.     

K(+)- and HCO3(-)-dependent acid-base transport in squid giant axons. I. Base efflux

We used microelectrodes to monitor the recovery (i.e., decrease) of intracellular pH (pHi) after using internal dialysis to load squid giant axons with alkali to pHi values of 7.7, 8.0, or 8.3. The dialysis fluid (DF) contained 400 mM K+ but was free of Na+ and Cl-. The artificial seawater (ASW) lacked Na+, K+, and Cl-, thereby eliminating effects of known acid-base transporters on pHi. Under these conditions, halting dialysis unmasked a slow pHi decrease caused at least in part by acid-base transport we refer to as "base efflux." Replacing K+ in the DF with either NMDG+ or TEA+ significantly reduced base efflux and made membrane voltage (Vm) more positive. Base efflux in K(+)-dialyzed axons was stimulated by decreasing the pH of the ASW (pHo) from 8 to 7, implicating transport of acid or base. Although postdialysis acidifications also occurred in axons in which we replaced the K+ in the DF with Li+, Na+, Rb+, or Cs+, only with Rb+ was base efflux stimulated by low pHo. Thus, the base effluxes supported by K+ and Rb+ appear to be unrelated mechanistically to those observed with Li+, Na+, or Cs+. The combination of 437 mM K+ and 12 mM HCO3- in the ASW, which eliminates the gradient favoring a hypothetical K+/HCO3- efflux, blocked pHi recovery in K(+)-dialyzed axons. However, the pHi recovery was not blocked by the combination of 437 mM Na+, veratridine, and CO2/HCO3- in the ASW, a treatment that inverts electrochemical gradients for H+ and HCO3- and would favor passive H+ and HCO3- fluxes that would have alkalinized the axon. Similarly, the recovery was not blocked by K+ alone or HCO3- alone in the ASW, nor was it inhibited by the K-H pump blocker Sch28080 nor by the Na-H exchange inhibitors amiloride and hexamethyleneamiloride. Our data suggest that a major component of base efflux in alkali-loaded axons cannot be explained by metabolism, a H+ or HCO3- conductance, or by a K-H exchanger. However, this component could be mediated by a novel K/HCO3- cotransporter.     

Basolateral Na-H exchange in the rabbit cortical collecting tubule

We used the intracellular absorbance spectrum of the dye 4',5'-dimethyl-5- (and -6-) carboxyfluorescein (Me2CF) to measure intracellular pH (pHi) in the isolated, perfused cortical collecting tubule (CCT) of the rabbit nephron. The incident spot of light was generally 10 micron in diameter, large enough to illuminate from two to six cells. No attempt was made to distinguish principal from intercalated cells. All experiments were carried out in HCO3- -free Ringer to minimize HCO3- transport. When cells were acid-loaded by briefly exposing them to Ringer containing NH+4 and then withdrawing the NH+4, pHi spontaneously recovered from the acid load. The pHi recovery was best fit by the sum of two exponentials. When the acid loading was performed in the absence of Na+, the more rapid of the two phases of pHi recovery was absent. The remaining slow phase never returned pHi to normal and was sometimes absent. Returning Na+ to the lumen had only a slight effect on the pHi recovery. However, when Na+ was returned to the basolateral (i.e., blood-side) solution, pHi recovered rapidly and completely. The apparent Km for basolateral Na+ was 27.3 +/- 4.5 mM. The basolateral Na-dependent pHi recovery was reversibly inhibited by amiloride. We conclude that the mechanism responsible for the rapid phase of pHi recovery is an Na-H exchanger confined primarily, if not exclusively, to the basolateral membrane of the CCT.