Sodium and proton transport in Mycoplasma gallisepticum.

When washed cells of Mycoplasma gallisepticum were incubated at 37 degrees C in 250 mM 22NaCl, the intracellular Na+ increased, and the K+ decreased. The addition of glucose to these Na+-loaded cells caused Na+ efflux and K+ uptake (both ions moving against concentration gradients). This effect of glucose was blocked by the ATPase inhibitor dicyclohexylcarbodiimide, which prevents the generation of a proton motive force in these cells. In additional experiments, Na+ extrusion was studied by diluting the 22Na+-loaded cells into Na+-free media and following the loss of 22Na+ from the cells. Glucose stimulated 22Na+ extrusion in such cells by a dicyclohexylcarbodiimide-sensitive mechanism. Proton movement was studied by measuring the pH gradient across the cell membrane with the 9-aminoacridine fluorescence technique. Glucose addition to cells preincubated with cations other than Na+ resulted in cell alkalinization (which was prevented by dicyclohexylcarbodiimide). This observation is consistent with the operation of a proton-extruding ATPase. When glucose was added to Na+-loaded cells and diluted into Na+-free media, intracellular acidification was observed, followed several minutes later by a dicyclohexylcarbodiimide-sensitive alkalinization process. The initial acidification was probably due to the operation of an Na+-H+ antiport, since Na+ exit was occurring simultaneously with H+ entry. When Na+-loaded cells were diluted into Na+-containing media, the subsequent addition of glucose resulted in a weak acidification, presumably due to H+ entry in exchange for Na+ (driven by the ATPase) plus a continuous passive influx of Na+. All of the data presented are consistent with the combined operation of an ATP-driven proton pump and an Na+ -H+ exchange reaction.     

Thimerosal induces calcium mobilization, fructose 2,6-bisphosphate synthesis and cytoplasmic alkalinization in rat thymus lymphocytes

The effect of thimerosal on intracellular calcium ([Ca2+]i), pH (pHi) and fructose 2,6-bisphosphate (Fru 2,6-P2) in thymus lymphocytes was investigated. The effect of thimerosal on cell growth was also examined. Thimerosal produced a dose-dependent increase in [Ca2+]i, pHi and in the level of fructose 2,6-bisphosphate. Thimerosal was, however, unable to produce cell proliferation and inhibited [3H]thymidine incorporation when cells were challenged with PHA and costimulator. In the absence of external calcium, thimerosal produced only a slight increase in [Ca2+]i. In Na(+)-containing buffer, thimerosal induced an initial acidification (0.05 +/- 0.01 pH units), followed by an alkalinization of 0.08 pH units/min, whereas in Na(+)-free media, pHi decreased 0.2 +/- 0.02 units and this acidification was maintained for more than 40 min. When external calcium was removed the initial acidification was unchanged and no further increase in pHi was observed. Polymyxin B, an inhibitor of protein kinase C, did not modify the initial thimerosal-induced acidification although pH returned to basal levels after 10 min. It was concluded that alkalinization induced by thimerosal is probably due to activation of the Na+/H+ exchanger and that changes in internal Ca2+, pH and metabolic rate are not sufficient to induce cellular proliferation. The mechanism by which thimerosal inhibits thymocyte proliferation remains to be clarified.     

Evidence for a Na+/H+ antiport in stomach smooth muscle cells

Single smooth muscle cells were isolated from circular muscle of the canine gastric corpus by collagenase incubation. Cytoplasmic pH (pHi) of these cells was measured fluorometrically using the trapped dye 2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein. Cells were examined for their Na+/H+ exchange activity after intracellular acidification. Cells acid-loaded by propionate exposure, the NH4+ prepulse technique or suspension in a Na+-depleted medium regained almost normal pHi upon exposure to a Na+ medium. The Na+-dependent alkalinization was amiloride sensitive. As well, addition of amiloride to cells suspended in a Na+ medium caused a concurrent decrease in pHi. The study indicates that a Na+/H+ antiport is present in these smooth muscle cells.     

Effects of nutrient and non-nutrient stimuli on cytosolic pH in cultured insulinoma (HIT-T15) cells

Intracellular pH (pHi) was measured in the insulin-secreting HIT-T15 cell line using the pH-sensitive fluorescent dye, 2',7'-bis(carboxyethyl)-5'(6')-carboxyfluorescein (BCECF). It was observed that the addition of a weak acid (e.g., acetate or propionate) caused a rapid decrease in pHi, followed by a slower recovery to the resting pH value. Conversely the addition of N4Cl caused an increase in pHi followed by recovery. The addition of amiloride caused a fall in pHi; however, in this case no recovery to basal pH levels was observed. Subsequent addition of a weak acid caused a further fall in pHi with no recovery. The addition of glucose caused a transient acidification followed by alkalinization. When glucose was added to cells which had been pretreated with amiloride, the initial acidification was not followed by recovery or alkalinization. Addition of glyceraldehyde, alpha-ketoisocaproate, lactate or pyruvate to HIT cells also resulted in intracellular acidification followed by recovery. Similarly, depolarisation of HIT cells by treatment with high K+ or with Ba2+ was associated with a pronounced fall in pHi, followed by a gradual recovery. Insulin secretion from HIT cells was stimulated by glucose, glyceraldehyde, alpha-ketoisocaproate, lactate, pyruvate and KCl, whilst amiloride and weak acids exerted only modest effects in the absence of glucose, but amiloride in particular markedly potentiated glucose-induced insulin release. Thus, HIT cells appear to have an amiloride-sensitive mechanism for the extrusion of protons, probably Na+-H+ exchange. Whilst intracellular acidification appears to potentiate secretory responses to nutrient stimuli, it seems unlikely that the activation of HIT cells by these nutrients occurs as a result of intracellular acidification. The mechanisms by which various nutrient and non-nutrient stimuli might exert distinct effects on pHi are discussed.     

Early agonist-mediated ionic events in cultured vascular smooth muscle cells. Calcium mobilization is associated with intracellular acidification

Angiotensin II, a potent vasoconstrictor peptide, increases free cytoplasmic Ca2+ concentration ([Ca2+]i) in vascular smooth muscle cells (VSMC) by release of nonmitochondrial Ca2+ stores and stimulates an amiloride-sensitive Na+ influx, presumably via Na+/H+ exchange. We recently have found that the angiotensin II-mediated change in VSMC intracellular pH has two components, an early rapid acidification phase and a slower recovery phase involving Na+-dependent alkalinization. In the present study, we show that the early acidification is not mediated via Na+/H+ exchange. Instead, we propose a mechanism which involves increases in [Ca2+]i and Ca2+ efflux with a subsequent rise in intracellular H+. Agonists, in addition to angiotensin II, which increase [Ca2+]i in cultured VSMC, including platelet-derived growth factor, vasopressin, and bradykinin, induce an acidification, while agonists which fail to raise [Ca2+]i do not. The time course and magnitude of agonist-stimulated 45Ca2+ efflux correlate with the acidification response. The angiotensin II concentration-response relationship for acidification and Ca2+ mobilization are similar. Furthermore, inhibition of changes in [Ca2+]i by treatment with phorbol ester, cyclic GMP, or quin2 loading prevent agonist-mediated acidification. The effects of altering extracellular [Ca2+] and [H+] on agonist-mediated intracellular acidification and H+ efflux suggest that the acidification is due to ATP-dependent unidirectional H+ influx, perhaps via the plasma membrane Ca2+-ATPase, and not to a Ca2+/H+ antiport. This agonist-mediated acidification represents a previously undescribed ionic event in VSMC activation which may be involved in excitation-response coupling.     

Effect of potassium depletion of Hep 2 cells on intracellular pH and on chloride uptake by anion antiport

The effect of K+ depletion of Hep 2 cells on ion fluxes, internal pH, cell volume, and membrane potential was studied. The cells were depleted of K+ by incubation in K+-free buffer with or without a preceding exposure to hypotonic medium. Efflux of K+ in cells not exposed to hypotonic medium was inhibited by furosemide or by incubation in Na+-free medium, indicating that in this case at least part of the K+ efflux occurs by Na+/K+/Cl- cotransport. After exposure to hypotonic medium, K+ efflux was not inhibited by furosemide, whereas it was partly inhibited by 4,4'-diisothiocyano-2,2'-stilbene-disulfonic acid (DIDS). Exposure to hypotonic medium induced acidification of the cytosol, apparently because of efflux of protons from intracellular acidic vesicles. When isotonicity was restored, a rebound alkalinization of the cytosol was induced, because of activation of the Na+/H+ antiporter. While hypotonic shock and a subsequent incubation in K+-free buffer rapidly depolarized the cells, depolarization occurred much more slowly when the K+ depletion was carried out by incubation in K+-free buffer alone. The cell volume was reduced in both cases. K+ depletion by either method strongly reduced the ability of the cells to accumulate 36Cl- by anion antiport, and K+-depleted cells were unable to increase the rate of 36Cl- uptake in response to alkalinization of the cytosol.     

Changes in intramitochondrial and cytosolic pH: early events that modulate caspase activation during apoptosis

Mitochondria trigger apoptosis by releasing caspase activators, including cytochrome c (cytC). Here we show, using a pH-sensitive green fluorescent protein (GFP), that mitochondria-dependent apoptotic stimuli (such as Bax, staurosporine and ultraviolet irradiation) induce rapid, Bcl-2-inhibitable mitochondrial alkalinization and cytosol acidification, followed by cytC release, caspase activation and mitochondrial swelling and depolarization. These events are not induced by mitochondria-independent apoptotic stimuli, such as Fas. Activation of cytosolic caspases by cytC in vitro is minimal at neutral pH, but maximal at acidic pH, indicating that mitochondria-induced acidification of the cytosol may be important for caspase activation; this finding is supported by results obtained from cells using protonophores. Cytosol acidification and cytC release are suppressed by oligomycin, a FoF1-ATPase/H +-pump inhibitor, but not by caspase inhibitors. Ectopic expression of Bax in wild-type, but not FoF1/H+-pump-deficient, yeast cells similarly results in mitochondrial matrix alkalinization, cytosol acidification and cell death. These findings indicate that mitochondria-mediated alteration of intracellular pH may be an early event that regulates caspase activation in the mitochondrial pathway for apoptosis.     

Cytoplasmic [Ca2+] and intracellular pH in lymphocytes. Role of membrane potential and volume-activated Na+/H+ exchange

The effect of elevating cytoplasmic Ca2+ [( Ca2+]i) on the intracellular pH (pHi) of thymic lymphocytes was investigated. In Na+-containing media, treatment of the cells with ionomycin, a divalent cation ionophore, induced a moderate cytoplasmic alkalinization. In the presence of amiloride or in Na+-free media, an acidification was observed. This acidification is at least partly due to H+ (equivalent) uptake in response to membrane hyperpolarization since: it was enhanced by pretreatment with conductive protonophores, it could be mimicked by valinomycin, and it was decreased by depolarization with K+ or gramicidin. In addition, activation of metabolic H+ production also contributes to the acidification. The alkalinization is due to Na+/H+ exchange inasmuch as it is Na+ dependent, amiloride sensitive, and accompanied by H+ efflux and net Na+ gain. A shift in the pHi dependence underlies the activation of the antiport. The effect of [Ca2+]i on Na+/H+ exchange was not associated with redistribution of protein kinase C and was also observed in cells previously depleted of this enzyme. Treatment with ionomycin induced significant cell shrinking. Prevention of shrinking largely eliminated the activation of the antiport. Moreover, a comparable shrinking produced by hypertonic media also activated the antiport. It is concluded that stimulation of Na+/H+ exchange by elevation of [Ca2+]i is due, at least in part, to cell shrinking and does not require stimulation of protein kinase C.     

Amiloride and glucose effects on the intracellular pH of Yoshida rat ascites hepatoma AH-130 cells grown in vivo

The equilibrium distribution of 5,5-dimethyloxazolidine-2,4-dione (DMO) between intra- and extracellular volume was used to estimate the intracellular pH in Yoshida rat ascites hepatoma AH-130 cells under different growth conditions (log, midlog and stationary). The cells were suspended in a Krebs-Ringer 25 mM phosphate buffer and the effects of variation of external pH, of glucose and amiloride addition on intracellular pH were measured. Proliferating cells had higher intracellular pH than stationary phase cells and this difference was inhibited by amiloride. On addition of glucose the fall in external pH was similar in all conditions and corresponded to lactate production. However, the intracellular pH decreased only in proliferating cells. Stationary phase cells showed an amiloride-sensitive cytoplasmic alkalinization with glucose. Glucose addition also caused prompt recovery to a normal polysomal pattern in these cells that might suggest increased efficiency of the initiation step of protein synthesis under these conditions. The data thus suggest that the increased intracellular pH of proliferating and of glucose-treated stationary phase cells is linked to the rate of protein synthesis and is mediated by the amiloride-sensitive Na+/H+ exchange system. This could lead to increased intracellular Na+ concentration under these conditions and to initiation of growth.     

Trehalase activation in yeasts is mediated by an internal acidification

It has been reported that the addition of glucose, uncouplers and nystatin to yeast cells grown in a sugarfree medium causes trehalase activation; it has been postulated that this activation might be mediated by the depolarization of the plasma membrane. In this article the values of membrane potential and pH gradient across the plasma membrane of Saccharomyces cerevisiae have been determined under the same conditions as those in which trehalase is activated. Membrane potential was evaluated from the distribution of triphenylmethylphosphonium, the pH gradient from the distribution of benzoic acid across the plasma membrane. When the effect of several agents on the two components of the electrochemical proton gradient across the plasma membrane of ethanol-grown yeast cells were studied, under trehalase activation conditions, the following observations were made. (a) The addition of glucose activated trehalase and caused internal acidification of the cells, but had practically no effect on the membrane potential. (b) The addition of 200 mM KCl depolarized the cell membrane but did not affect the internal pH, nor trehalase activity. (c) Although carbonyl cyanide m-chlorophenylhydrazone depolarized the cells at external pH 6.0 and 7.0, it only activated trehalase at an external pH 6.0, leading to the acidification of the internal medium at this pH. (d) Nystatin caused an increase in the triphenylmethylphosphonium accumulation at external pH 6.0 and 7.0, but only activated trehalase at external pH 6.0, causing acidification of the cell interior at this pH. (e) Activation of trehalase was also observed when the internal acidification was caused by addition of a weak acid such as acetate. It is concluded that trehalase activation is mediated by an intracellular acidification and is independent of the membrane potential.     

Cytoplasmic pH regulation in normal and abnormal neutrophils. Role of superoxide generation and Na+/H+ exchange

The cytoplasmic pH of human neutrophils was determined fluorometrically using carboxylated fluorescein derivatives. When normal neutrophils were activated by the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA) in Na+-containing medium, the cytoplasmic pH initially decreased but then returned to near normal values. In Na+-free media or in Na+ medium containing amiloride, TPA induced a marked monophasic intracellular acidification. The cytoplasmic acidification is associated with net H+ equivalent efflux, suggesting metabolic acid generation. The metabolic pathways responsible for the acidification were investigated by comparing normal to chronic granulomatous disease neutrophils. These cells are unable to oxidize NADPH and generate superoxide. When treated with TPA in Na+-free or amiloride-containing media, chronic granulomatous disease cells did not display a cytoplasmic acidification. This suggests that in normal cells NADPH oxidation and/or the accompanying activation of the hexose monophosphate shunt are linked to the acidification. Unlike normal neutrophils, chronic granulomatous disease cells treated with TPA in Na+-containing medium displayed a significant cytoplasmic alkalinization. The alkalinization was Na+-dependent and amiloride-sensitive, indicating activation of Na+/H+ exchange. Thus, the Na+/H+ antiport, which can be indirectly stimulated by the metabolic cytoplasmic acidification, is also directly activated by the phorbol ester.     

Internal acidification and cAMP increase are not correlated in Saccharomyces cerevisiae

Addition of glucose to a yeast suspension can produce both an increase in the level of cAMP and a decrease in the intracellular pH. This observation led to the idea that internal acidification triggers the cAMP increase. We have tested this hypothesis using different approaches. To study the effect of sugar metabolism on internal pH we added to the yeast either glucose or a sugar, like xylose, that cannot be phosphorylated. We also utilized yeast strains lacking hexose kinases or phosphoglucose isomerase. We found that phosphorylation of the sugar added is a requisite for internal acidification but not for the cAMP increase. Internal acidification is due to an imbalance between the rate of the metabolic reactions that generate protons and the rate at which protons can be pumped out of the cell. We have manipulated the excretion of protons by using yeast harvested at different phases of growth and resuspended in a medium with or without added K+. Addition of glucose produced a marked drop in internal pH only when the yeast was harvested in the stationary phase of growth and transferred to a medium without added K+. In contrast an increase in cAMP was observed in all situations. We conclude that in yeast there is no correlation between internal acidification and cAMP increase.     

A single mutation confers vanadate resistance to the plasma membrane H+-ATPase from the yeast Schizosaccharomyces pombe

A single-gene nuclear mutant has been selected from the yeast Schizosaccharomyces pombe for growth resistance to Dio-9, a plasma membrane H+-ATPase inhibitor. From this mutant, called pma1, an ATPase activity has been purified. It contains a Mr = 100,000 major polypeptide which is phosphorylated by [gamma-32P] ATP. Proton pumping is not impaired since the isolated mutant ATPase is able, in reconstituted proteoliposomes, to quench the fluorescence of the delta pH probe 9-amino-6-chloro-2-methoxy acridine. The isolated mutant ATPase is sensitive to Dio-9 as well as to seven other plasma membrane H+-ATPase inhibitors. The mutant H+-ATPase activity tested in vitro is, however, insensitive to vanadate. Its Km for MgATP is modified and its ATPase specific activity is decreased. The pma1 mutation decreases the rate of extracellular acidification induced by glucose when cells are incubated at pH 4.5 under nongrowing conditions. During growth, the intracellular mutant pH is more acid than the wild type one. The derepression by ammonia starvation of methionine transport is decreased in the mutant. The growth rate of pma1 mutants is reduced in minimal medium compared to rich medium, especially when combined to an auxotrophic mutation. It is concluded that the H+-ATPase activity from yeast plasma membranes controls the intracellular pH as well as the derepression of amino acid, purine, and pyrimidine uptakes. The pma1 mutation modifies several transport properties of the cells including those responsible for the uptake of Dio-9 and other inhibitors (Ulaszewski, S., Coddington, A., and Goffeau, A. (1986) Curr. Genet. 10, 359-364).     

Phosphorus-31 nuclear magnetic resonance studies of wild-type and glycolytic pathway mutants of Saccharomyces cerevisiae.

High-resolution phosphorus-31 nuclear magnetic resonance (31P NMR) spectra of wild-type and mutant strains of Saccharomyces cerevisiae were observed at a frequency of 145.7 MHz. Levels of various phosphorus metabolites were investigated upon addition of glucose under both aerobic and anaerobic conditions. Three mutant strains were isolated and their biochemical defects characterized: pfk lacked phosphofructokinase activity; pgi lacked phosphoglucose isomerase activity; and cif had no glucose catabolite repression of the fructose bisphosphatase activity. Each mutant strain was found to accumulate characteristic sugar phosphates when glucose was added to the cell suspension. In the case of the phosphofructokinase deficient mutant, the appearance of a pentose shunt metabolite was observed. 31P NMR peak assignments were made by a pH titration of the acid extract of the cells. Separate signals for terminal, penultimate, and central phosphorus atoms in intracellular polyphosphates allowed the estimation of their average molecular weight. Signals for glycero(3)phosphochline, glycero(3)phosphoserine, and glycero(3) phosphoethanolamine as well as three types of nucleotide diphosphate sugars could be observed. The intracellular pH in resting and anaerobic cells was in the range 6.5--6.8 and the level of adenosine 5'-triphosphate (ATP) low. Upon introduction of oxygen, the ATP level increased considerably and the intracellular pH reached a value of pH 7.2--7.3, irrespective of the external medium pH, indicating active proton transport in these cells. A new peak representing the inorganic phosphate of one of the cellular organelles, whose pH differed from the cytoplasmic pH, could be detected under appropriate conditions.     

Evidence that Na+/H+ exchange regulates angiotensin II-stimulated diacylglycerol accumulation in vascular smooth muscle cells

Angiotensin II stimulation of vascular smooth muscle cells results in initial, rapid diacylglycerol (DG) formation from the polyphosphoinositides accompanied by intracellular acidification, as well as a more sustained DG accumulation which is accompanied by a prolonged intracellular alkalinization. To determine whether intracellular pH (pHi) modulates DG accumulation, NH4Cl and potassium acetate were used to alter pHi and DG formation was measured. NH4Cl (10 mM) increased pHi from 7.15 +/- 0.05 to 7.34 +/- 0.02 pH units and markedly enhanced the sustained (5 min), but not the initial (15 s), phase of DG formation in response to 100 nM angiotensin II (65 +/- 13% increase). Conversely, intracellular acidification with Na+-free buffer and potassium acetate (20 mM) decreased pHi to 6.93 +/- 0.08 and reduced subsequent angiotensin II-induced sustained DG formation by 82 +/- 9%. In intact cells, inhibition of angiotensin II-stimulated alkalinization by incubation in Na+-free buffer or by addition of the Na+/H+ exchange inhibitor dimethylamiloride (10 microM) decreased the ability of the cell to sustain DG formation, suggesting that active Na+/H+ exchange is necessary for continued DG formation. Thus, it seems that sustained, angiotensin II-induced diacylglycerol accumulation is regulated by intracellular alkalinization secondary to Na+/H+ exchange in cultured vascular smooth muscle cells.     

Na+/H+ exchange in Ehrlich ascites tumor cells. Regulation by extracellular ATP and 12-O-tetradecanoylphorbol 13-acetate

The effects of extracellular ATP and/or the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) on the intracellular pH of Ehrlich ascites tumor cells were measured using both distribution of [14C]5,5-dimethyloxazolidine-2,4-dione, and the fluorescent indicator 5(6)-carboxyfluorescein. Micromolar concentrations of extracellular ATP induce a biphasic change in the intracellular pH characterized by a rapid acidification of 0.04 pH units followed by an alkalinization of 0.11 pH units. Concurrently with the alkalinization, an increase in the total cellular [Na+] from 37.5 to 45.0 mM is observed. The pH change is half-maximally activated by 0.5-2.5 microM extracellular ATP. The intracellular alkalinization, but not the initial acidification, phase requires extracellular Na+, with half-maximal alkalinization in the presence of 24-32 mM Na+, and is inhibited by amiloride. Exposure of Ehrlich ascites tumor cells to TPA alone produces a slight alkalinization of approximately 0.04 pH units. Conversely, preincubation of the cells with TPA partially inhibits the ATP-induced changes in intracellular pH. Under identical conditions TPA also inhibits the ATP-induced increase in the cytosolic [Ca2+]. The half-maximal dose for both effects is produced by 3-10 nM TPA. These data indicate that extracellular ATP triggers the activation of Na+/H+ exchange. Furthermore, activation of protein kinase C mediates at least part of the Na+/H+ exchange, although a second mechanism may also exist.     

Response of alkalinization or acidification by phytohemagglutinin is dependent on the activity of protein kinase C in human peripheral T Cells

The increase of intracellular free calcium concentration ([Ca(2+)](i)) and protein kinase C (PKC) activity are two major early mitogenic signals to initiate proliferation of human T cells. However, a rapid change in intracellular pH (pH(i)), acidification or alkalinization during the activation, is also associated after these two signals. The aim of this study was to define whether the change in pH(i) is affected by calcium and protein kinase C (PKC), in phytohemagglutinin (PHA)-stimulated T cells. T cells were isolated from human peripheral blood. The [Ca(2+)](i) and the pH(i) were measured using, respectively, the fluorescent dyes, Fura-2, and BCECF. In addition, down-regulation of PKC activity by PMA (1 microM, 18 h) was confirmed in these cells using a protein kinase assay. The results indicated that, (1) alkalinization was induced by PHA or PMA in T cells; the results of alkalinization was PKC-dependent and Ca(2+)-independent, (2) in PKC down-regulated T cells, PHA induced acidification; this effect was enhanced by pre-treating the cells with the Na(+)/H(+) exchange inhibitor, 5-(N,N-dimethyl)-amiloride, (DMA, 10 microM, 20 min), (3) the acidification was dependent on the Ca(2+) influx and blocked by removal of extracellular calcium or the addition of the inorganic channel blocker, Ni(2+), and (4) Thapsigargin (TG), a Ca(2+)-ATPase inhibitor, confirmed that acidification by the Ca(2+) influx occurred in T cells in which PKC was not down-regulated. These findings indicate two mechanisms, alkalinization by PKC and acidification by Ca(2+) influx, exist in regulating pH(i) in T cells. This is the first report that PHA stimulates the acidification by Ca(2+) influx but not alkalinization in T cells after down-regulation of PKC. In conclusion, the activity of PKC in T cells determines the response in alkalinization or acidification by PHA.     

Palytoxin acidifies chick cardiac cells and activates the Na+/H+ antiporter

The cardiotoxic action of palytoxin was investigated using embryonic chick ventricular cells. Under normal ionic conditions, palytoxin produced an intracellular acidification which is partially compensated for by the Na+/H+ antiporter thereby leading to an increased rate of ethylisopropylamiloride-sensitive 22Na+ uptake. Under depolarizing membrane conditions, palytoxin produced a cellular acidification, a cellular alkalinization or no change in intracellular pH depending on the value of the extracellular pH. We propose that palytoxin acidifies cardiac cells by opening preexisting H+ conducting pathways in the plasma membrane.     

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.     

A plant proton-pumping inorganic pyrophosphatase functionally complements the vacuolar ATPase transport activity and confers bafilomycin resistance in yeast

V-ATPases (vacuolar H+-ATPases) are a specific class of multi-subunit pumps that play an essential role in the generation of proton gradients across eukaryotic endomembranes. Another simpler proton pump that co-localizes with the V-ATPase occurs in plants and many protists: the single-subunit H+-PPase [H+-translocating PPase (inorganic pyrophosphatase)]. Little is known about the relative contribution of these two proteins to the acidification of intracellular compartments. In the present study, we show that the expression of a chimaeric derivative of the Arabidopsis thaliana H+-PPase AVP1, which is preferentially targeted to internal membranes of yeast, alleviates the phenotypes associated with V-ATPase deficiency. Phenotypic complementation was achieved both with a yeast strain with its V-ATPase specifically inhibited by bafilomycin A1 and with a vma1-null mutant lacking a catalytic V-ATPase subunit. Cell staining with vital fluorescent dyes showed that AVP1 recovered vacuole acidification and normalized the endocytic pathway of the vma mutant. Biochemical and immunochemical studies further demonstrated that a significant fraction of heterologous H+-PPase is located at the vacuolar membrane. These results raise the question of the occurrence of distinct proton pumps in certain single-membrane organelles, such as plant vacuoles, by proving yeast V-ATPase activity dispensability and the capability of H+-PPase to generate, by itself, physiologically suitable internal pH gradients. Also, they suggest new ways of engineering macrolide drug tolerance and outline an experimental system for testing alternative roles for fungal and animal V-ATPases, other than the mere acidification of subcellular organelles.