The Na+-dependent regulation of the internal pH in chick skeletal muscle cells. The role of the Na+/H+ exchange system and its dependence on internal pH.

The internal pH (pHi) of chick muscle cells is determined by the transmembrane Na+ gradient. Li+, but not K+, Rb+ or Cs+, can substitute for Na+ for regulating the internal pH of chick muscle cells. Pharmacological evidence using amiloride and amiloride analogs has shown that the Na+/H+ exchange system is the membrane mechanism that couples the pHi to the transmembrane Na+ gradient. The pHi dependence of the amiloride-sensitive Na+/H+ exchange mechanism was defined. Internal H+ interacts cooperatively with the Na+/H+ exchange system, in contrast with external H+, thus indicating an asymmetrical behaviour of this exchanger. The half-maximum effect for the activation by the internal H+ of the Na+ transporting activity of the amiloride-sensitive Na+/H+ exchange was observed at pH 7.4. The Hill coefficient of the H+ concentration dependence is higher than 3. Insulin was shown to have no effect on the pHi of chick muscle cells.     

A membrane potential-sensitive Na+-H+ exchange system in flagella isolated from sea urchin spermatozoa

Sea urchin sperm motility is activated by a Na+-dependent increase of internal pH. A flagellar preparation was used in the present study to investigate this ionic mechanism. Using 22Na and a pH electrode, the stoichiometry of Na+ uptake to H+ release in the isolated flagella was found to be 1.09 +/- 0.11. Reversing the Na+ gradient induced reacidification of the intraflagellar pH as measured by [14C]methylamine, while reversal of the H+ gradient resulted in a Na+ efflux. Furthermore, a parallel inhibition of both ionic movements was observed with increasing external [K+]. These results indicate that Na+ and H+ are coupled through an exchanger. Measurements of the membrane potential (psi) with [3H]tetraphenylphosphonium showed depolarization by K+, suggesting its inhibitory effect on the exchanger is through changes in psi. This is further supported by the following experiments. (a) Cs+ by itself had little effect on either psi or the Na+/H+ exchange, but in the presence of the ionophore valinomycin it depolarized psi and inhibited the exchange. (b) Tetraphenylphosphonium a highly permeant cation, at 2.5 mM caused depolarization and inhibition of the exchange, and these effects were reversible by repolarization of psi with valinomycin. The inhibitory effect of depolarization was not due to the electrogenicity of the exchange since both directions of the exchange were inhibited. It is proposed that the flagellar exchange is basically a electroneutral process but has a charged regulatory component (a gate or a conformational change) which confers the observed potential sensitivity.     

Modulation of the voltage-sensitive Na+/H+ exchange in sea urchin spermatozoa through membrane potential changes induced by the egg peptide speract

Sea urchin sperm motility can be activated by alkalinization of the internal pH, and previous studies have shown that the internal pH can be regulated by a voltage-sensitive Na+/H+ exchanger present in the flagellar plasma membrane. In this study, the effects of speract, a peptide purified from egg conditioned media, on the Na+/H+ exchange were investigated. Evidence presented indicates that speract activates K+ channels in the flagellar membrane and modulates the Na+/H+ exchange activity through resultant changes in membrane potential. In the presence of tetraphenylphosphonium, a lipophilic ion, or high external Na+, the isolated flagella were depolarized, and Na+/H+ exchanger was inhibited. Speract and valinomycin, a K+ ionophore, were able to reactivate 22Na+ uptake, H+ efflux, and alkalinization of intraflagellar pH under either of the depolarizing conditions. Membrane potential measurements using 3,3'-dipropylthiodicarbocyanide iodide indicated repolarization by either speract or valinomycin. The speract-induced voltage changes did not require Na+ but were sensitive to [K+]. Thus, speract induced a slight depolarization in Na+-free seawater with 10 mM K+ but a hyperpolarization with 2 mM K+. Further support for the activation of K+ channels in the flagella was the 2-5-fold stimulation of K+ efflux induced by speract as measured with a K+ electrode. The ionic selectivity of the speract-activated channel assessed by voltage measurements was K+ greater than Rb+ greater than Cs+. The half-maximally effective concentration of speract was about 0.2 nM. That the H+ and K+ efflux in response to peptide was receptor-mediated was confirmed by the use of speract or resact on intact sea urchin spermatozoa, where the peptides were found to stimulate K+ efflux and to reverse the tetraphenylphosphonium inhibition on H+ efflux only in the homologous spermatozoa. Modulation of the voltage-sensitive Na+/H+ exchange by egg peptides, therefore, appears to be indirect and is coupled through its action on membrane potential.     

The role of the Na+/H+ exchange system in the regulation of the internal pH in cultured cardiac cells

The Na+/H+ exchange system is not the major mechanism that regulates the internal pH value (pHi) of chick cardiac cells in culture under normal physiological conditions in the absence of carbonate. In cardiac cells in which the internal pH has been lowered to 6.6-6.7, the Na+/H+ exchanger becomes the major mechanism to bring back pHi to normal values (pHi = 7.3). The blockade of the Na+/H+ exchange activity with an active amiloride derivative, ethylisopropylamiloride, prevents internal pH recovery. The internal pH dependence of the Na+/H+ exchanger activity has been carefully studied. The [H+]i-dependence is very cooperative. For an external pH of 7.4, the system is nearly completely inactive at pHi 7.8 and nearly completely active at pHi 6.9-7.0 with half-maximum activation at pHi = 7.35. The increased activity of the Na+/H+ exchange system which follows the acidification of the internal medium produces an activation of the (Na+,K+)-ATPase.     

Internal GTP stimulates the speract receptor mediated voltage changes in sea urchin spermatozoa membrane vesicles

A voltage-sensitive Na+/H+ exchanger in the flagellar membrane is responsible for regulating the intracellular pH of the sea urchin spermatozoa. A previous study has shown that the egg peptide speract can modulate this Na+/H+ exchanger through its hyperpolarizing effect on the membrane potential. The effect of GTP on this speract receptor mediated process is investigated in this study. Plasma membrane vesicles with an outwardly directed K+ gradient were prepared from the isolated flagella by osmotic lysis. Vesicular membrane potential was monitored by a cationic probe, diS-C3-(5), and an anionic probe, diS-BA-C2-(3). Results show that the presence of internal GTP greatly stimulated the speract induced membrane hyperpolarization in this vesicle system. The analog GTP gamma S was not only active but could, by itself, induce partial hyperpolarization which was further enhanced by speract addition. Internal GDP was partially active in supporting the speract effect, whereas GDP beta S, cGMP, GMP, and ATP were all inactive. The ionic selectivity of the speract effect was investigated by increasing the external concentration of various cations. K+ and Rb+ abolished the hyperpolarization while Cs+ had no effect. These results indicate that internal GTP is involved in the coupling between the speract receptor and the membrane hyperpolarization, which is most likely due to the activation of K+ selective channels.     

Characterization of the Na+/H+ exchanger in human epidermoid carcinoma A431 vesicles

A previous report from this laboratory (Rothenberg et al., 1983a) demonstrated the presence of an Na+/H+ exchanger in human epidermoid carcinoma A431 cells. We now characterize surface-derived membrane vesicles from this cell line which contain a functional Na+/H+ exchanger. The Na+/H+ exchanger in A431 vesicles shares a number of characteristics in common with previously described Na+/H+ exchangers including the following: (1) Na+ uptake is stimulated by an outward-directed pH gradient and inhibited by an inward-directed pH gradient. (2) Na+ uptake is inhibited by amiloride and its analogs and their relative effectiveness is similar in vesicles and A431 cells. (3) The Na+/H+ exchanger uses Na+ or Li+ as a substrate but not K+ or Cs+. (4) H+ efflux is stimulated by an inward-directed Na+ gradient and inhibited by the amiloride analog 5-N-dimethylamiloride. The Na+/H+ exchanger in these membrane vesicles is activated allosterically by low intravesicular pH. The apparent pKa of the activating site is 6.4-6.6, characteristic of the NA+/H+ exchanger before activation by mitogens.     

Chemotactic factor-induced activation of Na+/H+ exchange in human neutrophils. II. Intracellular pH changes

The intracellular pH (pHi) changes resulting from chemotactic factor-induced activation of Na+/H+ exchange in isolated human neutrophils were characterized. Intracellular pH was measured from the equilibrium distribution of [14C]-5,5-dimethyloxazolidine-2,4-dione and from the fluorescence of 6-carboxyfluorescein. Exposure of cells to 0.1 microM N-formyl-methionyl-leucyl-phenylalanine (FMLP) in 140 mM Na+ medium at extracellular pH (pHo) 7.40 led to a rise in pHi along an exponential time course (rate coefficient approximately 0.55 min-1). By 10 min, a new steady-state pHi was reached (7.75-7.80) that was 0.55-0.60 units higher than the resting pHi of control cells (7.20-7.25). The initial rate of H+ efflux from the cells (approximately 15 meq/liter X min), calculated from the intrinsic intracellular buffering power of approximately 50 mM/pH, was comparable to the rate of net Na+ influx (approximately 17 meq/liter X min), an observation consistent with a 1:1 stoichiometry for Na+/H+ exchange. This counter-transport could be inhibited by amiloride (apparent Ki approximately 75 microM). When either the external ([Na+]o) or internal Na ([Na+]i) concentrations, pHo, or pHi were varied independently, the new steady-state [Na+]i and pHi values in FMLP-stimulated cells were those corresponding to a chemical equilibrium distribution of Na+ and H+ across the cell membrane. By analogy to other activated cells, these results indicate that an alkalinization of pHi in human neutrophils is mediated by a chemotactic factor-induced exchange of internal H+ for external Na+.     

Protons as substitutes for sodium and potassium in the sodium pump reaction

The role of protons as substitutes for Na+ and/or K+ in the sodium pump reaction was examined using inside-out membrane vesicles derived from human red cells. Na+-like effects of protons suggested previously (Blostein, R. (1985) J. Biol. Chem. 260, 829-833) were substantiated by the following observations: (i) in the absence of extravesicular (cytoplasmic) Na+, an increase in cytoplasmic [H+] increased both strophanthidin-sensitive ATP hydrolysis (nu) and the steady-state level of phosphoenzyme, EP, and (ii) as [H+] is increased, the Na+/ATP coupling ratio is decreased. K+-like effects of protons were evidenced in the following results: (i) an increase in nu, decrease in EP, and hence increase in EP turnover (nu/EP) occur when intravesicular (extracellular) [H+] is increased; (ii) an increase in the rate of Na+ influx into K+(Rb+)-free inside-out vesicles and (iii) a decrease in Rb+/ATP coupling occur when [H+] is increased. Direct evidence for H+ being translocated in place of cytoplasmic Na+ and extracellular K+ was obtained by monitoring pH changes using fluorescein isothiocyanate-dextran-filled vesicles derived from 4',4-diisothiocyano-2',2-stilbene disulfonate-treated cells. With the initial pHi = pHo = pH 6.2, a strophanthidin-sensitive decrease in pHi was observed following addition of ATP provided the vesicles contained K+. This pH gradient was abolished following addition of Na+. With alkali cation-free inside-out vesicles, a strophanthidin-sensitive increase in pH was observed upon addition of both ATP and Na+. The foregoing changes in pHi were not affected by the addition of tetrabutylammonium to dissipate any membrane potential and were not observed at pH 6.8. These ATP-dependent cardiac glycoside-sensitive proton movements indicate Na,K-ATPase mediated Na+/H+ exchange in the absence of extracellular K+ as well as H+/K+ exchange in the absence of cytoplasmic Na+.     

Proton pathways in rat renal brush-border and basolateral membranes

The quenching of acridine orange fluorescence was used to monitor the formation and dissipation of pH gradients in brush-border and basolateral membrane vesicles isolated from rat kidney cortex. The fluorescence changes of acridine orange were shown to be sensitive exclusively to transmembrane delta pH and not to membrane potential difference. In brush-border membrane vesicles, an Na+ (Li+)-H+ exchange was confirmed. At physiological Na+ concentrations, 40-70% of Na+-H+ exchange was mediated by the electroneutral Na+-H+ antiporter; the remainder consisted of Na+ and H+ movements through parallel conductive pathways. Both modes of Na+-H+ exchange were saturable, with half-maximal rates at about 13 and 24 mM Na+, respectively. Besides a Na+ gradient, a K+ gradient was also able to produce an intravesicular acidification, demonstrating conductance pathways for H+ and K+ in brush-border membranes. Experiments with Cl- or SO2-4 gradients failed to demonstrate measurable Cl--OH- or SO2-4-OH- exchange by an electroneutral antiporter in brush-border membrane vesicles; only Cl- conductance was found. In basolateral membrane vesicles, neither Na+(Li+)-H+ exchange nor Na+ or K+ conductances were found. However, in the presence of valinomycin-induced K+ diffusion potential, H+ conductance of basolateral membranes was demonstrated, which was unaffected by ethoxzolamide and 4,4'-diisothiocyanostilbene-2,2-disulfonic acid. A Cl- conductance of the membranes was also found, but antiporter-mediated electroneutral Cl--OH- or SO2-4-OH- exchange could not be detected by the dye method. The restriction of the electroneutral Na+-H+ exchanger to the luminal membrane can explain net secretion of protons in the mammalian proximal tubule which leads to the reabsorption of bicarbonate.     

High affinity binding of amiloride analogs at an internal site in renal microvillus membrane vesicles.

Amiloride analogs with hydrophobic substitutions on the 5-amino nitrogen atom are relatively high affinity inhibitors of the plasma membrane Na(+)-H+ exchanger. We demonstrated that a high affinity-binding site for [3H]5-(N-methyl-N-isobutyl)amiloride ([3H]MIA) (Kd = 6.3 nM, Bmax = 1.2 pmol/mg of protein) is present in microvillus membrane vesicles but not in basolateral membrane vesicles isolated from rabbit renal cortex, in accord with the known membrane localization of the Na(+)-H+ exchanger in this tissue. The rank order potency for inhibition of microvillus membrane [3H]MIA binding by amiloride analogs was: MIA (I50 approximately 10 nM) greater than amiloride (I50 approximately 200 nM) greater than benzamil (I50 approximately 1200 nM). This correlated with a qualitatively similar rank order potency for inhibition of Na(+)-H+ exchange: MIA (I50 approximately 4 microM) greater than amiloride (I50 approximately 15 microM) greater than benzamil (I50 approximately 100 microM), but did not correlate with the rank order potency for inhibition of the organic cation-H+ exchanger in microvillus membrane vesicles: MIA approximately benzamil (I50 approximately 0.5 microM) greater than amiloride (I50 approximately 10 microM). However, tetraphenylammonium, an inhibitor of organic cation-H+ exchange, inhibited the rate of [3H]MIA binding without an effect on equilibrium [3H]MIA binding; the dissociation of bound [3H]MIA was inhibited by preloading the membrane vesicles with tetraphenylammonium. These findings indicated that high affinity [3H]MIA binding to renal microvillus membrane vesicles takes place at an internal site to which access is rate-limited by the tetraphenylammonium-sensitive organic cation transporter. Equilibrium [3H]MIA binding was inhibited by H+ but was unaffected by concentrations of Na+ or Li+ that saturate the external transport site of the Na(+)-H+ exchanger. Binding of MIA to its high affinity binding site had no effect on the rate of Na(+)-H+ exchange. This study suggests that the renal Na(+)-H+ exchanger has a high affinity internal binding site for amiloride analogs that is distinct from the external amiloride inhibitory site.     

Proton dependence of the partial reactions of the sodium-proton exchanger in renal brush border membranes.

The pre-steady state time dependence of Na+ accumulation by the Na(+)-H+ exchanger in renal brush border membrane vesicles was investigated at 0 degree C by a manual mixing technique using amiloride to quench the reaction. Dilution of acid-loaded (pHi 5.7) vesicles into an alkaline medium (pHo 7.7) containing 1 mM 22Na+ produced a time course of amiloride-sensitive Na+ uptake that consisted of three distinct phases: 1) a lag, 2) a monoexponential "burst," and 3) a linear or steady state phase. Experiments testing for the presence of 22Na+ backflux, residual Na+ binding to the membrane, and hysteresis were negative, lending support to the hypothesis that the burst phase corresponds to Na+ translocation during the initial turnover of Na(+)-H+ exchanger. Lowering the internal pH increased the amount of na+ uptake in each of the phases without affecting the apparent burst rate, whereas lowering the external pH inhibited Na+ uptake while increasing the duration of the lag phase. The pattern of inhibition produced by external H+ was of the simple competitive type, indicating that Na+ and H+ share a common binding site. Steady state Na+ uptake showed a sigmoidal dependence on internal pH (Hill coefficient = 1.67), consistent with the presence of an internal allosteric H+ activation site. Alkaline loading conditions (pHi 7.7), which favor desaturation of the internal H+ binding sites, completely abolished Na+ uptake in the steady state. In contrast, Na+ accumulation during the burst phase was reduced to 25% of an acid-loaded (pHi 5.7) control. The persistence of the burst phase and the disappearance of steady state Na+ uptake under alkaline loading conditions suggest that recycling of the H(+)-loaded exchanger is a late event in the transport cycle that follows Na+ translocation (ping-pong mechanism) and controls the steady state rate of Na+ accumulation. Activation of the recycling step involves sequential binding of H+ to the allosteric and transport sites, thus accounting for the cooperative dependence of steady state Na+ uptake on the internal [H+].     

Intracellular acidification-induced alkali metal cation/H+ exchange in human neutrophils

Pretreatment of isolated human neutrophils (resting pHi congruent to 7.25 at pHo 7.40) with 30 mM NH4Cl for 30 min leads to an intracellular acidification (pHi congruen to 6.60) when the NH4Cl prepulse is removed. Thereafter, in 140 mM Na+ medium, pHi recovers exponentially with time (initial rate, approximately 0.12 pH/min) to reach the normal resting pHi by approximately 20 min, a process that is accomplished mainly, if not exclusively, though an exchange of internal H+ for external Na+. This Na+/H+ countertransport is stimulated by external Na+ (Km congruent to 21 mM) and by external Li+ (Km congruent to 14 mM), though the maximal transport rate for Na+ is about twice that for Li+. Both Na+ and Li+ compete as substrates for the same translocation sites on the exchange carrier. Other alkali metal cations, such as K+, Rb+, or Cs+, do not promote pHi recovery, owing to an apparent lack of affinity for the carrier. The exchange system is unaffected by ouabain or furosemide, but can be competitively inhibited by the diuretic amiloride (Ki congruent to 8 microM). The influx of Na+ or Li+ is accompanied by an equivalent counter-reflux of H+, indicating a 1:1 stoichiometry for the exchange reaction, a finding consistent with the lack of voltage sensitivity (i.e., electroneutrality) of pHi recovery. These studies indicate that the predominant mechanism in human neutrophils for pHi regulation after intracellular acidification is an amiloride-sensitive alkali metal cation/H+ exchange that shares a number of important features with similar recovery processes in a variety of other mammalian cell types.     

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.     

Role of Na+/H+ exchange in the control of intracellular pH and cell membrane conductances in frog skin epithelium

Ion-sensitive microelectrodes and current-voltage analysis were used to study intracellular pH (pHi) regulation and its effects on ionic conductances in the isolated epithelium of frog skin. We show that pHi recovery after an acid load is dependent on the operation of an amiloride-sensitive Na+/H+ exchanger localized at the basolateral cell membranes. The antiporter is not quiescent at physiological pHi (7.1-7.4) and, thus, contributes to the maintenance of steady state pHi. Moreover, intracellular sodium ion activity is also controlled in part by Na+ uptake via the exchanger. Intracellular acidification decreased transepithelial Na+ transport rate, apical Na+ permeability (PNa) and Na+ and K+ conductances. The recovery of these transport parameters after the removal of the acid load was found to be dependent on pHi regulation via Na+/H+ exchange. Conversely, variations in Na+ transport were accompanied by changes in pHi. Inhibition of Na+/K+ ATPase by ouabain produced covariant decreases in pHi and PNa, whereas increases in Na+ transport, occurring spontaneously or after aldosterone treatment, were highly correlated with intracellular alkalinization. We conclude that cytoplasmic H+ activity is regulated by a basolateral Na+/H+ exchanger and that transcellular coupling of ion flows at opposing cell membranes can be modulated by the pHi-regulating mechanism.     

Independent elevation of cytosolic [Ca2+] and pH of mammalian sperm by voltage-dependent and pH-sensitive mechanisms

Previous work (Babcock, D. F., Rufo, G. A., and Lardy, H.A. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 1327-1331) established that increased cytosolic pH (pHi) promotes metabolic and swimming activity of bull sperm and that intracellular alkalinization results from elevated extracellular K+, presumably as a consequence of membrane depolarization. The present studies show that a persistent but reversible increase in [Ca2+]i accompanies the increase in pHi that similarly results from treatment of ram sperm with elevated [K+] in alkaline media. Because comparable increases in pHi occur in the presence or absence of external Ca2+ and because [Ca2+]i is unaltered by imposed changes in pHi alone, [Ca2+]i and pHi apparently are neither directly linked by transmembrane Ca2+/H+ exchange nor indirectly linked through Na+/H+ and Na+/Ca2+ exchange under these conditions. Instead, inhibition of K+-induced increases in [Ca2+]i (but not of increases in pHi) by prenylamine, diltiazem, nifedipine, or verapamil (C1/2 = 6, 20, 30, and 60 microM, respectively) indicates that voltage-dependent Ca2+ channels, distinct from previously described voltage-dependent effectors of pHi, operate in mammalian sperm to control [Ca2+]i. Treatment with Cs+ plus valinomycin (as an alternative method of membrane depolarization) increases pHi much more effectively than it increases [Ca2+]i, and thus also partially supports this contention. In contrast to an apparent insensitivity to pHi, K+-dependent increases in [Ca2+]i are promoted reversibly by elevation of pHo, probably reflecting local surface charge effects on channel activity (as suggested by patch-clamp studies in other systems). A selective increase in membrane permeability to Ca2+ that is induced by 12 mM NaF under nondepolarizing conditions is not a consequence of cellular aggregation, but is attenuated by the chelator deferoxamine, suggesting that GTP-binding protein additionally may couple sperm Ca2+ channels to surface receptors and promote channel opening during sperm capacitation, presumably in response to agonists produced within the mammalian female reproductive tract.     

Inactivation of the renal microvillus membrane Na+-H+ exchanger by histidine-specific reagents

We examined the effect of histidine-specific reagents on the transport activity of the Na+-H+ exchanger in microvillus (brush-border) membrane vesicles isolated from the rabbit renal cortex. Rose bengal-catalyzed photo-oxidation caused irreversible inhibition of the rate of Na+-H+ exchange but also caused significant loss of vesicle integrity. Treatment of the membrane vesicles with diethylpyrocarbonate caused inactivation of Na+-H+ exchange that could not be attributed to vesicle disruption or collapse of transmembrane H+ gradients. Inactivation of Na+-H+ exchange by diethylpyrocarbonate followed pseudo-first order kinetics to below 10% residual activity, could be reversed by hydroxylamine, was reflected by a decreased Vmax with no change in the Km for Na+, was dependent on external pH but not internal pH, was blocked by amiloride, and was enhanced by Na+. These data are consistent with the hypothesis that a diethylpyrocarbonate-sensitive imidazolium residue is the titratable group found in kinetic studies to bind H+ at the external transport site of the Na+-H+ exchanger.     

The Na+/H+ exchange system in glial cell lines. Properties and activation by an hyperosmotic shock

The properties of the Na+/H+ exchange system in the glial cell lines C6 and NN were studied from 22Na+ uptake experiments and measurements of the internal pH (pHi) using intracellularly trapped biscarboxyethyl-carboxyfluorescein. In both cell types, the Na+/H+ exchanger is the major mechanism by which cells recover their pHi after an intracellular acidification. The exchanger is inhibited by amiloride and its derivatives. The pharmacological profile (ethylisopropylamiloride greater than amiloride greater than benzamil) is identical for the two cell lines. Both Na+ and Li+ can be exchanged for H+. Increasing the external pH increases the activity of the exchanger in the two cell lines. In NN cells the external pH dependence of the exchanger is independent of the pHi. In contrast, in C6 cells, changing the pHi value from 7.0 to 6.5 produces a pH shift of 0.6 pH units in the external pH dependence of the exchanger in the acidic range. Decreasing pHi activates the Na+/H+ exchanger in both cell lines. Increasing the osmolarity of the external medium with mannitol produces an activation of the exchanger in C6 cells, which leads to a cell alkalinization. Mannitol action on 22Na+ uptake and the pHi were not observed in the presence of amiloride derivatives. Mannitol produces a modification of the properties of interaction of the antiport with both internal and external H+. It shifts the pHi dependence of the system to the alkaline range and the external pH (pHo) dependence to the acidic range. It also suppresses the interdependence of pHi and pHo controls of the exchanger's activity. NN cells that possess an Na+/H+ exchange system with different properties do not respond to mannitol by an increased activity of the Na+/H+ exchanger. The action of mannitol on C6 cells is unlikely to be mediated by an activation of protein kinase C.     

Active amino acid transport in plasma membrane vesicles from Simian virus 40-transformed mouse fibroblasts. Characteristics of electrochemical Na+ gradient-stimulated uptake.

Selectively permeable membrane vesicles isolated from Simian virus 40-transformed mouse fibroblasts catalyzed Na+ gradient-coupled active transport of several neutral amino acids dissociated from intracellular metabolism. Na+-stimulated alanine transport activity accompanied plasma membrane material during centrifugation in discontinuous dextran 110 gradients. Carrier-mediated transport into the vesicle was demonstrated. When Na+ was equilibrated across the membrane, countertransport stimulation of L-[3H]alanine uptake occurred in the presence of accumulated unlabeled L-alanine, 2-aminoisobutyric acid, or L-methionine. Competitive interactions among neutral amino acids, pH profiles, and apparent Km values for Na+ gradient-stimulated transport into vesicles were similar to those previously described for amino acid uptake in Ehrlich ascites cells, which suggests that the transport activity assayed in vesicles is a component of the corresponding cellular uptake process. Both the initial rate and quasi-steady state of uptake were stimulated as a function of a Na+ gradient (external Na+ greater than internal Na+) applied artificially across the membrane and were independent of endogenous (Na+ + K+)-ATPase activity. Stimulation by Na+ was decreased when the Na+ gradient was dissipated by monensin, gramicidin D or Na+ preincubation. Na+ decreased the apparent Km for alanine, 2-aminoisobutyric acid, and glutamine transport. Na+ gradient-stimulated amino acid transport was electrogenic, stimulated by conditions expected to generate an interior-negative membrane potential, such as the presence of the permeant anions NO3- and SCN-. Na+-stimulated L-alanine transport was also stimulated by an electrogenic potassium diffusion potential (K+ internal greater than K+ external) catalyzed by valinomycin; this stimulation was blocked by nigericin. These observations provide support for a mechanism of active neutral amino acid transport via the "A system" of the plasma membrane in which both a Na+ gradient and membrane potential contribute to the total driving force.     

Delta pH, H+ diffusion potentials, and Mg2+ ATPase in neurosecretory vesicles isolated from bovine neurohypophyses

The proton gradient (delta pH) and electrical potential (delta psi) across the neurosecretory vesicles were measured using the optical probes 9-aminoacridine and Oxanol VI, respectively. The addition of neurosecretory vesicles to 9-aminoacridine resulted in a rapid quenching of the dye fluorescence which was reversed when the delta pH was collapsed with ammonium chloride or K+ in the presence of nigericin. From fluorescence quenching data and the intravesicular volume, delta pH across the membrane was calculated. Mg2+ ATP caused a marked carbonyl cyanide p-trifluoromethoxyphenylhydrazone-sensitive change in the membrane potential measured using Oxanol VI (plus 100 mV inside positive), presumably due to H+ translocation across the neurosecretory vesicle membrane. Imposition of this membrane potential was responsible for the lysis of vesicles in the presence of permeant anions. The effectiveness of these anions to support lysis reflected the relative permeability of the anion which followed the order acetate greater than I- greater than Cl greater than F- greater than SO4- = isethionate = methyl sulfate. These data showed that the neurosecretory vesicles possess a membrane H+-translocating system and prompted the study of Mg2+-dependent ATPase activities in the vesicle fractions. In intact vesicles a Mg2+ ATPase appeared to be coupled to electrogenic proton translocation, since the enzyme activity was enhanced by uncoupling the electrical potential, using proton ionophores. Inhibition of this enzyme with dicyclohexylcarbodiimide also inhibited the carbonyl cyanide p-trifluoromethoxyphenylhydrazone-sensitive delta psi across the vesicle membrane caused by H+ translocation. A second Mg2+ ATPase was also found on the vesicle membranes which is sensitive to vanadate. Complete inhibition of this enzyme with vanadate had little effect on the proton ionophore-uncoupled ATPase activity or on the Mg2+ ATP-induced membrane potential change.     

Intravesicular pH changes in submitochondrial particles induced by monovalent cations: relationship to the Na+/H+ and K+/H+ antiporters

The fluorescence of internalized fluorescein isothiocyanate dextran has been used to monitor the intravesicular pH of submitochondrial particles (SMP). Respiring SMP maintain a steady-state delta pH (interior acid) that results from the inwardly directed H+ flux of respiration and an opposing passive H+ leak. Addition of K+, Na+, or Li+ to SMP results in a shift to a more alkaline interior pH (pHi) in both respiring and nonrespiring SMP. The K+-dependent change in pHi, like the K+/H+ antiport in intact mitochondria, is inhibited by quinine and by dicyclohexylcarbodiimide. The Na+-dependent reaction is only partially inhibited by these reagents. Both the Na+- and the K+-dependent pH changes are sensitive to amiloride derivatives. The Km for both Na+ and K+ is near 20 mM whereas that for Li+ is closer to 10 mM. The K+/H+ exchange reaction is only slightly inhibited by added Mg2+, but abolished when A23187 is added with Mg2+. The passive exchange is optimal at pHi 6.5 with either Na+ or K+, and cannot be detected above pHi of 7.2. Both the Na+/H+ and the K+/H+ exchange reactions are optimal at an external pH of 7.8 in respiring SMP (pHi 7.1). Valinomycin stimulates the K+-dependent pH change in nonrespiring SMP, as does nigericin. It is concluded that SMP show K+/H+ antiport activity with properties distinct from those of Na+/H+ antiport. However, the properties of the K+/H+ exchange do not correspond in all respects to those of the antiport in intact mitochondria. Donnan equilibria and parallel uniport pathways for H+ and cations appear to contribute to cation-dependent pH changes in SMP.