Lysophosphatidylcholine stimulates ATP dependent proton accumulation in isolated oat root plasma membrane vesicles

Lysophosphatidylcholine at concentrations of 30 micromolar stimulated the rate of MgATP-dependent H⁺-accumulation in oat (Avena sativa L. cv Rhiannon) root plasma membrane vesicles about 85% while the passive permeability of H⁺ was unchanged. Activation was dependent on chain length, degree of saturation, and head group of the lysophospholipid. A H⁺-ATPase assay was developed that allowed the simultaneous measurement of proton pumping and ATPase activity in the same sample. ATP hydrolysis was also stimulated by lysophospholipids and showed the same lipid specificity, but stimulation was only about 25% at 30 micromolar. At higher concentrations of lysophosphatidylcholine the ATPase activity in a latency-free system could be stimulated about 150%. The enzymic properties of proton pumping and ATP hydrolysis were otherwise identical with respect to vanadate sensitivity, K_m for ATP and pH optimum. The stimulatory effect of lysophospholipids suggests that these compounds could be part of the regulatory system for plant plasma membrane H⁺-ATPase activity in vivo.     

Soil humic substances affect transport properties of tonoplast vesicles isolated from oat roots

The effect of a low molecular size (<5 KDa) humic fraction, essentially fulvic acids, on microsomal and tonoplast ion-stimulated ATPase activity was studied. After 20 min of pre-incubation with microsomal vesicles from oat roots, humic substances at organic C concentration of up to 0.5 μg cm^-3 increased KCl-stimulated ATPase activity, while they inhibited enzyme activity at higher concentrations. Cl^--stimulated ATPase activity of tightly sealed tonoplast-enriched vesicles was similarly affected by <5 KDa humic substances. This behaviour was not observed when gramicidin D was added to the assay medium. Proton transport by vesicles incubated up to 5 min with <5 KDa humic molecules was affected in a concentration-dependent manner, strongly resembling that observed for ATP hydrolysis, whereas it was severely reduced when the assay conditions were close to those used for measuring ATP hydrolysis (20 min pre-incubation of vesicles with humic substances). The transmembrane electrical potential was negatively affected, irrespective of the concentration of humic molecules. Furthermore, a 15-min pre-incubation strongly reduced the formation of a potential gradient. The size and concentrations of humic substances employed make an interaction with the vacuolar membrane of root cells plausible. The results show that the main target of humic molecules is the electrical membrane potential and suggest a possible way of interference of these naturally occurring substances with the biochemical mechanisms involved in plant mineral nutrition.     

The possible role of redox-associated protons in growth of plant cells

The protons excreted by plant cells may arise by two different mechanisms: (1) by the action of the plasma membrane H⁺-ATPase and (2) by plasma membrane redox reactions. The exact proportion from each source is not known, but the plasma membrane H⁺-ATPase is, by far, the major contributor to proton efflux. There is still some question of whether the redox-associated protons produced by NADH oxidation on the inner side of the plasma membrane traverse the membrane in a 1 : 1 relationship with electrons generated in the redox reactions. Membrane depolarization observed in the presence of ferricyanide reduction by plasma membranes of whole cells or tissues or the lag period between ferricyanide reduction and medium acidification argue that only scalar protons may be involved. The other major argument against tight coupling between protons and electrons involves the concept of strong charge compensation. When ferricyanide is reduced to ferrocyanide on the outside of cells or tissues, an extra negative charge arises, which is compensated for by the release of H⁺ or K⁺, so that the total ratio of increased H⁺ plus K⁺ equals the electrons transferred by transmembrane electron transport. These are strong arguments against a tight coupling between electrons and protons excreted by the plasma membrane. On the other hand, there is no question that inhibitor studies provide evidence for two mechanisms of proton generation by plasma membranes. When the H⁺-ATPase activity is totally inhibited, the addition of ferricyanide induces a burst of extra proton excretion, orvice versa, when plasma membrane redox reactions are inhibited, the H⁺-ATPase can function normally. Since plasma membrane redox reactions and associated H⁺ excretion are related to growth, it is possible that in plants the ATPase-generated protons have a different function from redox-associated protons. The H⁺-ATPase-generated protons have been considered for many years to be necessary for cell wall expansion, allowing elongation to take place. A special function of the redox-generated protons may be in initiating proliferative cell growth, based on the presence of a hormone-stimulated NADH oxidase in membranes of soybean hypocotyls and stimulation of root growth by low concentrations of oxidants. Here we propose that this NADH oxidase and the redox protons released by its action control growth. The mechanism for this may be the evolution of protons into a special membrane domain, from which a signal to initiate cell proliferation may originate, independent of the action of the H⁺-ATPase-generated protons. It is also possible that both expansion and proliferative growth are controlled by redox-generated protons.     

H-pumping driven by the plasma membrane ATPase in membrane vesicles from radish: stimulation by fusicoccin

The effect of fusicoccin on Mg:ATP-dependent H⁺-pumping in microsomal vesicles from 24-hour-old radish (Raphanus sativus L.) seedlings was investigated by measuring the initial rate of decrease in the absorbance of the ΔpH probe acridine orange. Fusicoccin stimulated Mg:ATP-dependent H⁺-pumping when the pH of the assay medium was in the range 7.0 to 7.6 while no effect of fusicoccin was detected between pH 6.6 and pH 6.0. Both basal and fusicoccin-stimulated H⁺-pumping were completely inhibited by vanadate and almost unaffected by nitrate. Fusicoccin did not change membrane permeability to protons and fusicoccin-induced stimulation of Mg:ATP-dependent H⁺-pumping was not affected by changes in the buffer capacity of the incubation medium. Deacetylfusicoccin stimulated H⁺-pumping as much as fusicoccin, while the physiologically inactive derivative 8-oxo-9-epideacetylfusicoccin did not. Stimulation of H⁺-pumping was saturated by 100 nanomolar fusicoccin. These data indicate that fusicoccin activates the plasma membrane H⁺-ATPase by acting at the membrane level independently of the involvement of other cell components. The percent stimulation by fusicoccin was the same at all ATP concentrations tested (0.5-5.0 millimolar), thus suggesting that with fusicoccin there is an increase in V_max of the plasma membrane H⁺-ATPase rather than a decrease in its apparent K_m for Mg:ATP.     

An ATP-driven proton pump in brush-border membranes from rat renal cortex

Summary The rate of ATP hydrolysis in ATP-preloaded plasma membrane vesicles derived from the luminal membrane of renal cortical tubules, and the rate of H⁺ secretion out of the same vesicles were investigated. Both were inhibited at low temperature, by the action of filipin, an antibiotic that complexes with cholesterol in plasma membranes, and by the action of blockers of mitochondrial F_o hydrogen channels, dicyclohexylcarbodiimide and Dio-9. Valinomycin in the presence of K⁺ showed a stimulatory effect, the protonophor carbonyl-cyanid-p-trifluormethoxy-phenylhydrazone stimulated the intravesicular ATP hydrolysis and apparently abolished acidification of the extravesccular medium. Lowering of the pH of the extravesicular medium retarded ATP hydrolysis, while readjustment of extra- and intravesicular pH accelerated ATP hydrolysis again. These findings strongly support the assumption that an ATP-driven proton pump is located in the luminal membrane of renal cortical tubules.     

Some Properties of a Functional Reconstituted Plasmalemma H-ATPase Activated by Fusicoccin

Fusicoccin was shown to stimulate the ATP-driven, intravesicular acidification of liposomes reconstituted with crude fusicoccin receptors and the H⁺-translocating ATPase, both solubilized from maize (Zea mays L.) plasma membrane. The present paper reports optimal conditions for dual reconstitution and fusicoccin activation as well as the biochemical characterization of the effect of fusicoccin on this system. Fusicoccin stimulation of proton pumping was dependent on pH and fusicoccin concentration. Its specificity was demonstrated by the positive effect of two cotylenins that have a high affinity for fusicoccin receptors and by the negative response to 7,9-epideacetylfusicoccin, an inactive fusicoccin derivative. Kinetic measurements at different ATP concentrations showed that fusicoccin increases the V_max of the enzyme. Fusicoccin stimulation of maize H⁺-ATPase was also maintained when receptors from maize were substituted by those from spinach (Spinacia oleracea L.).     

Loss of membrane cholesterol influences lysosomal permeability to potassium ions and protons

Cholesterol is an essential component of lysosomal membranes. In this study, we investigated the effects of membrane cholesterol on the permeability of rat liver lysosomes to K⁺ and H⁺, and the organelle stability. Through the measurements of lysosomal β-hexosaminidase free activity, membrane potential, membrane fluidity, intra-lysosomal pH, and lysosomal proton leakage, we established that methyl-β-cyclodextrin (MβCD)-produced loss of membrane cholesterol could increase the lysosomal permeability to both potassium ions and protons, and fluidize the lysosomal membranes. As a result, potassium ions entered the lysosomes through K⁺/H⁺ exchange, which produced osmotic imbalance across the membranes and osmotically destabilized the lysosomes. In addition, treatment of the lysosomes with MβCD caused leakage of the lysosomal protons and raised the intra-lysosomal pH. The results indicate that membrane cholesterol plays important roles in the maintenance of the lysosomal limited permeability to K⁺ and H⁺. Loss of this membrane sterol is critical for the organelle acidification and stability.     

Adenine nucleotide translocase as a site of regulation by ADP of the rat liver mitochondria permeability to H+ and K+ lons

In the presence of oligomycin ADP inhibits the osmotic swelling of the nonenergized rat liver mitochondria in the NH₄NO₃ medium. With the energized mitochondria ADP enhances contraction of the mitochondria swollen in the NH₄NO₃ medium. Carboxyatractyloside and atractyloside abolish or prevent the effects of ADP. The direct measurements of the proton conductance of rat liver mitochondria shows that the inhibitory action of ADP + oligomycin on the H⁺ permeability does not depend on the energization of mitochondria. In these experiments the local anesthetic nupercaine and ADP additively inhibit the inner membrane conductance for protons, but carboxyatractyloside abolishes only the effect of ADP. In the presence of oligomycin ADP also inhibits the osmotic swelling of the nonenergized liver mitochondria in the KNO₃ medium, and the energy-dependent swelling of rat liver mitochondria in the medium with K⁺ ions and P_i. The inhibition by ADP of the membrane passive permeability for K⁺ is also sensitive to carboxyatractyloside. It is concluded that rat liver mitochondria possess an ADP-regulated channel for H⁺ and K⁺. The properties of this pathway for protons and potassium ions favor the idea that ADP regulates the mitochondrial permeability via adenine nucleotide translocase. It is assumed that the adenine nucleotides carrier should operate according to the “gated pore” mechanism.     

Amiloride sensitivity of proton-conductive pathways in gastric and intestinal apical membrane vesicles

Summary Passive proton permeability of gastrointestinal apical membrane vesicles was determined. The nature of the pathways for proton permeation was investigated using amiloride. The rate of proton permeation (k _H ⁺ was determined by addition of vesicles (pH _i = 6.5) to a pH 8.0 solution containing acridine orange. The rate of recovery of acridine orange fluorescence after quenching by the acidic vesicles ranged from 4 × 10^–3 (gastric parietal cell stimulation-associated vesicles; SAV) and 5 × 10^–3 (duodenal brush-border membrane vesicles; dBBMV) to 11 × 10+^–3 sec^–1 (ileal BBMV; iBBMV). Amiloride, 0.03 and 0.1 mm, significantly reduced the rate of proton permeation in dBBMV and iBBMV, but not gastric SAV. The decreases in k _H ⁺ were proportionately greater in iBBMV as compared with dBBMV. The presence of Na⁺/H⁺ exchange was demonstrated in both dBBMV and iBBMV by proton-driven (pH _i < pH _o ) ²²Na⁺ uptake. Evidence was also sought for the conductive nature of pathways for proton permeation. Intravesicular acidification, again determined by quenching of acridine orange fluorescence, was observed during imposition of K⁺-diffusion potential ([K⁺] _i [K⁺ _o ). In dBBMV and iBBMV, intravesicular acidification was enhanced in the presence of the K⁺-ionophore valinomycin, indicating that the native K⁺ permeability is rate limiting. In the presence of valinomycin, the K⁺-diffusion potential drove BBMV intravesicular acidification to levels close to the electrochemical potential. In gastric SAV, acidification was not limited by the K⁺ permeability. Valinomycin was without effect, but the K⁺/H⁺ ionophore nigericin enhanced acidification in gastric SAV, illustrating the low proton permeability of these membranes. Amiloride, 0.03–1 mm, resulted in concentration-dependent reductions of K⁺-diffusion potential-driven acidification in dBBMV and iBBMV but not in gastric SAV. These data demonstrate that proton permeation in the three membrane types is rheogenic. The sensitivity of the proton-conductive pathways in intestinal BBMV to high concentrations of amiloride correlated with the presence of the Na⁺/H⁺ antiport and indicates that this transmembrane protein may represent a pathway for proton permeation.We thank Ruth Briggs for assistance with the Na/H exchange experiments. This work was supported by a grant from the Medical Research Council (G8418056CA).     

Functional analysis of amino acids of the Na+/H+ exchanger that are important for proton translocation

The Na⁺/H⁺ exchanger is an integral membrane protein found in the plasma membrane of eukaryotic and prokaryotic cells. In eukaryotes it functions to exchange one proton for a sodium ion. In mammals it removes intracellular protons while in plants and fungal cells the plasma membrane form removes intracellular sodium in exchange for extracellular protons. In this study we used the Na⁺/H⁺ exchanger of Schizosaccharomyces pombe (Sod2) as a model system to study amino acids critical for activity of the protein. Twelve mutant forms of the Na⁺/H⁺ exchanger were examined for their ability to translocate protons as assessed by a cytosensor microphysiometer. Mutation of the amino acid Histidine 367 resulted in defective proton translocation. The acidic residues Asp145, Asp178, Asp266 and Asp267 were important in the proton translocation activity of the Na⁺/H⁺ exchanger. Mutation of amino acids His98, His233 and Asp241 did not significantly impair proton translocation by the Na⁺/H⁺ exchanger. These results confirm that polar amino acids are important in proton flux activity of Na⁺/H⁺ exchangers.     

Mechanism of cAMP-induced H+-efflux ofDictyostelium cells: a role for fatty acids

AggregatingDictyostelium cells release protons when stimulated with cAMP. To find out whether the protons are generated by acidic vesicles or in the cytosol, we permeabilized the cells and found that this did not alter the cAMP-response. Proton efflux in intact cells was inhibited by preincubation with the V-type H⁺ ATPase inhibitor concanamycin A and with the plasma membrane H⁺ ATPase blocker miconazole. Surprisingly, miconazole also inhibited efflux in permeabilized cells, indicating that this type of H⁺ ATPase is present on intracellular vesicles as well. Vesicular acidification was inhibited by miconazole and by concanamycin A, suggesting that the acidic vesicles contain both V-type and P-type H⁺ ATPases. Moreover, concanamycin A and miconazole acted in concert, both in intact cells and in vesicles. The mechanism of cAMP-induced Ca²⁺-fluxes involves phospholipase A₂ activity. Fatty acids circumvent the plasma membrane and stimulate vesicular Ca²⁺-efflux. Here we show that arachidonic acid elicited H⁺-efflux not only from intact cells but also from acidic vesicles. The target of regulation by arachidonic acid seemed to be the vesicular Ca²⁺-relase channel.     

Modulation of NO 3 - uptake by water-extractable humic substances: involvement of root plasma membrane H+ATPase

The effect of a water extractable humic substances fraction (WEHS) on nitrate uptake and plasma membrane (pm) H⁺-ATPase activity of maize roots was investigated. Four days old maize root seedlings were exposed for 4 to 24 h to a nutrient solution containing 200 μ M nitrate in the absence or presence of 5 mg org. C { L ^-1 WEHS. Plants exposed to nitrate developed a higher capacity to absorb the anion (induction): the net uptake rate progressively increased up to 12 h of contact with the solution; thereafter, a decline was observed. When WEHS was present together with nitrate in the nutrient solution, the induction of nitrate uptake was evident and maximal already 4 h after starting the treatment. The rate of net nitrate uptake decreased only slightly during the remaining period (4-24 h). Stimulation of net nitrate uptake rate was also observed when WEHS was added to a nitrogen- or nitrate-free nutrient solution or to a 5 mM CaSO₄ solution. The activity of pmH⁺-ATPase raised upon exposure of the roots to nitrate with the same pattern observed for nitrate uptake. The contemporary presence of nitrate and WEHS caused a further stimulation of the pmH⁺-ATPase activity after 4 h treatment. An increase in the enzyme activity was also observed when plants were treated for 4 h in the presence of WEHS in CaSO₄, nitrogen- or nitrate-free solutions. However, when nitrate was present the enhancement was even greater. Results support the idea that the plasma membrane proton pump might be one of the primary targets of the action of humic substances on plant nutrient acquisition. A role of WEHS in the modulation of nitrate uptake via an interaction with the pm H⁺-ATPase is also discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effect of nickel on certain physiological and biochemical behaviors of an acid tolerantChlorella vulgaris

This study concerns the inhibitory effects of acid pH and nickel on growth, nutrient (NO₃ ^- and NH₄ ⁺) uptake, carbon fixation, O₂ evolution, electron transport chain and enzyme (nitrate reductase and ATPase) activities of acid tolerant and wild-type strains of Chlorella vulgaris. Though a general reduction in all these variables was noticed with decreasing pH, the tolerant strain was found to be metabolically more active than the wild-type. A reduced cation (NH₄ ⁺, Na⁺, K⁺ and Ca²⁺) uptake, coupled with a facilitated influx of anions (NH₄ ⁺, PO₄ ^3- and HCO₃ ^-), suggested the development of a positive membrane potential in acid tolerant Chlorella. Nevertheless, a tremendous increase in ATPase activity at decreasing pH revealed the involvement of superactive ATPase in exporting H⁺ ions and keeping the internal pH neutral. A difference in Na⁺ and K⁺ efflux of the two strains at decreasing pH suggests there is a difference in membrane permeability. The low toxicity of Ni in the acid tolerant strain may be due to the low Ni uptake brought about by a change in membrane potential as well as in permeability. Hence, the development of superactive ATPase and a change in both membrane potential and permeability not only offers protection against acidity, but also co-tolerance to metals.     

A Conserved Asparagine in a P-type Proton Pump Is Required for Efficient Gating of Protons

The minimal proton pumping machinery of the Arabidopsis thaliana P-type plasma membrane H⁺-ATPase isoform 2 (AHA2) consists of an aspartate residue serving as key proton donor/acceptor (Asp-684) and an arginine residue controlling the pK_a of the aspartate. However, other important aspects of the proton transport mechanism such as gating, and the ability to occlude protons, are still unclear. An asparagine residue (Asn-106) in transmembrane segment 2 of AHA2 is conserved in all P-type plasma membrane H⁺-ATPases. In the crystal structure of the plant plasma membrane H⁺-ATPase, this residue is located in the putative ligand entrance pathway, in close proximity to the central proton donor/acceptor Asp-684. Substitution of Asn-106 resulted in mutant enzymes with significantly reduced ability to transport protons against a membrane potential. Sensitivity toward orthovanadate was increased when Asn-106 was substituted with an aspartate residue, but decreased in mutants with alanine, lysine, glutamine, or threonine replacement of Asn-106. The apparent proton affinity was decreased for all mutants, most likely due to a perturbation of the local environment of Asp-684. Altogether, our results demonstrate that Asn-106 is important for closure of the proton entrance pathway prior to proton translocation across the membrane.     

Changes in plasma membrane lipids, aquaporins and proton pump of broccoli roots, as an adaptation mechanism to salinity

Salinity stress is known to modify the plasma membrane lipid and protein composition of plant cells. In this work, we determined the effects of salt stress on the lipid composition of broccoli root plasma membrane vesicles and investigated how these changes could affect water transport via aquaporins. Brassica oleracea L. var. Italica plants treated with different levels of NaCl (0, 40 or 80 mM) showed significant differences in sterol and fatty acid levels. Salinity increased linoleic (18:2) and linolenic (18:3) acids and stigmasterol, but decreased palmitoleic (16:1) and oleic (18:1) acids and sitosterol. Also, the unsaturation index increased with salinity. Salinity increased the expression of aquaporins of the PIP1 and PIP2 subfamilies and the activity of the plasma membrane H⁺-ATPase. However, there was no effect of NaCl on water permeability (P_f) values of root plasma membrane vesicles, as determined by stopped-flow light scattering. The counteracting changes in lipid composition and aquaporin expression observed in NaCl-treated plants could allow to maintain the membrane permeability to water and a higher H⁺-ATPase activity, thereby helping to reduce partially the Na⁺ concentration in the cytoplasm of the cell while maintaining water uptake via cell-to-cell pathways. We propose that the modification of lipid composition could affect membrane stability and the abundance or activity of plasma membrane proteins such as aquaporins or H⁺-ATPase. This would provide a mechanism for controlling water permeability and for acclimation to salinity stress.     

Electrogenic transport of protons driven by the plasma membrane ATPase in membrane vesicles from radish : biochemical characterization

Mg:ATP-dependent H⁺ pumping has been studied in microsomal vesicles from 24-hour-old radish (Raphanus sativus L.) seedlings by monitoring both intravesicular acidification and the building up of an inside positive membrane potential difference (Δ ψ). ΔpH was measured as the decrease of absorbance of Acridine orange and Δ ψ as the shift of absorbance of bis(3-propyl-5-oxoisoxazol-4-yl)pentamethine oxonol. Both Mg:ATP-dependent Δ pH and Δ ψ generation are completely inhibited by vanadate and insensitive to oligomycin; moreover, Δ pH generation is not inhibited by NO₃⁻. These findings indicate that this membrane preparation is virtually devoid of mitochondrial and tonoplast H⁺-ATPases. Both intravesicular acidification and Δ ψ generation are influenced by anions: Δ pH increases and Δ ψ decreases following the sequence SO₄²⁻, Cl⁻, Br⁻, NO₃⁻. ATP-dependent H⁺ pumping strictly requires Mg²⁺. It is very specific for ATP (apparent K_m 0.76 millimolar) compared to GTP, UTP, CTP, ITP. Δ pH generation is inhibited by CuSO₄ and diethylstilbestrol as well as vanadate. Δ pH generation is specificially stimulated by K⁺ (+ 80%) and to a lesser extent by Na⁺ and choline (+28% and +14%, respectively). The characteristics of H⁺ pumping in these microsomal vesicles closely resemble those described for the plasma membrane ATPase partially purified from several plant materials.     

K+/H+ antiporter in alkaliphilic Bacillus sp. no. 66 (JCM 9763)

A K⁺/H⁺ antiport system was detected for the first time in right-side-out membrane vesicles prepared from alkaliphilic Bacillus sp. no. 66 (JCM 9763). An outwardly directed K⁺ gradient (intravesicular K⁺ concentration, K_in, 100 mM; extravesicular K⁺ concentration, K_out, 0.25 mM) stimulated uphill H⁺ influx into right-side-out vesicles and created the inside-acidic pH gradient (ΔpH). This H⁺ influx was pH-dependent and increased as the pH increased from 6.8 to 8.4. Addition of 100 μM quinine inhibited the H⁺ influx by 75%. This exchange process was electroneutral, and the H⁺ influx was not stimulated by the imposition of the membrane potential (interior negative). Addition of K⁺ at the point of maximum ΔpH caused a rapid K⁺-dependent H⁺ eflux consistent with the inward exchange of external K⁺ for internal H⁺ by a K⁺/H⁺ antiporter. Rb⁺ and Cs⁺ could replace K⁺ but Na⁺ and Li⁺ could not. The H⁺ efflux rate was a hyperbolic function of K⁺ and increased with increasing extravesicular pH (pH_out) from 7.5 to 8.5. These findings were consistent with the presence of K⁺/H⁺ antiport activity in these membrane vesicles. Received: March 20, 1997 / Accepted: May 22, 1997     

Decrease of pH Gradients in Tonoplast Vesicles by NO(3) and Cl: Evidence for H-Coupled Anion Transport

Chloride or nitrate decreased a pH gradient (measured as [¹⁴C]methylamine accumulation) in tonoplast-enriched vesicles. The ΔpH decrease was dependent on the anion concentration. These effects are independent of the anion-sensitive H⁺-ATPase of the tonoplast, since the pH gradient (acid inside) was imposed artificially using a pH jump or a K⁺ gradient and nigericin. 4,4′-Diisothiocyano-2,2′-stilbene disulfonic acid partially prevented the decrease in pH gradient induced by Cl⁻. Two possible models to account for this anion-dependent decrease of ΔpH are: (a) H⁺ loss is accompanied by Cl⁻ or NO₃⁻ efflux from the vesicles via H⁺/anion symport systems on the tonoplast and (b) H⁺ loss is accompanied by Cl⁻ or NO₃⁻ uptake into the vesicles via H⁺/anion antiport systems. Depending on the requirements and conditions of the cell, these two systems would serve to either mobilize Cl⁻ and NO₃⁻ stored in the vacuole for use in the cytoplasm or to drive anions into the vacuole. Chloride or nitrate also decreased a pH gradient in fractions containing plasma membrane and Golgi, implying that these membranes may have similar H⁺-coupled anion transport systems.     

Evidence for a highly specific k/h antiporter in membrane vesicles from oil-seed rape hypocotyls

We present evidence strongly suggesting that a proton gradient (acid inside) is used to drive an electroneutral, substrate-specific, K⁺/H⁺ antiport in both tonoplast and plasma membrane-enriched vesicles obtained from oilseed rape (Brassica napus) hypocotyls. Proton fluxes into and out of the vesicles were monitored both by following the quenching and restoration of quinacrine fluorescence (indicating a transmembrane pH gradient) and of oxonol V fluorescence (indicating membrane potential.) Supply of K⁺ (with Cl⁻ or SCN⁻) after a pH gradient had been established across the vesicle membrane by provision of ATP to the H⁺-ATPase dissipated the transmembrane pH gradient but did not depolarize the positive membrane potential. Evidence that the K⁺/H⁺ exchange thus indicated could not be accounted for by mere electric coupling included the findings that, first, no positive potential was generated when KSCN or KCl was supplied, even in the absence of 100 millimolar Cl⁻ and, second, efflux of K⁺ from K⁺-loaded vesicles drives intravesicular accumulation of H⁺ against the electrochemical potential gradient. Neither was the exchange due to competition between K⁺ and quinacrine for membrane sites, nor to inhibition of the H⁺-ATPase. Thus, it is likely that it was effected by a membrane component. The exchanger utilized primarily K⁺ (at micromolar concentrations); Na⁺/H⁺ antiport was detected only at concentrations two orders of magnitude higher. Rb⁺, Li⁺, or Cs⁺ were ineffective. Dependence of tonoplast K⁺/H⁺ antiport on K⁺ concentration was complex, showing saturation at 10 millimolar K⁺ and inhibition by concentrations higher than 25 millimolar. Antiport activity was associated both with tonoplast-enriched membrane vesicles (where the proton pump was inhibited by more than 80% by 50 millimolar NO₃⁻ and showed no sensitivity to vanadate or oligomycin) and with plasma membrane-enriched fractions prepared by phase separation followed by separation on a sucrose gradient (where the proton pump was vanadate and diethylstilbestrol-sensitive but showed no sensitivity to NO₃⁻ or oligomycin). The possible physiological role of such a K⁺/H⁺ exchange mechanism is discussed.