H-pumping driven by the vanadate-sensitive ATPase in membrane vesicles from corn roots

The initial rate of quenching of quinacrine fluorescence was used to monitor Mg:ATP-dependent H⁺-pumping in membrane vesicles from corn (Zea mays L. cv WF9 × MO17) roots and obtain a preparation in which vanadate-sensitive H⁺-pumping could be observed. Separation of membranes on a linear sucrose density gradient resulted in two distinct peaks of H⁺-pumping activity: a major one, at density 1.11 grams per cubic centimeter, was sensitive to NO₃⁻ and resistant to vanadate, while a minor one, at density 1.17 grams per cubic centimeter, was substantially resistant to NO₃⁻ and sensitive to vanadate. A membrane fraction enriched in the vanadate-sensitive H⁺-pump could be obtained by washing microsomes prepared in the presence of 10% glycerol with 0.25 molar KI. The kinetics of inhibition of H⁺-pumping by vanadate in this membrane preparation indicated that most of the H⁺-pumping activity in this fraction is sensitive to inhibition by vanadate, 50% inhibition being reached at about 60 micromolar vanadate. This value is fairly close to that observed for inhibition by vanadate of the ATPase activity in similar experimental conditions (40 micromolar). The inhibitor sensitivity, divalent cation dependence, pH optimum (6.5), and K_m for ATP (0.7 millimolar) of the H⁺-pumping activity match quite closely those reported for the plasma membrane ATPase of corn roots and other plant materials.     

A Comparison Between the ATPase and Proton Pumping Activities of Plasma Membranes Isolated from the Stele and Cortex of Zea mays Roots

Plasma membrane vesicles of high purity, determined by markerenzyme assays, were obtained by phase partitioning microsomalfractions from stelar and cortical tissues of Zea mays (cv.LG11) roots. ATP hydrolytic activities in both of the plasmamembrane fractions were inhibited by vanadate, SW26 and erythrosinB, but were insensitive to nitrate. Activity in both fractionsexhibited a marked pH optimum of 6·5 and displayed typicalMichaelis-Menten kinetics. A high substrate specificity wasapparent in both the stele and cortex plasma membrane fractions,while the lower fractions, after phase partitioning, showedlower specificity for nucleotide substrates. Specific activitiesof the stele (67·8 µmol Pi mg^–1 h^–1)and cortex (78·4 µmol Pi mg^–1 h–¹)plasma membrane H⁺ -ATPases were very similar. Proton pumping activities in microsomal membrane fractions fromstele and cortex were inhibited by nitrate and insensitive tovanadate. Homogenization of stele and cortex tissue in the presenceof 250 mol m^–3 KI resulted in microsomal fractions exhibitingvanadate-sensitive, nitrate-insensitive proton pumping activity,suggesting a plasma membrane origin for this activity. SW26was also an effective inhibitor of proton pumping activity,although results indicated an interaction between SW26 and thefluorescent probes quinacrine and acridine orange. The results are discussed in relation to models for the transportof ions into the stele and are consistent with a role for theH⁺ -ATPase activity in this process. Key words: ATPase, cortex, plasma membrane, stele, Zea mays     

Anion-sensitive, h-pumping ATPase in membrane vesicles from oat roots

H⁺-pumping ATPases were detected in microsomal vesicles of oat (Avena sativa L. var Lang) roots using [¹⁴C]methylamine distribution or quinacrine fluorescent quenching. Methylamine (MeA) accumulation into vesicles and quinacrine quench were specifically dependent on Mg,ATP. Both activities reflected formation of a proton gradient (ΔpH) (acid inside) as carbonyl cyanide m-chlorophenylhydrazone, nigericin (in the presence of K⁺), or gramicidin decreased MeA uptake or increased quinacrine fluorescence. The properties of H⁺ pumping as measured by MeA uptake were characterized. The K_mapp for ATP was about 0.1 millimolar. Mg,GTP and Mg, pyrophosphate were 19% and 30% as effective as Mg,ATP. MeA uptake was inhibited by N,N′-dicyclohexylcarbodiimide and was mostly insensitive to oligomycin, vanadate, or copper. ATP-dependent MeA was stimulated by anions with decreasing order of potency of Cl⁻ > Br⁻ > NO₃⁻ > SO₄²⁻, iminodiacetate, benzene sulfonate. Anion stimulation of H⁺ pumping was caused in part by the ability of permeant anions to dissipate the electrical potential and in part by a specific requirement of Cl⁻ by a H⁺ -pumping ATPase. A pH gradient, probably caused by a Donnan potential, could be dissipated by K⁺ in the presence or absence of ATP. MeA uptake was enriched in vesicles of relatively low density and showed a parallel distribution with vanadate-insensitive ATPase activity on a continuous dextran gradient. ΔpH as measured by quinacrine quench was partially vanadate-sensitive. These results show that plant membranes have at least two types of H⁺ -pumping ATPases. One is vanadate-sensitive and probably enriched in the plasma membrane. One is vanadate-resistant, anion-sensitive and has many properties characteristic of a vacuolar ATPase. These results are consistent with the presence of electrogenic H⁺ pumps at the plasma membrane and tonoplast of higher plant cells.     

Effects of dicyclohexylcarbodiimide (DCCD) treatment on coupled activities of vanadate-sensitive ATPase from plasma membrane of maize roots

The presence of dicyclohexylcarbodiimide (DCCD) inhibited the activities of vanadate-sensitive H⁺ -ATPase in both native and reconstituted plasma membrane of maize (Zea mays L. cv. WF9 × Mo 17) roots. Concentration dependence of DCCD inhibition on adenosine triphosphate (ATP) hydrolysis of native plasma membrane vesicles suggested that the molar ratio of effective DCCD binding to ATPase was close to 1. The DCCD inhibition of ATP hydrolysis could be slightly reduced by the addition of ATP, Mg:ATP, adenosine monophosphate (AMP), Mg:AMP and adenosine diphosphate (ADP). More hydrophilic derivatives of DCCD such as l-ethyl-N^?-3-trimethyl ammonium carbodiimide (EDAC) or 1-ethyl-3-3-dimethyl-aminopropyl carbodiimide (EDC) gave no inhibition, indicating that the effective DCCD binding site was located in a hydrophobic region of the protein. The proton transport activity of reconstituted plasma membrane at a temperature below 20°C or above 25°C was much sensitive to DCCD treatment. Build-up of the proton gradient was analyzed according to a kinetic model, which showed that proton leakage across de-energized reconstituted plasma membranes was not affected by DCCD, but was sensitive to the method employed to quench ATP hydrolysis. Reconstituted plasma membrane vesicles treated with DCCD exhibited a differential inhibition of the coupled H⁺-transport and ATP hydrolysis. The presence of 50 μM DCCD nearly abolished transport but inhibited less than 50% of ATP hydrolysis. The above results suggest that the link between proton transport and vanadate-sensitive ATP hydrolysis is indirect in nature.     

Proton Transport Activity of the Purified Vacuolar H-ATPase from Oats : Direct Stimulation by Cl

To determine whether the detergent-solubilized and purified vacuolar H⁺-ATPase from plants was active in H⁺ transport, we reconstituted the purified vacuolar ATPase from oat roots (Avena sativa var Lang). Triton-solubilized ATPase activity was purified by gel filtration and ion exchange chromatography. Incorporation of the vacuolar ATPase into liposomes formed from Escherichia coli phospholipids was accomplished by removing Triton X-100 with SM-2 Bio-beads. ATP hydrolysis activity of the reconstituted ATPase was stimulated twofold by gramicidin, suggesting that the enzyme was incorporated into sealed proteoliposomes. Acidification of K⁺-loaded proteoliposomes, monitored by the quenching of acridine orange fluorescence, was stimulated by valinomycin. Because the presence of K⁺ and valinomycin dissipates a transmembrane electrical potential, the results indicate that ATP-dependent H⁺ pumping was electrogenic. Both H⁺ pumping and ATP hydrolysis activity of reconstituted preparations were completely inhibited by <50 nanomolar bafilomycin A₁, a specific vacuolar type ATPase inhibitor. The reconstituted H⁺ pump was also inhibited by N,N′-dicyclohexylcarbodiimide or NO₃⁻ but not by azide or vanadate. Chloride stimulated both ATP hydrolysis by the purified ATPase and H⁺ pumping by the reconstituted ATPase in the presence of K⁺ and valinomycin. Hence, our results support the idea that the vacuolar H⁺-pumping ATPase from oat, unlike some animal vacuolar ATPases, could be regulated directly by cytoplasmic Cl⁻ concentration. The purified and reconstituted H⁺-ATPase was composed of 10 polypeptides of 70, 60, 44, 42, 36, 32, 29, 16, 13, and 12 kilodaltons. These results demonstrate conclusively that the purified vacuolar ATPase is a functional electrogenic H⁺ pump and that a set of 10 polypeptides is sufficient for coupled ATP hydrolysis and H⁺ translocation.     

Purification and properties of the h-translocating ATPase from the plasma membrane of tomato roots

The proton-translocating, plasma membrane ATPase was purified from tomato roots. At the final stage of purification approximately 80% of the protein was found in a single band with an apparent molecular weight of 90 kilodaltons. Cross-linking studies indicated that the ATPase normally exists as a trimer of catalytic subunits. No evidence was found for any additional subunits. The pH optimum for ATP hydrolysis by the purified protein was 6.5. Activity was stimulated by K⁺, especially at low pH, and inhibited by vanadate, N,N′-dicyclohexylcarbodiimide, and diethylstilbestrol; nitrate was weakly inhibitory. Activity was stimulated by lysolecithin but inhibited by sonicated phospholipids. The inhibition by lipids could be prevented if octylglucoside was added with the lipids; the combination of octylglucoside and lipids actually stimulated activity. The purified protein could be reconstituted into liposomes and catalyzed ATP-dependent, vanadate-sensitive proton translocation.     

Inhibition by vanadate of the tonoplast H+ translocating ATPase of Rubus cells

Membranes were isolated from protoplasts of Rubus hispidus cells cultured in vitro and then separated with sucrose and Dextran T-70 gradients. Two peaks of ATPase activity were obtained. The first peak and proton pumping activity (density 1.085) was inhibited by both vanadate and nitrate. The second peak (density 1.150), was also inhibited by vanadate but not by nitrate; it closely coincided with UDP glucose-sterol-β-D-glucosyltransferase activity, a marker for plasma membrane. Tonoplast fractions isolated from vacuoles were characterized by the same nitrate- and vanadate-sensitive H⁺ translocating ATPase as described for the gradients.     

Factors associated with the instability of nitrate-insensitive proton transport by maize root microsomes

Proton transport catalyzed by the nitrate-insensitive, vanadate-sensitive H⁺-ATPase in microsomes from maize (Zea mays L.) roots washed with 0.25 molar KI decreased as a function of time at 0 to 4°C. The rate of proton transport was approximately one-half of that by freshly isolated microsomes after 6 to 18 hours of cold storage. The decrease in proton transport coincided with losses in membrane phosphatidylcholine and was not associated with a change in vanadate-sensitive ATP hydrolysis. A technique based on a protocol developed for the reconstitution of Neurospora crassa plasma membrane H⁺-ATPase (DS Perlin, K Kasamo, RJ Brooker, CW Slayman 1984 J Biol Chem 259: 7884-7892) was employed to restore proton transport activity to maize microsomes. These results indicated that the decline in proton transport by maize root membranes during cold storage was not due to degradation of the protein moiety of the H⁺-ATPase, but was due to the loss of phospholipids.     

Effects of temperature on the coupled activities of the vanadate-sensitive proton pump from maize root microsomes

The mechanism by which proton transport is coupled to ATP hydrolysis by vanadate-sensitive pumps is poorly understood. The effects of temperature on the activities of the vanadate-sensitive ATPase from maize (Zea mays) roots were assessed to provide insight into the coupling mechanism. The initial rate of proton transport had a bell-shaped dependence on temperature with an optimal range between 20 and 30°C. However, the rate of vanadate-sensitive ATP hydrolysis increased as the temperature was raised from 4 to 43°C. The differential sensitivity of proton transport to temperatures above 30°C was also observed when the ATPase was reconstituted into dioleoylphosphatidylcholine vesicles. Inhibition of proton transport with temperatures above 30°C was associated with higher rates of proton leakage from the membranes. In addition, proton transport was more inhibited than ATP hydrolysis at temperatures below 10°C. Reduced rates of proton transport at lower temperatures were not associated with higher rate of proton conductivity across the membranes. Therefore, the preferential inhibition of proton transport at temperatures below 10°C may reflect an effect of temperature on the coupling between proton transport and ATP hydrolysis within the vanadate-sensitive ATPase.     

Characterization of a plasma membrane H+-ATPase from the extremely acidophilic algaDunaliella acidophila

Summary Dunaliella acidophila is an unicellular green alga which grows optimally at pH 0–1 while maintaining neutral internal pH. A plasma membrane preparation of this algae has been purified on sucrose density gradients. The preparation exhibits vanadatesensitive ATPase activity of 2 mol P_i/mg protein/min, an activity 15 to 30-fold higher than that in the related neutrophilic speciesD. salina. The following properties suggest that the ATPase is an electrogenic plasma membrane H⁺ pump. (i) ATP induces proton uptake and generates a positive-inside membrane potential as demonstrated with optical probes. (ii) ATP hydrolysis and proton uptake are inhibited by vanadate, diethylstilbestrol, dicyclohexylcarbodiimide and erythrosine but not by molybdate, azide or nitrate. (iii) ATP hydrolysis and proton uptake are stimulated by fussicoccin in a pH-dependent manner as found for plants plasma membrane H⁺-ATPase. Unusual properties of this enzyme are: (i) theK _m for ATP is around 60 M, considerably lower than in other plasma membrane H⁺-ATPases, and (ii) the ATPase activity and proton uptake are stimulated three to fourfold by K⁺ and to a smaller extent by other monovalent cations. These results suggest thatD. acidophila possesses a vanadate-sensitive H⁺-ATPase with unusual features enabling it to maintain the large transmembrane pH gradient.     

Relevance of Divalent Cations to ATP-Driven Proton Pumping in Beef Heart Mitochondrial F0F1-ATPase

The ATP hydrolysis rate and the ATP hydrolysis-linked proton translocation by the F₀F₁-ATPase of beef heart submitochondrial particles were examined in the presence of several divalent metal cations. All Me–ATP complexes tested sustained ATP hydrolysis, although to a different extent. However, only Mg- and Mn-ATP-dependent hydrolysis could sustain a high level of proton pumping activity, as determined by acridine fluorescence quenching. Moreover, the K _m of the Me-ATP hydrolysis-induced proton pumping activity was very similar to the K _m value of Me-ATP hydrolysis. Both oligomycin and DCCD caused the full recovery of the fluorescence, providing clear evidence for the association of Mg-ATP hydrolysis with proton translocation through the F₀F₁-ATPase complex. In contrast, with other Me-ATP complexes, including Ca-ATP as substrate, the proton pumping activity was undetectable, implicating an uncoupling nature for these substrates. Attempts to demonstrate the involvement of the subunit of the enzyme in the coupling mechanism failed, suggesting that the participation of at least the N-terminal segment of the subunit in the coupling mechanism of the mitochondrial enzyme is unlikely.     

Purification and functional properties of the DCCD-reactive proteolipid subunit of the H+-translocating ATPase from Mycobacterium phlei

Interaction of N,N′-dicyclohexylcarbodiimide (DCCD) with ATPase of Mycobacterium phlei membranes results in inactivation of ATPase activity. The rate of inactivation of ATPase was pseudo-first order for the initial 30–65% inactivation over a concentration range of 5–50 μM DCCD. The second-order rate constant of the DCCD-ATPase interaction was k = 8.5·10⁵ M^?1·min^?1. The correlation between the initial binding of [¹⁴C]DCCD and 100% inactivation of ATPase activity shows 1.57 nmol DCCD bound per mg membrane protein. The proteolipid subunit of the F₀F₁-ATPase complex in membranes of M. phlei with which DCCD covalently reacts to inhibit ATPase was isolated by labeling with [¹⁴C]DCCD. The proteolipid was purified from the membrane in free and DCCD-modified form by extraction with chloroform/methanol and subsequent chromatography on Sephadex LH-20. The polypeptide was homogeneous on SDS-acrylamide gel electrophoresis and has an apparent molecular weight of 8000. The purified proteolipid contains phosphatidylinositol (67%), phosphatidylethanolamine (18%) and cardiolipin (8%). Amino acid analysis indicates that glycine, alanine and leucine were present in elevated amounts, resulting in a polarity of 27%. Cysteine and tryptophan were lacking. Butanol-extracted proteolipid mediated the translocation of protons across the bilayer, in K⁺-loaded reconstituted liposomes, in response to a membrane potential difference induced by valinomycin. The proton translocation was inhibited by DCCD, as measured by the quenching of fluorescence of 9-aminoacridine. Studies show that vanadate inhibits the proton gradient driven by ATP hydrolysis in membrane vesicles of M. phlei by interacting with the proteolipid subunit sector of the F₀F₁-ATPase complex.     

ATP-dependent carbon transport in perfused Chara cells

Carbon transport across the plasma membrane, and carbon fixation were measured in perfused Chara internodal cells. These parameters were measured in external media of pH 5·5 and pH 8·5, where CO₂ and HCO₃^- are, respectively, the predominant carbon species in both light and dark conditions. Cells perfused with medium containing ATP could utilize both CO₂ and HCO₃^- from the external medium in the light. Photosynthetic carbon fixation activity was always higher at pH 5·5 than at pH 8·5. When cells were perfused either with medium containing hexokinase and 2-deoxyglucose to deplete ATP from the cytosol (HK medium) or with medium containing vanadate, a specific inhibitor of the plasma membrane H⁺_-ATPase (V medium), photosynthetic carbon fixation was strongly inhibited at both pH 5·5 and 8·5. Perfusion of cells with medium containing pyruvate kinase and phosphoenolpyruvate (PEP) to maximally activate the H⁺_-ATPase (PK medium), stimulated the photosynthetic carbon fixation activities. Oxygen evolution of isolated chloroplasts and the carbon fixation of cells supplied ¹⁴C intracellularly were not inhibited by perfusion media containing either hexokinase and 2-deoxyglucose or vanadate. The results indicate that Chara cells possess CO₂ and HCO₃^- transport systems energized by ATP and sensitive to vanadate in the light. In the dark, intact cells also fix carbon. By contrast, in cells perfused with medium containing ATP, no carbon fixation was detected in 1 mol m ^-3 total dissolved inorganic carbon (TDIC) at pH 8·5. By increasing TDIC to 10 mol m^-3, dark fixation became detectable, although it was still lower than that of intact cells at 1mol m^-3 TDIC. Addition of PEP or PEP and PEP carboxylase to the perfusion media significantly increased the dark-carbon fixation. Perfusion with vanadate had no effect on the dark-carbon fixation.     

Subunit-subunit interactions in TF1 as revealed by ligand binding to isolated and integrated α and β subunits

The binding of 3′-O-(1-naphthoyl)adenosinetriphosphate (1-naphthoyl-ATP), ATP and ADP to TF₁ and to the isolated α and β subunits was investigated by measuring changes of intrinsic protein fluorescence and of fluorescence anisotropy of 1-naphthoyl-ATP upon binding. The following results were obtained. (1) The isolated α and β subunits bind 1 mol 1-naphthoyl-ATP with a dissociation constant (K_D(1-naphthoyl-ATP)) of 4.6 μM and 1.9 μM, respectively. (2) The K_D(ATP) for α and β subunits is 8 μM and 11 μM, respectively. (3) The K_D(ADP) for α and β subunits is 38 μM μM and 7 μM, respectively. (4) TF₁ binds 2 mol 1-naphthoyl-ATP per mol enzyme with K_D = 170 nM. (5) The rate constant for 1-naphthoyl-ATP binding to α and β subunit is more than 5 · 10⁴ M⁻¹s⁻¹. (6) The rate constant for 1-naphthoyl-ATP binding to TF₁ is 6.6 · 10³ M⁻¹ · s⁻¹ (monophasic reaction); the rate constant for its dissociation in the presence of ATP is biphasic with a fast first phase (k^A₋₁ = 3 · 10⁻³s⁻¹) and a slower second phase (k^A₋₂ < 0.2 · 10⁻³s⁻¹). From the appearance of a second peak in the fluorescence emission spectrum of 1-naphthoyl-ATP upon binding it is concluded that the binding sites in TF₁ are located in an environment more hydrophobic than the binding sites on isolated α and β subunits. The differences in kinetic and thermodynamic parameters for ligand binding to isolated versus integrated α and β subunits, respectively, are explained by interactions between these subunits in the enzyme complex.     

Supramolecular interaction between adenosine 5′-triphosphate (ATP) and polycharged tetraazamacrocycles. Thermodynamic and 31P NMR studies

The interaction of adenosine 5′-triphosphate (ATP) with the tetraammonium macrocyclic receptors 1,1,4,4,7,7,10,10-octamethyl-1,4,7,10-tetraazacyclododecane tetrakis(iodide) (L1·4I) and 1,6,11,16-tetraazacycloeicosane (L2) in its fully protonated form, has been studied by potentiometry and ³¹P NMR in water at I = 0.15 mol dm⁻³ and 25 °C H₄L2⁴⁺ reacts both with ATP⁴⁻ and HATP³⁻ to produce H₄L2·ATP and (H₄L2·HATP)⁺ whose equilibrium constants are 6.46 × 10³ and 1.10 x 10³, respectively. In the case of L1, in which the quaternarization of the nitrogen atoms prevents the formation of hydrogen bonds, no detectable interactions arise with ATP. These results are consistent with the hypothesis that the formation of hydrogen bonds play a role of major importance in the interaction between ATP and tetrammonium receptors.     

Kinetic analysis of proton transport by the vanadate-sensitive ATPase from maize root microsomes

Proton transport by the nitrate-insensitive, vanadate-sensitive ATPase in Kl-washed microsomes and reconstituted vesicles from maize (Zea mays L.) roots was followed by changes in acridine orange absorbance in the presence of either KNO₃ or KCl. Data from such studies obeyed a kinetic model in which net proton transport by the pump is the difference between the rate of proton transport by the action of the ATPase and the leak of protons from the vesicles in the direction opposite from the pump. After establishing the steady state proton gradient, the rate of return of transported protons was found to obey first-order kinetics when the activity of the ATPase was completely and rapidly stopped. The rate of return of these protons varied with the quencher used. When the substrate Mg:ATP was depleted by the addition of either EDTA or hexokinase, the rate at which the proton gradient collapsed was faster than when vanadate was used as the quencher. These trends were independent of the anion accompanying the K and the transport assay used.     

Hydrolysis of 3′,4′-dichloropropionanilide by an aryl acylamidase from Taraxacum officinale

An aryl acylamidase (aryl-acylamine amidohydrolase, E.C. 3.5. 1.a) which hydrolyses the herbicide propanil (3′,4′-dichloropropionanilide), was isolated from dandelion roots and partially purified and characterized. Specificity tests on the enzyme revealed that it could hydrolyse various chlorine ring-substituted propionanilides and 3,4-dichloroanilide alkyl compounds. The partially purified enzyme was inhibited by several sulfhydryl reagents and metal ions. The pH optimum was broad, between 7·4 and 7·8. The apparent activation energy, determined from an Arrhenius plot, was 9·0 kcal/mol (37 700 J/mol) for the hydrolysis of 3′,4′-dichloropropionanilide. The apparent K_m was 1·7 × 10⁻⁴ M with propanil as substrate.     

Electrogenic h-pumping pyrophosphatase in tonoplast vesicles of oat roots

A H⁺-translocating inorganic pyrophosphatase (H⁺-PPase) was associated with low density membranes enriched in tonoplast vesicles of oat roots. The H⁺-PPase catalyzed the electrogenic transport of H⁺ into the vesicles, generating a pH gradient, inside acid (quinacrine fluorescence quenching), and a membrane potential, inside positive (Oxonol V fluorescence quenching). Transport activity was dependent on cations with a selectivity sequence of Rb⁺ = K⁺ > Cs⁺; but it was inhibited by Na⁺ or Li⁺. Maximum rates of transport required at least 20 millimolar K⁺ and the K_m for this ion was 4 millimolar. Fluoride inhibited both ΔpH formation and K⁺-dependent PPase activity with an I₅₀ of 1 to 2 millimolar. Inhibitors of the anion-sensitive, tonoplast-type H⁺-ATPase (e.g. a disulfonic stilbene or NO₃⁻) had no effect on the PPase activity. Vanadate and azide were also ineffective. H⁺-pumping PPase was inhibited by 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole and N-ethylmaleimide, but its sensitivity to N,N′-dicyclohexylcarbodiimide was variable. The sensitivity to ions and inhibitors suggests that the tonoplast H⁺-PPase and the H⁺-ATPase are distinct activities and this was confirmed when they were physically separated after Triton X-100 solubilization and Sepharose CL-6B chromatography. H⁺ pumping activity was strongly affected by Mg²⁺ and pyrophosphate (PPi) concentrations. At 5 millimolar Mg²⁺, H⁺ pumping showed a K_maPP for PPi of 15 micromolar. The rate of H⁺ pumping at 60 micromolar PPi was often equivalent to that at 1.5 millimolar ATP. The results suggest PPi hydrolysis could provide another source of a proton motive force used for solute transport and other energy-requiring processes across the tonoplast and other membranes with H⁺-PPase.     

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.     

Solubilization, Reconstitution and Characterization of Vanadate-sensitive, ATP-driven H+ -transport from cotyledons of Ricinus communis

Several treatments were investigated in an attempt to increasethe proportion of vanadate-sensitive proton pumping activityderived from membrane fractions of Ricinus cotyledons. The mostsuccessful procedure involved KI treatment of the microsomalfraction followed by solubilization with 1.25% (w/v) octylglucosideand reconstitution into phosopholipid liposomes. KI treatmentof the microsomal fraction resulted in an increase in the ATPasesensitivity to vanadate. Reconstitution was carried out by adilution method and the existence of ATP-driven H⁺-transportacross the proteoliposomes was demonstrated by quinacrine fluorescencequenching. The quenching was gramicidin reversible and stronglyinhibited by vanadate, ER B and PCMBS. Less inhibition was observedin the presence of NEM. Fusicoccin and sucrose did not havemarked effects on H⁺ -transport. Key words: ATPase, proton pumping, KI-treatment, solubilization, reconstitution, Ricinus communis