Characterization of a partially purified adenosine triphosphatase from a corn root plasma membrane fraction

The (K⁺,Mg²⁺)-ATPase was partially purified from a plasma membrane fraction from corn roots (WF9 × Mol7) and stored in liquid N₂ without loss of activity. Specific activity was increased 4-fold over that of the plasma membrane fraction. ATPase activity resembled that of the plasma membrane fraction with certain alterations in cation sensitivity. The enzyme required a divalent cation for activity (Co²⁺ > Mg²⁺ > Mn²⁺ > Zn²⁺ > Ca²⁺) when assayed at 3 millimolar ATP and 3 millimolar divalent cation at pH 6.3. When assayed in the presence of 3 millimolar Mg²⁺, the enzyme was further activated by monovalent cations (K⁺, NH₄⁺, Rb⁺ Na⁺, Cs⁺, Li⁺). The pH optima were 6.5 and 6.3 in the absence and presence of 50 millimolar KCl, respectively. The enzyme showed simple Michaelis-Menten kinetics for the substrate ATP-Mg, with a K_m of 1.3 millimolar in the absence and 0.7 millimolar in the presence of 50 millimolar KCl. Stimulation by K⁺ approached simple Michaelis-Menten kinetics, with a K_m of approximately 4 millimolar KCl. ATPase activity was inhibited by sodium orthovanadate. Half-maximal inhibition was at 150 and 35 micromolar in the absence and presence of 50 millimolar KCl. The enzyme required the substrate ATP. The rate of hydrolysis of other substrates, except UDP, IDP, and GDP, was less than 20% of ATP hydrolysis. Nucleoside diphosphatase activity was less than 30% of ATPase activity, was not inhibited by vanadate, was not stimulated by K⁺, and preferred Mn²⁺ to Mg²⁺. The results demonstrate that the (K⁺,Mg²⁺)-ATPase can be clearly distinguished from nonspecific phosphohydrolase and nucleoside diphosphatase activities of plasma membrane fractions prepared from corn roots.     

Mechanism for Cd2+ inhibition of (K++ Mg2+)ATPase activity and K+ (86Rb+) uptake join roots of sugar beet (Beta vulgaris)

Steady state kinetics were used to examine the influence of Cd²⁺ both on K⁺ stimulation of a membrane-bound ATPase from sugar beet roots (Beta vulgaris L. cv. Monohill) and on K⁺(⁸⁶Rb⁺) uptake in intact or excised beet roots. The in vitro effect of Cd²⁺ was studied both on a 12000–25000 g root fraction of the (Na⁺+K⁺+Mg²⁺)ATPase and on the ATPase when further purified by an aqueous polymer two-phase system. The observed data can be summarized as follows: 1) Cd²⁺ at high concentrations (>100 μM) inhibits the MgATPase activity in a competitive way, probably by forming a complex with ATP. 2) Cd²⁺ at concentrations <100 μM inhibits the specific K⁺ activation at both high and low affinity sites for K⁺. The inhibition pattern appears to be the same in the two ATPase preparations of different purity. In the presence of the substrate MgATP, and at K⁺ <5 mM, the inhibition by Cd²⁺ with respect to K⁺ is uncompetitive. In the presence of MgATP and K⁺ >10 μM, the inhibition by Cd²⁺ is competitive. 3) At the low concentrations of K⁺, Cd²⁺ also inhibits the 2,4-dinitrophenol(DNP)-sensitive (metabolic) K⁺(⁸⁶Rb⁺) uptake uncompetitively both in excised roots and in roots of intact plants. 4) The DNP-insensitive (non metabolic) K⁺(⁸⁶Rb⁺) uptake is little influenced by Cd²⁺. As Cd²⁺ inhibits the metabolic uptake of K⁺(⁸⁶Rb⁺) and the K⁺ activation of the ATPase in the same way at low concentrations of K⁺, the same binding site is probably involved. Therefore, under field conditions, when the concentration of K⁺ is low, the presence of Cd²⁺ could be disadvantageous.     

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.     

Effects of Cations on (Ca2++ Mg2+)-Activated ATPase from Rat Brain

Abstract: With a partially purified, membrane-bound (Ca + Mg)-activated ATPase preparation from rat brain, the K_0.5 for activation by Ca²⁺ was 0.8 p μm in the presence of 3 mm -ATP, 6 mm -MgCl₂, 100 m_M-KCI, and a calcium EGTA buffer system. Optimal ATPase activity under these circumstances was with 6-100 μm -Ca²⁺, but marked inhibition occurred at higher concentrations. Free Mg²⁺ increased ATPase activity, with an estimated K_0.5, in the presence of 100 μm -CaCl₂, of 2.5 mm ; raising the MgCl₂ concentration diminished the inhibition due to millimolar concentrations of CaCl₂, but antagonized activation by submicromolar concentrations of Ca²⁺. Dimethylsulfoxide (10%, v/v) had no effect on the K_0.5 for activation by Ca²⁺, but decreased activation by free Mg²⁺ and increased the inhibition by millimolar CaCl₂. The monovalent cations K⁺, Na⁺, and TI⁺ stimulated ATPase activity; for K⁺ the K_0.5 was 8 mm , which was increased to 15 mm in the presence of dimethylsulfoxide. KCI did not affect the apparent affinity for Ca²⁺ as either activator or inhibitor. The preparation can be phosphorylated at 0°C by [γ-³²P]-ATP; on subsequent addition of a large excess of unlabeled ATP the calcium dependent level of phosphorylation declined, with a first-order rate constant of 0.12 s^?1. Adding 10 mm -KCI with the unlabeled ATP increased the rate constant to 0.20 s^?1, whereas adding 10 mm -NaCl did not affect it measurably. On the other hand, adding dimethyl-sulfoxide slowed the rate of loss, the constant decreasing to 0.06 s^?1. Orthovanadate was a potent inhibitor of this enzyme, and inhibition with 1 μm -vanadate was increased by both KCI and dimethylsulfoxide. Properties of the enzyme are thus reminiscent of the plasma membrane (Na + K)-ATPase and the sarcoplasmic reticulum (Ca + Mg)-ATPase, most notably in the K⁺ stimulation of both dephosphorylation and inhibition by vanadate.     

Effect of vanadate, molybdate, and azide on membrane-associated ATPase and soluble phosphatase activities of corn roots

The effects of vanadate, molybdate, and azide on ATP phosphohydrolase (ATPase) and acid phosphatase activities of plasma membrane, mitochondrial, and soluble supernatant fractions from corn (Zea mays L. WF9 × MO17) roots were investigated. Azide (0.1-10 millimolar) was a selective inhibitor of pH 9.0-ATPase activity of the mitochondrial fraction, while molybdate (0.01-1.0 millimolar) was a relatively selective inhibitor of acid phosphatase activity in the supernatant fraction. The pH 6.4-ATPase activity of the plasma membrane fraction was inhibited by vanadate (10-500 micromolar), but vanadate, at similar concentrations, also inhibited acid phosphatase activity. This result was confirmed for oat (Avena sativa L.) root and coleoptile tissues. While vanadate does not appear to be a selective inhibitor, it can be used in combination with molybdate and azide to distinguish the plasma membrane ATPase from mitochondrial ATPase or supernatant acid phosphatase.

Vanadate appeared to be a noncompetitive inhibitor of the plasma membrane ATPase, and its effectiveness was increased by K⁺. K⁺-stimulated ATPase activity was inhibited by 50% at about 21 micromolar vanadate. The rate of K⁺ transport in excised corn root segments was inhibited by 66% by 500 micromolar vanadate.

     

Adenosine Triphosphatases Bound to Plasmalemma, Mitochondria, and Microsomes or Present in the Cytoplasmic Phase from Potato Tubers

Between pH 4–10, basal ATPase activity, measured in the absence of mineral ions, was 10 to 100 times higher in the final cytoplasmic supernatant from potato tuber homogenates than in the membraneous fractions (purified plasmalemma, purified mitochondria and microsomes). The soluble ATPase was slightly inhibited, whereas the membrane-bound ATPases were all stimulated by Mg²⁺ ions. A further stimulation by Na⁺ or K⁺ ions was only observed in purified plasmalemma or mitochondria, at alkaline pH (7.5–9.5). At a fixed (Na⁺+ K⁺) concentrations (80 mM), this last stimulation was much greater in purified mitochondria (350%) than in plasmalemma (33%); it also increased with (Na⁺+ K⁺) concentrations up to 200 mM in mitochondria whereas, in plasmalemma, it was roughly constant for monovalent ion concentrations between 20 and 200 mM. General properties of the plasma membrane-bound ATPase have been determined, i.e. substrate specificity, activity variations with quantity of substrate, temperature, pH, etc. Divalent cations stimulated strongly the ATPase in the following order: Mn²⁺ > Mg²⁺ > Ca²⁺. The maximum ATP hydrolysis velocity for that part of ATPase activity which is strictly dependent on Mg²⁺ ions was 3.85 μmol × mg^?1 protein × h^?1. This plasma membrane ATPase was not sensitive to ouabaïn or to oligomycin.     

Effects of pH on the interaction of ligands with the (H+ + K+)-ATPase purified from pig gastric mucosa

The effects of K⁺, Na⁺ and ATP on the gastric (H⁺ + K⁺)-ATPase were investigated at various pH. The enzyme was phosphorylated by ATP with a pseudo-first-order rate constant of 3650 min^?1 at pH 7.4. This rate constant increased to a maximal value of about 7900 min^?1 when pH was decreased to 6.0. Alkalinization decreased the rate constant. At pH 8.0 it was 1290 min^?1. Additions of 5 mM K⁺ or Na⁺, did not change the rate constant at acidic pH, while at neutral or alkaline pH a decrease was observed. Dephosphorylation of phosphoenzyme in lyophilized vesicles was dependent on K⁺, but not on Na⁺. Alkaline pH increased the rate of dephosphorylation. K⁺ stimulated the ATPase and p-nitrophenylphosphatase activities. At high concentrations K⁺ was inhibitory. Below pH 7.0 Na⁺ had little or no effect on the ATPase and p-nitrophenylphosphatase, while at alkaline pH, Na⁺ inhibited both activities. The effect of extravesicular pH on transport of H⁺ was investigated. At pH 6.5 the apparent K_m for ATP was 2.7 μM and increased little when K⁺ was added extravesicularly. At pH 7.5, millimolar concentrations of K⁺ increased the apparent K_m for ATP. Extravesicular K⁺ and Na⁺ inhibited the transport of H⁺. The inhibition was strongest at alkaline pH and only slight at neutral or acidic pH, suggesting a competition between the alkali metal ions and hydrogen ions at a common binding site on the cytoplasmic side of the membrane. Two H⁺-producing reactions as possible candidates as physiological regulators of (H⁺ + K⁺)-ATPase were investigated. Firstly, the hydrolysis of ATP per se, and secondly, the hydration of CO₂ and the subsequent formation of H⁺ and HCO₃^?. The amount of hydrogen ions formed in the ATPase reaction was highest at alkaline pH. The H⁺/ATP ratio was about 1 at pH 8.0. When CO₂ was added to the reaction medium there was no change in the rate of hydrogen ion transport at pH 7.0, but at pH 8.0 the rate increased 4-times upon the addition of 0.4 mM CO₂. The results indicate a possible co-operation in the production of acid between the H⁺ + K⁺-ATPase and a carbonic anhydrase associated with the vesicular membrane.     

Purification and Characterization of a Cation-stimulated Adenosine Triphosphatase from Corn Roots

A membrane-bound, monovalent cation-stimulated ATPase from Zea mays roots has been purified to a single band on sodium dodecyl sulfate gel electrophoresis. Microsomal preparations with K⁺ -stimulated ATPase activity were extracted with 1 m NaClO₄, and the solubilized enzyme was purified by chromatography on columns of n-hexyl-Sepharose, DEAE-cellulose, and Sephadex G-100 Superfine. A 500-fold purification over the activity present in the microsomes was obtained. The K⁺ -stimulated activity shows positive cooperativity with increasing KCl concentrations. The purified enzyme shows K⁺ -stimulated activity with ATP, GTP, UTP, CTP, ADP, α + β-glycerophosphate, p-nitrophenyl phosphate, and pyrophosphate as substrates. Under most conditions ATP is the best substrate. Although dicyclohexyl carbodiimide and Ca²⁺ inhibit and alkylguanidines stimulate the K⁺ -ATPase while bound to microsomes, they have no effect on the purified enzyme.     

Lead ion activates phosphorylation of electroplax Na+- and K+-dependent adenosine triphosphatase ((NaK)-ATPase) in the absence of sodium ion.

PbCl₂ in micromolar concentrations stimulates phosphorylation of electroplax microsomal protein in the absence of Na⁺. Other divalent cations showed little or no such effect. The (Mg²⁺ + Pb²⁺)- and (Mg²⁺ + Na⁺)-dependent membrane-bound protein kinase activities in electroplax particulate preparations exhibit properties in common, including their acid stability, ouabain sensitivity, ATP specificity, and molecular size. It is concluded that the (Mg²⁺ + Pb²⁺)-dependent phosphoprotein is part of the Na⁺-, K⁺-dependent adenosine triphosphatase [(NaK)ATPase]. The Pb²⁺-dependent product, in contrast to the Na⁺-dependent one, is insensitive to K⁺ and the hydrolysis of ATP is thus inhibited.     

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 Characterization of the Soluble F(1)-ATPase of Oat Root Mitochondria

The properties of the soluble moiety (F₁) of the mitochondrial H⁺-ATPase from oat roots were examined and compared to those of the native mitochondrial membrane-bound enzyme. The chloroform soluble preparation was purified by Sephadex G-200 and DEAE-cellulose chromatography. The purified F₁ preparation contained major polypeptides corresponding to α, β, γ, δ, and ε of apparent molecular mass 58, 55, 35, 22, and 14 kilodaltons, respectively. The purified F₁-ATPase, like the native enzyme, was inhibited by azide (I₅₀ = 10 micromolar), nitrate (I₅₀ = 7-10 millimolar), 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (I₅₀ = 1-3 micromolar), and 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (I₅₀ = 3 micromolar). F₁-ATPase activity was stimulated by bicarbonate but not by chloride. In both the native and the F₁-form of the ATPase, ATP was hydrolyzed in preference to GTP. The results indicate that these properties of the native membrane-bound mitochondrial ATPase have been conserved in the purified F₁. In contrast to the membrane-bound enzyme, the F₁-ATPase was not inhibited by oligomycin or by N,N′-dicyclohexylcarbodiimide. The mitochondrial F₁-ATPase from oat roots is analogous to other known F₁F₀-ATPases.     

Modulation of water stress effects on photosynthesis by altered leaf k

Wheat irrigated with nutrient solutions containing 0, 0.2, 0.5, 1, 2, or 6 millimolar K⁺ had maximum photosynthetic rates at 1 to 2 millimolar K⁺ concentrations. Rates in the 6 millimolar K⁺-grown plants were not higher than the 2 millimolar K⁺-grown wheat, and rates were inhibited below 0.5 millimolar K⁺. Photosynthesis was measured by both attached whole leaf CO₂ uptake and by ¹⁴CO₂ fixation of leaf slices in solution. Exposure of leaf slices from 0.2, 2, and 6 millimolar K⁺-grown wheat to various assay media water potentials showed that photosynthesis of the 0.2 millimolar K⁺-grown wheat decreased from control (high water potential) rates by 35%, that of the 2 millimolar K⁺-grown wheat by 20.4%, and that of the 6 millimolar K⁺-grown wheat by only 8.3% at −3.11 megapascals. Also, photosynthesis of the 6 millimolar K⁺-grown wheat was enhanced by 28% over that of the 2 millimolar K⁺ wheat at the most severe water stress (−3.11 megapascals), indicating that the excess leaf K⁺ in the 6 millimolar K⁺-grown wheat partially reversed dehydration effects on photosynthesis. Oligomycin eliminated the protective effects of high K⁺ on photosynthesis in dehydrated leaf slices. These results suggest that the protective effect of high K⁺ under water stress may involve the exchange of K⁺ in the cytoplasm for stroma H⁺, thus altering stromal pH and restoring photosynthesis. The protective effect of high K⁺ was also observed in attached whole leaf photosynthesis of in situ water-stressed wheat grown on 0.2, 2, and 6 millimolar K⁺. Under water stress, rates of the 6 millimolar K⁺-grown wheat were enhanced by 66.2% and 113.9% over that of 2 millimolar K⁺-grown wheat in two separate experiments. Internal CO₂ concentration of the 6 millimolar K⁺-grown wheat was lower than that of the 0.2 and 2 millimolar K⁺-grown wheat. These results suggest that the high K⁺ effects on chloroplast photosynthesis seen in leaf slices also occur at the whole plant level.     

Stimulation of plasmalemma adenosine triphosphatase from oat roots by inorganic and organic cations: concentration-dependence, selectivity, and sites

K⁺-stimulated ATPase activity of a plasmalemma-enriched fraction from excised roots of oat was triphasic in the range 5 to 80 millimolar KCl. The phases obeyed Michaelis-Menten kinetics and were separated from each other by jumps or sharp breaks at about 10 and 20 millimolar. Stimulation by alkali cations was in the order K⁺ > Rb⁺ > Na⁺ > Cs⁺ > Li⁺ or in a closely related sequence. The specificity reflected differences in V_max, not in affinity (K_m⁻¹). Stimulation by the organic cations ethanolamine and choline in the interval 11 to 80 millimolar appeared monophasic rather than biphasic. Substitution on the quaternary nitrogen of the amino alcohols decreased their effectiveness, as did extension and branching of the chain. Stimulation was maximal at about pH 7 both for K⁺ and choline.     

Latency of Plasma Membrane H-ATPase in Vesicles Isolated by Aqueous Phase Partitioning : Increased substrate Accessibility or Enzyme Activation

The properties of the plasma membrane H⁺-ATPase and the cause of its latency have been studied using a highly purified plasma membrane fraction from oat (Avena sativa L., cv Victory) roots, prepared by aqueous two-phase partitioning. The ATPase has a maximum specific activity (at 37°C) in excess of 4 micromoles inorganic phosphate per milligram protein per minute in the presence of nondenaturing surfactants. It is inhibited by more than 90% by vanadate, is specific for ATP, has a pH optimum of 6.5, and is stimulated more than 4-fold by 50 millimolar K⁺ in the presence of low levels of the nondenaturing surfactants Triton X-100 and lysolecithin. This `latent' activity is usually explained as being a result of the inability of ATP to reach the ATPase in right-side out, sealed vesicles, until they are disrupted by surfactants. Consistent with this idea, trypsin digestion significantly inhibited the ATPase only in the presence of the surfactants. Electron spin resonance spectroscopy volume measurements confirmed that surfactant-free vesicles were mostly sealed to molecules similar to ATP. However, the Triton to protein ratio required to disrupt vesicle integrity completely is 10-fold less than that needed to promote maximum ATPase activity. We propose that plasma membrane ATPase activation is due not solely to vesicle disruption and accessibility of ATP to the ATPase but to the surfactants activating the ATPase by altering the lipid environment in its vicinity or by removing an inhibitory subunit.     

Cd2+-induced damage to yeast plasma membrane and its alleviation by Zn2+: studies on Schizosaccharomyces pombe cells and reconstituted plasma membrane vesicles

In Schizosaccharomyces pombe, Cd²⁺ shares the same uphill uptake system with Zn²⁺. Both heavy metals inhibited growth, respiration, H⁺/glucose uptake, and glucose-induced proton extrusion, Cd²⁺ being a 10–15-fold stronger inhibitor. In contrast, both had a similar effect on the plasma membrane H⁺-ATPase, enhancing its affinity for ATP and reducing the rate of ATP splitting. Cd²⁺ caused protracted strong fluidization of the plasma membrane of energized cells, whereas deenergized cells, phosphatidylcholine liposomes, and plasma membrane fragments, either purified or incorporated into the liposomes, exhibited only a short initial fluidization. Zn²⁺, which caused only a marginal membrane fluidization, suppressed the fluidizing action of Cd²⁺. The fluidizing effect of both heavy metals on liposomes was reduced by the presence of plasma membrane fragments in the liposome membrane. At 50 μM, Cd²⁺ brought about loss K⁺ (18 K⁺/1 Cd²⁺) from energized, but not from deenergized cells since Cd²⁺ must first accumulate in the cells before causing a detectable effect. A simple membrane disruption by external Cd²⁺ is, therefore, unlikely to be the main mechanism of cadmium-induced potassium loss in intact cells. Zn²⁺ had virtually no effect below 1 mM concentration, and it again weakened the K⁺-releasing effect of Cd²⁺. Cd²⁺ caused a strong loss of K⁺ also from K⁺-containing liposomes, probably because of a direct interaction with liposome phospholipids. Incorporation of plasma membrane fragments into the liposomes reduced the K⁺ loss sixfold. Received: 13 November 1995 / Accepted: 31 January 1996     

Characterization of an ATPase Associated with the Inner Envelope Membrane of Amyloplasts from Suspension-Cultured Cells of Sycamore (Acer pseudoplatanus L.)

Amyloplast envelope membranes isolated from cultured, white-wild cells of sycamore (Acer pseudoplatanus L.) have been found to contain a Mg²⁺-ATPase, ranging in specific activity from 5 to 30 nanomoles per minute per milligram protein. This ATPase hydrolyzes a broad range of nucleoside triphosphates, whereas it hydrolyzes nucleoside mono- and diphosphates poorly, if at all. The ATPase activity was stimulated by several divalent cations, including Mg²⁺, Mn²⁺ and Ca²⁺, whereas it was not affected by Sr²⁺, K⁺, or Na⁺. The K_m for total ATP was 0.6 millimolar, and the activity showed a broad pH optimum between 7.5 and 8.0. The ATPase was insensitive to N,N′-dicyclohexylcarbodiimide and oligomycin, but it was inhibited by vanadate. All these characteristics are basically similar to those reported previously for the Mg²⁺-ATPase of the chloroplast inner-envelope membrane. Likewise, the amyloplast envelope enzyme was shown to be located specifically on the inner envelope membrane. The amyloplast envelope membranes were chemically modified with a series of unique affinity labeling reagents, the adenosine polyphosphopyridoxals (M Tagaya, T Fukui 1986 Biochemistry 25: 2958-2964). About 90% of the ATPase activity was lost when the envelope membranes were preincubated with 0.1 millimolar adenosine triphosphopyridoxal. Notably, the enzyme was protected completely from inactivation in the presence of its substrate, ATP. In contrast, both adenosine diphosphopyridoxal and pyridoxal phosphate caused much less of an inhibitory effect. This greater relative reactivity of the triphosphopyridoxal analog is similar to that reported previously with Escherichia coli F₁ ATPase (T Noumi et al. 1987 J Biol Chem 262: 7686-7692).     

Effects of cadmium and lead on the accumulation of Ca2+ and K+ and on the influx and translocation of K+ in wheat of low and high K+ status

The effects of cadmium and lead on the internal concentrations of Ca²⁺ and K⁺, as well as on the uptake and translocation of K(⁸⁶Rb⁺) were studied in winter wheat (Triticum aestivum L. a. MV-8) grown hydroponically at 2 levels of K⁺ (100 uM and 10 mM). Cd²⁺ and Pb²⁺ were applied in the nutrient solution in the range of 0.3 to 1000 u.M. Growth was more severely inhibited by Cd²⁺ and in the high-K⁺ plants as compared to Pb^z+ and low-K⁺ plants. Ions of both heavy metals accumulated in the roots and shoots, but the K⁺ status influenced their levels. Ca²⁺ accumulation was increased by low concentrations of Cd²⁺ mainly in low-K⁺ shoots, whereas it was less influenced by Pb²⁺. The distribution of Cd²⁺ and Ca²⁺ in the plant and in the growth media indicated high selectivity for Cd²⁺ in the root uptake, while Ca²⁺ was preferred in the radial and/or xylem transport. Cd²⁺ strongly inhibited net K⁺ accumulation in high-K⁺ plants but caused stimulation at low K⁺ supply. In contrast, the metabolis-dependent influx of K⁺(⁸⁶Rb⁺) was inhibited in low-K⁺ plants, while the passive influx in high-K⁺ plants was stimulated. Translocation of K⁺ from the roots to the shoots was inhibited by Cd²⁺ but less influenced in Pb²⁺-treated plants. It is concluded that the effects of heavy metals depend upon the K⁺-status of the plants.     

Monovalent ion stimulated adenosine triphosphatase from oat roots

Monovalent ion stimulated ATPase activity from oat (Avena sativa) roots has been found to be associated with various membrane fractions (cell wall, mitochondrial and microsomal) of oat roots. The ATPase requires Mg²⁺ (or Mn⁺²) but is further stimulated by K⁺ and other monovalent ions. The monovalent ions are ineffective in the absence of the divalent activating cation. The ATPase has been described with respect to monovalent ion specificity, temperature, pH, substrate specificity, and Mg²⁺ and K⁺ concentrations. It was further shown that oligomycin inhibits a part of the total ATPase activity and on the basis of the oligomycin sensitivity it appears that at least 2 membrane associated ATPases are being measured. The mitochondrial fraction is most sensitive to oligomycin and the microsomal fraction is least sensitive to oligomycin. The oligomycin insensitive ATPase appears to be stimulated more by K⁺ than the oligomycin sensitive ATPase.     

Characterization of a proton-translocating ATPase in microsomal vesicles from corn roots

Sealed microsomal vesicles were prepared from corn (Zea mays, Crow Single Cross Hybrid WF9-Mo17) roots by centrifugation of a 10,000 to 80,000g microsomal fraction onto a 10% dextran T-70 cushion. The Mg²⁺-ATPase activity of the sealed vesicles was stimulated by Cl⁻ and NH₄⁺ and by ionophores and protonophores such as 2 micromolar gramicidin or 10 micromolar carbonyl cyanide p-trifluoromethoxyphenyl hydrazone (FCCP). The ionophore-stimulated ATPase activity had a broad pH optimum with a maximum at pH 6.5. The ATPase was inhibited by NO₃⁻, was insensitive to K⁺, and was not inhibited by 100 micromolar vanadate or by 1 millimolar azide.

Quenching of quinacrine fluorescence was used to measure ATP-dependent acidification of the intravesicular volume. Quenching required Mg²⁺, was stimulated by Cl⁻, inhibited by NO₃⁻, was insensitive to monovalent cations, was unaffected by 200 micromolar vanadate, and was abolished by 2 micromolar gramicidin or 10 micromolar FCCP. Activity was highly specific for ATP. The ionophore-stimulated ATPase and ATP-dependent fluorescence quench both required a divalent cation (Mg²⁺ ≥ Mn²⁺ > Co²⁺) and were inhibited by high concentrations of Ca²⁺. The similarity of the ionophore-stimulated ATPase and quinacrine quench and the responses of the two to ions suggest that both represent the activity of the same ATP-dependent proton pump. The characteristics of the proton-translocating ATPase differed from those of the mitochondrial F₁F₀-ATPase and from those of the K⁺-stimulated ATPase of corn root plasma membranes, and resembled those of the tonoplast ATPase.

     

Adenosinetriphosphatase and nucleotide metabolism in synaptosomes of rat brain

—In the presence of synaptosomes prepared from rat brain, only ATP, dATP and ADP but not dADP were active as substrates of phosphatase (ATP phosphohydrolase; EC 3.6.1 4) in the presence of 150mm-Na⁺ and 20mm-K⁺. An active adenylate kinase (ATP:AMP phosphotransferase; EC 2.7.4.3.) was demonstrated in the synaptosomal fractions by means of paper chromatography, paper electrophoresis and enzymic reactions, so that the high activity with ADP as substrate could represent an activity of an ATPase. Apparently dADP was not a substrate for the kinase; no dATP was formed when dADP was incubated with the synaptosomal fraction in the presence of Na⁺, K⁺ and Mg²⁺. Small amounts of P₁ were liberated with dADP, IDP, GDP or CDP, but not UDP, as substrates, but none was produced in the presence of mononucleotides. The adenine-deoxyribose bond, but not the adenine-ribose bond, was hydrolysed upon the addition of 5% (w/v) TCA to the reaction mixture. The K_M for the hydrolysis of ATP but not ITP, in the presence of Mg²⁺, or of Na⁺, K⁺ and Mg²⁺, was lower for the synaptosomal ATPase than for the microsomal ATPase, and the values for V_max for synaptosomal ATPase were higher. The activation increment was generally higher for the synaptosomal ATPase and no distinct differences in the properties of the enzyme from either particulate fractions were observed. Mg²⁺ could be partially replaced by Mn²⁺ in the synaptosomal ATPase system, but there was little Na⁺-K⁺-activation observed in the presence of the latter. The effects of ouabain and of homogenization under various conditions suggested localization of the K⁺-sensitive site of the ATPase on the surface of the synaptosomal membrane. Activity of the Na⁺-K⁺-Mg²⁺ ATPase increased after freezing and thawing of the sonicated, sucrose or tris-treated preparations but decreased considerably in the synaptosomes treated with 001 m-deoxycholate. Activity of the Mg²⁺ ATPase in the latter preparation showed little change.