Anion-Sensitive, H-Pumping ATPase of Oat Roots : Direct Effects of Cl, NO(3), and a Disulfonic Stilbene

To understand the mechanism and molecular properties of the tonoplast-type H⁺-translocating ATPase, we have studied the effect of Cl⁻, NO₃⁻, and 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS) on the activity of the electrogenic H⁺-ATPase associated with low-density microsomal vesicles from oat roots (Avena sativa cv Lang). The H⁺-pumping ATPase generates a membrane potential (Δψ) and a pH gradient (ΔpH) that make up two interconvertible components of the proton electrochemical gradient (μh⁺). A permeant anion (e.g. Cl⁻), unlike an impermeant anion (e.g. iminodiacetate), dissipated the membrane potential ([¹⁴C]thiocyanate distribution) and stimulated formation of a pH gradient ([¹⁴C]methylamine distribution). However, Cl⁻-stimulated ATPase activity was about 75% caused by a direct stimulation of the ATPase by Cl⁻ independent of the proton electrochemical gradient. Unlike the plasma membrane H⁺-ATPase, the Cl⁻-stimulated ATPase was inhibited by NO₃⁻ (a permeant anion) and by DIDS. In the absence of Cl⁻, NO₃⁻ decreased membrane potential formation and did not stimulate pH gradient formation. The inhibition by NO₃⁻ of Cl⁻-stimulated pH gradient formation and Cl⁻-stimulated ATPase activity was noncompetitive. In the absence of Cl⁻, DIDS inhibited the basal Mg,ATPase activity and membrane potential formation. DIDS also inhibited the Cl⁻-stimulated ATPase activity and pH gradient formation. Direct inhibition of the electrogenic H⁺-ATPase by NO₃⁻ or DIDS suggest that the vanadate-insensitive H⁺-pumping ATPase has anion-sensitive site(s) that regulate the catalytic and vectorial activity. Whether the anion-sensitive H⁺-ATPase has channels that conduct anions is yet to be established.     

Ion transport in isolated protoplasts from tobacco suspension cells: I. General characteristics

An investigation was conducted into the feasibility of using enzymically isolated protoplasts from suspension-cultured cells of Nicotiana glutinosa L. to study ion transport. Transport of K⁺ (⁸⁶Rb), ³⁶Cl⁻, H₂³²PO₄⁻ and ⁴⁵Ca²⁺ from 1 millimolar salt solutions was determined after separation of intact protoplasts from nonabsorbed tracers by centrifugation through a Ficoll step gradient. Influx of K⁺, Cl⁻, and H₂PO₄⁻ measured over a 30-minute period was reduced (up to 99%) by respiratory inhibitors such as 5 micrograms per milliliter oligomycin, 0.1 millimolar dinitrophenol, 0.1 millimolar cyanide, or N₂ gas. In contrast, Ca²⁺ influx was not tightly coupled to respiratory energy production. The influx of K⁺ was highest between pH 6.5 and 7.5 whereas the influx of H₂PO₄⁻ and Cl⁻ was greatest between pH 4.5 and 5.5. Influx of K⁺ and Cl⁻ was maximal at 35 and 45 C, respectively, and was almost completely inhibited below 10 C. Fusicoccin (0.01 millimolar) stimulated K⁺ influx by more than 200% but had no effect on the influx of either Cl⁻ or H₂PO₄⁻. Apparent H⁺ efflux, as measured by decrease in solution pH, was enhanced by K⁺, stimulated further by 0.01 millimolar fusicoccin, and inhibited by 0.1 millimolar dinitrophenol or 5 micrograms per milliliter oligomycin. The measured ionic fluxes into protoplasts were similar to those obtained with intact cultured cells. The results indicate that enzymic removal of the cell wall produced no significant alteration in the transport properties of the protoplast, and that it is feasible to use isolated protoplasts for studies on ion transport.     

Separation of two types of electrogenic h-pumping ATPases from oat roots

Microsomal vesicles of oat roots (Avena sativa var Lang) were separated with a linear dextran (0.5-10%, w/w) or sucrose (25-45%, w/w) gradient to determine the types and membrane identity of proton-pumping ATPases associated with plant membranes. ATPase activity stimulated by the H⁺/K⁺ exchange ionophore nigericin exhibited two peaks of activity on a linear dextran gradient. ATPase activities or ATP-generated membrane potential (inside positive), monitored by SCN⁻ distribution, included a vanadate-insensitive and a vanadate-sensitive component. In a previous communication, we reported that ATP-dependent pH gradient formation (acid inside), monitored by quinacrine fluorescence quenching, was also partially inhibited by vanadate (Churchill and Sze 1983 Plant Physiol 71: 610-617). Here we show that the vanadate-insensitive, electrogenic ATPase activity was enriched in the low density vesicles (1-4% dextran or 25-32% sucrose) while the vanadate-sensitive activity was enriched at 4% to 7% dextran or 32% to 37% sucrose. The low-density ATPase was stimulated by Cl⁻ and inhibited by NO⁻₃ or 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS). The distribution of Cl⁻-stimulated ATPase activity in a linear dextran gradient correlated with the distribution of H⁺ pumping into vesicles as monitored by [¹⁴C]methylamine accumulation. The vanadate-inhibited ATPase was mostly insensitive to anions or DIDS and stimulated by K⁺. These results show that microsomal vesicles of plant tissues have at least two types of electrogenic, proton-pumping ATPases. The vanadate-insensitive and Cl⁻-stimulated, H⁺-pumping ATPase may be enriched in vacuolar-type membranes; the H⁺-pumping ATPase that is stimulated by K⁺ and inhibited by vanadate is most likely associated with plasma membrane-type vesicles.     

Perturbation of Chara Plasmalemma Transport Function by 2[4(2',4'-Dichlorophenoxy)phenoxy]propionic Acid

Electrophysiological measurements on internodal cells of Chara corallina Klein ex Willd., em. R.D.W. revealed that in the presence of (2-[4-(2′,4′-dichlorophenoxy)phenoxy]propionic acid) (diclofop) the membrane potential was very sensitive to the pH of the bathing medium. At pH 5.7, 100 micromolar diclofop caused a slow reduction in the electrogenic component of the membrane potential to the value of −123 ± 5 millivolts. Membrane resistance initially decreased, recovered transiently, then stabilized at approximately 65% of the control value. At pH 7.0, the potential appeared to plateau around −200 millivolts before rapidly declining to −140 ± 4 millivolts; removal of diclofop resulted in recovery of the electrogenic component. Diclofop reduced cytoplasmic ATP levels by 96.4% and 36.6% at pH 5.7 and 7.0, respectively. At pH 8.2, diclofop did not change the ATP concentration significantly, but induced a hyperpolarization of the membrane potential to near −250 millivolts, and also reduced or inhibited the dark-induced hyperpolarization; the light-induced depolarization was reduced to a lesser extent. DCMU applied in the light elicited the same response at the plasmalemma as placing cells in the dark. When K⁺ channels were opened and cells depolarized with 10 millimolar K⁺, diclofop induced a further depolarization of approximately 30 millivolts. Cells decoupled with HPO₄⁻² were still sensitive to diclofop. Currents associated with OH⁻ efflux and HCO₃⁻ influx, as measured with a vibrating probe technique, became spatially destabilized and reduced in magnitude in the presence of diclofop. After 60 minutes, most of the cell surface was engaged in a low level of OH⁻ efflux activity. The results indicate that diclofop may be a proton ionophore at pH 7.0 and 5.7. At pH 8.2, diclofop may inhibit the operation of the H⁺-ATPase and OH⁻ efflux systems associated with HCO₃⁻ transport by perturbing the control processes that integrate the two, without a reduction in ATP concentration.     

Density gradient localization of plasma membrane and tonoplast from storage tissue of growing and dormant red beet : characterization of proton-transport and ATPase in tonoplast vesicles

Membranes from homogenates of growing and of dormant storage roots of red beet (Beta vulgaris L.) were centrifuged on linear sucrose gradients. Vanadate-sensitive ATPase activity, a marker for plasma membrane, peaked at 38% to 40% sucrose (1.165-1.175 grams per cubic centimeter) in the case of growing material but moved to as low as 30% sucrose (1.127 grams per cubic centimeter) during dormancy.

A band of nitrate-sensitive ATPase was found at sucrose concentrations of 25% to 28% or less (around 1.10 grams per cubic centimeter) for both growing and dormant material. This band showed proton transport into membrane vesicles, as measured by the quenching of fluorescence of acridine orange in the presence of ATP and Mg²⁺. The vesicles were collected on a 10/23% sucrose step gradient. The phosphate hydrolyzing activity was Mg dependent, relatively substrate specific for ATP (ATP > GTP > UTP > CTP = 0) and increased up to 4-fold by ionophores. The ATPase activity showed a high but variable pH optimum, was stimulated by Cl⁻, but was unaffected by monovalent cations. It was inhibited about 50% by 10 nanomolar mersalyl, 20 micromolar N,N′-dicyclohexylcarbodiimide, 80 micromolar diethylstilbestrol, or 20 millimolar NO₃⁻; but was insensitive to molybdate, vanadate, oligomycin, and azide. Proton transport into vesicles from the 10/23% sucrose interface was stimulated by Cl⁻, inhibited by NO₃⁻, and showed a high pH optimum and a substrate specificity similar to the ATPase, including some proton transport driven by GTP and UTP.

The low density of the vesicles (1.10 grams per cubic centimeter) plus the properties of H⁺ transport and ATPase activity are similar to the reported properties of intact vacuoles of red beet and other materials. We conclude that the low density, H⁺-pumping ATPase of red beets originated from the tonoplast. Tonoplast H⁺-ATPases with similar properties appear to be widely distributed in higher plants and fungi.

     

ATPase Activity of Pea Cotyledon Submitochondrial Particles: ACTIVATION, SUBSTRATE SPECIFICITY, AND ANION EFFECTS

Submitochondrial particles freshly prepared by sonication from pea cotyledon mitochondria showed low ATPase activity. Activity increased 20-fold on exposure to trypsin. The pea cotyledon submitochondrial particle ATPase was also activated by “aging” in vitro. At pH 7.0 addition of 1 millimolar ATP prevented the activation. ATPase of freshly prepared pea cotyledon submitochondrial particles had a substrate specificity similar to that of the soluble ATPase from pea cotyledon mitochondria, with GTPase > ATPase. “Aged” or trypsin-treated particles showed equal activity with the two substrates. NaCl and NaHCO₃, which stimulate the ATPase but not the GTPase activity of the soluble pea enzyme, were stimulatory to both the ATPase and GTPase activities of freshly prepared submitochondrial particles. However, they were stimulatory only to the ATPase activity of trypsin-treated or “aged” submitochondrial particles. In contrast, the ATPase activity of rat liver submitochondrial particles was stimulated by HCO₃⁻, but inhibited by Cl⁻, indicating that Cl⁻ stimulation is a distinguishing property of the pea mitochondrial ATPase complex.     

K Channels Are Responsible for an Inwardly Rectifying Current in the Plasma Membrane of Mesophyll Protoplasts of Avena sativa

In whole-cell recording, the conductance of the plasma membrane of protoplasts isolated from mesophyll cells of leaves of oat (Avena sativa) was greater for inward than outward current. The inward current in both the whole-cell mode and with isolated patches was dependent on [K⁺]_o. When the membrane voltage was more positive than −50 millivolts, the membrane conductance in the whole-cell mode was low, and K⁺ channels in cell-attached or outside-out patches had a low probability of being open. At a membrane voltage more negative than −50 millivolts, the membrane conductance increased by sevenfold in the whole-cell mode, and the probability of the channels being open increased. The inward current was highly selective for K⁺ compared with Cs⁺, Na⁺, choline or Cl⁻. Low concentrations of [Cs⁺]_o or [Na⁺]_o blocked the inward current in a strongly voltage-dependent fashion. Comparison of single-channel with the macroscopic current yields an estimate of about 200 inwardly rectifying K⁺ channels per cell at a density of 0.035 per square micrometer. At physiological membrane voltages and [K⁺]_o about 10 millimolar, the influx through these channels is sufficient to increase the internal [K⁺] by 2 millimolar per minute. These K⁺ channels are activated by membrane voltages in the normal physiological range and could contribute to K⁺ uptake whenever the membrane is more negative than the K⁺ equilibrium potential.     

Variable Effects of Nitrate on ATP-Dependent Proton Transport by Barley Root Membranes

The effects of NO₃⁻ and assay temperature on proton translocating ATPases in membranes of barley (Hordeum vulgare L. cv California Mariout 72) roots were examined. The membranes were fractionated on continuous and discontinuous sucrose gradients and proton transport was assayed by monitoring the fluorescence of acridine orange. A peak of H⁺-ATPase at 1.11 grams per cubic centimeter was inhibited by 50 millimolar KNO₃ when assayed at 24°C or above and was tentatively identified as the tonoplast H⁺-ATPase. A smaller peak of H⁺-ATPase at 1.16 grams per cubic centimeter, which was not inhibited by KNO₃ and was partially inhibited by vanadate, was tentatively identified as the plasma membrane H⁺-ATPase. A step gradient gave three fractions enriched, respectively, in endoplasmic reticulum, tonoplast ATPase, and plasma membrane ATPase. There was a delay before 50 millimolar KNO₃ inhibited ATP hydrolysis by the tonoplast ATPase at 12°C and the initial rate of proton transport was stimulated by 50 millimolar KNO₃. The time course for fluorescence quench indicated that addition of ATP in the presence of KNO₃ caused a pH gradient to form that subsequently collapsed. This biphasic time course for proton transport in the presence of KNO₃ was explained by the temperature-dependent delay of the inhibition by KNO₃. The plasma membrane H⁺-ATPase maintained a pH gradient in the presence of KNO₃ for up to 30 minutes at 24°C.     

Ion fluxes and abscisic Acid-induced proline accumulation in barley leaf segments

The increase in proline induced by ABA, a process stimulated by NaCl or KCl in barley leaves, did not occur when Na⁺ (or K⁺) was present in the external medium as the gluconate salt, namely with an anion unable to permeate the plasma membrane. However, proline increase was restored, to different extents, by the addition of various chloride salts but not by ammonium chloride. Moreover, it was shown that the stimulation of the process by NaCl (or KCl) was variously affected by the presence of different salts; all the ammonium salts (10 millimolar NH₄⁺ concentration) inhibited this stimulation almost completely. Inhibition by NH₄⁺ was accompanied by a decreased Na⁺ influx (−40%). Also, in the case of Na-gluconate, Na⁺ uptake was reduced and the addition of Cl⁻ as the calcium or magnesium salt (but not as ammonium salt) restored both the ion influxes and the increase in proline typical of NaCl treatments. Both 4,4′-diisothiocyano-2,2′-disulfonic acid stilbene (DIDS), an anion transport inhibitor, and tetraethylammonium chloride (TEA), a K⁺ channels-blocking agent, caused, as well as with a reduction of ion influxes, an inhibition of the proline accumulation. The inhibition was practically total with 1 millimolar DIDS and about 80% with 20 millimolar TEA. A possible role of ion influxes in the process leading to the increase in proline induced by ABA is proposed.     

Ion channels in Arabidopsis plasma membrane : transport characteristics and involvement in light-induced voltage changes

White light (25 watts per square meter) induced an increase in plasma membrane K⁺-channel activity and a 30- to 70-millivolt transient membrane depolarization (completed in 2-3 minutes) in Arabidopsis thaliana leaf mesophyll cells. Transport characteristics of three types of ion channels in the plasma membrane were determined using inside-out patches. With 220 millimolar K⁺ on the cytoplasmic side of the patch and 50 millimolar K⁺ in the pipette, (220/50 K), the open-channel current-voltage curves of these channels were sigmoidal and consistent with an enzyme kinetic model. Two channel types were selective for K⁺ over Na⁺ and Cl⁻. One (named PKC1) had a maximum conductance (G_max) of 44 picosiemens at a membrane voltage (V_m) of −65 mV in (220/50 K) and is stimulated by light. The other (PKC2) had G_max = 66 picosiemens at V_m = 60 millivolts in (220/50 K). The third channel type (PCC1) transported K⁺ and Na⁺ about equally well but not Cl⁻. It had G_max = 109 picosiemens at V_m = 55 millivolts in (250/50 K) with 10 millimolar Ca²⁺ on the cytoplasmic side. Reducing Ca²⁺ to 0.1 millimolar increased PCC1 open-channel currents by approximately 50% in a voltage-independent manner. Averaged over time, PKC2 and PCC1 currents strongly outward rectified and PKC1 currents did so weakly. Reductants (1 millimolar dithiothreitol or 10 millimolar β-mercaptoethanol) added to the cytoplasmic side of an excised patch increased the open probability of all three channel types.     

Isolation and transport properties of protoplasts from cortical cells of corn roots

A procedure was developed for the enzymic isolation of large quantities of protoplasts from the cortex of Zea mays L. WF9 × MO 17 roots. Cortex was separated from the primary root, sectioned, and the cell walls digested for 3.5 hours in 2% (w/v) Cellulysin, 0.1% Pectolyase Y-23, 1 millimolar CaCl₂, 0.05% bovine serum albumin, 0.5 millimolar dithiothreitol in 0.6 molar mannitol (pH 5.6). Cortical cell protoplasts were collected by centrifugation and purified by flotation in a Ficoll step gradient. The yield of protoplasts was approximately 650 × 10³/gram fresh tissue. To obtain maximum yield it was essential to include an effective pectinase (Pectolyase Y-23) and protectants (bovine serum albumin and dithiothreitol) in the digestion medium.

Cortical cell protoplasts exhibited energy-dependent uptake of K⁺ (⁸⁶Rb), H₂³²PO₄⁻, and ³⁶Cl⁻ as well as net H⁺ extrusion. Ion fluxes were sustained for at least 3 hours. Influx of K⁺ was highest between pH 7.5 and 8.0, whereas the influx of H₂PO₄⁻ was greatest between pH 4.0 and 5.0. K⁺ and H₂PO₄⁻ influx and net H⁺ efflux were inhibited by respiratory poisons such as cyanide (0.1 millimolar) and oligomycin (5 micrograms per milliliter), and by inhibitors of plasma membrane ATPase such as diethylstilbestrol (50 micromolar). Calculated flux for Cl⁻ was low, but not greatly different from that observed for other plant cells. K⁺ flux was somewhat high, probably because the K⁺ concentration in the cortical cells was below steady-state. The results indicate that isolated cortical cell protoplasts retain transport properties which are similar to those of root tissue.

     

Phosphate Transport across the Plasma Membrane of Wheat Leaf Protoplasts: Characteristics and Inhibitor Specificities

The kinetics and inhibitor specificities of phosphate transport across the plasma membrane of wheat leaf mesophyll protoplasts have been examined. Studies were also carried out on the effects of light and pH on phosphate transport and the plasma membrane electropotential. At pH 5.8 (30°C), protoplasts accumulated phosphate at the rate of 3.9 ± 0.2 nanomoles per milligram protein per hour. Phosphate uptake rates and inhibitor specificities for the leaf cell plasma membrane phosphate transporter were qualitatively similar to those observed with root protoplasts. Neither picrylsulfonic acid, or p-chloromercuribenzene sulfonate affected phosphate uptake significantly at 0.1 millimolar. Of all compounds tested, carbonyl cyanide-p-trifluoromethoxy phenylhydrazone was the most effective inhibitor of phosphate uptake (60% at 0.1 millimolar). Tribenzylphosphate inhibited uptake by 34% while dibenzylphosphate had no effect. The plasma membrane electropotential was found to be −37 ± 3 millivolts. Initiation of photosynthesis lowered the membrane potential to −39 ± 3 millivolts. Inhibition of phosphate uptake by 34% with the substrate analog tribenzylphosphate resulted in a measured membrane potential of −33 ± 3 millivolts. These changes in potential were not significant at the 5% probability level. Phosphate uptake rates remained constant under photosynthetic and nonphotosynthetic conditions. The utility of tribenzylphosphate as an inhibitor in plant systems is demonstrated.     

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.

     

Preparation of Membrane Vesicles Enriched in ATP-Dependent Proton Transport from Suspension Cultures of Tomato Cells

Membranes enriched in ATP-dependent proton transport were prepared from suspension cultures of tomato cells (Lycopersicon esculentum Mill cv VF36). Suspension cultures were a source of large quantities of membranes from rapidly growing, undifferentiated cells. Proton transport activity was assayed as quench of acridine orange fluorescence. The activity of the proton translocating ATPase and of several other membrane enzymes was measured as a function of the cell culture cycle. The relative distribution of the enzymes between the 3,000, 10,000, and 100,000g pellets remained the same throughout the cell culture cycle, but yield of total activity and activity per gram fresh weight with time had a unique profile for each enzyme tested. Maximal yield of the proton translocating ATPase activity was obtained from cells in the middle logarithmic phase of growth, and from 50 to 90% of the activity was found in the 10,000g pellet. The proton translocating ATPase activity was separable from NADPH cytochrome c reductase and cytochrome c oxidase on a sucrose gradient. Proton transport activity had a broad pH optimum (7.0-8.0), was stimulated by KCl with a K_m of 5 to 10 millimolar, stimulation being due to the anion, Cl⁻, and not the cation, K⁺, and was not inhibited by vanadate, but was inhibited by NO₃⁻. The activity is tentatively identified as the tonoplast ATPase.     

Proton extrusion by wheat roots exhibiting severe aluminum toxicity symptoms

The mechanisms of Al rhizotoxicity are not known, but disruption of membrane function has been a persistent hypothesis. The objective of this study was to establish whether cells of Al-cultured wheat roots (Triticum aestivum L. cv Tyler) exhibiting severe Al toxicity symptoms were capable of vigorous proton extrusion. The membrane electrical potential difference (E_m) was measured in individual cells throughout the first centimeter of root tips during perfusion with Al solutions similar to or more concentrated than those of the culture medium. For both Al-cultured and control roots the resting E_m was −100 millivolts, and 1 millimolar acetic acid induced cyanide-sensitive hyperpolarizations to −180 millivolts at a maximum rate of −30 millivolts per minute. Al, like Ca²⁺, enhanced the negativity of the E_m of cells already treated with acetic acid. Both acetic acid and fusicoccin stimulated net proton extrusion from Al-cultured and control roots, both of which also extruded protons in the absence of these stimulants. These results demonstrate that wheat roots exhibiting severe Al toxicity symptoms had an undiminished capacity to extrude protons, that the membranes were intact, and that ATP synthesis was sufficient to supply the proton-translocating ATPases.     

Electrical noise measurements on red beet vacuoles : another way to detect the ATPase activity

The vacuolar potential (V_vac) and its fluctuations were recorded in red beet vacuoles (Beta vulgaris L.). Measurements with vacuoles in their suspension medium gave V_vac = 10 ± 2 millivolts (referred to the external medium) when 3 molar KCl microelectrodes were used. Buffering the microelectrode filling solution at pH 7.7 reversed the sign of the potential: V_vac = −7 ± 2 millivolts. The magnitude of the potential fluctuations was lowered by dilution (5-1000 times) with the suspension medium containing components released by the cells during the mechanical preparation. Fluctuations were decreased by 50 millimolar KNO₃ while they were enhanced by 5 millimolar ATP-Mg. No noticeable change in membrane resistance was detected. The presence of an ATPase bound to the tonoplast may explain the recorded noise spectra. These spectra imply a close connection between the rate of ATPase functioning and the magnitude of ionic fluxes across the tonoplast. It is suggested that noise analysis could be used to detect ATPase (or related enzyme) activity in vacuoles. Possible use of H⁺ diffusion through a buffered microelectrode, to modify intravacuolar pH, is also suggested.     

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.     

Electrostatic Changes in Lycopersicon esculentum Root Plasma Membrane Resulting from Salt Stress

Salinity-induced alterations in tomato (Lypersicon esculentum Mill. cv Heinz 1350) root plasma membrane properties were studied and characterized using a membrane vesicle system. Equivalent rates of MgATP-dependent H⁺-transport activity were measured by quinacrine fluorescence (ΔpH) in plasma membrane vesicles isolated from control or salt-stressed (75 millimolar salt) tomato roots. However, when bis-[3-phenyl-5-oxoisoxazol-4-yl] pentamethine was used to measure MgATP-dependent membrane potential (ΔΨ) formation, salt-stressed vesicles displayed a 50% greater initial quench rate and a 30% greater steady state quench than control vesicles. This differential probe response suggested a difference in surface properties between control and salt-stressed membranes. Fluorescence titration of vesicles with the surface potential probe, 8-anilino-1-napthalenesulphonic acid (ANS) provided dissociation constants (K_d) of 120 and 76 micromolar for dye binding to control and salt-stressed vesicles, respectively. Membrane surface potentials (Ψ_o) of−26.0 and −13.7 millivolts were calculated for control and salt-stressed membrane vesicles from the measured K_d values and the calculated intrinsic affinity constant, K_i. The concentration of cations and anions at the surface of control and salt-stressed membranes was estimated using Ψ_o values and the Boltzmann equation. The observed difference in membrane surface electrostatic properties was consistent with the measured differences in K⁺-stimulated kinetics of ATPase activity between control and salt-stressed vesicles and by the differential ability of Cl⁻ ions to stimulate H⁺-transport activity. Salinity-induced changes in plasma membrane electrostatic properties may influence ion transport across the plasma membrane.     

H-ATPase Activity from Storage Tissue of Beta vulgaris: I. Identification and Characterization of an Anion-Sensitive H-ATPase

Microsomal membranes isolated from red beet (Beta vulgaris L.) storage tissue were found to contain high levels of ionophore-stimulated ATPase activity. The distribution of this ATPase activity on a continuous sucrose gradient showed a low density peak (1.09 grams per cubic centimeter) that was stimulated over 400% by gramicidin and coincided with a peak of NO₃⁻-sensitive ATPase activity. At higher densities (1.16-1.18 grams per cubic centimeter) a shoulder of gramicidin-stimulated ATPase that coincided with a peak of vanadate-sensitive ATPase was apparent. A discontinuous sucrose gradient of 16/26/34/40% sucrose (w/w) was effective in routinely separating the NO₃⁻-sensitive ATPase (16/26% interface) from the vanadate-sensitive ATPase (34/40% interface). Both membrane fractions were shown to catalyze ATP-dependent H⁺ transport, with the transport process showing the same differential sensitivity to NO₃⁻ and vanadate as the ATPase activity.

Characterization of the lower density ATPase (16/26% interface) indicated that it was highly stimulated by gramicidin, inhibited by KNO₃, stimulated by anions (Cl⁻ > Br⁻ > acetate > HCO₃⁻ > SO₄²⁻), and largely insensitive to monovalent cations. These characteristics are very similar to those reported for tonoplast ATPase activity and a tonoplast origin for the low density membrane vesicles was supported by comparison with isolated red beet vacuoles. The membranes isolated from the vacuole preparation were found to possess an ATPase with characteristics identical to those of the low density membrane vesicles, and were shown to have a peak density of 1.09 grams per cubic centimeter. Furthermore, following osmotic lysis the vacuolar membranes apparently resealed and ATP-dependent H⁺ transport could be demonstrated in these vacuole-derived membrane vesicles. This report, thus, strongly supports a tonoplast origin for the low density, anion-sensitive H⁺-ATPase and further indicates the presence of a higher density, vanadate-sensitive, H⁺-ATPase in the red beet microsomal membrane fraction, which is presumably of plasma membrane origin.

     

Characterization of Anion Effects on the Nitrate-Sensitive ATP-Dependent Proton Pumping Activity of Soybean (Glycine max L.) Seedling Root Microsomes

The ATP-dependent proton-pumping activity of soybean (Glycine max L.) root microsomes is predominantly nitrate sensitive and presumably derived from the tonoplast. We used microsomes to characterize anion effects on proton pumping of the tonoplast vesicles using two distinctly different techniques.

Preincubation of the vesicles with nitrate caused inhibition of proton pumping and ATPase activity, with similar concentration dependence. Fluoride, which preferentially inhibits the plasma membrane ATPase, inhibited ATPase activity strongly at concentrations which did not affect proton pumping activity.

Addition of potassium salts, after a steady-state pH gradient is established in the absence of such salts, caused an increased pH gradient which was due to alleviation of Δ Ψ and subsequent increased influx of H⁺ into these vesicles. This anion-induced increase in the pH gradient could be used as a measure of the relative anion permeabilities, which were of the order Br⁻ = NO₃⁻ > Cl⁻ SO₄²⁻. Phosphate and fluoride caused no increase in the pH gradient. Since the concentration dependence of KCl- and KNO₃-induced quenching exhibited a saturable component, and since H⁺ uptake was increased by only certain anions, the data suggest that there may be a relatively specific anion channel associated with tonoplast-derived vesicles.