THE INVOLVEMENT OF A PLASMA MEMBRANE H+‐ATPase IN THE BLUE‐LIGHT ENHANCEMENT OF PHOTOSYNTHESIS IN LAMINARIA DIGITATA (PHAEOPHYTA)1

Many brown algae, including the kelp Laminaria digitata (Huds.) Lamour., exhibit enhanced photosynthesis when they are given a small amount of blue‐light in addition to a background of saturating red light. This blue light effect is correlated with an increased uptake of carbon. In the present study, we tested the hypothesis that blue light acts by increasing the activity of a plasma membrane H ⁺ ‐ATPase, thereby promoting an active carbon uptake across the plasma membrane. Photosynthetic carbon uptake was studied in pH‐drift experiments under illumination with red and blue light and using different inhibitors. Vanadate, an inhibitor of plasma membrane H ⁺ ‐ATPases, had a minor inhibitory effect on carbon uptake rates under saturating red light conditions, but inhibited the blue‐light enhancement by approximately 60%. An inhibitor of external carbonic anhydrase, acetazolamide, decreased the carbon uptake in both red light and in red plus blue light by 48% and 68%, respectively. These results suggest that photosynthetic carbon uptake depends on an external carbonic anhydrase under both red and red plus blue light conditions, and that blue light induces an increased activity of a P‐type H ⁺ ‐ATPase in the plasma membrane. The proton buffer Tris, which has a buffering capacity similar to vanadate in seawater, had no inhibitory effect on carbon uptake rates neither in red light nor in red plus blue light, showing that the inhibitory effect of vanadate is not caused by its effect as a buffer. The blue‐light enhancement was also abolished by a protein kinase inhibitor (H‐7), suggesting that the transduction of the blue‐light signal involves a protein kinase, which activates the plasma membrane H ⁺ ‐ATPase by phosphorylation.     

Effect of Mg2+, tritorn X-100 and temperature on basal and FC- stimulated plasma membrane ATPase activity

H⁺-pumping driven by the plasma membrane H⁺-ATPase in membrane vesicles from 24-hour-old radish seedlings is stimulated by pretreatment of the membranes with fusicoccin (FC) (Rasi-Caldogno et al., Plant Physiol., 82 (1986) 121).FC-pretreatment stimulates also the ATPase activity, but to a lesser extentthan H⁺-pumping. More than 80% of the ATPase activity is inhibited by 100 μM vanadate or by 3 mM Ca²⁺.Preincubation of diluted membranes in the presence of 5 mM MgSO₄ without ATP lowers both ATPase and H⁺-pumping activity by 20—30% without affecting FC-stimulated activities (i.e. the differences between FC-treated samples and the controls).After preincubation with MgSO₄, ATPase activity of membranes pretreatedwith or without FC is delivery affected by Triton X-100 and by temperature: Triton X-100 activates FC-stimulated ATPase more than that of the controls and an increase of temperature (between 13 and 33°C) enhances ATPase activity of the controls more than the FC-stimulated one.These results have been interpreted as suggesting that, while H⁺-pumping in this membrane fraction is driven only by the plasma membrane H⁺-ATPase, ATP-hydrolysis is catalyzed by two different enzymes (or forms of the same enzxxyme) diversely sensitive to FC, Triton X-100 and temperature and possibly diversely involved in H⁺-pumping.     

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.

     

Effects of vanadate on the ATP content,ATPase activity and phosphate absorption capacity of maize roots

Although the sensitivity of the plasma membrane H⁺-ATPase to vanadate is well known, the metabolic response of plant cells to vanadate is less well characterised in vivo and its use as an inhibitor in whole plant experiments has had mixed success. Experiments with maize (Zea mays, L.) roots and with purified plasma membrane fractions from the same tissues showed that exposure to vanadate caused: (i) a reduction in the capacity for phosphate uptake; (ii) a reduction in the extractable ATPase activity from the tissue; and (iii) a significant increase in the ATP level. The measurements on the extractable ATPase activity and the ATP level showed that the effect of vanadate developed slowly, apparently reflecting the slow accumulation of intracellular vanadate. The marked effect of vanadate on the ATP level-exposure to 500 M vanadate for 5 h doubled the ATP content of the roots tips-indicates that there is no stringent control over the ATP level in the roots and that the plasma membrane H⁺-ATPase activity is likely to have a significant role in determining the ATP level under normal conditions.     

Ca2+-dependent ATPase associated with plasma membrane from a calcareous alga, Serraticardia maxima (Corallinaceae, Rhodophyta)

The plasma membrane was isolated from a calcareous red alga, Serraticardia maxima (Yendo) Silva (Corallinaceae), by aqueous two-phase partitioning. Its purity was examined with marker enzymes, Mg²⁺-dependent ATPase, inosine diphosphatase, cytochrome c oxidase and NADH-cytochrome c reductase, as well as the sensitivity of Mg²⁺-dependent ATPase to vanadate, azide and nitrate. The results showed that the isolated plasma membrane was purified enough to study its functions. Electron microscopic observations on thin tissue sections revealed that most vesicles of the isolated plasma membrane were stained by the plasma membrane specific stain, phosphotungstic acid-chromic acid. Mg²⁺- or Ca²⁺-dependent ATPases were associated with the plasma membrane. Ca²⁺-dependent ATPase was activated at physiological cytoplasmic concentrations of Ca²⁺ (0.1–10 μmol/L). However, calmodulin (0.5 μmol/L) did not affect its activity. The pH optimum was 8.0, in contrast to 7.0 for Mg²⁺-dependent ATPase. The isolated plasma membrane vesicles were mostly right side-out. To test for H⁺-translocation, right side-out vesicles were inverted; 27% of vesicles were inside-out after treatment with Triton X-100. The inside-out plasma membrane vesicles showed reduction of quinacrine fluorescence in the presence of 1 mmol/L ATP and 100 μmol/L Ca²⁺. The reduced fluorescence was recovered with the addition of 10 mmol/L NH₄Cl, or 5 μmol/L nigericin plus 50 mmol/L KCl. UTP and CTP substituted for ATP, but ADP did not. Ca²⁺-dependent ATPase might pump H⁺ out in the physiological state. The acidification by this pump might be coupled with alkalinization at the calcifying sites, which induces calcification.     

Light-induced h secretion and the relation to senescence of oat leaves

When abraded oat (Avena sativa L. cv Victory) leaf segments are floated on KCl solution, white light causes acidification of the solution external to leaf tissue. The presence of mannitol amplifies the light-induced proton secretion. Mature leaves as well as young ones acidify the medium in light, while senescing leaves (after 3 to 4 days incubated in water in the dark) lose the ability to produce this response to light. The decrease in H⁺ secretion is already measureable after as little as 30 minutes in darkness, while the increase in proteolysis rate was detected only after 6 hours in dark. The decrease in capacity to secrete protons is one of the symptoms of leaf senescence. Moreover, fusicoccin mimics light in stimulating H⁺ pumping and delaying the senescence in the dark. On the other hand vanadate, an apparent inhibitor of plasma membrane H⁺ ATPase, blocks the acidification and promotes the chlorophyll and protein degradation in leaf segments during the 2-day period of incubation. These results, which show a parallel between cessation of H⁺ secretion and acceleration of senescence, may suggest a regulatory role for H⁺ secretion in leaf senescence.     

Characterization of nigericin-stimulated ATPase from sealed microsomal vesicles of tobacco callus

To understand the function and membrane origin of ionophore-stimulated ATPases, the activity of nigericin-stimulated ATPase was characterized from a low-density microsomal fraction containing sealed vesicles of autonomous tobacco (Nicotiana tabacum Linnaeous cv. Wisconsin no. 38) callus. The properties of KCl-stimulated, Mg-requiring ATPases (KCl-Mg,ATPase) were similar in the absence or presence of nigericin. Nigericin (or gramicidin) stimulation of a KCl-Mg,ATPase activity was optimum at pH 6.5 to 7.0. The enzyme was inhibited completely by N,N′-dicyclohexylcarbodiimide (10 μm), tributyltin (5 μm), and partially by vanadate (200 μm), but it was insensitive to fusicoccin and mitochondrial ATPase inhibitors, such as azide (1 mm) and oligomycin (5 μg/ml). The ATPase was more sensitive to anions than cations. Cations stimulated ATPase activity with a selectivity sequence of NH₄⁺ > K⁺, Rb⁺, Cs⁺, Na⁺, Li⁺ > Tris⁺. Anions stimulated Mg, ATPase activity with a decreasing sequence of Cl⁻ = acetate > SO₄²⁻ > benzene sulfonate > NO₃⁻. The anion stimulation was caused partly by dissipation of the electrical potential (interior positive) by permeant anions and partly by a specific ionic effect. Plant membranes had at least two classes of nigericin-stimulated ATPases: one sensitive and one insensitive to vanadate. Many of the properties of the nigericin-sensitive, salt-stimulated Mg,ATPase were similar to a vanadate-sensitive plasma membrane ATPase of plant tissues, yet other properties (anion stimulation and vanadate insensitivity) resembled those of a tonoplast ATPase. These results support the idea that nigericin-stimulated ATPases are mainly electrogenic H⁺ pumps originated in part from the plasma membrane and in part from other nonmitochondrial membranes, such as the tonoplast.     

Effects of vanadate on the plasma membrane ATPase of red beet and corn

The effect of vanadate on the plant plasma membrane ATPase were investigated in plasma membrane fractions derived from corn roots (Zea mays L.) and red beets (Beta vulgaris L.). The K_i for vanadate inhibition of the plasma membrane ATPase from corn roots and red beets was between 6 and 15 micromolar vanadate. In both membrane fractions, 80% to 90% of the total ATPase was inhibited at vanadate concentrations below 100 micromolar. Vanadate inhibition was optimal at pH 6.5, enhanced by the presence of K⁺, and was partially reversed by 1 millimolar EDTA. The Mg:ATP kinetics for the plasma membrane ATPase were hyperbolic in both the absence and presence of vanadate. Vanadate decreased both the K_m and V_max of the red beet plasma membrane ATPase, indicating that vanadate inhibits the ATPase uncompetitively. These results indicate many similarities with respect to vanadate inhibition between the plant plasma membrane ATPase and other major iontranslocating ATPases from fungal and animal cells. The high sensitivity to vanadate reported here, however, differs from other reports of vanadate inhibition of the plant plasma membrane ATPase from corn, beets, and in some instances oats.     

Age-dependent changes of the ion content and the circadian leaf movement period in thePhaseolus pulvinus

The circadian movement of the lamina of primary leaves ofPhaseolus coccineus L. depends on circadian changes of the K⁺, Cl^- and (depending on the Cl^- availability) malate content in the swelling and shrinking motor cells of the laminar pulvinus. After sowing in soil, the laminar pulvinus develops within about 26 days. When the leaves emerge from the soil (about 6 days after sowing) and the pulvinus starts with the diurnal movement (about 9 days after sowing) the pulvinar dimensions are about half of those of the mature pulvinus. The anatomical structure, however, is basically the same as in the developed pulvinus. In soil-grown plants, the K⁺, Cl^- and malate content as well as the period length of the circadian leaf movement rhythm change in the developing pulvinus. In the embryo of the dry seed, the Cl^- content is low (0.03 mmol g^-1 DW), the K⁺ content, however, 22-fold higher than the Cl^- content. When the leaves emerge from the soil, the pulvinar K⁺ and Cl^- content is the same as in the whole embryo of the dry seed. In the developing pulvinus the K⁺ content increases by a factor of 2 and the Cl^- content by a factor of 41 in the mature pulvinus. The pulvinar malate content increases between the 6th and 10th day from about 40 to 180Μmol g^-1 DW, then decreases until the 17th day and remains thereafter on a low level (around 80 Μmol g^-1 DW). These results indicate that the Cl^- availability increases in the developing pulvinus with age. It explains furthermore why in young leaves malate was found as counterion to K⁺ in the osmotic leaf movement motor, in older ones, however, Cl^-. The circadian leaf movement starts 9 days after sowing. The period length decreases during the development of the pulvinus from 31.3 to 28.6 h in leaves of intact soil-grown plants. In leaves which were cut from the plants and immersed with their petioles in distilled water, the age dependent decrease of the period length is also found. However, the period lengths are shorter by more than 1 h than in the leaves of intact plants. The increasing Cl^- availability in the developing pulvinus does not seem to be the cause for the age dependent shortening of the period length, because the period length in 22 days old Cl^- deprived pulvini is the same as in 22 days old pulvini with a high Cl^- content.     

H fluxes in excised samanea motor tissue : I. Promotion by light

Previous investigators revealed that white light-promoted leaflet opening in Samanea saman (Jacq) Merrill depends upon K⁺ uptake by extensor cells and efflux from flexor cells of the pulvinus, while dark-promoted closure depends upon K⁺ fluxes in the opposite directions. We now monitored H⁺ fluxes during pulvinar movement to test a model proposing coupled H⁺/K⁺ fluxes. H⁺ fluxes were monitored by measuring changes in the pH of a weakly buffered solution (initial pH = 5.5) bathing excised strips of extensor or flexor tissue. White light at hour 3 of the usual dark period promoted pulvinar opening, H⁺ efflux from extensor cells and uptake by flexor cells, while darkness at hours 2 to 4 of the usual light period promoted pulvinar closure, H⁺ uptake by extensor cells and efflux from flexor cells. The following conditions altered H⁺ fluxes during dark-promoted closure. (a) Light reversed the directions of the fluxes in both extensor and flexor cells. (b) Anoxia increased the rate of H⁺ uptake by extensor cells and promoted H⁺ uptake (rather than efflux) by flexor cells, consistent with an outwardly directed H⁺ pump. KCN showed similar effects initially, but they were transient. (c) Increase in external pH from 5.5 to 6.7 promoted H⁺ efflux (rather than uptake) by extensor cells and increased the rate of H⁺ efflux from flexor cells, presumably by decreasing the rate of inward diffusion. (d) Change in external K⁺ did not alter H⁺ fluxes by extensor cells, but removal of external K⁺ decreased the rate of H⁺ efflux from flexor cells by 70%. These observations support a model for coupled H⁺/K⁺ fluxes in pulvinar cells during light-and dark-promoted leaflet movements.     

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

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

Effects of glycine on dark-and ligh-induced pulvinar movements and modifications of proton fluxes in the pulvinus of Mimosa pudica during glycine uptake

Glycine (1–50 mM) increases the rate of the dark-induced (scotonastic) movements and decreases the amplitude and the rate of the light-induced (photonastic) movements of the secondary pulvini of Mimosa pudica leaves. The uptake of glycine is accompanied by a long-lasting dose-dependent increase in the alkalinity of the bathing medium of the excised pulvini. The data are in agreement with a H⁺-glycine co-transport mechanism within the pulvinar cells. Fusicoccin (50 M), known to promote H⁺–K⁺ exchange, antagonizes the effects of glycine on the movements and the alkalization of the bathing medium of the excised pulvini. The present results argue for the hypothesis that proton fluxes mediate the scotonastic and photonastic pulvinar movements.Abbreviations Gly glycine - FC fusicoccin - P₁ primary pulvinus - P₂ secondary pulvinus     

ATPase and Proton Pumping Activities in Cotyledons and other Phloem-Containing Tissues2Ricinus communis

ATPase activity was investigated in phloem-containing tissuesof Ricinus communis in relation to its proposed role in phloemloading. Cytochemical staining of cotyledons revealed an ATP-hydrolysingactivity on the plasma membrane of the sieve tube/companioncell complex. Microsomal fractions prepared from cotyledonsand main veins contained a Mg²⁺-dependent ATPase activity whichshowed low stimulation by KC1 particularly at pH 6.5. The pHoptimum was at pH 8.5 to 90, although the effect of azide indicatedthe presence of mitochondrial ATPase. At pH 6.5, the cited optimumfor plasma membrane ATPase, the activity showed strong inhibitionby PCMBS, vanadate and DCCD. A high pyrophosphatase activitywas observed at pH 8.5. Acidification of the medium by intactcotyledons was increased by fusicoccin and inhibited by PCMBS,NEM and vanadate. Proton pumping by microsomal vesicles as measuredby quinacrine fluorescence was also inhibited by PCMBS, NEMand vanadate. Sucrose uptake by cotyledon discs showed stronginhibition by PCMBS, NEM and CCCP but was little affected byvanadate. Sucrose uptake varied with the developmental stageof the cotyledons and this correlated with microsomal ATPaseactivity measured at pH 6.5, although the precise cellular originof this activity is not certain. The results are discussed inrelation to the role of ATPase activity and proton pumping inphloem loading. Key words: ATPase, phlocm loading, proton pumping, Ricinus communis, sucrose     

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.     

The Ca-Transport ATPase of Plant Plasma Membrane Catalyzes a nH/Ca Exchange

Microsomal vesicles from 24-hour-old radish (Raphanus sativus L.) seedlings accumulate Ca²⁺ upon addition of MgATP. MgATP-dependent Ca²⁺ uptake co-migrates with the plasma membrane H⁺-ATPase on a sucrose gradient. Ca²⁺ uptake is insensitive to oligomycin, inhibited by vanadate (IC₅₀ 40 micromolar) and erythrosin B (IC₅₀ 0.2 micromolar) and displays a pH optimum between pH 6.6 and 6.9. MgATP-dependent Ca²⁺ uptake is insensitive to protonophores. These results indicate that Ca²⁺ transport in these microsomal vesicles is catalyzed by a Mg²⁺-dependent ATPase localized on the plasma membrane. Ca²⁺ strongly reduces ΔpH generation by the plasma membrane H⁺-ATPase and increases MgATP-dependent membrane potential difference (Δψ) generation. These effects of Ca²⁺ on ΔpH and Δψ generation are drastically reduced by micromolar erythrosin B, indicating that they are primarily a consequence of Ca²⁺ uptake into plasma membrane vesicles. The Ca²⁺-induced increase of Δψ is collapsed by permeant anions, which do not affect Ca²⁺-induced decrease of ΔpH generation by the plasma membrane H⁺-ATPase. The rate of decay of MgATP-dependent ΔpH, upon inhibition of the plasma membrane H⁺-ATPase, is accelerated by MgATP-dependent Ca²⁺ uptake, indicating that the decrease of ΔpH generation induced by Ca²⁺ reflects the efflux of H⁺ coupled to Ca²⁺ uptake into plasma membrane vesicles. It is therefore proposed that Ca²⁺ transport at the plasma membrane is mediated by a Mg²⁺-dependent ATPase which catalyzes a nH⁺/Ca²⁺ exchange.     

Role of K+ in leaf growth: K+ uptake is required for light-stimulated H+ efflux but not solute accumulation

The stimulation of dicotyledonous leaf growth by light depends on increased H⁺ efflux, to acidify and loosen the cell walls, and is enhanced by K⁺ uptake. The role of K⁺ is generally considered to be osmotic for turgor maintenance. In coleoptiles, auxin‐induced cell elongation and wall acidification depend on K⁺ uptake through tetraethylammonium (TEA)‐sensitive channels (Claussen et al., Planta 201, 227–234, 1997), and auxin stimulates the expression of inward‐rectifying K⁺ channels ( Philippar et al. 1999) . The role of K⁺ in growing, leaf mesophyll cells has been investigated in the present study by measuring the consequences of blocking K⁺ uptake on several growth‐related processes, including solute accumulation, apoplast acidification, and membrane polarization. The results show that light‐stimulated growth and wall acidification of young tobacco leaves is dependent on K⁺ uptake. Light‐stimulated growth is enhanced three‐fold over dark levels with increasing external K⁺, and this effect is blocked by the K⁺ channel blockers, TEA, Ba⁺⁺ and Cs⁺. Incubation in 10 mm TEA reduced light‐stimulated growth and K⁺ uptake by 85%, and completely inhibited light‐stimulated wall acidification and membrane polarization. Although K⁺ uptake is significantly reduced in the presence of TEA, solute accumulation is increased. We suggest that the primary role of K⁺ in light‐stimulated leaf growth is to provide electrical counterbalance to H⁺ efflux, rather than to contribute to solute accumulation and turgor maintenance.     

Characteristics and Regulatory Properties of the H+-ATPase in a Plasma Membrane Fraction Purified from Arabidopsis thaliana

The aqueous two-phase partitioning technique was utilized to isolate a plasma membrane (PM) fraction from etiolated seedlings of Arabidopsis thaliana. The purification procedure adopted yielded a fraction highly enriched in PM as compared to inner membranes, with a recovery of about 30%, as judged from the activities of PM markers such as vanadate-sensitive ATPase, FC binding and UDP-glucose sterol glucosyltransferase. The purified PM fraction displayed vanadate-sensitive H⁺ pumping activity. Its purity was confirmed by the biochemical characteristics of its ATPase activity assayed in the absence of Ca²⁺: sensitivity to vanadate (IC₅₀ ca. 1 μM), Mg²⁺-dependence, insensitivity to molybdate, oligomycin and nitrate, pH optimum at 6.6. The PM H⁺-ATPase activity was stimulated by fusicoccin and by a controlled treatment of the PM with trypsin. In both cases stimulation was much stronger on the activity assayed at pH 7.5 than on the activity at pH 6.6. Moreover, neither fusicoccin nor the treatment with trypsin stimulated the portion of activity (30 to 40% at pH 7.5) which decayed upon preincubation of the PM in assay medium without ATP.     

Potassium uptake by platelets from Down's syndrome and normal subjects

Potassium uptake was studied in Down's syndrome (D.S.) platelets to determine if the Na⁺/K⁺ ATPase mediated movement of this ion was decreased compared to normal platelets. Total uptake of ⁴²K was 1.58±0.16 μmoles/hr/10⁹ normal platelets but was decreased to 1.06±0.06 μmoles/hr/10⁹ D.S. platelets (p<.001). Na⁺/K⁺ ATPase mediated (ouabain sensitive) K⁺ uptake was 0.87±0.05 μmoles/hr/10⁹ normal platelets but only 0.54±0.04 μmoles/hr/10⁹ in D.S. platelets (p<.001). As the Na⁺/K⁺ ATPase mediated outward movement of Na⁺ is decreased in D.S. platelets, the present work demonstrates that bidirectional functional imparrment of the Na⁺/K⁺ ATPase pump is present in D.S. platelets.     

ATP-dependent chloride transport in plasma membrane vesicles from Aplysia intestine

A Cl⁻-stimulated ATPase activity, which is sensitive to both thiocyanate and vanadate, has been localized to the plasma membrane of Aplysia enterocytes. Utilizing plasma membrane vesicles from Aplysia enterocytes, ATP stimulated Cl⁻ uptake to approximately 2.5-times that of control in a Na⁺, K⁺ and HCO₃⁻-free medium. This ATP-dependent Cl⁻ uptake was sensitive to both thiocyanate and vanadate. These results are consistent with the hypothesis that the active Cl⁻ absorptive process in Aplysia intestine could be a Cl⁻-stimulated ATPase found in the enterocyte plasma membrane.     

Presence of Na+-Stimulated P-Type ATPase in the Membrane of a Facultatively Anaerobic Alkaliphile, Exiguobacterium aurantiacum

It was found that a facultatively anaerobic alkaliphile, Exiguobacterium aurantiacum, possesses a membrane-bound ATPase, which was activated specifically by Na⁺. The Na⁺-stimulated ATPase activity reached a maximum value at 200 mM NaCl. In the presence of 200 mM NaCl, the activity was drastically reduced by vanadate, a potent inhibitor of P-type ATPase, with a half-maximal inhibition at 1 μM. Incubation of the membranes with [γ-³²P]ATP followed by acidic lithium dodecyl sulfate–polyacrylamide gel electrophoresis demonstrated the existence of two phosphorylated intermediates with apparent molecular masses of 60 and 100 kDa. Only phosphorylation of the 100-kDa polypeptide was inhibited by vanadate. The membrane extract containing Na⁺-stimulated ATPase, when reconstituted into soybean phospholipid vesicles, exhibited ²²Na⁺ transport by the addition of ATP, which was inhibited by vanadate and gramicidin. It is likely that the Na⁺-stimulated ATPase belongs to P-type and is involved in Na⁺ transport. Received: 3 February 1999 / Accepted: 3 March 1999