Localization of plasma membrane H+-ATPase in nodules of Phaseolus vulgaris L.

Legume nodules have specialized transport functions for the exchange of carbon and nitrogen compounds between bacteroids and root cells. Plasma membrane-type (vanadate-sensitive) H⁺-ATPase energizes secondary active transporters in plant cells and it could drive exchanges across peribacteroidal and plasmatic membranes. A nodule cDNA corresponding to a major isoform of Phaseolus vulgaris H⁺-ATPase (designated BHA1) has been cloned. BHA1 is a functional proton pump because after removal of its inhibitory domain and can complement a yeast mutant unable to synthesize a H⁺-ATPase. BHA1 is not nodule-specific, since it is also expressed in roots of uninfected plants. It belongs to the subfamily of plasma membrane H⁺-ATPases defined by the Arabidopsis AHA1, AHA2 and AHA3 genes and the tobacco PMA4 and corn MHA2 genes. In situ hybridization in nodule sections indicates high expression of BHA1 limited to uninfected cells. These results were confirmed by immunocytochemistry. The relatively low expression of plasma membrane-type H⁺-ATPase in Rhizobium-infected cells put a note of caution on the origin of the vanadate-sensitive ATPase described in preparations of peribacteroidal membranes. Also, our results indicate that active transport in symbiotic nodules is most intense at the plasma membrane of uninfected cells and support a specialized role of uninfected tissue for nitrogen transport.     

Blue light activates the plasma membrane H(+)-ATPase by phosphorylation of the C-terminus in stomatal guard cells.

The opening of stomata, which is driven by the accumulation of K(+) salt in guard cells, is induced by blue light (BL). The BL activates the H(+) pump; however, the mechanism by which the perception of BL is transduced into the pump activation remains unknown. We present evidence that the pump is the plasma membrane H(+)-ATPase and that BL activates the H(+)-ATPase via phosphorylation. A pulse of BL (30 s, 100 micromol/m(2)/s) increased ATP hydrolysis by the plasma membrane H(+)-ATPase and H(+) pumping in Vicia guard cell protoplasts with a similar time course. The H(+)-ATPase was phosphorylated reversibly by BL, and the phosphorylation levels paralleled the ATP hydrolytic activity. The phosphorylation occurred exclusively in the C-termini of H(+)-ATPases on both serine and threonine residues in two isoproteins of H(+)-ATPase in guard cells. An endogenous 14-3-3 protein was co-precipitated with H(+)-ATPase, and the recombinant 14-3-3 protein bound to the phosphorylated C-termini of H(+)-ATPases. These findings demonstrate that BL activates the plasma membrane H(+)-ATPase via phosphorylation of the C-terminus by a serine/threonine protein kinase, and that the 14-3-3 protein has a key role in the activation.     

Calcium signaling and sugar-induced activation of plasma membrane H(+)-ATPase in Saccharomyces cerevisiae cells

In this work, we show that glucose-induced activation of plasma membrane H(+)-ATPase from Saccharomyces cerevisiae is strongly dependent on calcium metabolism and that the glucose sensor Snf3p works in a parallel way with the G protein Gpa2p in the control of the pathway. The role of Snf3p is played by the Snf3p C-terminal tail, since in a strain with the deletion of the SNF3 gene, but also expressing a chimera protein formed by Hxt1p (a glucose transporter) and the Snf3p C-terminal tail, a normal glucose-activation process can be observed. We present evidences indicating that Snf3p would be the sensor for the internal signal (phosphorylated sugars) of this pathway that would connect calcium signaling and activation of the plasma membrane ATPase. We also show that Snf3p could be involved in the control of Pmc1p activity that would regulate the calcium availability in the cytosol.     

Iron-induced oxidative damage of corn root plasma membrane H(+)-ATPase

The effect of iron on the activity of the plasma membrane H(+)-ATPase (PMA) from corn root microsomal fraction (CRMF) was investigated. In the presence of either Fe(2+) or Fe(3+) (100-200 microM of FeSO(4) or FeCl(3), respectively), 80-90% inhibition of ATP hydrolysis by PMA was observed. Half-maximal inhibition was attained at 25 microM and 50 microM for Fe(2+) and Fe(3+), respectively. Inhibition of the ATPase activity was prevented in the presence of metal ion chelators such as EDTA, deferoxamine or o-phenanthroline in the incubation medium. However, preincubation of CRMF in the presence of 100 microM Fe(2+), but not with 100 microM Fe(3+), rendered the ATPase activity (measured in the presence of excess EDTA) irreversibly inhibited. Inhibition was also observed using a preparation further enriched in plasma membranes by gradient centrifugation. Addition of 0.5 mM ATP to the preincubation medium, either in the presence or in the absence of 5 mM MgCl(2), reduced the extent of irreversible inhibition of the H(+)-ATPase. Addition of 40 microM butylated hydroxytoluene and/or 5 mM dithiothreitol, or deoxygenation of the incubation medium by bubbling a stream of argon in the solution, also caused significant protection of the ATPase activity against irreversible inhibition by iron. Western blots of CRMF probed with a polyclonal antiserum against the yeast plasma membrane H(+)-ATPase showed a 100 kDa cross-reactive band, which disappeared in samples previously exposed to 500 microM Fe(2+). Interestingly, preservation of the 100 kDa band was observed when CRMF were exposed to Fe(2+) in the presence of either 5 mM dithiothreitol or 40 microM butylated hydroxytoluene. These results indicate that iron causes irreversible inhibition of the corn root plasma membrane H(+)-ATPase by oxidation of sulfhydryl groups of the enzyme following lipid peroxidation.     

Lysophosphatidylcholine specifically stimulates plasma membrane H(+)-ATPase from corn roots

The plasma membrane H(+)-ATPase activity from corn seedling roots is shown to be stimulated 3- to 4-fold by the addition of lysophosphatidylcholine (lysoPC). This effect clearly differs from that of other detergents by both the magnitude and the absence of inhibition at higher concentrations. LysoPC decreases the apparent Km for MgATP, increases Vmax of the ATPase reaction but does not change its pH optimum. On the contrary, the acid phosphatase activity associated with plasma membranes is not influenced by lysoPC. A lysoPC stimulation is also demonstrated for the solubilized preparation of the H(+)-ATPase. It is assumed that lysoPC stimulation of the plant plasma membrane H(+)-ATPase is not only due to permeabilization of the vesicles for MgATP, but also to direct action on the enzyme.     

Characterization of native and reconstituted plasma membrane H+-ATPase from the plasma membrane ofBeta vulgaris

Summary Characteristics of the native and reconstituted H⁺-ATPase from the plasma membrane of red beet (Beta vulgaris L.) were examined. The partially purified, reconstituted H⁺-ATPase retained characteristics similar to those of the native plasma membrane H⁺-ATPase following reconstitution into proteoliposomes. ATPase activity and H⁺ transport of both enzymes were inhibited by vanadate, DCCD, DES and mersalyl. Slight inhibition of ATPase activity associated with native plasma membranes by oligomycin, azide, molybdate or NO ₃ ^– was eliminated during solubilization and reconstitution, indicating the loss of contaminating ATPase activities. Both native and reconstituted ATPase activities and H⁺ transport showed a pH optimum of 6.5, required a divalent cation (Co²⁺>Mg²⁺>Mn²⁺>Zn²⁺>Ca²⁺), and preferred ATP as substrate. The Mg:ATP kinetics of the two ATPase activities were similar, showing simple Michaelis-Menten kinetics. Saturation occurred between 3 and 5mM Mg: ATP, with aK _m of 0.33 and 0.46mM Mg: ATP for the native and reconstituted enzymes, respectively. The temperature optimum for the ATPase was shifted from 45 to 35°C following reconstitution. Both native and reconstituted H⁺-ATPases were stimulated by monovalent ions. Native plasma membrane H⁺-ATPase showed an order of cation preference of K⁺>NH ₄ ⁺ >Rb⁺>Na⁺>Cs⁺>Li⁺>choline⁺. This basic order was unchanged following reconstitution, with K⁺, NH ₄ ⁺ , Rb⁺ and Cs⁺ being the preferred cations. Both enzymes were also stimulated by anions although to a lesser degree. The order of anion preference differed between the two enzymes. Salt stimulation of ATPase activity was enhanced greatly following reconstitution. Stimulation by KCl was 26% for native ATPase activity, increasing to 228% for reconstituted ATPase activity. In terms of H⁺ transport, both enzymes required a cation such as K⁺ for maximal transport activity, but were stimulated preferentially by Cl^– even in the presence of valinomycin. This suggests that the stimulatory effect of anions on enzyme activity is not simply as a permeant anion, dissipating a positive interior membrane potential, but may involve a direct anion activation of the plasma membrane H⁺-ATPase.     

Effect of membrane voltage on the plasma membrane H(+)-ATPase of Saccharomyces cerevisiae

A novel system for generating large interior positive membrane potentials in proteoliposomes was used to examine the effects of membrane voltage on reconstituted plasma membrane H(+)-ATPase from Saccharomyces cerevisiae. The membrane potential-generating system was dependent upon the lipophilic electron carrier tetracyanoquinodimethane, located within the bilayer, to mediate electron flow from vesicle entrapped ascorbate to external K3Fe(CN)6. Membrane potential formation was followed by the potential-dependent probe oxonol V and was found to rapidly reach a steady-state which lasted at least 90 s. A membrane potential of approximately 254 mV was determined under optimal conditions and ATP hydrolysis by wild-type H(+)-ATPase was inhibited from 34 to 46% under these conditions. In contrast, membrane potential had little effect on pma1-105 mutant enzyme suggesting that it is defective in electrogenic proton translocation. Applied membrane voltage was also found to alter the sensitivity of wild-type enzyme to vanadate at concentrations less than 50 microM. These data suggest a coupling between the charge-transfer and ATP hydrolysis domains and establish a solid basis for future probing of the electrogenic properties of the yeast H(+)-ATPase.     

Phenylarsine oxide inhibits the fusicoccin-induced activation of plasma membrane H(+)-ATPase

To investigate the mechanism by which fusicoccin (FC) induces the activation of the plasma membrane (PM) H(+)-ATPase, we used phenylarsine oxide (PAO), a known inhibitor of protein tyrosine-phosphatases. PAO was supplied in vivo in the absence or presence of FC to radish (Raphanus sativus L.) seedlings and cultured Arabidopsis cells prior to PM extraction. Treatment with PAO alone caused a slight decrease of PM H(+)-ATPase activity and, in radish, a decrease of PM-associated 14-3-3 proteins. When supplied prior to FC, PAO drastically inhibited FC-induced activation of PM H(+)-ATPase, FC binding to the PM, and the FC-induced increase of the amount of 14-3-3 associated with the PM. On the contrary, PAO was completely ineffective on all of the above-mentioned parameters when supplied after FC. The H(+)-ATPase isolated from PAO-treated Arabidopsis cells maintained the ability to respond to FC if supplied with exogenous, nonphosphorylated 14-3-3 proteins. Altogether, these results are consistent with a model in which the dephosphorylated state of tyrosine residues of a protein(s), such as 14-3-3 protein, is required to permit FC-induced association between the 14-3-3 protein and the PM H(+)-ATPase.     

Structure-function relationships in membrane segment 6 of the yeast plasma membrane Pma1 H(+)-ATPase

The crystal structures of the Ca(2+)- and H(+)-ATPases shed light into the membrane embedded domains involved in binding and ion translocation. Consistent with site-directed mutagenesis, these structures provided additional evidence that membrane-spanning segments M4, M5, M6 and M8 are the core through which cations are pumped. In the present study, we have used alanine/serine scanning mutagenesis to study the structure-function relationships within M6 (Leu-721-Pro-742) of the yeast plasma membrane ATPase. Of the 22 mutants expressed and analyzed in secretory vesicles, alanine substitutions at two well conserved residues (Asp-730 and Asp-739) led to a complete block in biogenesis; in the mammalian P-ATPases, residues corresponding to Asp-730 are part of the cation-binding domain. Two other mutants (V723A and I736A) displayed a dramatic 20-fold increase in the IC(50) for inorganic orthovanadate compared to the wild-type control, accompanied by a significant reduction in the K(m) for Mg-ATP, and an alkaline shift in the pH optimum for ATP hydrolysis. This behavior is apparently due to a shift in equilibrium from the E(2) conformation of the ATPase towards the E(1) conformation. By contrast, the most striking mutants lying toward the extracellular side in a helical structure (L721A, I722A, F724A, I725A, I727A and F728A) were expressed in secretory vesicles but had a severe reduction of ATPase activity. Moreover, all of these mutants but one (F728A) were unable to support yeast growth when the wild-type chromosomal PMA1 gene was replaced by the mutant allele. Surprisingly, in contrast to M8 where mutations S800A and E803Q (Guerra et al., Biochim. Biophys. Acta 1768: 2383-2392, 2007) led to a dramatic increase in the apparent stoichiometry of H(+) transport, three substitutions (A726S, A732S and T733A) in M6 showed a reduction in the apparent coupling ratio. Taken together, these results suggest that M6 residues play an important role in protein stability and function, and probably are responsible for cation binding and stoichiometry of ion transport as suggested by homology modeling.     

Targeting of two Arabidopsis H(+)-ATPase isoforms to the plasma membrane.

More than 11 different P-type H(+)-ATPases have been identified in Arabidopsis by DNA cloning. The subcellular localization for individual members of this proton pump family has not been previously determined. We show by membrane fractionation and immunocytology that a subfamily of immunologically related P-type H(+)-ATPases, including isoforms AHA2 and AHA3, are primarily localized to the plasma membrane. To verify that AHA2 and AHA3 are both targeted to the plasma membrane, we added epitope tags to their C-terminal ends and expressed them in transgenic plants. Both tagged isoforms localized to the plasma membrane, as indicated by aqueous two-phase partitioning and sucrose density gradients. In contrast, a truncated AHA2 (residues 1-193) did not, indicating that the first two transmembrane domains alone are not sufficient for plasma membrane localization. Two epitope tags were evaluated: c-myc, a short, 11-amino acid sequence, and beta-glucuronidase (GUS), a 68-kD protein. The c-myc tag is recommended for its sensitivity and specific immunodetection. GUS worked well as an epitope tag when transgenes were expressed at relatively high levels (e.g. with AHA2-GUS944); however, evidence suggests that GUS activity may be inhibited when a GUS domain is tethered to an H(+)-ATPase complex. Nevertheless, the apparent ability to localize a GUS protein to the plasma membrane indicates that a P-type H(+)-ATPase can be used as a delivery vehicle to target large, soluble proteins to the plasma membrane.     

Functional expression of plant plasma membrane H(+)-ATPase in yeast endoplasmic reticulum.

Recombinant plant plasma membrane H(+)-ATPase has been produced in a yeast expression system comprising a multicopy plasmid and the strong promoter of the yeast PMA1 gene. Western blotting with a specific monoclonal antibody showed that the plant ATPase is one of the major membrane proteins made by the transformed cells, accounting for about 1% of total yeast protein. The plant ATPase synthesized in yeast is fully active. It hydrolyzes ATP, pumps protons, and the reaction cycle involves a phosphorylated intermediate. Phosphorylation is possible from both ATP and Pi. Unlike the situation in plants, however, most of the plant ATPase is not expressed in the yeast plasma membrane. Rather, the enzyme appears to remain trapped at a very early stage of secretory pathway: insertion into the endoplasmic reticulum. This organelle was observed to proliferate in the form of stacked membranes surrounding the yeast nucleus in order to accommodate the large amount of plant ATPase produced. In this location, the plant ATPase can be purified with high yield (70 mg from 1 kg of yeast) from membranes devoid of endogenous yeast plasma membrane H(+)-ATPase. This convenient expression system could be useful for other eukaryotic membrane proteins and ATPases.     

The plant plasma membrane H(+)-ATPase: structure, function and regulation

The proton-pumping ATPase (H(+)-ATPase) of the plant plasma membrane generates the proton motive force across the plasma membrane that is necessary to activate most of the ion and metabolite transport. In recent years, important progress has been made concerning the identification and organization of H(+)-ATPase genes, their expression, and also the kinetics and regulation of individual H(+)-ATPase isoforms. At the gene level, it is now clear that H(+)-ATPase is encoded by a family of approximately 10 genes. Expression, monitored by in situ techniques, has revealed a specific distribution pattern for each gene; however, this seems to differ between species. In the near future, we can expect regulatory aspects of gene expression to be elucidated. Already the expression of individual plant H(+)-ATPases in yeast has shown them to have distinct enzymatic properties. It has also allowed regulatory aspects of this enzyme to be studied through random and site-directed mutagenesis, notably its carboxy-terminal region. Studies performed with both plant and yeast material have converged towards deciphering the way phosphorylation and binding of regulatory 14-3-3 proteins intervene in the modification of H(+)-ATPase activity. The production of high quantities of individual functional H(+)-ATPases in yeast constitutes an important step towards crystallization studies to derive structural information. Understanding the specific roles of H(+)-ATPase isoforms in whole plant physiology is another challenge that has been approached recently through the phenotypic analysis of the first transgenic plants in which the expression of single H(+)-ATPases has been up- or down-regulated. In conclusion, the progress made recently concerning the H(+)-ATPase family, at both the gene and protein level, has come to a point where we can now expect a more integrated investigation of the expression, function and regulation of individual H(+)-ATPases in the whole plant context.     

Constitutive activation of a plasma membrane H(+)-ATPase prevents abscisic acid-mediated stomatal closure

Light activates proton (H(+))-ATPases in guard cells, to drive hyperpolarization of the plasma membrane to initiate stomatal opening, allowing diffusion of ambient CO(2) to photosynthetic tissues. Light to darkness transition, high CO(2) levels and the stress hormone abscisic acid (ABA) promote stomatal closing. The overall H(+)-ATPase activity is diminished by ABA treatments, but the significance of this phenomenon in relationship to stomatal closure is still debated. We report two dominant mutations in the OPEN STOMATA2 (OST2) locus of Arabidopsis that completely abolish stomatal response to ABA, but importantly, to a much lesser extent the responses to CO(2) and darkness. The OST2 gene encodes the major plasma membrane H(+)-ATPase AHA1, and both mutations cause constitutive activity of this pump, leading to necrotic lesions. H(+)-ATPases have been traditionally assumed to be general endpoints of all signaling pathways affecting membrane polarization and transport. Our results provide evidence that AHA1 is a distinct component of an ABA-directed signaling pathway, and that dynamic downregulation of this pump during drought is an essential step in membrane depolarization to initiate stomatal closure.     

Assessing hydrophobic regions of the plasma membrane H(+)-ATPase from Saccharomyces cerevisiae.

The hydrophobic, photoactivatable probe TID [3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine] was used to label the plasma membrane H(+)-ATPase from Saccharomyces cerevisiae. The H(+)-ATPase accounted for 43% of the total label associated with plasma membrane protein and incorporated 0.3 mol of [125I]TID per mol of 100 kDa polypeptide. The H(+)-ATPase was purified by octyl glucoside extraction and glycerol gradient centrifugation, and was cleaved by either cyanogen bromide digestion or limited tryptic proteolysis to isolate labeled fragments. Cyanogen bromide digestion resulted in numerous labeled fragments of mass less than 21 kDa. Seven fragments suitable for microsequence analysis were obtained by electrotransfer to poly(vinylidene difluoride) membranes. Five different regions of amino-acid sequence were identified, including fragments predicted to encompass both membrane-spanning and cytoplasmic protein structure domains. Most of the labeling of the cytoplasmic domain was concentrated in a region comprising amino acids 347 to 529. This catalytic region contains the site of phosphorylation and was previously suggested to be hydrophobic in character (Goffeau, A. and De Meis, L. (1990) J. Biol. 265, 15503-15505). Complementary labeling information was obtained from an analysis of limited tryptic fragments enriched for hydrophobic character. Six principal labeled fragments, of 29.6, 20.6, 16, 13.1, 11.4 and 9.7 kDa, were obtained. These fragments were found to comprise most of the putative transmembrane region and a portion of the cytoplasmic region that overlapped with the highly labeled active site-containing cyanogen bromide fragment. Overall, the extensive labeling of protein structure domains known to lie outside the bilayer suggests that [125I]TID labeling patterns cannot be unambiguously interpreted for the purpose of discerning membrane-embedded protein structure domains. It is proposed that caution should be applied in the interpretation of [125I]TID labeling patterns of the yeast plasma membrane H(+)-ATPase and that new and diverse approaches should be developed to provide a more definitive topology model.     

Characterization of H(+)-ATPase activity in plasma membrane from pea seedlings under altered gravity

The specific properties and characteristics of the H+-ATPase, lipid and fatty acids content and composition in plasma membrane vesicles isolated from pea seedlings grown under clinorotation (2 rev/min) and stationary conditions were studied.     

Immunocytological localization of an epitope-tagged plasma membrane proton pump (H(+)-ATPase) in phloem companion cells.

In higher plants, the plasma membrane proton pump (H(+)-ATPase) is encoded by a surprisingly large multigene family whose members are expressed in different tissues. Using an 18-amino acid epitope tag derived from the animal oncogene c-Myc, we have performed immunocytolocalization measurements of the protein expressed by one member of this family, AHA3 (Arabidopsis H(+)-ATPase isoform 3). Immunofluorescence studies with tissue sections of transgenic plants have revealed that c-Myc-tagged AHA3 is restricted to the plasma membrane of phloem companion cells, whereas other AHA isoproteins are more widely distributed in the plasma membrane of other cell types. Electron microscopy with immunogold-labeled tissue sections suggests that there is a high concentration of proton pumps in the plasma membrane of companion cells but a much lower concentration in the plasma membrane of sieve elements. Due to plasmodesmata connecting the plasma membrane of these two adjacent cell types, it is likely that the proton motive force generated by the proton pump in companion cells can serve to power the uptake of sugar by proton-coupled symporters in either the companion cell or sieve element cell. The abundance of the proton pump in the plasma membrane of companion cells supports an apoplastic model for phloem loading in which the metabolic energy that drives sugar uptake is consumed by AHA3 at the companion cell plasma membrane. These experiments with a genetically altered integral plasma membrane protein demonstrate the utility of using a short c-Myc sequence as an epitope tag in Arabidopsis. Furthermore, our results demonstrate that, using genes encoding individual members of a gene family, it is possible to label plasma membrane proteins immunologically in specific, differentiated cell types of higher plants.