Cosuppression of a plasma membrane H(+)-ATPase isoform impairs sucrose translocation, stomatal opening, plant growth, and male fertility

The plasma membrane H(+)-ATPase builds up a pH and potential gradient across the plasma membrane, thus activating a series of secondary ion and metabolite transporters. pma4 (for plasma membrane H(+)-ATPase 4), the most widely expressed H(+)-ATPase isogene in Nicotiana plumbaginifolia, was overexpressed in tobacco. Plants that overexpressed PMA4 showed no major changes in plant growth under normal conditions. However, two transformants were identified by their stunted growth, slow leaf initiation, delayed stem bolting and flowering, and male sterility. Protein gel blot analysis showed that expression of the endogenous and transgenic pma4 was cosuppressed. Cosuppression was developmentally regulated because PMA4 was still present in developing leaves but was not detected in mature leaves. The glucose and fructose content increased threefold, whereas the sucrose content remained unchanged. The rate of sucrose exudation from mature leaves was reduced threefold and the sugar content of apical buds was reduced twofold, suggesting failure of sucrose loading and translocation to the sink tissues. Cosuppression of PMA4 also affected the guard cells, stomatal opening, and photosynthesis in mature leaves. These results show that a single H(+)-ATPase isoform plays a major role in several transport-dependent physiological processes.     

Differential activation of H+-ATPase genes by an arbuscular mycorrhizal fungus in root cells of transgenic tobacco

In arbuscular mycorrhizas, H⁺-ATPase is active in the plant membrane around arbuscules but absent from plant mutants defective in arbuscule development (Gianinazzi-Pearson et al. 1995, Can J Bot 73: S526–S532). The proton-pumping H⁺-ATPase is encoded by a family of genes in plants. Immunocytochemical studies and promoter-gusA fusion assays were performed in transgenic tobacco (Nicotiana tabacum L.) to determine whether the periarbuscular enzyme activity results from de-novo activation of plant genes by an arbuscular mycorrhizal fungus. The H⁺-ATPase protein was localized in the plant membrane around arbuscule hyphae. The enzyme was absent from non-colonized cortical cells. Regulation of seven H⁺-ATPase genes (pma) was compared in non-mycorrhizal and mycorrhizal roots by histochemical detection of β-glucuronidase (GUS) activity. Two genes (pma2, pma4) were induced in arbuscule-containing cells of mycorrhizal roots but not in non-mycorrhizal cortical tissues or senescent mycorrhiza. It is concluded that de-novo H⁺-ATPase activity in the periarbuscular membrane results from selective induction of two H⁺-ATPase genes, which can have diverse roles in plant-fungal interactions at the symbiotic interface. Received: 23 October 1999 / Accepted: 7 February 2000     

The pma1 and pma2 H(+)-ATPases from Schizosaccharomyces pombe are functionally interchangeable.

The pma2 gene of Schizosaccharomyces pombe codes for a polypeptide having a predicted Mr of 110,126 and which is 79% identical to the plasma membrane H(+)-ATPase encoded by the pma1 gene. The pma2 gene, unlike pma1, is weakly expressed and not essential to mitotic growth. By constructing yeast strains in which the chromosomal pma2 gene is under control of the adh promoter, it has been possible to identify the overproduced ATPase in plasma membrane via formation of a phosphoenzyme. In a pma1-1 mutant strain whose ATPase activity is insensitive to vanadate, the overexpressed pma2 gene restores vanadate sensitivity. It also rescues a pma1 null mutant from lethality. These results demonstrate that the two H(+)-ATPases are functionally interchangeable in vivo but differently expressed.     

Altered plasma membrane H(+)-ATPase from the Dio-9-resistant pma1-2 mutant of Schizosaccharomyces pombe.

The pma1-2 mutation affecting the plasma membrane H(+)-ATPase of Schizosaccharomyces pombe has been selected for resistance to the antibiotic Dio-9. In membrane fractions purified from glucose-starved cells, the mutant ATPase activity is reduced by 96%, is insensitive to inhibition by vanadate and has a pH profile displaced in the acidic pH range when compared to the wild type. The maximum velocity of the H(+)-ATPase activity of plasma membranes from glucose-activated pma1-2 cells is activated 20-fold. This is in striking contrast with the wild-type ATPase activity, the maximal velocity of which is not affected by glucose. However, similar to the wild-type enzyme, glucose activation of the pma1-2 mutant H(+)-ATPase reduces the Km for MgATP 9-2 mM and shifts the optimal pH from 4.8 to 6.0-6.5. The pma1-2 mutation modifies Lys250 to a threonine, which is highly conserved in fungal and plant H(+)-ATPases. These results, compared to those reported for mutations of neighbour residues in yeast or mammalian P-type ATPases, suggest that Lys250 could play a significant role, not only in phosphate binding and/or in the E1P-E2P conformational isomerisation, but also in glucose activation of the H(+)-ATPase.     

Post-translational modification of plant plasma membrane H(+)-ATPase as a requirement for functional complementation of a yeast transport mutant.

Many heterologous membrane proteins expressed in the yeast Saccharomyces cerevisiae fail to reach their normal cellular location and instead accumulate in stacked internal membranes. Arabidopsis thaliana plasma membrane H(+)-ATPase isoform 2 (AHA2) is expressed predominantly in yeast internal membranes and fails to complement a yeast strain devoid of its endogenous H(+)-ATPase Pma1. We observed that phosphorylation of AHA2 in the heterologous host and subsequent binding of 14-3-3 protein is crucial for the ability of AHA2 to substitute for Pma1. Thus, mutants of AHA2, complementing pma1, showed increased phosphorylation at the penultimate residue (Thr(947)), which creates a binding site for endogenous 14-3-3 protein. Only a pool of ATPase in the plasma membrane is phosphorylated. Double mutants carrying in addition a T947A substitution lost their ability to complement pma1. However, mutants affected in both autoinhibitory regions of the C-terminal regulatory domain complemented pma1 irrespective of their ability to become phosphorylated at Thr(947). This demonstrates that it is the activity status of the mutant enzyme and neither redirection of trafficking nor 14-3-3 binding per se that determines the ability of H(+)-pumps to rescue pma1.     

Effects of phosphate and hydrophobic molecules on two mutations in the beta-strand sector of the H(+)-ATPase from the yeast plasma membrane

At concentrations from 10 to 100 mM, inorganic phosphate and sulfate stimulate the activity of the H(+)-ATPase purified from the wild type Schizosaccharomyces pombe plasma membranes. Compared to the wild type ATPase, the stimulation by phosphate is more pronounced in the mutant pma1-1 (Gly-268----Asp) and is much reduced in the mutant pma1-2 (Lys-250----Thr) enzymes. In contrast, the inhibition by trifluoperazine is less pronounced in the pma1-1 mutant than in the wild type or pma1-2 mutant. The mutant pma1-2 ATPase activity is markedly stimulated by 10-20% dimethyl sulfoxide, which has a limited effect on the wild type and pma1-1 enzymes. These data indicate that the protein domain located in the beta-strand sector, including Lys-250 and Gly-268, is located in the active site and that its hydrophobic character influences the interactions of the yeast H(+)-ATPase with inorganic phosphate, as well as with the hydrophobic inhibitor trifluoperazine or the hydrophobic solvent dimethyl sulfoxide.     

Defective H(+)-ATPase of hygromycin B-resistant pma1 mutants fromSaccharomyces cerevisiae

Mutations in the plasma membrane H(+)-ATPase gene (PMA1) of Saccharomyces cerevisiae that confer growth resistance to hygromycin B have been shown recently to cause a marked depolarization of whole cell membrane potential (Perlin, D. S., Brown, C. L., and Haber, J. E. (1988) J. Biol. Chem. 263, 18118-18122). In this report, the biochemical and genetic properties of H+-ATPases from four prominent hygromycin B-resistant pma1 mutants, pma1-105, pma1-114, pma1-147, and pma1-155, are described. Single base pair changes were identified in pma1-105, pma1-114, and pma1-147 that resulted in amino acid substitutions of Ser-368----Phe, Gly-158----Asp, Pro-640----Leu, respectively. An A----G transition mutation at -39 in the 5'-untranslated region of the mRNA of pma1-155 was also found. This mutation creates an out-of-Frame upstream AUG initiation codon that apparently reduces normal translation of PMA1. DNA sequence analysis of PMA1 from strain Y55 identified 9 base pair substitutions that resulted in 6 amino acid changes in nonconserved regions when compared to the published sequence for strain S288C. Plasma membranes of three of the four pma1 mutants contained normal amounts of H(+)-ATPase; membranes from pma1-155 contained enzyme at 62% of the wild-type level. The kinetics of ATP hydrolysis were most strongly altered for enzymes from pma1-105 and pma1-147 which showed changes in both Km and Vmax. A striking pH dependence for these parameters was found for enzyme from pma1-105 which resulted in a precipitous decline in Km and Vmax below pH 6.5. ATP hydrolysis by enzymes from pma1-105 and pma1-147 was insensitive to inhibition by vanadate. These enzymes, in contrast to wild-type and vanadate-sensitive mutant enzymes, were poorly protected from trypsin-induced inactivation by MgATP and vanadate or Pi alone. These results are pertinent to the mechanism of vanadate-induced enzyme inhibition and suggest that Ser-368 and Pro-640 influence the affinity of the phosphate-binding site for Pi. All mutant enzymes catalyzed ATP-induced pH gradient formation following purification and reconstitution into liposomes. Finally, these results further demonstrate the usefulness of hygromycin B as a generalized screening tool for isolating diverse plasma membrane ATPase mutants.     

C-terminal deletion analysis of plant plasma membrane H(+)-ATPase: yeast as a model system for solute transport across the plant plasma membrane.

The plasma membrane proton pump (H(+)-ATPase) energizes solute uptake by secondary transporters. Wild-type Arabidopsis plasma membrane H(+)-ATPase (AHA2) and truncated H(+)-ATPase lacking 38, 51, 61, 66, 77, 92, 96, and 104 C-terminal amino acids were produced in yeast. All AHA2 species were correctly targeted to the yeast plasma membrane and, in addition, accumulated in internal membranes. Removal of 38 C-terminal residues from AHA2 produced a high-affinity state of plant H(+)-ATPase with a low Km value (0.1 mM) for ATP. Removal of an additional 12 amino acids from the C terminus resulted in a significant increase in molecular activity of the enzyme. There was a close correlation between molecular activity of the various plant H(+)-ATPase species and their ability to complement mutants of the endogenous yeast plasma membrane H(+)-ATPase (pma1). This correlation demonstrates that, at least in this heterologous host, activation of H(+)-ATPase is a prerequisite for proper energization of the plasma membrane.     

Molecular cloning of a family of plant genes encoding a protein homologous to plasma membrane H+-translocating ATPases

cDNA clones from Nicotiana plumbaginifolia have been isolated by hybridization to a yeast H+-ATPase gene. The largest one encodes a polypeptide (PMA2) of 956 amino acid residues which exhibits a homology of 73% with a limited protein sequence obtained from purified oat plasma membrane H+-ATPase (Schaller and Sussman, Plant Physiol. 86, 512-516, 1988) and an 82% homology with the Arabidopsis thaliana pma gene (Harper et al., Proc. Natl. Acad. Sci. USA 86, 1234-1238). It is therefore concluded that the N. plumbaginifolia pma2 gene encodes a plasma membrane H+-ATPase. Southern blot hybridization indicates that the plant pma2 gene belongs to a multigene family. Partial sequences of cDNA clones show that at least three pma genes are expressed in root cells.     

Expression of a constitutively activated plasma membrane H+-ATPase alters plant development and increases salt tolerance

The plasma membrane proton pump ATPase (H(+)-ATPase) plays a major role in the activation of ion and nutrient transport and has been suggested to be involved in several physiological processes, such as cell expansion and salt tolerance. Its activity is regulated by a C-terminal autoinhibitory domain that can be displaced by phosphorylation and the binding of regulatory 14-3-3 proteins, resulting in an activated enzyme. To better understand the physiological consequence of this activation, we have analyzed transgenic tobacco (Nicotiana tabacum) plants expressing either wild-type plasma membrane H(+)-ATPase4 (wtPMA4) or a PMA4 mutant lacking the autoinhibitory domain (DeltaPMA4), generating a constitutively activated enzyme. Plants showing 4-fold higher expression of wtPMA4 than untransformed plants did not display any unusual phenotype and their leaf and root external acidification rates were not modified, while their in vitro H(+)-ATPase activity was markedly increased. This indicates that, in vivo, H(+)-ATPase overexpression is compensated by down-regulation of H(+)-ATPase activity. In contrast, plants that expressed DeltaPMA4 were characterized by a lower apoplastic and external root pH, abnormal leaf inclination, and twisted stems, suggesting alterations in cell expansion. This was confirmed by in vitro leaf extension and curling assays. These data therefore strongly support a direct role of H(+)-ATPase in plant development. The DeltaPMA4 plants also displayed increased salt tolerance during germination and seedling growth, supporting the hypothesis that H(+)-ATPase is involved in salt tolerance.     

Polyamines as physiological regulators of 14-3-3 interaction with the plant plasma membrane H+-ATPase

Polyamines are abundant polycationic compounds involved in many plant physiological processes such as cell division, dormancy breaking, plant morphogenesis and response to environmental stresses. In this study, we investigated the possible role of these polycations in modulating the association of 14-3-3 proteins with the H(+)-ATPase. In vivo experiments demonstrate that, among the different polyamines, spermine brings about 2-fold stimulation of the H(+)-ATPase activity and this effect is due to an increase in 14-3-3 levels associated with the enzyme. In vivo administration of polyamine synthesis inhibitors causes a small but statistically significant decrease of the H(+)-ATPase phosphohydrolytic activity, demonstrating a physiological role for the polyamines in regulating the enzyme activity. Spermine stimulates the activity of the H(+)-ATPase AHA1 expressed in yeast, in the presence of exogenous 14-3-3 proteins, with a calculated S(50) of 70 microM. Moreover, spermine enhances the in vitro interaction of 14-3-3 proteins with the H(+)-ATPase and notably induces 14-3-3 association with the unphosphorylated C-terminal domain of the proton pump. Comparison of spermine with Mg(2+), necessary for binding of 14-3-3 proteins to different target proteins, shows that the polyamine effect is stronger than and additive to that of the divalent cation.     

A single mutation confers vanadate resistance to the plasma membrane H+-ATPase from the yeast Schizosaccharomyces pombe

A single-gene nuclear mutant has been selected from the yeast Schizosaccharomyces pombe for growth resistance to Dio-9, a plasma membrane H+-ATPase inhibitor. From this mutant, called pma1, an ATPase activity has been purified. It contains a Mr = 100,000 major polypeptide which is phosphorylated by [gamma-32P] ATP. Proton pumping is not impaired since the isolated mutant ATPase is able, in reconstituted proteoliposomes, to quench the fluorescence of the delta pH probe 9-amino-6-chloro-2-methoxy acridine. The isolated mutant ATPase is sensitive to Dio-9 as well as to seven other plasma membrane H+-ATPase inhibitors. The mutant H+-ATPase activity tested in vitro is, however, insensitive to vanadate. Its Km for MgATP is modified and its ATPase specific activity is decreased. The pma1 mutation decreases the rate of extracellular acidification induced by glucose when cells are incubated at pH 4.5 under nongrowing conditions. During growth, the intracellular mutant pH is more acid than the wild type one. The derepression by ammonia starvation of methionine transport is decreased in the mutant. The growth rate of pma1 mutants is reduced in minimal medium compared to rich medium, especially when combined to an auxotrophic mutation. It is concluded that the H+-ATPase activity from yeast plasma membranes controls the intracellular pH as well as the derepression of amino acid, purine, and pyrimidine uptakes. The pma1 mutation modifies several transport properties of the cells including those responsible for the uptake of Dio-9 and other inhibitors (Ulaszewski, S., Coddington, A., and Goffeau, A. (1986) Curr. Genet. 10, 359-364).     

The Na+-K+-ATPase as self-adhesion molecule and hormone receptor

Thanks to the homeostasis of the internal milieu, metazoan cells can enormously simplify their housekeeping efforts and engage instead in differentiation and multiple forms of organization (tissues, organs, systems) that enable them to produce an astonishing diversity of mammals. The stability of the internal milieu despite drastic variations of the external environment (air, fresh or seawater, gastrointestinal fluids, glomerular filtrate, bile) is due to transporting epithelia that can adjust their specific permeability to H(2)O, H(+), Na(+), K(+), Ca(2+), and Cl(-) over several orders of magnitude and exchange substances with the outer milieu with exquisite precision. This exchange is due to the polarized expression of membrane proteins, among them Na(+)-K(+)-ATPase, an oligomeric enzyme that uses chemical energy from ATP molecules to translocate ions across the plasma membrane of epithelial cells. Na(+)-K(+)-ATPase presents two types of asymmetries: the arrangement of its subunits, and its expression in one pole of the epithelial cell ("polarity"). In most epithelia, polarity consists of the expression of Na(+)-K(+)-ATPase towards the intercellular space and arises in part from the interaction of the extracellular segment of the β-subunit with another β-subunit present in a Na(+)-K(+)-ATPase molecule expressed by a neighboring cell. In addition to enabling the Na(+)-K(+)-ATPase to transport ions and water vectorially, this position exposes its receptors to ouabain and analogous cardiotonic steroids, which are present in the internal milieu because these were secreted by endocrine cells.