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

The Plasma Membrane H+ ATPase CsPMA2 Regulates Lipid Droplet Formation, Appressorial Development and Virulence in Colletotrichum siamense

Plasma membrane H+-ATPases (PMAs) play an important role in the pathogenicity of pathogenic fungi. Lipid droplets are important storage sites for neutral lipids in fungal conidia and hyphae and can be used by plant pathogenic fungi for infection. However, the relationship between plasma membrane H+-ATPase, lipid droplets and virulence remains unclear. Here, we characterized a plasma membrane H+-ATPase, CsPMA2, that plays a key role in lipid droplet formation, appresorial development and virulence in C. siamense. Deletion of CsPMA2 impaired C. siamense conidial size, conidial germination, appressorial development and virulence but did not affect hyphal growth. ΔCsPMA2 increased the sensitivity of C. siamense to phytic acid and oxalic acid. CsPMA2 was localized to lipids on the plasma membrane and intracellular membrane. Deletion of CsPMA2 significantly inhibited the accumulation of lipid droplets and significantly affected the contents of some species of lipids, including 12 species with decreased lipid contents and 3 species with increased lipid contents. Furthermore, low pH can inhibit CsPMA2 expression and lipid droplet accumulation. Overall, our data revealed that the plasma membrane H+-ATPase CsPMA2 is involved in the regulation of lipid droplet formation and affects appressorial development and virulence in C. siamense.

VmPma1 contributes to virulence via regulation of the acidification process during host infection in Valsa mali

Valsa mali is a destructive phytopathogenic fungus that mainly infects apple and pear trees. Infection with V. mali results in host tissue acidification via the generation of citric acid, which promote invasion. Here, two plasma membrane H⁺-ATPases, VmPma1 and VmPma2, were identified in V. mali. The VmPma1 deletion mutant (∆VmPma1) displayed higher intracellular acid accumulation and a lower growth rate compared to the wild type. In contrast, the VmPma2 deletion mutant (∆VmPma2) showed no obvious phenotypic differences. Meanwhile, loss of VmPma1, but not VmPma2, in V. mali led to a significant decrease in growth under acidic or alkaline conditions compared with WT. More importantly, ∆VmPma1 showed a greater reduction in ATPase hydrolase activity and acidification of the external environment, more sensitivity to abiotic stress, and weaker pathogenicity than ∆VmPma2. This evidence indicates that VmPma1 is the main gene of the two plasma membrane H⁺-ATPases. Transcriptomic analysis indicated that many metabolic processes regulated by VmPma1 are strictly pH-regulated. Besides, we identified two genes (named VmAgn1p and Vmap1) that contribute to the pathogenicity of V. mali by differentially regulating external acidification capacity. Overall, our findings show that VmPma1 plays a pivotal role in pathogenicity by affecting the acidification of V. mali.

Screening of protonstatin-1 (PS-1) analogs for improved inhibitors of plant plasma membrane H+-ATPase activity

We previously identified protonstatin-1 (PS-1) as a selective inhibitor of plasma membrane H⁺-ATPase (PM H⁺-ATPase) activity and used it as a tool to validate the chemiosmotic model for polar auxin transport. Here, to obtain compounds with higher affinity than PS-1 for PM H⁺-ATPase, we synthesized 34 PS-1 analogs and examined their ability to inhibit PM H⁺-ATPase activity. The 34 analogs showed varying inhibitory effects on the activity of this enzyme. The strongest effect was observed for the small molecule PS-2, which was approximately five times stronger than PS-1. Compared to PS-1, PS-2 was also a stronger inhibitor of auxin uptake as well as acropetal and basipetal polar auxin transport in Arabidopsis thaliana seedlings. Because PS-2 is a more potent inhibitor of PM H⁺-ATPase than PS-1, we believe that this compound could be used as a tool to study the functions of this key plant enzyme.

Testing the polar auxin transport model with a selective plasma membrane H+ -ATPase inhibitor

Auxin is unique among plant hormones in that its function requires polarized transport across plant cells. A chemiosmotic model was proposed to explain how polar auxin transport is derived by the H⁺ gradient across the plasma membrane (PM) established by PM H⁺ -adenosine triphosphatases (ATPases). However, a classical genetic approach by mutations in PM H⁺ -ATPase members did not result in the ablation of polar auxin distribution, possibly due to functional redundancy in this gene family. To confirm the crucial role of PM H⁺ -ATPases in the polar auxin transport model, we employed a chemical genetic approach. Through a chemical screen, we identified protonstatin-1 (PS-1), a selective small-molecule inhibitor of PM H⁺ -ATPase activity that inhibits auxin transport. Assays with transgenic plants and yeast strains showed that the activity of PM H⁺ -ATPases affects auxin uptake as well as acropetal and basipetal polar auxin transport. We propose that PS-1 can be used as a tool to interrogate the function of PM H⁺ -ATPases. Our results support the chemiosmotic model in which PM H⁺ -ATPase itself plays a fundamental role in polar auxin transport.

The plasma membrane H+ -ATPase FgPMA1 regulates the development, pathogenicity, and phenamacril sensitivity of Fusarium graminearum by interacting with FgMyo-5 and FgBmh2

Fusarium graminearum, as the causal agent of Fusarium head blight (FHB), not only causes yield loss, but also contaminates the quality of wheat by producing mycotoxins, such as deoxynivalenol (DON). The plasma membrane H⁺ -ATPases play important roles in many growth stages in plants and yeasts, but their functions and regulation in phytopathogenic fungi remain largely unknown. Here we characterized two plasma membrane H⁺ -ATPases: FgPMA1 and FgPMA2 in F. graminearum. The FgPMA1 deletion mutant (∆FgPMA1), but not FgPMA2 deletion mutant (∆FgPMA2), was impaired in vegetative growth, pathogenicity, and sexual and asexual development. FgPMA1 was localized to the plasma membrane, and ∆FgPMA1 displayed reduced integrity of plasma membrane. ∆FgPMA1 not only impaired the formation of the toxisome, which is a compartment where DON is produced, but also suppressed the expression level of DON biosynthetic enzymes, decreased DON production, and decreased the amount of mycelial invasion, leading to impaired pathogenicity by exclusively developing disease on inoculation sites of wheat ears and coleoptiles. ∆FgPMA1 exhibited decreased sensitivity to some osmotic stresses, a cell wall-damaging agent (Congo red), a cell membrane-damaging agent (sodium dodecyl sulphate), and heat shock stress. FgMyo-5 is the target of phenamacril used for controlling FHB. We found FgPMA1 interacted with FgMyo-5, and ∆FgPMA1 showed an increased expression level of FgMyo-5, resulting in increased sensitivity to phenamacril, but not to other fungicides. Furthermore, co-immunoprecipitation confirmed that FgPMA1, FgMyo-5, and FgBmh2 (a 14-3-3 protein) form a complex to regulate the sensitivity to phenamacril and biological functions. Collectively, this study identified a novel regulating mechanism of FgPMA1 in pathogenicity and phenamacril sensitivity of F. graminearum.

The plasma membrane H+ -ATPase, a simple polypeptide with a long history

The plasma membrane H+ -ATPase of fungi and plants is a single polypeptide of fewer than 1,000 residues that extrudes protons from the cell against a large electric and concentration gradient. The minimalist structure of this nanomachine is in stark contrast to that of the large multi-subunit FO F1 ATPase of mitochondria, which is also a proton pump, but under physiological conditions runs in the reverse direction to act as an ATP synthase. The plasma membrane H+ -ATPase is a P-type ATPase, defined by having an obligatory phosphorylated reaction cycle intermediate, like cation pumps of animal membranes, and thus, this pump has a completely different mechanism to that of FO F1 ATPases, which operates by rotary catalysis. The work that led to these insights in plasma membrane H+ -ATPases of fungi and plants has a long history, which is briefly summarized in this review.

Enhanced cellulase production by decreasing intercellular pH through H+-ATPase gene deletion in Trichoderma reesei RUT-C30

BACKGROUND

Cellulolytic enzymes produced by Trichoderma reesei are widely used for the industrial production of biofuels and chemicals from lignocellulose. We speculated that intracellular pH during the fermentation process can affect cellulase induction.

RESULTS

In this study, two H⁺-ATPase genes, tre76238 and tre78757, were first identified in T. reesei. Deletion of tre76238 and tre78757 in T. reesei RUT-C30 confirmed that tre76238 has a major function in maintaining intracellular pH, whereas tre78757 has a minor function. The tre76238 deletion strain Δ76238 displayed a high level of cellulase production using cellulase-repressive glucose as a sole carbon source, along with intracellular acid accumulation and growth retardation. Our results indicated that intracellular acid accumulation in Δ76238 stimulated a significant increase in the cytosolic Ca²⁺ levels. Ca²⁺ channels were shown to be necessary for cellulase production using glucose as the carbon source in Δ76238. Delayed Δ76238 growth could be reversed by optimizing the medium's nitrogen sources to produce ammonia for intracellular acid neutralization in the early phase. This may be useful for scale-up of cellulase production using glucose as the carbon source.

CONCLUSIONS

This study provides a new perspective for significant alterations in the cellulase expression pattern of T. reesei Δ76238, indicating a new mechanism for cellulase regulation under conditions of low intracellular pH.

Electrical control of cell polarization in the fission yeast Schizosaccharomyces pombe

Electric signals surround tissues and cells and have been proposed to participate in directing cell polarity in processes such as development, wound healing, and host invasion [1, 2]. The application of exogenous electric fields (EFs) can direct cell polarization in cell types ranging from bacteria and fungi to neurons and neutrophils [3-7]. The mechanisms by which EFs modulate cell polarity, however, remain poorly understood. Here we introduce the fission yeast Schizosaccharomyces pombe as a model organism to elucidate the mechanisms underlying this process. In these rod-shaped cells, an exogenous EF reorients cell growth in a direction orthogonal to the field, producing cells with a bent morphology. A candidate genetic screen identifies conserved factors involved in this process: an integral membrane proton ATPase pma1p that regulates intracellular pH, the small GTPase cdc42p, and the formin for3p that assembles actin cables. Interestingly, mutants in these genes still respond to the EF but orient in a different direction, toward the anode. In addition, EFs also cause electrophoretic movement of cell wall synthase complex proteins toward the anode. These data suggest molecular models for how the EF reorients cell polarization by modulating intracellular pH and steering cell polarity factors in multiple directions.

The Lmpma1 gene of Leptosphaeria maculans encodes a plasma membrane H+-ATPase isoform essential for pathogenicity towards oilseed rape

Following Agrobacterium tumefaciens-mediated mutagenesis in Leptosphaeria maculans, we identified the mutant 210, displaying total loss of pathogenicity towards its host plant (Brassica napus). Microscopic observations showed that m210 is unable to germinate on the host leaf surface and is thus blocked at the pre-penetration stage. The pathogenicity phenotype is linked with a single T-DNA insertion into the promoter region of a typical plasma membrane H(+)-ATPase-encoding gene, termed Lmpma1, thus leading to a twofold reduction in Lmpma1 expression. Since LmPMA1 is involved in intracellular pH homeostasis, we postulate that reduction in LmPMA1 activity disturbs the electrochemical transmembrane gradient in m210, thus leading to conidia defective in turgor pressure generation on leaf surface. Whole genome survey showed that L. maculans possesses a second plasma membrane H(+)-ATPase-encoding gene, termed Lmpma2. Silencing experiments, expression analyses and phylogenetic studies allowed us to highlight the essential role assumed by the Lmpma1 isoform in L.maculans pathogenicity.

Fluctuations during growth of the plasma membrane H(+)-ATPase activity of Saccharomyces cerevisiae and Schizosaccharomyces pombe

The plasma membrane H(+)-ATPase activity was determined under various growth conditions using the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe. Under early batch-growth conditions in a rich medium, the budding yeast S. cerevisiae ATPase specific activity increased 2- to 3-fold during exponential growth. During late exponential growth, a peak of ATPase activity, followed by a sudden decrease, was observed and termed "growth-arrest control". The growth arrest phenomenon of S. cerevisiae could not be related to the acidification of the culture medium or to glucose exhaustion in the medium or to variation of glucose activation of the H(+)-ATPase. Addition of ammonium to a proline minimum medium also stimulated transiently the ATPase activity of S. cerevisiae. Specific activity of the fission yeast S. pombe ATPase did not show a similar profile and steadily increased to reach a plateau in stationary growth. Under synchronous mitotic growth conditions, the ATPase activity of S. cerevisiae increased during the cell division cycle according to the "peak" type cycle, while that of S. pombe was of the "step" type.

Sequencing and heterologous expression in Saccharomyces cerevisiae of a Cryptococcus neoformans cDNA encoding a plasma membrane H(+)-ATPase

A cDNA containing an open reading frame encoding a putative plasma membrane H(+)-ATPase in the human pathogenic basidiomycetous yeast Cryptococcus neoformans was cloned and sequenced by means of PCR and cDNA library hybridization. The cloned cDNA is 3475 bp in length, containing a 2994 bp open reading frame encoding a polypeptide of 997 amino acids. As in the case of another basidiomycetous fungus (Uromyces fabae), the deduced amino acid sequence of CnPMA1 was found to be more homologous to those of P-type H(+)-ATPases from higher plants than to those from ascomycetous fungi. In order to prove the sequenced cDNA corresponds to a H(+)-ATPase, it was expressed in Saccharomyces cerevisiae and found to functionally replace its own H(+)-ATPase. Kinetic studies of CnPMA1 compared to ScPMA1 show differences in V(max) values and H(+)-pumping in reconstituted vesicles. The pH optimum and K(m) values are similar in both enzymes.

Regulation of plasma membrane H(+)-ATPase in fungi and plants

The plasma membrane H+-ATPase from fungi and plants is a proton pump which plays a key role in the physiology of these organisms controlling essential functions such as nutrient uptake and intracellular pH regulation. In fungal and plant cells the activity of the proton pump is regulated by a large number of environmental factors at both transcriptional and post-translational levels. During the last years the powerful tools of molecular biology have been successfully used in fungi and plants allowing the cloning of a wide diversity of H+-ATPase genes and rapid progress on the molecular basis of reaction mechanism and regulation of the proton pump. This review focuses on recent results on regulation of plasma membrane H+-ATPase obtained by molecular approaches.

The Pzh1 protein phosphatase and the Spm1 protein kinase are involved in the regulation of the plasma membrane H+-ATPase in fission yeast

We have previously shown that the mutation of the Schizosaccharomyces pombe PPZ-like protein phosphatase encoded by the gene pzh1+ results in increased tolerance to sodium and in hypersensitivity to potassium ions. A similar phenotype has also been reported for deletants in the spm1/pmk1 gene, encoding a mitogen-activated protein (MAP) kinase. We have found that the sodium tolerance phenotype of pzh1 deletants is stronger than that of spm1 mutants, and both effects are additive. Therefore, most probably both gene products mediate different pathways on sodium tolerance. In our hands, mutation of the kinase does not alter the tolerance to potassium, but it yields cells more tolerant to magnesium ions. While in budding yeast the mutations are synthetically lethal, fission yeast cells lacking both the phosphatase and the kinase genes are viable. Interestingly, their ability to export H+ to the medium is greatly impaired (although not that of pzh1 or spm1 single mutants). We have observed that, although the amount of the H+-ATPase in the plasma membrane is not altered, the activity of the enzyme is lower than normal and cannot be induced by glucose. These observations suggest that the activity of the H+-ATPase in fission yeast might be regulated by phospho-dephosphorylation mechanisms that might involve the pzh1+ and spm1+ gene products.

The essential Aspergillus nidulans gene pmaA encodes an homologue of fungal plasma membrane H(+)-ATPases

pmaA, an Aspergillus nidulans gene encoding a P-ATPase, has been cloned by heterologous hybridization with the yeast PMA1 gene. The putative 990-residue PmaA polypeptide shows 50% identity to Saccharomyces cerevisiae and Neurospora crassa plasma membrane H(+)-ATPases and weak (19-26%) identity to other yeast P-type cation-translocating ATPases. PmaA contains all catalytic domains characterizing H(+)-ATPases. pmaA transcript levels are not regulated by PacC, the transcription factor mediating pH regulation, and were not significantly affected by an extreme creAd mutation resulting in carbon catabolite derepression. Deletion of pmaA causes lethality, but a single copy of the gene is sufficient to support normal growth rate in pmaA hemizygous diploids, even under acidic growth conditions. As compared to other fungal H(+)-ATPases, PmaA presents three insertions, 39, 7, and 16 residues long, in the conserved central region of the protein. Two of these insertions are predicted to be located in extracellular loops and might be of diagnostic value for the identification of Aspergillus species. Their absence from most mammalian P-type ATPases may have implications for antifungal therapy.

Properties and heterologous expression of the glucose transporter GHT1 from Schizosaccharomyces pombe

Genomic DNA of the Schizosaccharomyces pombe glucose transporter, GHT1, was obtained by complementation of the glucose transport deficient Sz. pombe strain YGS-5. Here we describe the GHT1 gene that encodes a protein of 565 amino acids with a corresponding molecular mass of 62.5 kDa. This eukaryotic glucose transporter contains 12 putative transmembrane segments and is homologous to the HXT multigene family of S. cerevisiae with several amino acid motifs of this sugar transporter family. It is also homologous to other sugar carriers from human, mouse and Escherichia coli. The function of the Ght1 protein as a glucose transporter was proved both by homologous and heterologous expression in the Sz. pombe mutant YGS-5 and in the S. cerevisiae hxt mutant RE700A, respectively. Both transformed yeast strains transported D-glucose with substrate specificity similar to that in Sz. pombe wild-type cells. Moreover, the cells of the two transformed yeast strains accumulated 2-deoxy-D-glucose, a non-metabolizable D-glucose analogue, with an efficiency similar to Sz. pombe wild-type cells. The ability of the S. cerevisiae mutant RE700A to accumulate 2DG in an delta mu H+ dependent manner after transformation with GHT1 provides evidence that the Sz. pombe transporter catalyses an energy-dependent uptake of glucose.

Cloning and characterization of an ATPase gene from Pneumocystis carinii which closely resembles fungal H+ ATPases

A gene encoding a P-type cation translocating ATPase was cloned from a genomic library of rat-derived Pneumocystis carinii. The nucleotide sequence of the gene contains a 2781 base-pair open reading frame that is predicted to encode a 101,401 dalton protein composed of 927 amino acids. The P. carinii ATPase protein (pcal) is 69-75% identical when compared with eight proton pumps from six fungal species. The Pneumocystis ATPase is less than 34% identical to ATPase proteins from protozoans, vertebrates or the Ca++ ATPases of yeast. The P. carinii ATPase contains 115 of 121 residues previously identified as characteristic of H+ ATPases. Alignment of the Pneumocystis and fungal proton pumps reveals five homologous domains specific for fungal H+ ATPases.

The in vivo activation of Saccharomyces cerevisiae plasma membrane H(+)-ATPase by ethanol depends on the expression of the PMA1 gene, but not of the PMA2 gene

The expression of the PMA1 and PMA2 genes during Saccharomyces cerevisiae growth in medium with glucose plus increasing concentrations of ethanol was monitored by using PMA1-lacZ and PMA2-lacZ fusions and Northern blot hybridizations of total RNA probed with PMA1 gene. The presence of sub-lethal concentrations of ethanol enhanced the expression of PMA2 whereas it reduced the expression of PMA1. The inhibition of PMA1 expression by ethanol corresponded to a decrease in the content of plasma membrane ATPase as quantified by immunoassays. Although an apparent correspondence could exist between the increase of plasma membrane ATPase activity and the level of PMA2 expression, the maximal level of PMA2 expression remained about 200 times lower than PMA1. On the other hand, ethanol activated the plasma membrane H(+)-ATPase activity from a strain expressing only the PMA1 ATPase but did not activate that from a strain expressing only the PMA2 ATPase. These results provide evidence that in the presence of ethanol it is the PMA1 ATPase which is activated, probably by a post-translational mechanism and that the PMA2 ATPase is not involved.

The plasma membrane H(+)-ATPase gene family in Arabidopsis: genomic sequence of AHA10 which is expressed primarily in developing seeds

The plasma membrane H(+)-ATPases in Arabidopsis thaliana represent the largest family of cation translocating P-type ATPases identified in plants or animals. We report here seven new isoforms, which were identified by polymerase chain reaction (PCR) amplification of genomic DNA. Amplifications were performed with degenerate primers corresponding to two short conserved sequence motifs ("CSDK" and "GDGV") found in most P-type ATPases. A comparison was made of three CSDK-side primers, which were used either as totally degenerate mixtures or rendered less degenerate by substitution with deoxyinosine or fluorodeoxyuridine. Amplified genomic fragments were cloned, partially sequenced and shown to correspond to Arabidopsis genes by Southern blot analysis with gene-specific probes. One newly identified isoform, AHA10, was isolated as a cosmid clone and sequenced. The 5' and 3' ends of the gene were determined by comparison with the AHA10 cDNA sequence. AHA10 is the most divergent isoform characterized in the Arabidopsis family. AHA10 appears to be expressed primarily in developing seeds, as indicated by Northern blot analysis of AHA10 mRNA and by the analysis of transgenic plants expressing a beta-glucuronidase (GUS) reporter gene fused to an AHA10 promoter. Our results indicate that one function of this unusually large H(+)-ATPase gene family is to allow for expression of different isoforms in different cell types.

ATP activation of plasma membrane yeast H(+)-ATPase shows complex kinetics independently of the degree of purification

ATP stimulation of plasma membrane H(+)-ATPase activity from a wild baker's yeast (Saccharomyces cerevisiae) was followed under conditions of progressive degrees of purification. A particular emphasis was put to cover a wide range of concentrations which went from 2 microM up to 3000 microM ATP. The preparations used were (i) crude membrane fraction, (ii) untreated plasma membrane fraction obtained by differential centrifugation, (iii) residual plasma membrane treated with Triton X-100, (iv) enzyme solubilized with either Zwittergent 3-14 alone or after Triton X-100 treatment. Under all conditions the fitting of the dose-response curves required an equation composed by the sum of two Michaelian terms. Depending on the treatment, the Km values and Vmax values varied. The fitted curves displayed a high affinity-low Vmax (Km values of 7-60 microM and Vmax values of 0.03-0.50 mumol P(i)/mg per min) and a low affinity-high Vmax component (Km values of 408-1960 microM and Vmax values of 0.26-5.82 mumol P(i)/mg per min). The complex ATP activation curve of the yeast plasma membrane H(+)-ATPase is in line with similar behavior found for the H(+)-ATPase of higher plants and all known animal cation transport ATPases.

Intracellular pH in Schizosaccharomyces pombe--comparison with Saccharomyces cerevisiae

We examined cytoplasmic pH regulation in Schizosaccharomyces pombe and Saccharomyces cerevisiae using pH-sensitive fluorescent dyes. Of several different fluorescent compounds tested, carboxy-seminaphthorhodafluor-1 (C.SNARF-1) was the most effective. Leakage of C.SNARF-1 from S. pombe was much slower than leakage from C. cerevisiae. Using the pH-dependent fluorescence of C.SNARF-1 we showed that at an external pH of 7, mean resting internal pH was 7.0 for S. pombe and 6.6 for S. cerevisiae. We found that internal pH in S. pombe was maintained over a much narrower range in response to changes in external pH, especially at acidic pH. The addition of external glucose caused an intracellular alkalinization in both species, although the effect was much greater in S. cerevisiae than in S. pombe. The plasma membrane H(+)-ATPase inhibitor diethylstilbestrol reduced both the rate and extent of alkalinisation, with an IC50 of approximately 35 microM in both species. Amiloride also inhibited internal alkalinisation with IC50's of 745 microM for S. cerevisiae and 490 microM for S. pombe.

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.