Large-scale purification and phosphorylation of a detergent-treated adenosine triphosphatase complex from plasma membrane of Saccharomyces cerevisiae

Functional characterization of the Ca2+-ATPase SMA1 from Schistosoma mansoni

Schistosoma mansoni is a parasite that causes bilharzia, a neglected tropical disease affecting hundreds of millions of people each year worldwide. In 2012, S. mansoni had been identified as the only invertebrate possessing two SERCA-type Ca2+-ATPases, SMA1 and SMA2. However, our analysis of recent genomic data shows that the presence of two SERCA pumps is rather frequent in parasitic flatworms. To understand the reasons of this redundancy in S. mansoni, we compared SMA1 and SMA2 at different levels. In terms of sequence and organization, the genes SMA1 and SMA2 are similar, suggesting that they might be the result of a duplication event. At the protein level, SMA1 and SMA2 only slightly differ in length and in the sequence of the nucleotide-binding domain. To get functional information on SMA1, we produced it in an active form in Saccharomyces cerevisiae, as previously done for SMA2. Using phosphorylation assays from ATP, we demonstrated that like SMA2, SMA1 bound calcium in a cooperative mode with an apparent affinity in the micromolar range. We also showed that SMA1 and SMA2 had close sensitivities to cyclopiazonic acid but different sensitivities to thapsigargin, two specific inhibitors of SERCA pumps. On the basis of transcriptomic data available in GeneDB, we hypothesize that SMA1 is a housekeeping Ca2+-ATPase, whereas SMA2 might be required in particular striated-like muscles like those present the tail of the cercariae, the infecting form of the parasite.

Partial characterization of a phosphorylated intermediate associated with the plasma membrane ATPase of corn roots

The phosphorylated protein associated with a deoxycholate-extracted plasma membrane fraction from corn (Zea mays L. var WF9 x Mol7) roots was characterized in order to correlate its properties with those of plasma membrane ATPase. Its phosphorylation, like that of plasma membrane ATPase, was dependent on Mg(2+), substrate specific for ATP, insensitive to azide, oligomycin, or molybdate, and sensitive to N,N'-dicyclohexylcarbodiimide, diethylstilbestrol, or vanadate. Monovalent cations affected the phosphorylation of the protein in a manner consistent with their stimulatory effects on ATPase. For K(+), this was shown to occur through an increase in the turnover of the phosphoenzyme. Analysis of the phosphorylated protein by NaDodSO(4)/polyacrylamide gel electrophoresis revealed the presence of a single labeled polypeptide with a molecular weight of about 100,000. Phosphorylation of this polypeptide was dependent on Mg(2+), sensitive to K(+), and inhibited by vanadate. It is concluded that this polypeptide represents the catalytic subunit of the plasma membrane ATPase. These results are discussed in terms of a model for the coupling of metabolic energy to H(+) and K(+) transport in higher plants.

Rabbit sarcoplasmic reticulum Ca(2+)-ATPase replaces yeast PMC1 and PMR1 Ca(2+)-ATPases for cell viability and calcineurin-dependent regulation of calcium tolerance

SERCA1a, the fast-twitch skeletal muscle isoform of sarco(endo)plasmic reticulum Ca(2+)-ATPase, was expressed in yeast using the promoter of the plasma membrane H(+)-ATPase. In the yeast Saccharomyces cerevisiae, the Golgi PMR1 Ca(2+)-ATPase and the vacuole PMC1 Ca(2+)-ATPase function together in Ca2+ sequestration and Ca2+ tolerance. SERCA1a expression restored growth of pmc1 mutants in media containing high Ca2+ concentrations, consistent with increased Ca2+ uptake in an internal compartment. SERCA1a expression also prevented synthetic lethality of pmr1 pmc1 double mutants on standard media. Electron microscopy and subcellular fractionation analysis showed that SERCA1a was localized in intracellular membranes derived from the endoplasmic reticulum. Finally, we found that SERCA1a ATPase activity expressed in yeast was regulated by calcineurin, a Ca2+/calmodulin-dependent phosphoprotein phosphatase. This result indicates that calcineurin contributes to calcium homeostasis by modulating the ATPase activity of Ca2+ pumps localized in intra-cellular compartments.

Substitutions of aspartate 378 in the phosphorylation domain of the yeast PMA1 H+-ATPase disrupt protein folding and biogenesis

There is strong evidence that Asp-378 of the yeast PMA1 ATPase plays an essential role in ATP hydrolysis by forming a covalent beta-aspartyl phosphate reaction intermediate. In this study, Asp-378 was replaced by Asn, Ser, and Glu, and the mutant ATPases were expressed in a temperature-sensitive secretion-deficient strain (sec6-4) that allowed their properties to be examined. Although all three mutant proteins were produced at nearly normal levels and remained stable for at least 2 h at 37 degrees C, they failed to travel to the vesicles that serve as immediate precursors of the plasma membrane; instead, they became arrested at an earlier step of the secretory pathway. A closer look at the mutant proteins revealed that they were firmly inserted into the bilayer and were not released by washing with high salt, urea, or sodium carbonate (pH 11), treatments commonly used to strip nonintegral proteins from membranes. However, all three mutant ATPases were extremely sensitive to digestion by trypsin, pointing to a marked abnormality in protein folding. Furthermore, in contrast to the wild-type enzyme, the mutant ATPases could not be protected against trypsinolysis by ligands such as MgATP, MgADP, or inorganic orthovanadate. Thus, Asp-378 functions in an unexpectedly complex way during the acquisition of a mature structure by the yeast PMA1 ATPase.

Molecular cloning of the plasma membrane H(+)-ATPase from Kluyveromyces lactis: a single nucleotide substitution in the gene confers ethidium bromide resistance and deficiency in K+ uptake

A Kluyveromyces lactis strain resistant to ethidium bromide and deficient in potassium uptake was isolated. Studies on the proton-pumping activity of the mutant strain showed that a decreased H(+)-ATPase specific activity was responsible for the observed phenotypes. The putative K. lactis PMA1 gene encoding the plasma membrane H(+)-ATPase was cloned by its ability to relieve the potassium transport defect of this mutant and by reversing its resistance to ethidium bromide. Its deduced amino acid sequence predicts a protein 899 residues long that is structurally colinear in its full length to H(+)-ATPases cloned from different yeasts, except for the presence of a variable N-terminal domain. By PCR-mediated amplification, we identified a transition from G to A that rendered the substitution of the fully conserved methionine at position 699 by isoleucine. We attribute to this amino acid change the low capacity of the mutant H(+)-ATPase to pump out protons.

Transcriptional regulation by glucose of the yeast PMA1 gene encoding the plasma membrane H(+)-ATPase

The yeast plasma membrane H(+)-ATPase generates a membrane electrochemical gradient which is required for the secondary uptake of nutrients. Although the ATPase has previously been shown to be post-translationally regulated in response to the availability of glucose, there has been no evidence to date for transcriptional regulation of the ATPase gene (PMA1). In this work, we have examined the pool of newly synthesized ATPase that accumulates in secretory vesicles en route to the cell surface in the temperature-sensitive secretory mutant sec6-4, and have observed changes in the level of ATPase polypeptide as a function of the glucose concentration in the growth medium. In parallel, there were rapid and reversible changes in the levels of ATPase mRNA. Finally, when cells were grown on a variety of carbon sources, the amount of ATPase polypeptide was proportional to the specific growth rate, suggesting that PMA1 expression is adjusted according to the metabolic state of the cell. These results complement the findings of Capieaux et al. (Capieaux, E., Vignais, M.-L., Sentenac, A. and Goffeau, A. (1989). J. Biol. Chem. 264, 7437-7446), who show that the transcriptional factor TUF/RAP1 binds to upstream activating sequences in the PMA1 gene. Taken together, the results suggest a model in which transcriptional regulation of the ATPase gene by glucose is mediated by TUF/RAP1.

An alignment of 17 deduced protein sequences from plant, fungi, and ciliate H(+)-ATPase genes

Seventeen protein sequences of H(+)-ATPases from plants (Arabidopsis thaliana, Nicotiana plumbaginifolia, Lycopersicum esculentum), fungi (Saccharomyces cerevisiae, Schizosaccharomyces pombe, Zygosaccharomyces rouxii, Neuropora crassa, Candida albicans), and a parasitic ciliate (Leishmania donovani) have been aligned. Twenty sequence fragments were identified which were conserved in H(+)-, Na+/K(+)-, and Ca++ plasma membrane-ATPases. In addition, a total of 118 residues not located in these fragments were found to be conserved in all H(+)-ATPases. Among those, 38 amino acid residues were screened out as being priority targets for site-directed mutagenesis experiments aimed at the identification of the amino acid residues specifically involved in cation specificity.

Molecular and biochemical characterization of the Dio-9-resistant pma1-1 mutation of the H(+)-ATPase from Saccharomyces cerevisiae

The plasma-membrane H(+)-ATPase gene PMA1 was sequenced in four Dio-9-resistant strains of Saccharomyces cerevisiae, isolated independently. The same amino acid substitution Ala608----Thr was found in the four mutated strains. The mutant ATPase activity was decreased while the Km value for MgATP was increased. The ATPase efficiency (V/Km) of the mutant was reduced by a factor of 25 under acid conditions (pH 5.5), and by a factor of 10 at physiological pH (pH 6.6). The mutation also strongly reduces the inhibition by vanadate of ATPase activity, suggesting that the altered amino acid is involved in phosphate binding and/or in the E1-E2 transition.

The H(+)-ATPase of the plasma membrane from yeast. Kinetics of ATP hydrolysis in native membranes, isolated and reconstituted enzymes

The H(+)-ATPase of the plasma membrane from Saccharomyces cerevisiae has been isolated, purified and reconstituted into asolectin liposomes. The kinetics of ATP hydrolysis have been compared for the H(+)-ATPase in the plasma membrane, in a protein/lipid/detergent micelle (isolated enzyme) and in asolectin proteoliposomes (reconstituted enzyme). In all three cases the kinetics of ATP hydrolysis can be described by Michaelis-Menten kinetics with Km = 0.2 mM MgATP (plasma membranes), Km = 2.4 mM MgATP (isolated enzyme) and Km = 0.2 mM MgATP (reconstituted enzyme). However, the maximal turnover decreases only by a factor of two during isolation of the enzyme and does not change during reconstitution; the activation of the H(+)-ATPase by free Mg2+ is also only slightly influenced by the detergent. The dissociation constant of the enzyme-Mg2+ complex Ka, does not alter during isolation and the dissociation constant of the enzyme-substrate complex, Ks, increases from Ks = 30 microM (plasma membranes) to Ks = 90 microM (isolated enzyme). ATP binding to the H(+)-ATPase ('single turnover' conditions) for the isolated and the reconstituted enzyme resulted in both cases in a second-order rate constant k1 = 2.6 x 10(4) M-1.s-1. From these observations it is concluded that the detergent used (Zwittergent TM 3-14) interacts reversibly with the H(+)-ATPase and that practically all H(+)-ATPase molecules are reconstituted into the liposomes with the ATP-binding site being directed to the outside of the vesicle.

A Cl(-)-translocating adenosinetriphosphatase in Acetabularia acetabulum. 1. Purification and characterization of a novel type of adenosinetriphosphatase that differs from chloroplast F1 adenosinetriphosphatase

ATPases were solubilized from membranes of Acetabularia acetabulum using nonanoyl-N-methylgluconamide and purified by ion-exchange and gel permeation chromatography. Three fractions of ATPase, Mono Q-I, -II, and -III, were separated. Activity in fraction Mono Q-I was very labile and could not be accurately determined. Fractions Mono Q-II and -III had specific activities of 0.6 and 6 units/mg of protein, respectively. By SDS-polyacrylamide gel electrophoresis, isoelectric focusing, and peptide mapping, it was shown that fractions Mono Q-II and -III consisted of the same polypeptides with molecular masses of 54K (a-subunit) and 50K (b-subunit). Fractions Mono Q-II and -III had the following catalytic properties: pH optimum at 6.0; substrate specificity, ATP = GTP = ITP much greater than UTP = CTP (Km for ATP 0.6 mM); divalent cation requirement, Mn2+ = Mg2+ greater than Co2+ greater than Zn2+ much greater than Ca2+, Ni2+. Both activities were inhibited by monovalent anions, while monovalent cations had neither inhibitory nor stimulatory effects. Orthovanadate inhibited both activities to 50% at 1 mM, and the most effective inhibitor of both was azide (95% inhibition at 100 microM). An enzyme-phosphate complex was formed after incubation of fraction Mono Q-III with [gamma-32P]ATP. The CF1-ATPase subcomplexes were isolated from the same organism and compared with the fraction Mono Q-III. Data supported the difference of fraction Mono Q-III from CF1-ATPase.

Transmembrane segments of the P-type cation-transporting ATPases. A comparative study

The transmembrane segments predicted for the Neurospora H-ATPase are laid out diagrammatically in Figure 10. Although the eight segments have arbitrarily been compressed into rectangles of the same size, they range in length from 20 residues (II) to 30 residues (IV and VI), so the corresponding helices must vary in length as well. Notable features of the model include the charged residues located just outside the plane of the membrane, with a clear excess of negative charges (5-, 1+) at the extracellular surface and a slight excess of positive charges (4+, 3-) at the cytoplasmic surface. There are also a conspicuous number of bulky residues (tryptophan, phenylalanine, and tyrosine) just inside the plane of the membrane. Within the bilayer, most of the helices are noticeably amphipathic, consistent with the expectation that at least some of them stack together to form a channel-like structure with a hydrophobic surface and a hydrophilic core. The charged residues predicted to lie within the membrane are listed in Table 2, which is a summary of data from eight of the P-type ATPases; the S. cerevisiae and S. pombe enzymes have not been included because they are nearly identical in this respect to the Neurospora enzyme. Interestingly, all of the ATPases have more membrane-embedded negative charges (5 to 8) than positive ones (0 to 4), a pattern that may be connected with their role as cation transporters. Certainly, other unrelated transport proteins have a rather different pattern of positive and negative charges: for example, the mammalian glucose transporter (1+, 2-), Na-glucose transporter (3+, 3-), and the E. coli lac permease (11+, 7-). The actual positioning of the negative charges in the P-type ATPases does not make it easy to single out the functionally important ones, however. The glutamyl residue in segment I is present in the fungal, plant, and Leishmania H-ATPases but not in the gastric H,K-ATPase. The same is true for the aspartate in segment II, except that it also appears in the muscle and brain Ca-ATPases. A glutamate is found at one end of segment III in the E. coli and fungal enzymes and at the other end in Arabidopsis; in segment IV, another glutamate appears in a well-conserved region in the Leishmania and mammalian enzymes but not in the bacterial, fungal, or plant ones.(ABSTRACT TRUNCATED AT 400 WORDS)

Molecular properties of the fungal plasma-membrane [H+]-ATPase

The fungal plasma membrane contains a proton-translocating ATPase that is closely related, both structurally and functionally, to the [Na+, K+]-, [H+, K+]-, and [Ca2+]-ATPases of animal cells, the plasma-membrane [H+]-ATPase of higher plants, and several bacterial cation-transporting ATPases. This review summarizes currently available information on the molecular genetics, protein structure, and reaction cycle of the fungal enzyme. Recent efforts to dissect structure-function relationships are also discussed.

Immunological cross-reactivity of fungal and yeast plasma membrane H+-ATPase

The plasma membrane H+-ATPases from fungi and yeasts have similar catalytic and molecular properties. A structural comparison has been performed using immunoblot analysis with polyclonal antibodies directed toward the 102 kDa polypeptide of the plasma membrane H+-ATPase from Neurospora crassa. A strong cross-reactivity is observed between the fungal H+-ATPase and the enzyme from the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe. Structural homologies are indicated also by the analysis of the cross-reactive peptides originated by proteolytic digestion of Neurospora and S. cerevisiae purified enzymes. Neither enzyme from these two sources appears to be glycosylated by a highly sensitive concanavalin A affinity assay on blotted proteins. A glycoprotein of Mr 115000 and pI 4.8-5, which comigrates with a cell cycle-modulated protein on 2D gel, is present in partially purified preparations of plasma membrane H+-ATPase of S. cerevisiae and it is shown to be structurally unrelated to H+-ATPase.

Essential arginyl residues in the H+-translocating ATPase of plasma membrane from the yeast Schizosaccharomyces pombe

The H+-translocating adenosine-5'-triphosphatase (ATPase) purified from the yeast Schizosaccharomyces pombe is inactivated upon incubation with the arginine modifier 2,3-butanedione. The inactivation of the enzyme is maximal at pH values above 8.5. The modified enzyme is reactivated when incubated in the absence of borate after removal of 2,3-butanedione. The extent of inactivation is half maximal at 10 mM 2,3-butanedione for an incubation of 30 min at 30 degrees C at pH 7.0. Under the same conditions, the time-dependence of inactivation is biphasic in a semi-logarithmic plot with half-lives of 10.9 min and 65.9 min. Incubation with 2,3-butanedione lowering markedly the maximal rate of ATPase activity does not modify the Km for MgATP. These data suggest that two classes of arginyl residues play essential role in the plasma membrane ATPase activity. Magnesium adenosine 5'-triphosphate (MgATP) and magnesium adenosine 5'-diphosphate (MgADP), the specific substrate and product, protect partially against enzyme inactivation by 2,3-butanedione. Free ATP or MgGTP which are not enzyme substrates do not protect. Free magnesium, another effector of enzyme activity, exhibits partial protection at magnesium concentrations up to 0.5 mM, while increased inactivation is observed at higher Mg2+ concentrations. These protections indicate either the existence of at least one reactive arginyl in the substrate binding site or a general change of enzyme conformation induced by MgATP, MgADP or free magnesium.

Lack of immunological cross reactivity between the transport enzymes (Na+ + K+)-ATPase and (K+ + H+)-ATPase

Goat antisera against (Na+ + K+)-ATPase and its isolated subunits and against (K+ + H+)-ATPase have been prepared in order to test for immune cross-reactivity between the two enzymes, whose catalytic subunits show great chemical similarity. None of the (Na+ + K+)-ATPase antisera cross-reacted with (K+ + H+)-ATPase or inhibited its enzyme activity. The same was true for the (K+ + H+)-ATPase antiserum with regard to (Na+ + K+)-ATPase and its subunits and its enzyme activity. So notwithstanding the chemical similarity of their subunits, there is no immunological cross-reactivity between these two plasma membrane ATPases.