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

Chloride-ATPase dephosphorylation in Aplysia gut

The present study was done primarily to compare cation-ATPase dephosphorylation kinetics with a Cl(-)-ATPase's dephosphorylation kinetics because of the paucity of information in this area. Utilizing a proteoliposomal preparation containing Cl(-)-ATPase from Aplysia gut, it was demonstrated that dephosphorylation of this P-type ATPase was absolutely dependent upon Cl(-). Adenosine triphosphate (ATP) concentrations directly stimulated dephosphorylation of Cl(-)-ATPase in the presence of increasing concentrations of Cl(-). It was also shown that the calculated rate constant for E(1)-P disintegration was 20/sec. This rate constant value approximated E(1)-P rate constant disintegration values for other electrogenic, uniport P-type ATPases. Therefore, it was concluded from these results that the Cl(-)-ATPase dephosphorylation kinetics did not differ greatly from cation-ATPase dephosphorylation kinetics.

An NH2-terminal deleted plasma membrane H+-ATPase is a dominant negative mutant and is sequestered in endoplasmic reticulum derived structures

The NH2-terminus of the plasma membrane H+-ATPase is one of the least conserved segments of this protein among fungi. We constructed and expressed a mutant H+-ATPase from Saccharomyces cerevisiae deleted at an internal peptide within the cytoplasmic NH2-terminus (D44-F116). When the enzyme was subjected to limited trypsinolysis it was digested more rapidly than wild type H+-ATPase. Membrane fractionation experiments and immunofluorescence microscopy, using antibodies against H+-ATPase showed that the mutant ATPase is retained in the endoplasmic reticulum. The pattern observed in the immunofluorescence microscopy resembled structures similar to Russell bodies (modifications of the endoplasmic reticulum membranes) recently described in yeast. When the wild type H+-ATPase was co-expressed with the mutant, wild type H+-ATPase was also retained in the endoplasmic reticulum. Co-expression of both ATPases in a wild type yeast strain was lethal, demonstrating that this is a dominant negative mutant.

An alternative model for the transmembrane segments of the yeast H+-ATPase

An alternative topological model for the yeast plasma membrane H(+)-ATPase from K. lactis was deduced by joint prediction, using 11 algorithms for the prediction of transmembrane segments complemented with hydrophobic moment analysis. Similarly to the model currently used in the literature, this alternative model contains 10 transmembrane segments, four in the N-half and six in the C-half of the protein. However, the distribution of the membrane-associated segments on the C-half of the enzyme differs in both models. Nine of the 10 transmembrane segments are highly hydrophobic with low hydrophobic moments, and are probably involved in structural roles. The fifth transmembrane segment is, on the other hand, less hydrophobic, with the highest hydrophobic moment, suggesting that this segment might have a dynamic role in the coupling of the hydrolysis of ATP with the translocation of protons across the membrane. The alignment of the Ca(2+)-ATPase, the Na(+)/K(+)-ATPase and the H(+)-ATPase sequences showed that these proteins have the same topology in the N-half, but important differences were found at the C-half of the enzymes. In contrast with the mammalian ATPases, the fifth transmembrane segment in the H(+)-ATPase appears early in the sequence, giving rise to a shorter cytoplasmic central loop. This alternative model will be useful in the designing of site-directed mutagenesis experiments and contains information for the fitting of the amino acid sequence into the transmembrane region of the three-dimensional model of the ATPase.

Structure and function of the P-type ATPases

The P-type ATPases are integral membrane proteins that generate essential transmembrane ion gradients in virtually all living cells. The structures of two of these have recently been elucidated at a resolution of 8 A. When considered together with the large body of biochemical information that has accrued for these transporters and for enzymes in general, this new structural information is providing tantalizing insights regarding the molecular mechanism of active ion transport catalyzed by these proteins.

Structure of the P-type ATPases

Electron cryocrystallography of precipitant-induced two-dimensional surface crystals of the neurospora plasma membrane H+ - ATPase and tubular crystals of the sarcoplasmic reticulum Ca(2+)-ATPase has recently yielded structure maps for these ion transporters at a resolution of about 8 A. The membrane-embedded regions of these closely related enzymes are similar, but the cytoplasmic regions appear to be significantly different.

Three-dimensional map of the plasma membrane H+-ATPase in the open conformation

The H+-ATPase from the plasma membrane of Neurospora crassa is an integral membrane protein of relative molecular mass 100K, which belongs to the P-type ATPase family that includes the plasma membrane Na+/K+-ATPase and the sarcoplasmic reticulum Ca2+-ATPase. The H+-ATPase pumps protons across the cell's plasma membrane using ATP as an energy source, generating a membrane potential in excess of 200mV. Despite the importance of P-type ATPases in controlling membrane potential and intracellular ion concentrations, little is known about the molecular mechanism they use for ion transport. This is largely due to the difficulty in growing well ordered crystals and the resulting lack of detail in the three-dimensional structure of these large membrane proteins. We have now obtained a three-dimensional map of the H+-ATPase by electron crystallography of two-dimensional crystals grown directly on electron microscope grids. At an in-plane resolution of 8 A, this map reveals ten membrane-spanning alpha-helices in the membrane domain, and four major cytoplasmic domains in the open conformation of the enzyme without bound ligands.

Reactive cysteines of the yeast plasma-membrane H+-ATPase (PMA1). Mapping the sites of inactivation by N-ethylmaleimide

We have taken advantage of cysteine mutants described previously (Petrov, V. V., and Slayman, C. W. (1995) J. Biol. Chem. 270, 28535-28540) to map the sites at which N-ethylmaleimide (NEM) reacts with the plasma-membrane H+ATPase (PMA)1 of Saccharomyces cerevisiae. When membrane vesicles containing the ATPase were incubated with NEM, six of nine mutants with single cysteine substitutions showed sensitivity similar to the wild-type enzyme. By contrast, C221A and C532A were inactivated more slowly than the wild-type control, and the C221, 532A double mutant was completely resistant, indicating that Cys-221 and Cys-532 are NEM-reactive residues. In the presence of 10 mM MgADP, the wild-type ATPase was partially protected against NEM; parallel experiments with the C221A and C532A mutants showed that the protection occurred at Cys-532, located in or near the nucleotide-binding site. Unexpectedly, the inactivation of the C409A ATPase was approximately 4-fold more rapid than in the case of the wild-type enzyme. Experiments with double mutants made it clear that this resulted from an acidic shift in pKa and a consequent acceleration of the reaction rate at Cys-532. One simple interpretation is that substitution of Cys-409 leads to a local conformational change within the central hydrophilic domain. Consistent with this idea, the reaction of fluorescein 5'-isothiocyanate at Lys-474 was also stimulated approximately 3. 5-fold by the C409A mutation. Taken together, the results of this study provide new information about the reactivity of individual Cys residues within the ATPase and pave the way to tag specific sites for structural and functional studies of the enzyme.

Alanine-scanning mutagenesis along membrane segment 4 of the yeast plasma membrane H+-ATPase. Effects on structure and function

Membrane segment 4 of P-type cation pumps has been suggested to play a critical role in the coupling of ATP hydrolysis to ion translocation. In this study, structure-function relationships in M4 of the yeast (Saccharomyces cerevisiae) plasma membrane H+-ATPase have been explored by alanine-scanning mutagenesis. Mutant enzymes were expressed behind an inducible heat-shock promoter in yeast secretory vesicles, as described previously (Nakamoto, R. K., Rao, R. , and Slayman, C. W. (1991) J. Biol. Chem. 266, 7940-7949). One substitution (I329A) led to arrest of the enzyme at an early stage of biogenesis, and three others (G333A, L338A, G349A) reduced ATP hydrolysis to near-background levels. The remaining 26 mutants were expressed well enough in secretory vesicles (44-121% of wild type) and had sufficient ATPase activity (16-123% of wild type) to be characterized in detail. When acridine orange fluorescence quenching was used to measure rates of ATP-dependent proton pumping over a range of ATP concentrations, only minor changes were seen. In kinetic studies, however, seven of the mutant enzymes (I331A, I332A, V334A, V336A, V341A, V342A, and M346A) were resistant to vanadate inhibition, and three of them (I332A, V336A, and V341A) also had a decreased Km and increased pH optimum for ATP hydrolysis. Limited trypsinolysis was used to probe the structure of two different Val-336 substitutions, V336A, described above, and V336R, which displayed little or no ATPase activity. Both were cleaved at a relatively normal rate to give a pattern of fragments essentially identical to that seen with the wild-type enzyme. However, while vanadate, ADP, and ATP were able to protect the wild-type and V336A enzymes against trypsinolysis, the V336R ATPase was protected only by ADP and ATP. Taken together, the data suggest that key residues in the M4 segment may help to communicate the E1-E2 conformational change to ion-binding sites in the membrane.

Probing the cytoplasmic LOOP1 domain of the yeast plasma membrane H(+)-ATPase by targeted factor Xa proteolysis

The cytoplasmic domain linking transmembrane segments 2 and 3 (LOOP1) of the yeast H(+)-ATPase was probed by the introduction of unique factor Xa recognition sites. Three sites, I170EGR, I254EGR and I275EGR, representing different structural regions of the LOOP1 domain, were engineered by site-specific mutagenesis of the PMA1 gene. In each case, multiple amino acid substitutions were required to form the factor Xa sites, which enabled an analysis of clustered mutations. Both I170EGR and I275EGR-containing mutants grew at normal rates, but showed prominent growth resistance to hygromycin B and sensitivity to low external pH. The engineered I254EGR site within the predicted beta-strand region produced a recessive lethal phenotype, indicating that mutations G254I and F257R were not tolerated. Mutant I170EGR- and I275EGR-containing enzymes showed relatively normal Km and Vmax values, but they displayed a strong insensitivity to inhibition by vanadate. An I170EGR/I275EGR double mutant was more significantly perturbed showing a reduced Vmax and pronounced vanadate insensitivity. The I170EGR site within the putative alpha-helical stalk region was cleaved to a maximum of 10% by factor Xa under non-denaturing conditions resulting in a characteristic 81 kDa fragment, whereas the I275EGR site, near the end of the beta-strand region, showed about 30-35% cleavage with the appearance of a 70 kDa fragment. A I170EGR/I275EGR double mutant enzyme showed about 55-60% cleavage. The cleavage profile for the mutant enzymes was enhanced under denaturing conditions, but was unaffected by MgATP or MgATP plus vanadate. Cleavage at the I275EGR position had no adverse effects on ATP hydrolysis or proton transport by the H(+)-ATPase making it unlikely that this localized region of LOOP1 influences coupling. Overall, these results suggest that the local region encompassing I275EGR is accessible to factor Xa, while the region around I170EGR appears buried. Although there is no evidence for gross molecular motion at either site, the effects of multiple amino acid substitutions in these regions suggest that the LOOP1 domain is conformationally active, and that perturbations in this domain affect the distribution of conformational intermediates during steady-state catalysis.

A multi-substrate single-file model for ion-coupled transporters

Ion-coupled transporters are simulated by a model that differs from contemporary alternating-access schemes. Beginning with concepts derived from multi-ion pores, the model assumes that substrates (both inorganic ions and small organic molecules) hop a) between the solutions and binding sites and b) between binding sites within a single-file pore. No two substrates can simultaneously occupy the same site. Rate constants for hopping can be increased both a) when substrates in two sites attract each other into a vacant site between them and b) when substrates in adjacent sites repel each other. Hopping rate constants for charged substrates are also modified by the membrane field. For a three-site model, simulated annealing yields parameters to fit steady-state measurements of flux coupling, transport-associated currents, and charge movements for the GABA transporter GAT1. The model then accounts for some GAT1 kinetic data as well. The model also yields parameters that describe the available data for the rat 5-HT transporter and for the rabbit Na(+)-glucose transporter. The simulations show that coupled fluxes and other aspects of ion transport can be explained by a model that includes local substrate-substrate interactions but no explicit global conformational changes.

Site-directed mutagenesis of the yeast PMA1 H(+)-ATPase. Structural and functional role of cysteine residues

The yeast plasma-membrane H(+)-ATPase contains nine cysteines, three in presumed transmembrane segments (Cys-148, Cys-312, and Cys-867) and the rest in hydrophilic regions thought to be exposed at the cytoplasmic surface (Cys-221, Cys-376, Cys-409, Cys-472, Cys-532, and Cys-569). To gather new functional and structural information, we have studied the yeast ATPase by cysteine mutagenesis. It proved possible to replace seven of the nine cysteines by alanine, one at a time, without any significant decrease in ATP hydrolysis or ATP-dependent proton pumping. In the remaining two cases (Cys-409 and Cys-472), there were small but reproducible effects; the results clearly indicated, however, that no single Cys is required for activity and that, if a disulfide bridge is formed in the yeast ATPase, it does not play an obligatory structural or functional role. Next, multiple mutants were constructed to ask how many Cys residues could be replaced simultaneously while leaving a fully functional enzyme. After substitution of all "membrane" Cys (Cys-148, Cys-312, and Cys-867) together with two non-conserved Cys located in hydrophilic regions (Cys-221 and Cys-569), there were no significant abnormalities in expression (87%) or activity (89% ATP hydrolysis/93% H+ pumping) of the mutant protein. Replacement of two additional cysteines (Cys-376 near the phosphorylation site and Cys-532, in or near the ATP-binding site) caused a drop in expression (to 54%), although the corrected hydrolytic and H+ pumping activities were still normal. When Cys-472 was also mutated, the corrected activity fell to 44% hydrolysis/47% pumping; finally, substitution of Cys-409 to give a "cysteine-free" ATPase led to a very poorly expressed and poorly active enzyme. Brief exposure of the "one-cysteine" and "two-cysteine" ATPases to trypsin revealed a normal pattern of degradation, but there was a slight impairment in the ability of vanadate to protect against proteolysis. Thus, although single Cys replacements are tolerated well by the yeast ATPase, multiple replacements are progressively more harmful, suggesting that they cause small but additive perturbations of protein folding.

Primary structure of the plasma membrane H(+)-ATPase from the halotolerant alga Dunaliella bioculata

P-type ATPase-specific oligodeoxyribonucleotides were used to obtain a fragment of the H(+)-ATPase of the salt tolerant alga Dunaliella bioculata by polymerase chain reaction (PCR). This fragment served as a probe in screening a cDNA-library from this organism. The complete primary structure of the ATPase protein (DBPMA1) was deduced from sequencing a 4.7 kb cDNA clone. The protein shows highest homology to H(+)-ATPases from higher plants and fungi (43% identity, 67% similarity) but has a higher calculated molecular mass (123 kDa). The latter can be assigned mainly to an additional hydrophilic domain between transmembrane segments VI and VII and to an extended carboxyterminus. These unusual structural features of DBPMA1 are interpreted in terms of providing regulatory sites of the enzyme. Southern blot analysis suggests the presence of only a single copy of the gene in the haploid D. bioculata genome. To investigate the role of the H(+)-ATPase in the adaption of D. bioculata to different external NaCl concentrations, we employed northern blot analyses. The results indicate that the pma1 transcript level of cells growing in salinities between 0.1 and 3 M NaCl is not directly correlated with the external salt concentration.

Mutations of G158 and their second-site revertants in the plasma membrane H(+)-ATPase gene (pma1) in Saccharomyces cerevisiae

A G158D mutation residing near the cytoplasmic end of transmembrane segment 2 of the H(+)-ATPase from Saccharomyces cerevisiae appears to alter electrogenic proton transport by the proton pump (Perlin et al. (1988) J. Biol. Chem. 263, 18118-18122.) The mutation confers upon whole cells a pronounced growth sensitivity to low pH and a resistance to the antibiotic hygromycin B. The isolated enzyme retains high activity (70% of wild type) but is inefficient at pumping protons in a reconstituted vesicle system, suggesting that this enzyme may be partially uncoupled (Perlin et al. (1989) J. Biol. Chem. 264, 21857-21864). In this study, the acid-sensitive growth phenotype of the pma1-D158 mutant was utilized to isolate second site suppressor mutations in an attempt to probe structural interactions involving amino acid 158. Site-directed mutagenesis of the G158 locus was also performed to explore its local environment. Nineteen independent revertants of pma1-G158D were selected as low pH-resistant colonies. Four were full phenotypic revertants showing both low pH resistance and hygromycin B sensitivity. Of three full revertants analyzed further, one restored the original glycine residue at position 158 while the other two carried compensatory mutations V336A or F830S, in transmembrane segments 4 and 7, respectively. Partial revertants, which could grow on low pH medium but still retained hygromycin B resistance, were identified in transmembrane segments 1 (V127A) and 2 (C148T, G156C), as well as in the cytoplasmic N-terminal domain (E110K) and in the cytoplasmic loop between transmembrane segments 2 and 3 (D170N, L275S). Relative to the G158D mutant, all revertants showed enhanced net proton transport in whole-cell medium acidification assays and/or improved ATP hydrolysis activity. Small polar amino acids (Asp and Ser) could be substituted for glycine at the 158 position to produce active, albeit somewhat defective, enzymes; larger hydrophobic residues (Leu and Val) produced more severe phenotypes. These results suggest that G158 is likely to reside in a tightly packed polar environment which interacts, either directly or indirectly, with transmembrane segments 1, 4 and 7. The revertant data are consistent with transmembrane segments 1 and 2 forming a conformationally sensitive helical hairpin structure.

Modeling a conformationally sensitive region of the membrane sector of the fungal plasma membrane proton pump

A molecular model for transmembrane segments 1 and 2 from the fungal proton pumping ATPase has been developed, and this structure is predicted to form a helical hairpin loop structure in the membrane. This region was selected because it is highly conformationally active and is believed to be an important site of action for clinically important therapeutics in related animal cell enzymes. The hairpin loop is predicted to form an asymmetric tightly packed structure that is stabilized by an N-cap between D140 and V142, by hydrogen bonding between residues in the turn region and the helices, and by pi-pi interactions between closely apposed aromatic residues. A short four-residue S-shaped turn is stabilized by hydrogen bonding but is predicted to be conformationally heterogeneous. The principal effect of mutations within the hairpin head region is to destabilize the local close packing of side groups which disrupts the pattern of hydrogen bonding in and around the turn region. Depending on the mutation, this causes either a localized or a more global distortion of the primary structure in the hairpin region. These altered structures may explain the effects of mutations in transmembrane segments 1 and 2 on ATP hydrolysis, sensitivity to vanadate, and electrogenic proton transport. The conformational sensitivity of the hairpin structure around the S-turn may also account for the effects of SCH28080 and possibly ouabain in blocking ATPase function in related animal cell enzymes. Finally, the model of transmembrane segments 1 and 2 serves as a template to position transmembrane segments 3 and 8. This model provides a new view of the H(+)-ATPase that promotes novel structure/function experimentation and could serve as the basis for a more detailed model of the membrane sector of this enzyme.

Reaction sequence and molecular mass of a Cl(-)-translocating P-type ATPase

The basolateral membranes of Aplysia californica foregut absorptive cells contain both Cl(-)-stimulated ATPase and ATP-dependent Cl- transport activities, and each was inhibited by orthovanadate. Both of these orthovanadate-sensitive activities were reconstituted into proteoliposomes. The reaction sequence kinetics were determined by [gamma-32P]ATP-induced phosphorylation of the reconstituted Cl- pump. Rapid phosphorylation and dephosphorylation kinetics of acyl phosphate bonding were confirmed by destabilization of the phosphoprotein by either hydroxylamine or high pH. Mg2+ caused phosphorylation of the enzyme; Cl- caused dephosphorylation. Orthovanadate almost completely inhibited the Mg(2+)-driven phosphorylation reaction. The molecular mass of the catalytic unit (subunit) of the enzyme appeared to be 110 kDa, which is in agreement with molecular masses of all other catalytic units (subunits) of P-type ATPases.

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.

Mutagenesis of the yeast plasma membrane H(+)-ATPase. A novel expression system

The plasma membrane H(+)-ATPase of the yeast Saccharomyces cerevisiae is a prototype for the mutagenic analysis of structure-function relationships in P-type cation pumps. Because a functional H+ pump is required for viability, wild-type ATPase must be maintained in the plasma membrane for normal cell growth. Our expression strategy involves a rapid switch in expression from the wild-type ATPase gene to a mutant allele followed by entrapment of the newly synthesized mutant enzyme in an internal, secretory vesicle pool. The isolated vesicles prove to be ideally suited for the study of the catalytic and transport properties of the ATPase. Work to date has focused on conserved residues in the vicinity of the aspartyl-phosphate reaction intermediate. Substitution of Asp378 with Glu, Ser, or Asn and of Lys379 with Gln prevents normal biogenesis of the mutant ATPase. The more conservative Lys379----Arg mutation was tolerated, but with a sixfold loss of activity and substantial alterations in Km for ATP and Ki for vanadate. Nonconservative replacement of Thr380, Thr382, or Thr384 with Ala led to inactive enzyme, whereas the conservative change to Ser caused a two to threefold reduction in ATP hydrolysis and H(+)-pumping. Taken together, the results are consistent with an essential role for these invariant residues in phosphate-binding and ATP hydrolysis.