| 3.A.3 The P-type ATPase (P-ATPase) Superfamily
Nearly all of the members of this superfamily, found in bacteria, archaea and eukaryotes, catalyze cation uptake and/or efflux driven by ATP hydrolysis. Clustering on the phylogenetic tree is usually in accordance with specificity for the transported ion(s). Many of these protein complexes are multisubunit with a large subunit serving the primary ATPase and ion translocation functions. In eukaryotes, they are present in the plasma membranes or endoplasmic reticular membranes. In prokaryotes, they are localized to the cytoplasmic membranes. Gastric H+-translocating ATPases (ouabain-insensitive) comprise a subgroup of the larger and more diverse Na+/K+ ATPase family (ouabain-sensitive) (Family 1). The ouabain-binding pocket can be functionally reconstituted in the gastric H+,K+ ATPase by substitution of only seven residues (Qiu et al., 2005). Ca2+ ATPases of prokaryotes and eukaryotes comprise a very diverse family (Family 2) including in eukaryotes plasma membrane, golgi, and sarcoplasmic reticular types. Sarcoplasmic reticular Ca2+ ATPases (SERCA) in brown adipose tissue can uncouple ATP hydrolysis from Ca2+ transport and be thermogenic (de Meis, 2003). H+-translocating P-type ATPases of plants and fungi comprise their own family (Family 3). Distinct bacterial enzymes specific for K+ (Family 7; only in prokaryotes) or Mg2+ (Family 4, mostly in prokaryotes; uptake), Cu2+, Ag+, Zn2+, Co2+, Pb2+, Ni2+, and/or Cd2+ (Family 6; efflux) and Cu2+ or Cu+ (Family 5; uptake or efflux, depending on the system) have been characterized, and each of these types of enzymes comprises a distinct family. Cu2+ or Cu+-translocating ATPases from bacteria, archaea and animals cluster together, and at least some of these also transport Ag+. The Cu+/Ag+ (Family 5 and heavy metal (Family 6)) ATPases have an 8 TMS topology (Mandal et al., 2002). A cys-pro-cys motif in CopA of E. coli (TC #3.A.3.5.5) is essential for Cu+/Ag+ efflux and phosphoenzyme formation (Fan and Rosen, 2002.
Many eukaryotic P-type ATPases are monomeric or homodimeric enzymes of the catalytic subunit that hydrolyzes ATP. They contain the aspartyl phosphorylation site and catalyzes ion transport. The Na+,K+-ATPases, the Ca2+-ATPases and the (fungal) H+-ATPases of higher organisms exhibit 10 STET, transmembrane α helical spanners (TMSs), some of them highly tilted. Additional subunits that appear to lack catalytic activity may be present in the ATPase complex. For example, the 10 TMS catalytic α-subunit of the Na+,K+-ATPase of animals is tightly complexed to the 1 TMS β-subunit and the tissue-specific, regulatory, 1 TMS γ-subunit. The β-subunit, which may influence the activity of the α-subunit, probably functions to facilitate proper insertion of the α-subunit into the membrane, to allow proper targeting to a subcellular membrane site in post-translational processing, and to stabilize the catalytic subunit. The β-subunit can therefore be considered to be an auxiliary protein of the Na+,K+-ATPase catalytic subunit. The γ-subunit of the Na+,K+-ATPase has been reported to influence kinetic parameters and is homologous to a family of pore-forming peptides, the peptides of the phospholemman family (TC #1.A.27), and the C-subunits of V-type ATPases (TC #3.A.2). This γ-subunit is induced under stress conditions and modulates Na+,K+-ATPase activity and cell growth (Wetzel et al., 2004). The Na+, K+-ATPase can serve as a steroid hormone receptor (Schoner, 2002). Several other P-type ATPases also depend on small proteolipids, the functions of which are uncertain.
The stoichiometries of transport are sometimes known and complex. In the case of the Na+,K+-ATPases, 3 Na+ are exchanged for 2 K+ per ATP molecule hydrolyzed. The gastric H+-translocating ATPases replace H+ for K+ but with an H+/K+ stoichiometry of 2:2. Thus, although these two enzymes are ~65% identical, the Na+,K+-ATPases are electrogenic while the H+,K+-ATPases are electroneutral. Gastric H+, K+-ATPase transports 2 moles of H+ together with two H2O (two H3O+) per mole of ATP hydrolyzed in isolated hog gastric vesicles. Protons are charge-transferred from the cytosolic side to H2O in sites 2 and 1, the H2O coming from the cytosol, and H3O+ in these sites are transported into the lumen during the conformational transition from E1P to E2P (Morii et al., 2008). Ca2+ ATPases may catalyze Ca2+/K+ or Ca2+/H+ antiport. A single organism often possesses multiple isoforms of these enzymes.
Considerable evidence is available showing that animals have Cl- translocating, Cl- stimulating P-type ATPases. Although extensive biochemical data are available, the protein sequence of any one such Cl- ATPase has not yet been determined (Gerencser, 1993; Inagaki et al., 1996; Zeng et al., 1999). Evidence for mammalian iron-inducible, iron-transporting ATPases is also available (Baranano et al., 2000). Finally bacterial Na+-transporting P-type ATPases probably exist (Ueno et al., 2000). Thus the breadth of substrates transported by P-type ATPases is likely to be much greater than currently recognized.
The Na+,K+-ATPase acts as a signal transducer and transcription activator, modulating cell growth, apoptosis, and cell motility. A prominent binding motif linking the Na+,K+-ATPase to intracellular signaling effectors is the N-terminal tail of the Na+,K+-ATPase catalytic α-subunit which binds directly to the N-terminus of the inositol 1,4,5-trisphosphate receptor (Zhang et al., 2006). Three amino acyl residues, LKK, conserved in most species and most α-isoforms, are essential for binding. In wild-type cells, low concentrations of ouabain trigger low frequency calcium oscillations that activate NF-κB and protect from apoptosis. Thus, the LKK motif binds the inositol 1,4,5-trisphosphate receptor and triggers an anti-apoptotic calcium signal. However, the N-terminal hydrophilic region in front of the first TMS does not interact with the transported cation (Na+, K+, or Ca2+) although this first TMS does (Einholm et al., 2007).
P-type ATPases provide a polar transmembrane pathway, to which access is strictly controlled by coupled gates that are constrained to open alternately, thereby enabling thermodynamically uphill ion transport. Reyes and Gadsby (2006) have examined the ion pathway through the N+, K+-ATPase, a representative P-type pump, after uncoupling its extra- and intracellular gates with the marine toxin palytoxin. They found a wide outer vestibule penetrating deep into the Na+, K+-ATPase, where the pathway narrows and leads to a charge-selectivity filter. Acidic residues in this region, which are conserved to coordinate pumped ions, allow the approach of cations but exclude anions. Reversing the charge at just one of those positions converts the pathway from cation selective to anion selective. Cysteine scans from TM1 to TM6 in the Na+, K+-ATPase revealed a single unbroken cation pathway that traverses palytoxin-bound Na+,K+-pump-channels from one side of the membrane to the other (Takeuchi et al. 2008). This pathway comprises residues from TM1, TM2, TM4 and TM6, passes through ion-binding site II, and is probably conserved in structurally and evolutionarily related P-type pumps. Close structural homology among the catalytic subunits of Ca2+-, Na+, K+- and H+, K+-ATPases argues that their extracytosolic cation exchange pathways all share these physical characteristics (Reyes and Gadsby, 2006).
The X-ray crystal structure at 3.5 Å resolution of the pig renal Na+,K+-ATPase has been determined with two rubidium ions bound in an occluded state in the transmembrane part of the α-subunit (Morth et al., 2007). Several of the residues forming the cavity for rubidium/potassium occlusion in the Na+,K+-ATPase are homologous to those binding calcium in the Ca2+-ATPase of the sarco(endo)plasmic reticulum. The β- and γ-subunits specific to the Na+,K+-ATPase are associated with transmembrane helices αM7/αM10 and αM9, respectively. The γ-subunit corresponds to a fragment of the V-type ATPase c subunit. The carboxy terminus of the α-subunit is contained within a pocket between transmembrane helices and seems to be a novel regulatory element controlling sodium affinity, possibly influenced by the membrane potential.
The Na+,K+-ATPase can be transformed into an ion channel using pharmacological agents. Palytoxin (PTX), produced by soft coral of the genus Palythoa, binds to the ATPase with a Kd of 20 pM and creates a monovalent cation-selective channel with a single channel conductance of 10 pS. The presence of external Na+ seems to be essential for channel activation (Wu et al., 2003). When the N-terminal 35 residues are removed from the ATPase, the toxin-activated channel does not exhibit a time-dependent inactivation gating at positive potentials as is characteristic of the wild-type protein. The truncated pump exhibits no electrogenic current, and the ion stoichiometry for active transport is altered. Addition of the synthetic peptide restores activity towards wild type. The N-terminal peptide therefore appears to act as an inactivation gate (similar to Shaker B channels of the VIC family (TC #1.A.1)). It may also play a critical role in determining the ion stoichiometry (Wu et al., 2003). Fluorometric studies indicate that under normal conditions, α- and β-subunits move towards each other during the E2 to E1 transition (Dempski et al., 2006).
The structures of the sarcoplasmic reticular Ca2+-ATPase have been solved at 2.6 Å resolution for the complex to which 2 Ca2+ are bound, and at 3.1 Å resolution for the complex lacking Ca2+ (Toyoshima et al., 2000; Toyoshima and Nomura, 2002). The two Ca2+ are located side by side, surrounded by 4 transmembrane helices, two of which are unwound for efficient coordination geometry. There are 3 cytoplasmic domains, one, the central catalytic domain, bearing the phosphorylation site, a second bearing the adenosine nucleotide binding site, and a third of unknown function. The central domain has the same fold as haloacid dehydrogenases (Aravind et al., 1998; Stokes and Green, 2000). The Ca2+-free form shows large conformational differences from the Ca2+-bound form with the three cytoplasmic domains tightly associated to form a single headpiece and six of the ten TMSs largely rearranged. These latter rearrangements guarantee the release of external Ca2+ and create a pathway for entry of Ca2+ from the cytoplasm. ATPase activity and Ca2+ binding are cooperatively interdependent, but the two processes can be separated by mutations (Zhang et al., 2002).
Structures are available for both the E1 and E2 states of the Ca2+ ATPase showing that Ca2+ binding induces major changes in all three cytoplasmic domains relative to each other (Xu et al., 2002). Xu et al. proposed how Ca2+ binding induces conformational changes in TMS4 and 5 in the membrane domain (M) that in turn induce rotation of the phosphorylation domain (P). The nucleotide binding (N) and β-sheet (β) domains are highly mobile, with N flexibly linked to P, and β flexibly linked to M. Modeling of the fungal H+ ATPase, based on the structures of the Ca2+ pump, suggested a comparable 70º rotation of N relative to P to deliver ATP to the phosphorylation site (Kühlbrandt et al., 2002). One report suggests that this S.R. Ca2+ ATPase is homodimeric (Ushimaru and Fukushima, 2008).
Crystal structures (Gadsby, 2007) have shown that the conserved TGES loop of the Ca2+-ATPase is isolated in the Ca2E1 state but becomes inserted in the catalytic site in E2 states. Anthonisen et al. (2006) characterized the kinetics of the partial reaction steps of the transport cycle and the binding of the phosphoryl analogs BeF, AlF, MgF, and vanadate in mutants with alterations to the TGES residues. The data provide functional evidence supporting a role of Glu183 in activating the water molecule involved in the E2P → E2 dephosphorylation and suggest a direct participation of the side chains of the TGES loop in the control and facilitation of the insertion of the loop in the catalytic site. The interactions of the TGES loop furthermore seem to facilitate its disengagement from the catalytic site during the E2 → Ca2E1 transition.
Olesen et al. (2007) have described functional studies and three new crystal structures of the rabbit skeletal muscle Ca2+-ATPase. These represent the phosphoenzyme intermediates associated with (1) Ca2+ binding, (2) Ca2+ translocation and (3) dephosphorylation. They are based on complexes with a functional ATP analogue, beryllium fluoride or aluminium fluoride. The structures complete the cycle of nucleotide binding and cation transport of Ca2+-ATPase. Phosphorylation of the enzyme triggers a conformational change that leads to opening of a luminal exit pathway defined by the transmembrane segments M1 through M6. M1-M6 represent the canonical membrane domain of P-type pumps. Ca2+ release is promoted by translocation of the M4 helix, exposing Glu 309, Glu 771 and Asn 796 to the lumen. The mechanism explains how P-type ATPases are able to form the steep electrochemical gradients required for key functions in eukaryotic cells (Olesen et al., 2007).
The structure of a P-type proton pump was determined by X-ray crystallography by Pederson et al., (2007). Ten transmembrane helices and three cytoplasmic domains define the functional unit of ATP-coupled proton transport across the plasma membrane. The structure is locked in a functional state not previously observed in P-type ATPases. The transmembrane domain reveals a large cavity, which is likely to be filled with water, located near the middle of the membrane plane where it is lined by conserved hydrophilic and charged residues. Proton transport against a high membrane potential is readily explained by this structural arrangement.
As in other P-type ATPases, metal binding to transmembrane metal-binding sites (TM-MBS) in Cu+-ATPases is required for enzyme phosphorylation and subsequent transport. However, Cu+ does not access Cu+-ATPases in a free (hydrated) form but is bound to a chaperone protein. The delivery of Cu+ by Archaeoglobus fulgidus Cu+ chaperone CopZ to the corresponding Cu+-ATPase, CopA, has been studied (González-Guerrero and Argüello, 2008). CopZ interacted with and delivered the metal to the N-terminal metal binding domain(s) of CopA (MBDs). Cu+-loaded MBDs, acting as metal donors, were unable to activate CopA or a truncated CopA lacking MBDs. Conversely, Cu+-loaded CopZ activated the CopA ATPase and CopA constructs in which MBDs were rendered unable to bind Cu+. Furthermore, under nonturnover conditions, CopZ transferred Cu+ to the TM-MBS of a CopA lacking MBDs altogether. Thus, MBDs may serve a regulatory function without participating directly in metal transport, and the chaperone delivers Cu+ directly to transmembrane transport sites of Cu+-ATPases (González-Guerrero and Argüello, 2008). Wu et al (2008) have determined structures of two constructs of the Cu (CopA) pump from Archaeoglobus fulgidus by cryoelectron microscopy of tubular crystals, which revealed the overall architecture and domain organization of the molecule. They localized its N-terminal MBD within the cytoplasmic domains that use ATP hydrolysis to drive the transport cycle and built a pseudoatomic model by fitting existing crystallographic structures into the cryoelectron microscopy maps for CopA. The results also similiarly suggested a Cu-dependent regulatory role for the MBD.
Chintalapati et al. (2008) have characterized two copper-transporting ATPases, CtrA2 and CtrA3 from Aquifex aeolicus. CtrA2 has a CPC metal-binding sequence in TM6 and a CxxC metal-binding N-terminal domain, while CtrA3 has a CPH metal-binding motif in TM6 and a histidine-rich N-terminal metal-binding domain. CtrA2 is activated by Ag+ and Cu+ and presumably transports reduced Cu+, while CtrA3 is activated by, and presumably transports, the oxidized copper ion. Both CtrA2 and CtrA3 are thermophilic proteins with an activity maximum at 75 degrees C. Electron cryomicroscopy of two-dimensional crystals of CtrA3 yielded a projection map at approximately 7 A resolution with density peaks indicating eight membrane-spanning alpha-helices per monomer. A fit of the Ca-ATPase structure to the projection map indicates that the arrangement of the six central helices surrounding the ion-binding site in the membrane is conserved, and suggests the position of the two additional N-terminal transmembrane helices that are characteristic of the heavy metal, eight-helix P(1B)-type ATPases (Chintalapati et al., 2008).
The 8TMS CadA of Listeria monocytogenes (Family 6) confirs resistance to cadmium. Residues in TMS6 (Cys354 and Cys356), TMS8 (Asp692) and TMS3 (Met149) may bind Cd2+ (Wu et al., 2006). However, the two cysteine residues in the CPC motif act at different steps: Cys354 is involved in Cd2+ binding while Cys356 is involved in Cd2+ occlusion. The two equivalent cysteines in the yeast Cu2+ ATPase may also act at different steps. The conserved Glu164 may be required for Cd2+ release. Possibly two Cd2+ are involved in the reaction cycle of CadA (Wu et al., 2006).
The phospholipid translocating P-type ATPases (Family 8; TC #3.A.3.8) are found only in eukaryotes. They appear to function with β-subunits of about 400 aas with 2 TMSs. These have been functionally characterized from yeast and protozoans (TC #8.A.27; Perez-Victoria et al., 2006). These enzymes catalyze the ATP-dependent flipping of phospholipids and lysophospholipids from the outer leaflet of the cytoplasmic membrane to the inner leaflet. Evidence for a Na+-P-type ATPase has been obtained for the halotolerant cyanobacterium, Aphanothece halophytica. (Wiangon et al., 2007).
The generalized reaction for P-type ATPases is:
nMe1 (out) + mMe2 (in) + ATP → nMe1 (in) + mMe2 (out) + ADP + Pi. |
| References: |
Adle, D.J., D. Sinani, H. Kim, and J. Lee. (2007). A cadmium-transporting P1B-type ATPase in yeast Saccharomyces cerevisiae. J. Biol. Chem. 282: 947-955.
|
Ahn, W., M.G. Lee, K.H. Kim, and S. Muallem. (2003). Multiple effects of SERCA2b mutations associated with Darier's disease. J. Biol. Chem. 278: 20795-20801.
|
Anthonisen, A.N., J.D. Clausen, and J.P. Andersen. (2006). Mutational analysis of the conserved TGES loop of sarcoplasmic reticulum Ca2+-ATPase. J. Biol. Chem. 281: 31572-31582.
|
Aravind, L., M.Y. Galperin, and E.V. Koonin. (1998). The catalytic domain of the P-type ATPase has the haloacid dehalogenase fold. Trends Biochem. Sci. 23: 127-129.
|
Auer, M., G.A. Scarborough, and W. Kühlbrandt. (1999). Surface crystallisation of the plasma membrane H+-ATPase on a carbon support film for electron crystallography. J. Mol. Biol. 287: 961-968.
|
Axelsen, K.B. and M.G. Palmgren. (1998). Evolution of substrate specificities in the P-type ATPase superfamily. J. Mol. Evol. 46: 84-101.
|
Baekgaard, L., L. Luoni, M.I. De Michelis, and M.G. Palmgren. (2006). The plant plasma membrane Ca2+ pump ACA8 contains overlapping as well as physically separated autoinhibitory and calmodulin-binding domains. J. Biol. Chem. 281: 1058-1065.
|
Banuelos, M.A. and A. Rodríguez-Navarro. (1998). P-type ATPases mediate sodium and potassium effluxes in Schwanniomyces occidentalis. J. Biol. Chem. 273: 1640-1646.
|
Baranano, D.E., H. Wolosker, B. Bae, R. K. Barrow, S.H. Snyder, and C.D. Ferris. (2000). A mammalian iron ATPase induced by iron. J. Biol. Chem. 275: 15166-15173.
|
Barnes, N., R. Tsivkovskii, N. Tsivkovskaia, and S. Lutsenko. (2005). The copper-transporting ATPases, Menkes and Wilson disease proteins, have distinct roles in adult and developing cerebellum. J. Biol. Chem. 280: 9640-9645.
|
Beard, S.J., R. Hashim, J. Membrillo-Hernández, M.N. Hughes, and R.K. Poole. (1997). Zinc(II) tolerance in Escherichia coli K-12: evidence that the zntA gene (o732) encodes a cation transport ATPase. Mol. Microbiol. 25: 883-891.
|
Benito, B., B. Garciadeblás, and A. Rodríguez-Navarro. (2002). Potassium- or sodium-efflux ATPase, a key enzyme in the evolution of fungi. Microbiology 148: 933-941.
|
Benito, B., B. Garciadeblás, and A. Rodríguez-Navarro. (2000). Molecular cloning of the calcium and sodium ATPases in Neurospora crassa. Mol. Microbiol. 35: 1079-1088.
|
Benito, B., B. Garciadeblás, J. Pérez-Martín, and A. Rodríguez-Navarro. (2009). Growth at high pH, and sodium and potassium tolerance in above cytoplasmic pH media depend on ENA ATPases in Ustilago maydis. Eukaryot. Cell. [Epub: Ahead of Print]
|
Bertini, I. and A. Rosato. (2008). Menkes disease. Cell Mol Life Sci 65(1): 89-91.
|
Bramkamp, M., K. Altendorf, and J.C. Greie. (2007) Common patterns and unique features of P-type ATPases: a comparative view on the KdpFABC complex from Escherichia coli (Review). Mol. Membr. Biol. 24: 375-386.
|
Cairo, E.R., T. Friedrich, H.G. Swarts, N.V. Knoers, R.J. Bindels, L.A. Monnens, P.H. Willems, J.J. De Pont, and J.B. Koenderink. (2008). Impaired routing of wild type FXYD2 after oligomerisation with FXYD2-G41R might explain the dominant nature of renal hypomagnesemia. Biochim. Biophys. Acta. 1778: 398-404.
|
Catty, P., A.D. d’Exaerde, and A. Goffeau. (1997). The complete inventory of the yeast Saccharomyces cerevisiae P-type transport ATPases. FEBS Lett. 409: 325-332.
|
Chintalapati, S., R. Al Kurdi, A.C. van Scheltinga, and W. Kühlbrandt. (2008). Membrane structure of CtrA3, a copper-transporting P-type-ATPase from Aquifex aeolicus. J. Mol. Biol. 378: 581-595.
|
Coleman, J.A., M.C. Kwok, and R.S. Molday. (2009). Localization, purification and functional reconstitution of the P4-ATPASE, ATP8A2, a phosphatidylserine flippase in photoreceptor disc membranes. J. Biol. Chem. [Epub: Ahead of Print]
|
Cronin S.R., R. Rao, R.Y. Hampton. (2002). Cod1p/Spf1p is a P-type ATPase involved in ER function and Ca2+ homeostasis. J. Cell. Biol. 157: 1017-1028.
|
de Meis, L. (2003). Brown adipose tissue Ca2+-ATPase. Uncoupled ATP hydrolysis and thermogenic activity. J. Biol. Chem. 278: 41856-41861.
|
de Meis, L., A.P. Arruda, R.M. da Costa, and M. Benchimol. (2006). Identification of a Ca2+-ATPase in brown adipose tissue mitochondria: regulation of thermogenesis by ATP and Ca2+. J. Biol. Chem. 281: 16384-16390.
|
Dempski, R.E., K. Hartung, T. Friedrich, and E. Bamberg. (2006). Fluorometric measurements of intermolecular distances between the α- and β-subunits of the Na+/K+-ATPase. J. Biol. Chem. 281: 36338-36346.
|
Ding, J., Z. Wu, B.P. Crider, Y. Ma, X. Li, C. Slaughter, L. Gong, and X. Xie. (2000). Identification and functional expression of four isoforms of ATPase II, the putative aminophospholipid translocase. Effect of isoform variation on the ATPase activity and phospholipid specificity. J. Biol. Chem. 275: 23378-23386.
|
Eide, D.J. (1998). The molecular biology of metal ion transport in Saccharomyces cerevisiae. Annu. Rev. Nutr. 18: 441-469.
|
Einholm, A.P., J.P. Andersen, and B. Vilsen. (2007). Roles of transmembrane segment M1 of Na(+), K(+)-ATPase and Ca (2+)-ATPase, the gatekeeper and the pivot. J. Bioenerg. Biomembr. 39(5-6):357-66.
|
Elvington, S.M., F. Bu, and J.W. Nichols. (2005). Fluorescent, acyl chain-labeled phosphatidylcholine analogs reveal novel transport pathways across the plasma membrane of yeast. J. Biol. Chem. 280: 40957-40964.
|
Eren, E., Kennedy, D.C., Maroney, M.J., and Arguello, J.M. (2006). A novel regulatory metal binding domain is present in the C terminus of Arabidopsis Zn2+-ATPase HMA2. J. Biol. Chem. 281: 33881-33891.
|
Ettema, T.J., A.B. Brinkman, P.P. Lamers, N.G. Kornet, W.M. de Vos, and J. van der Oost. (2006). Molecular characterization of a conserved archaeal copper resistance (cop) gene cluster and its copper-responsive regulator in Sulfolobus solfataricus P2. Microbiology 152: 1969-1979.
|
Fagan, M.J. and M.H. Saier, Jr. (1994). P-type ATPases of eukaryotes and bacteria: sequence analyses and construction of phylogenetic trees. J. Mol. Evol. 38: 57-99.
|
Fan, B. and B.P. Rosen. (2002). Biochemical characterization of CopA, the Escherichia coli Cu(I)-translocating P-type ATPase. J. Biol. Chem. 277: 46987-46992.
|
Gaballa, A., and J.D. Helmann. (2002). A peroxide-induced zinc uptake system plays an important role in protection against oxidative stress in Bacillus subtilis. Mol. Microbiol. 45: 997-1005.
|
Gassel, M., T. Möllenkamp, W. Puppe, and K. Altendorf. (1999). The KdpF subunit is part of the K(+)-translocating Kdp complex of Escherichia coli and is responsible for stabilization of the complex in vitro. J. Biol. Chem. 274: 37901-7.
|
Geering, K. (1991). The functional role of the β-subunit in the maturation and intracellular transport of Na,K-ATPase. FEBS Lett. 285: 189-193.
|
Geering, K. (2000). Topogenic motifs in P-type ATPases. J. Memb. Biol. 174: 181-190.
|
Gerencser, G.A. (1993). A novel P-type Cl- stimulated ATPase: phosphorylation and specificity. Biochem. Biophys. Res. Commun. 196: 1188-1194.
|
Gomès, E., M.K. Jakobsen, K.B. Axelsen, M. Geisler, and M.G. Palmgren. (2000). Chilling tolerance in Arabidopsis involves ALA1, a member of a new family of putative aminophospholipid translocases. Plant Cell 12: 2441-2454.
|
González-Guerrero, M. and J.M. Argüello. (2008). Mechanism of Cu+-transporting ATPases: soluble Cu+ chaperones directly transfer Cu+ to transmembrane transport sites. Proc. Natl. Acad. Sci. USA 105: 5992-5997.
|
Greie, J.C., and K. Altendorf. (2007). The K+-translocating KdpFABC complex from Escherichia coli: A P-type ATPase with unique features. J. Bioenerg. Biomembr. 39: 397-402.
|
Gupta, A., K. Matsui, J.-F. Lo, and S. Silver. (1999). Molecular basis for resistance to silver cations in Salmonella. Nature Med. 5: 183-188.
|
Hao, Z., S. Chen, and D.B. Wilson. (1999). Cloning, expression, and characterization of cadmium and manganese uptake genes from Lactobacillus plantarum. Appl. Environ. Microbiol. 65: 4746-4752.
|
Harper J.F., B. Hong, I. Hwang, H.Q. Guo, R. Stoddard, J.F. Huang, M.G. Palmgren, H. Sze. (1998). A novel calmodulin-regulated Ca2+-ATPase (ACA2) from Arabidopsis with an N-terminal autoinhibitory domain. J. Biol. Chem. 273: 1099-1106.
|
Hasman, H., (2005). The tcrB gene is part of the tcrYAZB operon conferring copper resistance in Enterococcus faecium and Enterococcus faecalis. Microbiol. 151: 3019-3025.
|
Haupt, M., M. Bramkamp, M. Coles, H. Kessler, and K. Altendorf. (2005). Prokaryotic Kdp-ATPase: recent insights into the structure and function of KdpB. J. Mol. Microbiol. Biotechnol. 10: 120-131.
|
Heitkamp, T., R. Kalinowski, B. Böttcher, M. Börsch, K. Altendorf, and J.C. Greie. (2008). K(+)-translocating KdpFABC P-type ATPase from Escherichia coli acts as a functional and structural dimer. Biochemistry 47: 3564-75.
|
Herrmann, L., D. Schwan, R. Garner, H.L.T. Mobley, R. Haas, K.P. Schäfer, and K. Melchers. (1999). Heliocobacter pylori cadA encodes an essential Cd(II)-Zn(II)-Co(II) resistance factor influencing urease activity. Mol. Microbiol. 33: 524-536.
|
Holmgren, M., J. Wagg, F. Bezanilla, R.F. Rakowski, P. De Weer, and D.C. Gadsby. (2000). Three distinct and sequential steps in the release of sodium ions by the Na+/K+-ATPase. Nature 403: 898.
|
Hou, Z. and B. Mitra. (2003). The metal specificity and selectivity of ZntA from Escherichia coli using the acylphosphate intermediate. J. Biol. Chem. 278: 28455-28461.
|
Hou, Z.-J., S. Narindrasorasak, B. Bhushan, B. Sarkar, and B. Mitra. (2001). Functional analysis of chimeric proteins of the Wilson Cu(I)-ATPase (ATP7B) and ZntA, a Pb(II)/Zn(II)/Cd(II)-ATPase from Escherichia coli. J. Biol. Chem. 276: 40858-40863.
|
Huang L., T. Berkelman, A.E. Franklin, N.E. Hoffman. (1993). Characterization of a gene encoding a Ca2+-ATPase-like protein in the plastid envelope. Proc Natl Acad Sci U.S.A. 90: 10066-10070.
|
Inagaki, C., M. Hara, and X.T. Zeng. (1996). A Cl- pump in rat brain neurons. J. Exp. Zool. 275: 262-268.
|
Karjalainen E.L., K. Hauser, A. Barth. (2007). Proton paths in the sarcoplasmic reticulum Ca2+-ATPase. Biochim Biophys Acta. 1767: 1310-1318.
|
Kraev A., N. Kraev, E. Carafoli. (1999). Identification and functional expression of the plasma membrane calcium ATPase gene family from Caenorhabditis elegans. J. Biol. Chem. 274: 4254-4258.
|
Kühlbrandt, W., J. Zeelen, and J. Dietrich. (2002). Structure, mechanism, and regulation of the Neurospora plasma membrane H+-ATPase. Science 297: 1692-1696.
|
Kühlbrandt, W., M. Auer, and G.A. Scarborough. (1998). Structure of the P-type ATPases. Curr. Opin. Struc. Biol. 8: 510-516.
|
Lauer Júnior, C.M., D. Bonatto, A.A. Mielniczki-Pereira, A.Z. Schuch, J.F. Dias, M.L. Yoneama, and J.A. Pêgas Henriques. (2008). The Pmr1 protein, the major yeast Ca2+-ATPase in the Golgi, regulates intracellular levels of the cadmium ion. FEMS Microbiol. Lett. 285: 79-88.
|
Leedjärv, A., A. Ivask, and M. Virta. (2008). Interplay of different transporters in the mediation of divalent heavy metal resistance in Pseudomonas putida KT2440. J. Bacteriol. 190: 2680-2689.
|
Lewinson, O., A.T. Lee, and D.C. Rees. (2009). A P-type ATPase importer that discriminates between essential and toxic transition metals. Proc. Natl. Acad. Sci. USA 106: 4677-4682.
|
Li, Z. and Z. Xie. (2009). The Na/K-ATPase/Src complex and cardiotonic steroid-activated protein kinase cascades. Pflugers Arch 457: 635-644.
|
Liang F., K.W. Cunningham, J.F. Harper, H. Sze. (1997). ECA1 complements yeast mutants defective in Ca2+ pumps and encodes an endoplasmic reticulum-type Ca2+-ATPase in Arabidopsis thaliana.
|
Liu, T., H. Reyes-Caballero, C. Li, R.A. Scott, and D.P. Giedroc. (2007). Multiple metal binding domains enhance the Zn(II) selectivity of the divalent metal ion transporter AztA. Biochemistry 46: 11057-11068.
|
Liu, Y., S. Sitaraman, and A. Chang. (2006). Multiple degradation pathways for misfolded mutants of the yeast plasma membrane ATPase, Pma1. J. Biol. Chem. 281: 31457-31466.
|
Lowe J., A. Vieyra, P. Catty, F. Guillain, E. Mintz, M. Cuillel. (2004). A mutational study in the transmembrane domain of Ccc2p, the yeast Cu(I)-ATPase, shows different roles for each Cys-Pro-Cys cysteine. J. Biol. Chem. 279: 25986-25994.
|
Luo S., F.A. Ruiz, S.N. Moreno. (2005). The acidocalcisome Ca2+-ATPase (TgA1) of Toxoplasma gondii is required for polyphosphate storage, intracellular calcium homeostasis and virulence. Mol. Microbiol. 55: 1034-1045.
|
Luo, S., J. Fang, and R. Docampo. (2006). Molecular characterization of Trypanosoma brucei P-type H+-ATPases. J. Biol. Chem. 281: 21963-21973.
|
Lübben, M., J. Güldenhaupt, M. Zoltner, K. Deigweiher, P. Haebel, C. Urbanke, and A.J. Scheidig. (2007). Sulfate acts as phosphate analog on the monomeric catalytic fragment of the CPx-ATPase CopB from Sulfolobus solfataricus. J. Mol. Biol. 369: 368-385.
|
MacLennan, D.H., W.J. Rice, and N.M. Green. (1997). The mechanism of Ca2+ transport by sarco(endo)plasmic reticulum Ca2+-ATPases. J. Biol. Chem. 272: 28815-28818.
|
Mahmmoud, Y.A. (2008a). Capsazepine, a synthetic vanilloid that converts the Na, K-ATPase to Na-ATPase. Proc. Natl. Acad. Sci. U.S.A. 105: 1757-1761.
|
Mahmmoud, Y.A. (2008b). Capsaicin stimulates uncoupled ATP hydrolysis by the sarcoplasmic reticulum calcium pump. J. Biol. Chem. 283: 21418-21426.
|
Mana-Capelli, S., A.K. Mandal, and J.M. Argüello. (2003). Archaeoglobus fulgidus CopB is a thermophilic Cu2+-ATPase. Functional role if its histidine-rich N-terminal metal binding domain. J. Biol. Chem. 278: 40534-40541.
|
Mandal, A.K., W.D. Cheung, and J.M. Argüello. (2002). Characterization of a thermophilic P-type Ag+/Cu+-ATPase from the extremophile Archaeoglobus fulgidus. J. Biol. Chem. 277: 7201-7208.
|
Maudoux, O., H. Batoko, C. Oecking, K. Gevaert, J. Vandekerckhove, M. Boutry, and P. Morsomme. (2000). A plant plasma membrane H+-ATPase expressed in yeast is activated by phosphorylation at its penultimate residue and binding of 14-3-3 regulatory proteins in the absence of fusicoccin. J. Biol. Chem. 275: 17762-17770.
|
Mills R.F., M.L. Doherty, R.L. López-Marqués, T. Weimar, P. Dupree, M.G. Palmgren, J.K. Pittman, and L.E. Williams. (2008). ECA3, a golgi-localized P2A-type ATPase, plays a crucial role in manganese nutrition in Arabidopsis. Plant Physiol. 146: 116-128.
|
Moniakis J., M.B. Coukell, A. Forer. (1995). Molecular cloning of an intracellular P-type ATPase from Dictyostelium that is up-regulated in calcium-adapted cells. J. Biol. Chem. 270: 28276-28281.
|
Moreno I., L. Norambuena, D. Maturana, M. Toro, C. Vergara, A. Orellana, A. Zurita-Silva, V.R. Ordenes. (2008). AtHMA1 Is a Thapsigargin-sensitive Ca2+/Heavy Metal Pump. J. Biol. Chem. 283: 9633-9641.
|
Morii, M., M. Yamauchi, T. Ichikawa, T. Fujii, Y. Takahashi, S. Asano, N. Takeguchi, and H. Sakai. (2008). Involvement of the H3O+-Lys-164 -Gln-161-Glu-345 charge transfer pathway in proton transport of gastric H+,K+-ATPase. J. Biol. Chem. 283: 16876-16884.
|
Morsomme, P., M. Chami, S. Marco, J. Nader, K.A. Ketchum, A. Goffeau, and J.-L. Rigaud. (2002). Characterization of a hyperthermophilic P-type ATPase from Methanococcus jannaschii expressed in yeast. J. Biol. Chem. 277: 29608-29616.
|
Morth J.P., B.P. Pedersen, M.S. Toustrup-Jensen, T.L. Sørensen, J. Petersen, J.P. Andersen, B. Vilsen, P. Nissen. (2007). Crystal structure of the sodium-potassium pump.
Nature. 450: 1043-1049.
|
Mukherjee, T., D. Mandal, and A. Bhaduri. (2001). Leishmania plasma membrane Mg2+-ATPase is a H+/K+-antiporter involved in glucose symport. J. Biol. Chem. 276: 55563-55569.
|
Okunade, G.W., M.L. Miller, M. Azhar, A. Andringa, L.P. Sanford, T. Doetschman, V. Prasad, and G.E. Shull. (2007). Loss of the Atp2c1 secretory pathway Ca2+-ATPase (SPCA1) in mice causes Golgi stress, apoptosis, and midgestational death in homozygous embryos and squamous cell tumors in adult heterozygotes. J. Biol. Chem. 282: 26517-26527.
|
Olesen C., M. Picard, A.M. Winther, C. Gyrup, J.P. Morth, C. Oxvig, J.V. Møller, P. Nissen. (2007). The structural basis of calcium transport by the calcium pump. Nature. 450: 1036-1042.
|
Palmgren M.G., Christensen G. (1994). Functional comparisons between plant plasma membrane H(+)-ATPase isoforms expressed in yeast. J. Biol. Chem. 269: 3027-3033.
|
Pedersen, B.P., M.J. Buch-Pedersen, J.P. Morth, M.G. Palmgren, and P. Nissen. (2007). Crystal structure of the plasma membrane proton pump. Nature 450: 1111-1114.
|
Peréz-Victoria, F.J., F. Gamarro, M. Ouellette, and S. Castanys. (2003). Functional cloning of the miltefosine transporter. A novel P-type phospholipid translocase from Leishmania involved in drug resistance. J. Biol. Chem. 278: 49965-49971.
|
Peréz-Victoria, F.J., Sanchez-Canete, M.P., Castanys, S., and Gamarro, F. (2006). Phospholipid translocation and miltefosine potency require both L. donovani miltefosine transporter and the new protein LdRos3 in Leishmania parasites. J. Biol. Chem. 281: 23766-23775.
|
Pomorski, T., R. Lombardi, H. Riezman, P.F. Devaux, G. van Meer, and J.C. Holthuis. (2003). Drs2p-related P-type ATPases Dnf1p and Dnf2p are required for phospholipid translocation across the yeast plasma membrane and serve a role in endocytosis. Mol. Biol. Cell. 14(3):1240-1254.
|
Pontel, L.B., M.E. Audero, M. Espariz, S.K. Checa, and F.C. Soncini. (2007). GolS controls the response to gold by the hierarchical induction of Salmonella-specific genes that include a CBA efflux-coding operon. Mol. Microbiol. 66: 814-825.
|
Poulsen, L.R., R.L. López-Marqués, S.C. McDowell, J. Okkeri, D. Licht, A. Schulz, T. Pomorski, J.F. Harper, and M.G. Palmgren. (2008). The Arabidopsis P4-ATPase ALA3 Localizes to the Golgi and Requires a β-Subunit to Function in Lipid Translocation and Secretory Vesicle Formation. Plant Cell 20: 658-676.
|
Qiu, L.Y., E. Krieger, G. Schaftenaar, H.G. Swarts, P.H. Willems, J.J. De Pont, and J.B. Koenderink. (2005). Reconstruction of the complete ouabain-binding pocket of Na,K-ATPase in gastric H,K-ATPase by substitution of only seven amino acids. J. Biol. Chem. 280: 32349-32355.
|
Rajendran, V.M., P. Sangan, J. Geibel, and H.J. Binder. (2000). Ouabain-sensitive H,K-ATPase functions as Na,K-ATPase in apical membranes of rat distal colon. J. Biol. Chem. 275: 13035-13040.
|
Rensing, C., B. Fan, R. Sharma, B. Mitra, amd B.P. Rosen. (2000). CopA: an Escherichia coli Cu(I)-translocating P-type ATPase. Proc. Natl. Acad. Sci. USA 97: 652-656.
|
Rensing, C., M. Ghosh, and B.P. Rosen. (1999). Families of soft-metal-ion transporting ATPase. J. Bacteriol. 181: 5891-5897.
|
Rensing, C., Y. Sun, B. Mitra, and B.P. Rosen. (1998). Pb(II)-translocating P-type ATPases. J. Biol. Chem. 273: 32614-32617.
|
Reyes, N., and D.C. Gadsby. (2006). Ion permeation through the Na+ ,K+ -ATPase. Nature 443: 470-474.
|
Riekhof, W.R. and D.R. Voelker. (2009). The yeast plasma membrane P(4)-ATPases are major transporters for lysophospholipids. Biochim. Biophys. Acta. 1791: 620-627.
|
Riekhof, W.R. and Voelker, D.R. (2006). Uptake and utilization of lyso-phosphatidylethanolamine by Saccharomyces cerevisiae. J. Biol. Chem. 281: 36588-36596.
|
Riekhof, W.R., J. Wu, M.A. Gijón, S. Zarini, R.C. Murphy, and D.R. Voelker. (2007). Lysophosphatidylcholine metabolism in Saccharomyces cerevisiae: the role of P-type ATPases in transport and a broad specificity acyltransferase in acylation. J. Biol. Chem. 282: 36853-36861.
|
Rossbach, S., D.J. Mai, E.L. Carter, L. Sauviac, D. Capela, C. Bruand, and F.J. de Bruijn. (2008). Response of Sinorhizobium meliloti to elevated concentrations of cadmium and zinc. Appl. Environ. Microbiol. 74: 4218-4221.
|
Scarborough, G.A. (1999). Structure and function of the P-type ATPases. Curr. Opin. Cell Biol. 11: 517-522.
|
Scheiner-Bobis, G. (2002). The sodium pump. Its molecular properties and mechanics of ion transport. Eur. J. Biochem. 269: 2424-2433.
|
Schiøtt, M., S.M. Romanowsky, L. Baekgaard, M.K. Jakobsen, M.G. Palmgren, and J.F. Harper. (2004). A plant plasma membrane Ca2+ pump is required for normal pollen tube growth and fertilization. Proc. Natl. Acad. Sci. USA 101: 9502-9507.
|
Schoner, W. (2002). Endogenous cardiac glycosides, a new class of steroid hormones. Eur. J. Biochem. 269: 2440-2448.
|
Seigneurin-Berny, D., A. Gravot, P. Auroy, C. Mazard, A. Kraut, G. Finazzi, D. Grunwald, F. Rappaport, A. Vavasseur, J. Joyard, P. Richaud, and N. Rolland. (2006). HMA1, a new Cu-ATPase of the chloroplast envelope, is essential for growth under adverse light conditions. J. Biol. Chem. 281: 2882-2892.
|
Shinoda, T., H. Ogawa, F. Cornelius, and C. Toyoshima. (2009). Crystal structure of the sodium-potassium pump at 2.4 Å resolution. Nature 459: 446-450.
|
Shono, M., M. Wada, Y. Hara, and T. Fujii. (2001). Molecular cloning of Na+-ATPase cDNA from a marine alga Heterosigma akashiwo. Biochim. Biophys. Acta 1511: 193-199.
|
Silver, S. (1996). Transport of inorganic cations. In F.C. Neidhardt et al. (eds.), Escherichia coli and Salmonella typhimurium: Cellular and Molecular Biology, 2nd ed. Washington, D.C.: ASM Press, pp. 1091-1102.
|
Sinkins, W.G., M. Estacion, V. Prasad, M. Goel, G.E. Shull, D.L. Kunze, and W.P. Schilling. (2009). MAITOTOXIN CONVERTS THE PLASMALEMMAL Ca2+ PUMP (PMCA) INTO A Ca2+-PERMEABLE NON-SELECTIVE CATION CHANNEL. Am. J. Physiol. Cell Physiol. [Epub: Ahead of Print]
|
Sitthisak, S., L. Knutsson, J.W. Webb, and R.K. Jayaswal. (2007). Molecular characterization of the copper transport system in Staphylococcus aureus. Microbiology. 153: 4274-4283.
|
Stevens, H.C., L. Malone, and J.W. Nichols. (2008). The putative aminophospholipid translocases, DNF1 and DNF2, are not required for 7-nitrobenz-2-oxa-1,3-diazol-4-yl-phosphatidylserine flip across the plasma membrane of Saccharomyces cerevisiae. J. Biol. Chem. 283: 35060-35069.
|
Stokes, D.L. and N.M. Green. (2000). Modeling a dehalogenase fold into the 8-Å density map for Ca2+-ATPase defines a new domain structure. Biophys. J. 78: 1765-1776.
|
Swarts, H.G., J.B. Koenderink, P.H. Willems, and J.J. De Pont. (2005). The non-gastric H,K-ATPase is oligomycin-sensitive and can function as an H+,NH4+-ATPase. J. Biol. Chem. 280: 33115-33122.
|
Takeda, K., H. Eguchi, S. Soeda, A. Shirahata, and M. Kawamura. (2005). Fe(II)/Cu(I)-dependent P-type ATPase activity in the liver of Long-Evans cinnamon rats. Life Sci. 76: 2203-2209.
|
Takeuchi, A., N. Reyes, P. Artigas, and D.C. Gadsby. (2008). The ion pathway through the opened Na+,K+-ATPase pump. Nature 456: 413-416.
|
Tang, X., M.S. Halleck, R.A. Schlegel, and P. Williamson. (1996). A subfamily of P-type ATPases with aminophospholipid transporting activity. Science 272: 1495-1497.
|
Therien, A.G., S.J.D. Karlish, and R. Blostein. (1999). Expression and functional role of the γ-subunit of the Na,K-ATPase in mammalian cells. J. Biol. Chem. 274: 12252-12256.
|
Ton, V.-K., D. Mandal, C. Vahadji, and R. Rao. (2002). Functional expression in yeast of the human secretory pathway Ca2+, Mn2+-ATPase defective in Hailey-Hailey disease. J. Biol. Chem. 277: 6422-6427.
|
Tong, L., S. Nakashima, M. Shibasaka, M. Katsuhara, and K. Kasamo. (2002). A novel histidine-rich CPx-ATPase from the filamentous cyanobacterium Oscillatoria brevis related to multiple-heavy-metal cotolerance. J. Bacteriol. 184: 5027-5035.
|
Toyoshima, C. and H. Nomura. (2002). Structural changes in the calcium pump accompanying the dissociation of calcium. Nature 418: 598-599.
|
Toyoshima, C., M. Nakasako, H. Nomura, and H. Ogawa. (2000). Crystal structure of the calcium pump of sarcoplasmic reticulum at 2.6 Å resolution. Nature 405: 633-634.
|
Tsai, K.-J., Y.-F. Lin, M.D. Wong, H.H.-C. Yang, H.-L. Fu, and B.P. Rosen. (2002). Membrane topology of the p1258 CadA Cd(II)/Pb(II)/Zn(II)-translocating P-type ATPase. J. Bioenerg. Biomembr. 34: 147-156.
|
Ueno, S., N. Kaieda, and N. Koyama. (2000). Characterization of a P-type Na+-ATPase of a facultatively anaerobic alkaliphile, Exiguobacterium aurantiacum. J. Biol. Chem. 275: 14537-14540.
|
Ushimaru, M. and Y. Fukushima. (2008). The dimeric form of Ca2+-ATPase is involved in Ca2+ transport in the sarcoplasmic reticulum. Biochem. J. 414: 357-361.
|
Van Baelen K., J. Vanoevelen, L. Missiaen, L. Raeymaekers, F. Wuytack. (2001). The Golgi PMR1 P-type ATPase of Caenorhabditis elegans. Identification of the gene and demonstration of calcium and manganese transport. J. Biol. Chem. 276: 10683-10691.
|
Villafane, A.A., Y. Voskoboynik, M. Cuebas, I. Ruhl, and E. Bini. (2009). Response to excess copper in the hyperthermophile Sulfolobus solfataricus strain 98/2. Biochem. Biophys. Res. Commun. 385: 67-71.
|
Watanabe, Y., Y. Shimono, H. Tsuji, and Y. Tamai. (2002). Role of the glutamic and aspartic residues in Na+-ATPase function in the ZrENA1 gene of Zygosaccharomyces rouxii. FEMS Microbiol. Lett. 209: 39-43.
|
Weissman, Z., R. Shemer, and D. Kornitzer. (2002). Deletion of the copper transporter CaCCC2 reveals two distinct pathways for iron acquisition in Candida albicans. Mol. Microbiol. 44: 1551-1560.
|
Wetzel, R.K., J.L. Pascoa, and E. Arystarkhova. (2004). Stress-induced expression of the γsubunit (FXYD2) modulates Na,K-ATPase activity and cell growth. J. Biol. Chem. 279: 41750-41757.
|
Wiangnon, K., W. Raksajit, and A. Incharoensakdi. (2007). Presence of a Na+-stimulated P-type ATPase in the plasma membrane of the alkaliphilic halotolerant cyanobacterium Aphanothece halophytica. FEMS Microbiol. Lett. 270: 139-145.
|
Worrell, R.T., L. Merk, and J.B. Matthews. (2008). Ammonium transport in the colonic crypt cell line, T84: role for Rhesus glycoproteins and NKCC1. Am. J. Physiol. Gastrointest. Liver Physiol. 294: G429-440.
|
Wu, C.C., A. Gardarin, A. Martel, E. Mintz, F. Guillain, and P. Catty. (2006). The cadmium transport sites of CadA, the Cd2+-ATPase from Listeria monocytogenes.
J. Biol. Chem. 281: 29533-29541.
|
Wu, C.C., W.J. Rice, and D.L. Stokes. (2008). Structure of a copper pump suggests a regulatory role for its metal-binding domain. Structure 16: 976-985.
|
Wu, C.H., L.A. Vasilets, K. Takeda, M. Kawamura, and W. Schwarz. (2003). Functional role of the N-terminus of a Na+,K+-ATPase α-subunit as an inactivation gate of palytoxin-induced pump channel. Biochim. Biophys. Acta 1609: 55-62.
|
Xiang, M., D. Mohamalawari, and R. Rao. (2005). A novel isoform of the secretory pathway Ca2+,Mn2+-ATPase, hSPCA2, has unusual properties and is expressed in the brain. J. Biol. Chem. 280: 11608-11614.
|
Xu, C., W.J. Rice, W. He, and D.L. Stokes. (2002). A structural model for the catalytic cycle of Ca2+-ATPase. J. Mol. Biol. 316: 201-211.
|
Zeng, X.T., T. Higashida, M. Hara, N. Hattori, K. Kitagawa, K. Omori, and C. Inagaki. (1999). Antiserum against Cl- pump complex recognizes 51 kDa protein, a possible catalytic unit in rat brain. Neurosci. Lett. 258: 85-88.
|
Zhang, S., S. Malmersjö, J. Li, H. Ando, O. Aizman, P. Uhlén, K. Mikoshiba, and A. Aperia. (2006). Distinct role of the N-terminal tail of the Na,K-ATPase catalytic subunit as a signal transducer. J. Biol. Chem. 281: 21954-21962.
|
Zhang, Z., D. Lewis, C. Strock, G. Inesi, M. Nakasako, H. Nomura, and C. Toyoshima. (2000). Detaled characterization of the cooperative mechanism of a Ca(2+) binding and catalytic activation in the Ca(2+) transport (SERCA) ATPase. Biocemistry 39: 8758-8767.
|
Zhou, X. and T.R. Graham. (2009). Reconstitution of phospholipid translocase activity with purified Drs2p, a type-IV P-type ATPase from budding yeast. Proc. Natl. Acad. Sci. USA 106: 16586-16591.
|
| Examples: |
| TC# | Name | Organismal Type | Example |
| 3.A.3.1.1 | Na+-, K+-ATPase (Na+ efflux; K+ uptake) (Mutations in the γ-subunit causes renal hypomagnesemia, associated with hypocalciurea) (Cairo et al., 2008). The Na/K-ATPase is an important signal transducer that not only interacts and regulates protein kinases, but also functions as a scaffold (Li and Xie, 2009). Capsazepine, a synthetic vanilloid, converts the Na, K-ATPase to a Na-ATPase (Mahmmoud, 2008a). | Animals | Na+-, K+-ATPase from Homo sapiens
γ-subunit (FXyD) (P54710) |
| |
| 3.A.3.1.2 | H+-, K+-ATPase (gastric; H+ efflux; K+ uptake) (Two H3O+ are transported per ATP hydrolyzed) | Animals | Gastric H+-, K+-ATPase from Homo sapiens |
| |
| 3.A.3.1.3 | Na+-ATPase | Marine algae | Na+-ATPase (HANA) of Heterosigma akashiwo |
| |
| 3.A.3.1.4 | Non-gastric H+-, K+- or NH4+-ATPase (Swarts et al., 2005; Worrell et al., 2007) | Animals | H+-, K+ or NH4+-ATPase of Rattus norvegicus (P54708) |
| |
| 3.A.3.1.5 | Putative spirochete Na+, K+-ATPase, Lbi6 (1046 aas) (K. Hak & M.H. Saier) | Bacteria | Lbi6 of Leptospira biflexa (B0SMV3) |
| |
| 3.A.3.1.6 | Spiny dogfish Na+,K+-ATPase (3-d structure solved at 2.4 Å resolution, Shinoda et al., 2009). The α-subunit is 88% identical to the human Na+,K+ ATPase (TC# 3.A.3.1.1). | Animals | Na+,K+-ATPase α, β, and γ subunits of Squalus acanthias
α (1028aas; Q4H132)
β (305aas; C4IX13)
γ (94aas; Q70Q12) |
| |
| 3.A.3.2.1 | Ca2+-ATPase (efflux) | Eukaryotes | Plasma membrane Ca2+-translocating ATPase of Homo sapiens (P23634) |
| |
| 3.A.3.2.2 | Ca2+-ATPase (uptake into vacuoles) | Yeast | Vacuolar membrane Ca2+-translocating ATPase from Saccharomyces cerevisiae Pmc1 |
| |
| 3.A.3.2.3 | Ca2+-ATPase (efflux) (may also transport Mn2+ and Cd2+) (Lauer et al., 2008)
| Eukaryotes | Golgi Ca2+-ATPase Pmr1 of Saccharomyces cerevisiae |
| |
| 3.A.3.2.4 | Ca2+-ATPase (efflux) | Bacteria | Putative Ca2+-ATPase of Synechocystis sp. pMA1 |
| |
| 3.A.3.2.5 | The Golgi Ca2+, Mn2+-ATPase, hSPCA1 (efflux) (the Hailey-Hailey disease protein). Involved in responses to golgi stress, apoptosis and midgestational death (Okunade et al., 2007) | Animals | hSPCA1 of Homo sapiens |
| |
| 3.A.3.2.6 | Ca2+, Mn2+- ATPase (efflux) | Fungi | Pmr1 of Neurospora crassa |
| |
| 3.A.3.2.7 | The sarco/endoplasmic reticulum Ca2+-ATPase, SERCA2b (encoded by the ATPLA2 gene) (Darier's disease protein) (Ahn et al., 2003) (SERCA1 functions as a heat generator in mitochondria of brown adipose tissue; de Meis et al., 2006). Functions as a Ca2+:H+ antiporter (Karjalainen et al., 2007). Capsaicin converts SERCA to a Ca2+ non-transporting ATPase that generates heat. Capsaicin is the first natural drug that augments uncoupled SERCA, resulting in thermogenesis (Mahmmoud, 2008b).
| Animals | SERCA2b of Homo sapiens (P16615) |
| |
| 3.A.3.2.8 | Ca2+-ATPase (efflux) broad Ca2+ dependence (3.2-320 μm) | Protozoa | PfATPase4 of Plasmodium falciparum |
| |
| 3.A.3.2.9 | Ca2+,Mn2+-ATPase, hSPCA2 (ATP2C2) (efflux). 64% identical to hSPCA1 (TC #3.A.3.2.5) but lower affinity for Ca2+ and more restricted tissue distribution (brain and testis); present in the trans-Golgi network. May function in Mn2+ detoxification (Xiang et al., 2005). | Animals | hSPCA2 of Homo sapiens (NP_055676) |
| |
| 3.A.3.2.10 | The autoinhibited, calmodulin-binding Ca2+-ATPase, isoform 8, ACA8 (Baekgaard et al., 2006) | Plants | ACA8 of Arabidopsis thaliana (Q9LF79) |
| |
| 3.A.3.2.11 | Plastid Envelope Ca2+ ATPase, PEA1 (lacks a C-terminal calmodulin domain) | Plants | PEA1 of Arabidopsis thaliana
(Q37145) |
| |
| 3.A.3.2.12 | Endomembrane plasma membrane-type Ca2+ ATPase, ACA2 (Arabidopsis Ca2+ ATPase isoform 2) (lacks a C-terminal calmodulin domain, but activity is stimulated 5x by calmodulin which binds to an N-terminal inhibitory domain (Harper et al., 1998). | Plants | ACA2 of Arabidopsis thaliana
(O81108) |
| |
| 3.A.3.2.13 | Endoplasmic Reticular (ER)-type ER Ca2+/Mn2+ ATPase, ECA1 | Plants | ECA1 of Arabidopsis thaliana
(P92939) |
| |
| 3.A.3.2.14 | Autoinhibited Ca2+ ATPase (ACA9) (expressed in pollen plasma membrane and required for male fertility), calmodulin-binding (Schiøtt et al., 2004). | Plants | ACA9 of Arabidopsis thaliana
(Q9LU41) |
| |
| 3.A.3.2.15 | Plasma membrane Ca2+ ATPase, Mca1 (Kraev et al., 1999) | Animals | Mca1 of Caenorhabditis elegans
(O45215)
|
| |
| 3.A.3.2.16 | Golgi Ca2+, Mn2+ ATPase, PMR1 (Van Baelen et al., 2001). (The human orthologue ATP2Cl, TC#3.A.3.2.5, causes Hailey-Hailey disease.) | Animals | PMR1 of Caenorhabditis elegans
(Q9XTG4) |
| |
| 3.A.3.2.17 | Intracellular (contractile vacuole) Ca2+ ATPase, PatA (lacks the C-terminal calmodulin domain of most plasma membrane Ca2+ ATPases) (Moniakis et al., 1995) | Slime molds | PatA of Dictyostelium discoideum
(P54678) |
| |
| 3.A.3.2.18 | The acidocalcisome (vacuole) Ca2+/H+ ATPase TgA1 (involved in Ca2+ homeostasis, vacuolar polyphosphate storage and virulence) (Luo et al., 2005). | Protozoa | TgA1 of Toxoplasma gondii
(Q9N694) |
| |
| 3.A.3.2.19 | Endomembrane (golgi) Ca2+/Mn2+-ATPase, ECA3 (one of 4 close paralogues in A. thaliana (Mills et al., 2008) | Plants | ECA3 of Arabidopsis thaliana (Q0WP80) |
| |
| 3.A.3.2.20 | Putative Ca2+ ATPase Cac1 (possible pseudogene?)
| Firmicutes | Cac1 of Clostridium acetobutylicum (Q97JK5) |
| |
| 3.A.3.2.21 | Putative Ca2+ ATPase, Pmo1
| Thermotogales | Pmo1 of Petrotoga mobilis (A9BJX0) |
| |
| 3.A.3.2.22 | Putative Ca2+ ATPase, Sth1
| Firmicutes | Sth1 of Streptococcus thermophilus (Q5M0A4) |
| |
| 3.A.3.2.23 | Putative Ca2+ ATPase most similar to golgi Ca2+ ATPases of eukaryotes
| Archaea | Putative Ca2+ ATPase of Methanococcus vannielii (A6URW9) |
| |
| 3.A.3.2.24 | Putative Ca2+-ATPase (48% identical to 3.A.3.2.23) (like golgi Ca2+-ATPases of eukaryotes) | Bacteria | Putative Ca2+-ATPase of Aguifex aeolicus (O66938) |
| |
| 3.A.3.2.25 | Plasma membrane Ca2+-ATPase, isoform 1a (PMCA1) (78% identical to PMCA4 (TC# 3.A.3.2.1)). Maitotoxin converts it into a Ca2+--permeable nonselective cation channel (Sinkins et al., 2009). | Animals | PMCA1 of Homo sapiens (P20020) |
| |
| 3.A.3.3.1 | H+-ATPase (efflux) | Plants; fungi; protozoa; slime molds; archaea | H+-ATPase, plasma membrane of Neurospora crassa |
| |
| 3.A.3.3.2 | H+ (in)/K+ (out) Mg2+-ATPase (antiporter) | Protozoa | H+/K+ antiport ATPase 1A of Leishmania donovani |
| |
| 3.A.3.3.3 | Mn2+/Cd2+-ATPase, MntA (Hao et al. 1999).
| Bacteria | MntA of Lactobacillus plantarum |
| |
| 3.A.3.3.4 | Putative H+-ATPase | Archaea | Aha1 (MJ1226) of Methanococcus jannaschii |
| |
| 3.A.3.3.5 | Plasma membrane H+-ATPase, TbHA1 (912 aas) (3 isoforms are present in T. brucei) (Luo et al., 2006) | Protozoan | TbHA1 of Trypanosoma brucei (AAP30857) |
| |
| 3.A.3.3.6 | H+-ATPase (pumps protons out of the cell to generate a membrane potential and regulate cytosolic pH) (Liu et al., 2006) | Yeast | H+-ATPase of Saccharomyces cerevisiae (P05030) |
| |
| 3.A.3.3.7 | Plasma membrane H+ ATPase, AHA1 (3 isoforms, AHA1, 2 & 3, exhibit different kinetic properties) (Palmgren and Christensen, 1994). | Plants | AHA1 of Arabidopsis thaliana
(P20649) |
| |
| 3.A.3.4.1 | Mg2+/Ni2+-ATPase (uptake) | Bacteria | MgtA of Salmonella typhimurium |
| |
| 3.A.3.4.2 | Putative spirochete Mg2+-ATPase, Lin3 (843 aas) | Bacteria | Lin3 of Leptospira interrogans (Q72RN5) |
| |
| 3.A.3.5.1 | Cu2+-ATPase (uptake) | Bacteria | CopA of Enterococcus hirae |
| |
| 3.A.3.5.2 | Cu+-, Ag+-ATPase (efflux) | Bacteria | CopB of Enterococcus hirae |
| |
| 3.A.3.5.3 | Cu+-, Ag+-ATPase (efflux from the cytosol into the secretory pathway) (Barnes et al., 2005); ATP7B (Wilson's disease protein, α-chain) (continuously expressed in Purkinje neurons). It delivers Cu+ to the ferroxidase, ceruloplasmin, in liver. May also transport Fe2+ (Takeda et al., 2005). | Eukaryotes | Cu+-ATPase, ATP7B, of Homo sapiens |
| |
| 3.A.3.5.4 | Ag+-ATPase (efflux) | Bacteria | Ag+-ATPase, SilP of Salmonella typhimurium |
| |
| 3.A.3.5.5 | Cu+, Ag+-ATPase (efflux) (Fan and Rosen, 2002) | Bacteria | CopA of E. coli |
| |
| 3.A.3.5.6 | Cu+-ATPase, ATP7A (MNK or Mc1) (efflux from the cytosol into the secretory pathway) (Menkes disease protein, α-chain). Expressed in Purkinje cells early in development and later in Bergmann glia. In melanocytes, it delivers Cu2+ to tyrosinase (Barnes et al., 2005). ATP7A has dual functions: 1) it incorporates copper into copper-dependent enzymes; and 2) it maintains intracellular copper levels by removing excess copper from the cytosol. To accomplish both functions, the protein traffics between different cellular locations, depending on copper levels (Bertini and Rosato, 2008). | Animals | ATP7A of Homo sapiens |
| |
| 3.A.3.5.7 | Cu+-Ag+-ATPase (efflux), CopA. Exhibits maximal activity at 75˚C (Cattoni et al., 2007). The 3-D structure of the ATP-binding domain has been solved (2HC8_A) (functions with the Cu+ chaperone, CopZ; 130aas) (González-Guerrero and Argüello, 2008). | Euryarchaea | CopAZ of Archaeoglobus fulgidus:
CopA (PaeS) (O29777)
CopZ (2HU9_A) |
| |
| 3.A.3.5.8 | Cu+ transporting ATPase (intracellular, in the transgolgi membrane), Ccc2 | Yeast | Ccc2 of Candida albicans |
| |
| 3.A.3.5.9 | Cu+ transporting (copper detoxification) ATPase, Crp1 | Yeast | Crp1 of Candida albicans |
| |
| 3.A.3.5.10 | Cu+ (Km 0.3 μM), Ag+ transporting ATPase, CopB (Mana-Capelli et al., 2003) | Euryarchaea | CopB of Archaeoglobus fulgidus (AAB91079) |
| |
| 3.A.3.5.11 | Chloroplast envelope Cu+-uptake ATPase, PAA1 | Plants | PAA1 of Arabidopsis thaliana (Q9SZC9) |
| |
| 3.A.3.5.12 | Chloroplast thylakoid Cu+-ATPase, PAA2 (delivers Cu+ to the thylakoid lumen) | Plants | PAA2 of Arabidopsis thaliana (AAP55720) |
| |
| 3.A.3.5.13 | The archaeal Cu+ efflux pump (CopA) | Archaea | CopA of Sulfolobus solfataricus (Q97UU7) |
| |
| 3.A.3.5.14 | The yeast Cd2+ efflux pump, PCA1 (Adle et al., 2007) | Yeast | PCA1 of Saccharomyces cerevisiae (P38360) |
| |
| 3.A.3.5.15 | The transferable, plasmid-localized Copper sensitivity (uptake) ATPase, TcrA (811aas) (43% identical to 3.A.3.1.1) (Hasman, 2005) | Bacteria | TcrA of Enterococcus faecium (ABA39707) |
| |
| 3.A.3.5.16 | The transferable, plasmid-localized Copper resistance efflux) ATPase, TcrB (43% identical to 3.A.3.5.2) (Hasman, 2005) | Bacteria | TcrB of Enterococcus faecium (AAL05407) |
| |
| 3.A.3.5.17 | Golgi Cu2+ ATPase, Ccc2, retrieves Cu2+ from the metallochaperone Atx1 and transports it to the lumen of golgi vesicles (Lowe et al., 2004) | Yeast | Ccc2 of Saccharomyces cerevisiae
(P38995) |
| |
| 3.A.3.5.18 | The copper resistance ATPase, CopA (Ettema et al., 2006; Lübben et al., 2007; Villafane et al., 2009). | Bacteria | CopA of Bacillus subtilis (O32220) |
| |
| 3.A.3.5.19 | The Cu2+, Fe3+, Pb2+ resistance efflux pump, CopA (induced by copper and to a lesser extent by Fe3+ and Pb2+) (Sitthisak et al., 2007) | Gram-positive bacterium | CopA of Staphylococcus aureus (Q7A3E6) |
| |
| 3.A.3.5.20 | The gold (Au2+) resistance ATPase, GolT (regulated by GolS in response to Au2+; it may function with a cytoplasmic metal binding protein, GolB (AAL19308; Pontel et al., 2007). | Bacteria | GolT of Salmonella enterica (Q8ZRG7) |
| |
| 3.A.3.5.21 | The Cu+, Ag+-ATPase, CtrA2 (Chintalapati et al., 2008) | Bacteria | CtrA2 of Aquifex aeolicus (O67432) |
| |
| 3.A.3.5.22 | The Cu2+-ATPase, CtrA3 (Chintalapati et al., 2008) | Bacteria | CtrA3 of Aquifex aeolicus (O67203) |
| |
| 3.A.3.5.23 | Putative spirochete Cu+ ATPase (6 proteins in spirochetes) | Bacteria | Lin1 of Leptospira interrogans (Q72N56) |
| |
| 3.A.3.5.24 | The putative copper ATPase, Sso1 (PacS)
| Crenarchaeota | PacS of Sulfolobus solfataricus (Q97VH4) |
| |
| 3.A.3.5.25 | The putative copper ATPase, Pae1
| Crenarchaeota | Pae1 of Pyrobaculum aerophilum (Q8ZUJ0) |
| |
| 3.A.3.5.26 | The putative copper ATPase, Tro1
| Euryarchaeota | Tro1 of Thermoplasma volcanium (Q978Z8) |
| |
| 3.A.3.5.27 | Putative Copper P-type ATPase (46% identical to 3.A.3.5.10) | Korarchaea | Putative Copper P-type ATPase of Candidatus Korarchaeum cryptofilum (B1L487) |
| |
| 3.A.3.5.28 | The putative copper ATPase, Ape2
| Crenarchaeota | Ape2 of Aeropyrum pernix (Q9YBZ6) |
| |
| 3.A.3.6.1 | Zn2+-, Cd2+-, Pb2+-ATPase (efflux) | Bacteria; plants; fungi; protozoa | CadA of Staphylococcus aureus plasmid |
| |
| 3.A.3.6.2 | Zn2+-, Cd2+-, Co2+-, Hg2+-, Ni2+-, Cu2+, Pb2+-ATPase (efflux) (Hou and Mitra, 2003) | Bacteria | ZntA of E. coli |
| |
| 3.A.3.6.3 | Cd2+-, Zn2+, Co2+-ATPase (efflux) | Bacteria | CadA (HP0791) of Helicobacter pylori |
| |
| 3.A.3.6.4 | Pb2+-ATPase (efflux) | Bacteria | PbrA of Ralstonia metallidurans |
| |
| 3.A.3.6.5 | Mono- and divalent heavy metal (Cu+, Ag+, Zn2+, Cd2+) ATPase, Bxa1 (bxa1 gene expression is induced by all four heavy metal ions (Tong et al., 2003). | Bacteria | Bxa1 ATPase of Oscillatoria brevis |
| |
| 3.A.3.6.6 | Chloroplast envelope Cu+-ATPase, HMA1 (Seigneurin-Berny et al., 2006). Transports many heavy metals (Zn2+, Cu2+, Cd2+, Co2+), increasing heavy metal tolerance. Also transports Ca2+ (Km=370nM) in a thapsigargin-sensitive fashion (Moreno et al, 2008). | Plants | HMA1 of Arabidopsis thaliana
(Q9M3H5) |
| |
| 3.A.3.6.7 | The Zn2+ (and Cd2+)-ATPase, HMA2. HMA2 maintains metal homeostasis and has a long C-terminal sequence rich in Cys and His residues that binds Zn2+, Kd≈16 nM and regulates activity (Eren et al., 2006). | Plants | HMA2 of Arabidopsis thaliana (Q9SZW4) |
| |
| 3.A.3.6.8 | The Cd2+ resistance ATPase, CadA (Wu et al., 2006) | Bacteria | CadA of Listeria monocytogenes (Q60048) |
| |
| 3.A.3.6.9 | The Zn2+ uptake ATPase, ZosA (YkvW) (Gaballa and Helmann, 2002) | Bacteria | ZosA of Bacillus subtilis (O31688) |
| |
| 3.A.3.6.10 | The Cd2+, Zn2+, Co2+ resistance ATPase, CadA (YvgW) | Bacteria | CadA of Bacillus subtilis (O32219) |
| |
| 3.A.3.6.11 | The Zn2+ efflux P-type ATPase, CadA1 (Leedjarv et al., 2007) | | CadA1 of Pseudomonas putida (Q88RT8) |
| |
| 3.A.3.6.12 | The Cd2+/Pb2+ resistance P-type ATPase, CadA2; induced by Zn2+, Cd2+, Pb2+, Ni2+, Co2+ and Hg2+ (Leedjarv et al., 2007) | | CadA2 of Pseudomonas putida (Q88CP1) |
| |
| 3.A.3.6.13 | The heavy metal efflux pump, AztA (exports Zn2+, Cd2+, Pb2+; has two adjacent heavy metal binding domains (Liu et al., 2008) | Bacteria | AztA of Anabaena (Nostoc) sp. PCC7120 (Q8ZS90) |
| |
| 3.A.3.6.14 | The heavy metal (Zn2+, Cd2+) P-type ATPase, Smc04128 (Rossbach et al., 2008) | Bacteria | Smc04128 of Sinorhizobium meliloti (Q92T56) |
| |
| 3.A.3.6.15 | Putative heavy metal ATPase, Lin1 (739 aas) | Bacteria | Lin1 of Leptospira interrogans |
| |
| 3.A.3.6.16 | Functionally uncharacterized P-type ATPase (FUPA) (3 proteins from γ-proteobacteria; 634-661 aas)
| Proteobacteria | FUPA of Pseudomonas aeruginosa (Q9I147) |
| |
| 3.A.3.6.17 | The putative heavy metal ATPase, Mac1
| Euryarchaeota | Mac1 of Methanosarcina acetivorans (Q8TJZ4) |
| |
| 3.A.3.6.18 | The heavy metal transporter A (HmtA) mediates uptake of copper and zinc but not of silver, mercury, or cadmium (Lewinson et al., 2009).
| Bacteria | HmtA of Pseudomonas aeruginosa (Q9I147) |
| |
| 3.A.3.7.1 | K+-ATPase (uptake), KdpFABC. (KdpA is homologous to other K+ transporters such as KcsA (1.A.1.1.1), KtrB (2.A.38.4.2 and 2.A.38.4.3), and HKT (2.A.38.3.1 and 2.A.38.3.2); KdpB is homologous to P-ATPase α-subunits; KdpC and KdpF may facilitate complex assembly and stabilize the complex (Bramkamp et al., 2007; Haupt et al., 2005; Greie and Altendorf, 2007). The KdpFABC acts as a functional and structural dimer with the two KdpB subunits in direct contact, but the enzyme can dissociate to the monomer (Heitkamp et al., 2008). KdpF is part of and stabilizes the KdpABC complex (Gassel et al., 1999). | Bacteria | KdpABCF of E. coli
KdpA (P03959)
KdpB (P03960)
KdpC (P03961)
KdpF (P36937) |
| |
| 3.A.3.8.1 | Golgi Aminophospholipid (phosphatidyl serine and phosphatidyl ethanolamine) translocase (flipping from the exofacial to the cytosolic leaflet of membranes to generate phospholipid asymmetry), required for vesicle-mediated protein transport from the Golgi and endosomes. The system has been reconstituted after purification in proteoliposomes. It flips phosphatidyl serine but not phosphatidylcholine or sphinogomyelin (Zhou and Graham, 2009). | Animals | ATPase II of Bos taurus |
| |
| 3.A.3.8.2 | Golgi aminophospholipid translocase (flipping from the exofacial to the cytosolic leaflet of membranes), required for vesicle-mediated protein transport from the Golgi and endosomes (Pomorski et al., 2003). The system has been reconstituted after purification in proteoliposomes. It flips phosphatidyl serine but not phosphatidylcholine or sphingomyelin (Zhou and Graham, 2009). | Eukaryotes | DRS2 of Saccharomyces cerevisiae |
| |
| 3.A.3.8.3 | Miltefosine/glycerophospholipid translocase, MIL (Peréz-Victoria et al., 2003) | Protozoa | MIL of Leishmania donovani (Q6VXY9) |
| |
| 3.A.3.8.4 | Inwardly directed phospholipid and lysophospholipid (phosphatidylcholine, phosphatidyl serine and lysophosphoethanolamine) flippase, Dnf1 (functions with the β-subunit, Lem3) (Elvington et al., 2005; Pomorski et al., 2003; Riekhof and Voelker, 2006; Riekhof et al., 2007) Also transports the anti-neoplastic and anti-parasitic ether lipid substrates related to edelfosine (Riekhof and Voelker, 2009) (is not required for phosphotidyl serine inwardly directed flipping (Stevens et al. 2008)).
| Yeast | Dnf1 of Saccharomyces cerevisiae (P32660) |
| |
| 3.A.3.8.5 | Inwardly directed phosphatidylcholine, phosphatidyl serine, and lysophosphoethanolamine flippase, Dnf2 (functions with the β-subunit, Lem3) (Elvington et al., 2005; Pomorski et al., 2003; Riekhof and Voelker, 2006; Riekhof et al., 2007) | Yeast | Dnf2 of Saccharomyces cerevisiae (Q12675) |
| |
| 3.A.3.8.6 | Golgi phospholipid transporting (flipping) ATPase3 (1213aas; 10TMSs). Involved in growth of roots and shoots. Uses a β-ATPase3 subunit, ALIS1 (TC#8.A.27.4) (Paulsen et al., 2008). | Plants | ATPase3/ALIS1 of Arabidopsis thaliana (Q9XIE6) |
| |
| 3.A.3.8.7 | The aminophospholipid ATPase1 (ALA1) (mediate chilling tolerance; Gomes et al., 2000) | Plants | ALA1 of Arabidopsis thaliana (P98204) |
| |
| 3.A.3.8.8 | The phosphatidylserine flippase in photoreceptor disc membranes, ATP8A2 (Coleman et al., 2009) | Animals | ATP8A2 of Mus musculus (P98200) |
| |
| 3.A.3.9.1 | Na+-ATPase (efflux) | Fungi and protozoa | Pmr2ap (ENa1) of Saccharomyces cerevisiae |
| |
| 3.A.3.9.2 | K+-ATPase (efflux) | Fungi and protozoa | Cta3 of Schizosaccharomyces pombe |
| |
| 3.A.3.9.3 | Monovalent alkali cation (Na+ and K+) ATPase (efflux of both cations) | Fungi and protozoa | ENA2 of Debaryomyces occidentalis |
| |
| 3.A.3.9.4 | Na+ ATPase, ENA1 (Watanabe et al., 2002) | Fungi | ENA1 of Zygosaccharomyces rouxii (BAA11411) |
| |
| 3.A.3.9.5 | Plasma membrane K+ or Na+ efflux ATPase (required for growth at pH9, and for Na+ or K+ tolerance above pH8; Benito et al., 2009) (50% identical to 3.A.3.9.3).
| Fungi | Ena1 of Ustilago maydis (B5B9V9) |
| |
| 3.A.3.9.6 | Endoplasmic reticulum K+ or Na+ efflux ATPase; confers Na+ resistance (Benito et al., 2009) (43% identical to 3.A.3.9.2).
| Fungi | Ena2 of Ustilago maydis (Q4PI59) |
| |
| 3.A.3.10.1 | The endoplasmic reticular ATPase of unknown function. May transport phospholipids and play a role in Ca2+ homeostasis (Cronin et al., 2002) | Yeast | Cod1 of Saccharomyces cerevisiae (P39986) |
| |
| 3.A.3.11.1 | Functionally uncharacterized P-type ATPase family 11 (FUPA11) (one member; 1146 aas) | Microsporidian | FUPA11a of Encephalitozoon cuniculi (Q8SRH4) |
| |
| 3.A.3.12.1 | Functionally uncharacterized P-type ATPase family 12 (FUPA12) (one member; 1998 aas) | Protozoan | FUPA12a of Cyanidioschyzon merolae (CMR432C) (not in NCBI) |
| |
| 3.A.3.13.1 | Functionally uncharacterized P-type ATPase family 13 (FUPA13) (5 members; 1150-1230 aas). (Families 3.A.13-16 (FUPA 13-16) are more closely related to each other than they are to other P-type ATPases. They may comprise a single family from distantly related eukaryotic organisms). | Animals | FUPA13a of Homo sapiens (gi13435129) |
| |
| 3.A.3.14.1 | Functionally uncharacterized P-type ATPase family 14 (FUPA14) (6 proteins from fungi; 1263-1592 aas). (Families 3.A.13-16 (FUPA 13-16) are more closely related to each other than they are to other P-type ATPases. They may comprise a single family from distantly related eukaryotic organisms). | Fungi | FUPA14a of Saccharomyces cerevisiae (gi6324865) |
| |
| 3.A.3.15.1 | Functionally uncharacterized P-type ATPase family 15 (FUPA15) (3 proteins from D. discoideum; 1158-1533 aas). (Families 3.A.13-16 (FUPA 13-16) are more closely related to each other than they are to other P-type ATPases. They may comprise a single family from distantly related eukaryotic organisms). | Slime molds | FUPA15a of Dictyostelium discoideum (gi66815633) |
| |
| 3.A.3.16.1 | Functionally uncharacterized P-type ATPase family 16 (FUPA16) (11 proteins; all from Tetrahymena thermophila; 1088-1982 aas). (Families 3.A.13-16 (FUPA 13-16) are more closely related to each other than they are to other P-type ATPases. They may comprise a single family from distantly related eukaryotic organisms). | Alveolata (ciliates) | FUPA16a of Tetrahymena thermophila (Q23QW3) |
| |
| 3.A.3.17.1 | Functionally uncharacterized P-type ATPase family 17 (FUPA17) (one protein; 1096 aas) | Yeast | FUPA17a of Schizosaccharomyces pombe (O14022) |
| |
| 3.A.3.18.1 | Functionally uncharacterized P-type ATPase family 18 (FUPA18) (one protein; 1491 aas) | Alveolata | FUPA18a of Cryptosporidium parvum (Q5CW06) |
| |
| 3.A.3.19.1 | Functionally uncharacterized P-type ATPase family 19 (FUPA19) (one protein; 1807 aas) | Alveolata (ciliates) | FUPA19a of Tetrahymena thermophila (gi118355868) |
| |
| 3.A.3.20.1 | Functionally uncharacterized P-type ATPase family 20 (FUPA20) (11 proteins in Tetrahymena thermophila; 1072-1845 aas) | Alveolata (ciliates) | FUPA20a of Tetrahymena thermophila (Q22V52) |
| |
| 3.A.3.21.1 | Functionally uncharacterized P-type ATPase family 21 (FUPA21); (1 protein in Thalassiosira pseudonana; 1372 aas)
| Protozoan | FUPA21a of Thalassiosira pseudonana (ORF00905) (B8BVH9) |
| |
| 3.A.3.22.1 | Functionally uncharacterized P-type ATPase family 22 (FUPA22) (6 proteins from Alveolata; 1212-2393 aas) | Alveolata | FUPA22a of Cryptosporidium parvum (Q5CTJ9) |
| |
| 3.A.3.23.1 | Functionally uncharacterized P-type ATPase family 23 (FUPA23) (8 proteins from Actinomycetes; 650-802 aas) | Actinobacteria | FUPA23a of Streptomyces coelicolor (Q9KXM5) |
| |
| 3.A.3.23.2 | Functionally uncharacterized P-type ATPase family 23 (FUPA23.2) (5 proteins from Firmicutes (778-1056aas; 10TMSs; type 2)). | Firmicutes | FUPA23b of Enterococcus faecalis (Q835V4) |
| |
| 3.A.3.23.3 | Functionally uncharacterized P-type ATPase family 23 (FUPA23) (2 proteins from Cyanobacteria (826-831aas; 10+MSs, type 2))
| Cyanobacteria | FUPA23c of Trichodesmium erythraeum (Q10YH7)
|
| |
| 3.A.3.24.1 | Functionally uncharacterized P-type ATPase family 24 (FUPA24) (6 proteins of Actinomycetes; 760-1625 aas) | Actinobacteria | FUPA24a of Mycobacterium bovis (Q7U2U7) |
| |
| 3.A.3.24.2 | Functionally uncharacterized P-type ATPase family 24 (FUPA24) (1607aas); The first half is most like type I (Copper) ATPases, while the second half is most like type II ATPases (Ca2+). | Chloroflexi | FUPA24b of Thermomicrobium roseum (B9L3W5) |
| |
| 3.A.3.24.3 | Functionally uncharacterized P-type ATPase family 24 (FUPA24) (1430aas) | δ-Proteobacteria | FUPA24c of Haliangium ochraceum (C1UT40) |
| |
| 3.A.3.24.4 | Functionally uncharacterized P-type ATPase family 24 (FUPA24) (1446aas) | γ-Proteobacteria | FUPA24d of Hahella chejuensis (ABC27339) |
| |
| 3.A.3.25.1 | Functionally uncharacterized P-type ATPase family 25 (FUPA25.1) (4 proteins from Actinomycetes; 645-776 aas). | Actinobacteria | FUPA25a of Streptomyces coelicolor (Q9RJ01) |
| |
| 3.A.3.25.2 | Functionally uncharacterized P-type ATPase family 25 (FUPA25.2) (3 proteins from α- and β-proteobacteria; 617-759 aas). These proteins show greatest similarity with established families 5&6. Family 25 members have 6 TMSs and lack TMSs A&B. Some fairly close homologues have 7 TMSs. | Proteobacteria | FUPA25b of Sinorhizobium meliloti (Q92Z60) |
| |
| 3.A.3.25.3 | Functionally uncharacterized P-type ATPase family 25 (FUPA25.3) (2 proteins from firmicutes; 601-623 aas; 7TMSs and an extra putative N-terminal TMS). | Firmicutes | FUPA25c of Enterococcus faecalis (Q830Z1) |
| |
| 3.A.3.26.1 | Functionally uncharacterized P-type ATPase family 26 (FUPA26) (3 proteins from Corynebacteria 841-976 aas) | Actinobacteria | FUPA26a of Corynebacterium diphtheriae (Q6NJJ6) |
| |
| 3.A.3.27.1 | Functionally uncharacterized P-type ATPase family 27 (FUPA27) (multiple proteins from α-, β- and γ- proteobacteria; 817-851aas)
| Proteobacteria | FUPA27a of Neisseria meningitidis (Q9JZI0) |
| |
| 3.A.3.27.2 | Functionally uncharacterized P-type ATPase family 27 (FUPA27), Lbi2 (2 proteins in Spirochetes)
| Spirochetes | FUPA27b of Leptospira biflexa (B0STR2) |
| |
| 3.A.3.27.3 | Functionally uncharacterized ε-proteobacteria P-type ATPase | ε-proteobacteria | FUPA27c of Nitratiruptor sp. SB155-2 (A6Q500) |
| |
| 3.A.3.28.1 | Functionally uncharacterized P-type ATPase family 28 (FUPA28) (2 proteins in γ-proteobacteria, 847-852 aas) | Proteobacteria | FUPA28a of Legionella pneumophila (Q5ZYY0) |
| |
| 3.A.3.29.1 | Functionally uncharacterized P-type ATPase family 29 (FUPA29) (1 protein from a δ-proteobacterium, 798 aas) | Proteobacteria | FUPA29a of Bdellovibrio bacteriovorus (Q6MK07) |
| |
| 3.A.3.29.2 | Functionally uncharacterized P-type ATPase family 29(FUPA29)(2 proteins from flavobacteria; 792-795)
| Bacteroidetes | FUPA29b of Flavobacterium johnsoniae (A5FGV9) |
| |
| 3.A.3.30.1 | Functionally uncharacterized P-type ATPase family 30 (FUPA30) (4 proteins from α-, β- and δ-proteobacteria; 825-896 aas)
| Proteobacteria | FUPA30a of Bdellovibrio bacteriovorus (Q6MPD9) |
| |
| 3.A.3.30.2 | Functionally uncharacterized P-type ATPase family 30 (FUPA30) (1 protein from Flavobacteria 838 aas) | Bacteroidetes | FUPA30b of Flavobacterium johnsoniae (A5FBE4) |
| |
| 3.A.3.30.3 | Functionally uncharacterized P-type ATPase family 30 (FUPA30), Lbi5 (1 protein in spirochetes) | Spirochetes | FUPA30c of Leptospira biflexa (B0SLF7) |
| |
| 3.A.3.30.4 | Functionally uncharacterized P-type ATPase family 30 (FUPA30) (1 ptotein from cyanobacteria; 867 aas).
| Cyanobacteria | FUPA30d of Anabaena variabilis (Q3M5P5) |
| |
| 3.A.3.31.1 | Functionally uncharacterized P-type ATPase family 31 (FUPA31) (3 proteins from γ-proteobacteria; 673-1068) (most closely related to FUPA32 homologues) (probably an active enzyme). | Proteobacteria | FUPA31a of Methylococcus capsulatus (Q606V3) |
| |
| 3.A.3.31.2 | Functionally uncharacterized P-type ATPase family 31 (FUPA31b) (probably a pseudogene). | Proteobacteria | FUPA31b of Methylococcus capsulatus (Q606U9) |
| |
| 3.A.3.32.1 | Functionally uncharacterized P-type ATPase family 32 (FUPA32) (multiple proteins from α-, β-, γ-, δ- and ε-proteobacteria (690-720 aas)
| Proteobacteria | FUPA32a of Azoarcus sp. EbN1 (Q5P8C0) |
| |
| 3.A.3.32.2 | Probable heavy metal cation-transporting P-type ATPase, FUPA32.2 (718aas) | Actinobacteria | FUPA32b of Mycobacterium bovis (P0A503) |
| |
| 3.A.3.32.3 | Functionally uncharacterized P-type ATPase family 32 (FUPA32) (many homologues in Firmicutes (704-730 aas))
| Firmicutes | FUPA32c of Clostridium bartiettii (A6NST6) |
| |
| 3.A.3.32.4 | Functionally uncharacterized P-type ATPase family 32 (FUPA32) (3 proteins from Fusobacteria) (735 aas) | Fusobacteria | FUPA32d of Fusobacterium nucleatum (Q8REB9) |
| |
| 3.A.3.32.5 | Functionally uncharacterized P-type ATPase family 32 (FUPA32) (699 aas) (1 protein in Spirochetes)
| Spirochetes | FUPA32e of Treponema denticola (Q73QH0) |
| |
| 3.A.3.32.6 | Functionally uncharacterized P-type ATPase family 32 (FUPA32) (2 proteins from Euryarchaeota)
| Euryarchaeota | FUPA32f of Methanobrevibacter smithii (A5UJX0) |
| |
| 3.A.3.32.7 | Functionally uncharacterized P-type ATPase family 32 (FUPA32) (several proteins from Verrucomicrobia)
| Verrucomicrobia | FUPA32g of Akkermansia muciniphila (B2UR24) |
| |
| 3.A.3.32.8 | Functionally uncharacterized P-type ATP family 32 (FUPA32) (several in cyanobacteria)
| Cyanobacteria | FUPA32h of Thermosynechococcus elongatus (Q8DL41) |
| |