Protective effect of Na+ and K+ against inactivation of (Na+ + K+)-ATPase by high concentrations of 2-mercaptoethanol at high temperatures

β subunit affects Na+ and K+ affinities of Na+/K+-ATPase: Na+ and K+ affinities of a hybrid Na+/K+-ATPase composed of insect α and mammalian β subunits

The affinity for K⁺ of silkworm Na⁺/K⁺-ATPase, which is composed of α and β subunits, is remarkably lower than that of mammalian Na⁺/K⁺-ATPase, with a slightly higher affinity for Na⁺. Because the α subunit had more than 70% identity to the mammalian α subunit in the amino acid sequence, whereas the β subunit, a glycosylated protein, had less than 30% identity to the mammalian β subunit, it was suggested that the β subunit was involved in the affinities for Na⁺ and K⁺ of Na⁺/K⁺-ATPase. To confirm this hypothesis, we examined whether replacing the silkworm β subunit with the mammalian β subunit affected the affinities for Na⁺ and K⁺ of Na⁺/K⁺-ATPase. Cloned silkworm α and cloned rat β1 were co-expressed in BM-N cells, a cultured silkworm ovary-derived cell lacking endogenous Na⁺/K⁺-ATPase, to construct a hybrid Na⁺/K⁺-ATPase, in which the silkworm β subunit was replaced with the rat β1 subunit. The hybrid Na⁺/K⁺-ATPase increased the affinity for K⁺ by 4.1-fold and for Na⁺ by 0.65-fold compared to the wild-type one. Deglycosylation of the silkworm β subunit did not affect the K⁺ affinity. These results support the involvement of the β subunit in the Na⁺ and K⁺ affinities of Na⁺/K⁺-ATPase.

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Silkworm Na⁺/K⁺-ATPase has much lower affinity for K⁺ than mammalian Na⁺/K⁺-ATPase with a slightly higher affinity for Na⁺.

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Silkworm Na⁺/K⁺-ATPase β subunit has less than 30% identity to the mammalian β subunit in the amino acid sequence.

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Replacement of the silkworm β with the rat β increased K⁺ affinity and decreased Na⁺ affinity of Na⁺/K⁺-ATPase.

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β subunit is involved in Na⁺ and K⁺ affinities of Na⁺/K⁺-ATPase.

Inner workings and biological impact of phospholipid flippases

The plasma membrane, trans-Golgi network and endosomal system of eukaryotic cells are populated with flippases that hydrolyze ATP to help establish asymmetric phospholipid distributions across the bilayer. Upholding phospholipid asymmetry is vital to a host of cellular processes, including membrane homeostasis, vesicle biogenesis, cell signaling, morphogenesis and migration. Consequently, defining the identity of flippases and their biological impact has been the subject of intense investigations. Recent work has revealed a remarkable degree of kinship between flippases and cation pumps. In this Commentary, we review emerging insights into how flippases work, how their activity is controlled according to cellular demands, and how disrupting flippase activity causes system failure of membrane function, culminating in membrane trafficking defects, aberrant signaling and disease.

Cdc50p plays a vital role in the ATPase reaction cycle of the putative aminophospholipid transporter Drs2p

Members of the P(4) subfamily of P-type ATPases are believed to catalyze transport of phospholipids across cellular bilayers. However, most P-type ATPases pump small cations or metal ions, and atomic structures revealed a transport mechanism that is conserved throughout the family. Hence, a challenging problem is to understand how this mechanism is adapted in P(4)-ATPases to flip phospholipids. P(4)-ATPases form heteromeric complexes with Cdc50 proteins. The primary role of these additional polypeptides is unknown. Here, we show that the affinity of yeast P(4)-ATPase Drs2p for its Cdc50-binding partner fluctuates during the transport cycle, with the strongest interaction occurring at a point where the enzyme is loaded with phospholipid ligand. We also find that specific interactions with Cdc50p are required to render the ATPase competent for phosphorylation at the catalytically important aspartate residue. Our data indicate that Cdc50 proteins are integral components of the P(4)-ATPase transport machinery. Thus, acquisition of these subunits may have been a crucial step in the evolution of flippases from a family of cation pumps.

E2P state stabilization by the N-terminal tail of the H,K-ATPase beta-subunit is critical for efficient proton pumping under in vivo conditions

The catalytic alpha-subunits of Na,K- and H,K-ATPase require an accessory beta-subunit for proper folding, maturation, and plasma membrane delivery but also for cation transport. To investigate the functional significance of the beta-N terminus of the gastric H,K-ATPase in vivo, several N-terminally truncated beta-variants were expressed in Xenopus oocytes, together with the S806C alpha-subunit variant. Upon labeling with the reporter fluorophore tetramethylrho da mine-6-maleimide, this construct can be used to determine the voltage-dependent distribution between E(1)P/E(2)P states. Whereas the E(1)P/E(2)P conformational equilibrium was unaffected for the shorter N-terminal deletions betaDelta4 and betaDelta8, we observed significant shifts toward E(1)P for the two larger deletions betaDelta13 and betaDelta29. Moreover, the reduced DeltaF/F ratios of betaDelta13 and betaDelta29 indicated an increased reverse reaction via E(2)P --> E(1)P + ADP --> E(1) + ATP, because cell surface expression was completely unaffected. This interpretation is supported by the reduced sensitivity of the mutants toward the E(2)P-specific inhibitor SCH28080, which becomes especially apparent at high concentrations (100 microm). Despite unaltered apparent Rb(+) affinities, the maximal Rb(+) uptake of these mutants was also significantly lowered. Considering the two putative interaction sites between the beta-N terminus and alpha-subunit revealed by the recent cryo-EM structure, the N-terminal tail of the H,K-ATPase beta-subunit may stabilize the pump in the E(2)P conformation, thereby increasing the efficiency of proton release against the million-fold proton gradient of the stomach lumen. Finally, we demonstrate that a similar truncation of the beta-N terminus of the closely related Na,K-ATPase does not affect the E(1)P/E(2)P distribution or pump activity, indicating that the E(2)P-stabilizing effect by the beta-N terminus is apparently a unique property of the H,K-ATPase.

Mechanism and significance of P4 ATPase-catalyzed lipid transport: lessons from a Na+/K+-pump

Members of the P(4) subfamily of P-type ATPases are believed to catalyze phospholipid transport across membrane bilayers, a process influencing a host of cellular functions. Atomic structures and functional analysis of P-type ATPases that pump small cations and metal ions revealed a transport mechanism that appears to be conserved throughout the family. A challenging problem is to understand how this mechanism is adapted in P(4) ATPases to flip phospholipids. P(4) ATPases form oligomeric complexes with members of the CDC50 protein family. While formation of these complexes is required for P(4) ATPase export from the endoplasmic reticulum, little is known about the functional role of the CDC50 subunits. The Na(+)/K(+)-ATPase and closely-related H(+)/K(+)-ATPase are the only other P-type pumps that are oligomeric, comprising mandatory beta-subunits that are strikingly reminiscent of CDC50 proteins. Besides serving a role in the functional maturation of the catalytic alpha-subunit, the beta-subunit also contributes specifically to intrinsic transport properties of the Na(+)/K(+) pump. As beta-subunits and CDC50 proteins likely adopted similar structures to accomplish analogous tasks, current knowledge of the Na(+)/K(+)-ATPase provides a useful guide for understanding the inner workings of the P(4) ATPase class of lipid pumps.

The thermal unfolding and domain structure of Na+/K+-exchanging ATPase. A scanning calorimetry study

The thermal unfolding and domain structure of Na+/K+-ATPase from pig kidney were studied by high-sensitivity differential scanning calorimetry (HS-DSC). The excess heat capacity function of Na+/K+-ATPase displays the unfolding of three cooperative domains with midpoint transition temperatures (Td) of 320.6, 327.5, 331.5 K, respectively. The domain with Td = 327.5 K was identified as corresponding to the beta subunit, while two other domains belong to the alpha subunit. The thermal unfolding of the low-temperature domain leads to large changes in the amplitude of the short-circuit current, but has no effect on the ATP hydrolysing activity. Furthermore, dithiothreitol or 2-mercaptoethanol treatment causes destruction of this domain, accompanied by significant disruption of the ion transporting function and a 25% loss of ATPase activity. The observed total unfolding enthalpy of the protein is rather low (approximately 12 J.g-1), suggesting that thermal denaturation of Na+/K+-ATPase does not lead to complete unfolding of the entire molecule. Presumably, transmembrane segments retain most of their secondary structure upon thermal denaturation. The binding of physiological ligands results in a pronounced increase in the conformational stability of both enzyme subunits.

Role of beta-subunit domains in the assembly, stable expression, intracellular routing, and functional properties of Na,K-ATPase

The beta-subunit of Na,K-ATPase (betaNK) interacts with the catalytic alpha-subunit (alphaNK) in the ectodomain, the transmembrane, and the cytoplasmic domain. The functional significance of these different interactions was studied by expressing alphaNK in Xenopus oocytes along with N-terminally modified betaNK or with chimeric betaNK/betaH,K-ATPase (betaHK). Complete truncation of the betaNK N terminus allows for cell surface-expressed, functional Na,K-pumps that exhibit, however, reduced apparent K+ and Na+ affinities as assessed by electrophysiological measurements. A mutational analysis suggests that these functional effects are not related to a direct interaction of the beta N terminus with the alphaNK but rather that N-terminal truncation induces a conformational change in another functionally relevant beta domain. Comparison of the functional properties of alphaNK.betaNK, alphaNK.betaHK, or alphaNK. betaNK/betaHK complexes shows that the effect of the betaNK on K+ binding is mainly mediated by its ectodomain. Finally, betaHK/NK containing the transmembrane domain of betaHK produces stable but endoplasmic reticulum-retained alphaNK.beta complexes, while alphaNK/betaHK complexes can leave the ER but exhibit reduced ouabain binding capacity and transport function. Thus, interactions of both the transmembrane and the ectodomain of betaNK with alphaNK are necessary to form correctly folded Na,K-ATPase complexes that can be targeted to the plasma membrane and/or become functionally competent. Furthermore, the beta N terminus plays a role in the beta-subunit's folding necessary for correct interactions with the alpha-subunit.

Mechanism of depression in cardiac sarcolemmal Na+-K+-ATPase by hypochlorous acid

Oxidative stress during pathological conditions such as ischemia-reperfusion is known to promote the formation of hypochlorous acid (HOCl) in the heart and to result in depression of cardiac sarcolemmal (SL) Na+-K+-ATPase activity. In this study, we examined the direct effects of HOCl on SL Na+-K+-ATPase from porcine heart. HOCl decreased SL Na+-K+-ATPase activity in a concentration- and time-dependent manner. Characterization of Na+-K+-ATPase activity in the presence of different concentrations of MgATP revealed a decrease in the maximal velocity (Vmax) value, without a change in affinity for MgATP on treatment of SL membranes with 0.1 mM HOCl. The Vmax value of Na+-K+-ATPase, when determined in the presence of different concentrations of Na+, was also decreased, but affinity for Na+ was increased when treated with HOCl. Formation of acylphosphate by SL Na+-K+-ATPase was not affected by HOCl. Scatchard plot analysis of [3H]ouabain binding data indicated no significant change in the affinity or maximum binding capacity value for ouabain binding following treatment of SL membranes with HOCl. Western blot analysis of Na+-K+-ATPase subunits in HOCl-treated SL membranes showed a decrease (34 +/- 9% of control) in the beta1-subunit without any change in the alpha1- or alpha2-subunits. These data suggest that the HOCl-induced decrease in SL Na+-K+-ATPase activity may be due to a depression in the beta1-subunit of the enzyme.

Role of glycosylation and disulfide bond formation in the beta subunit in the folding and functional expression of Na,K-ATPase

Initial folding is a prerequisite for subunit assembly in oligomeric proteins. In this study, we have compared the role of co-translational modifications in the acquisition of an assembly-competent conformation of the beta subunit, the assembly of which is required for the structural and functional maturation of the catalytic Na,K-ATPase alpha subunit. Cysteine or asparagine residues implicated in disulfide bond formation or N-glycosylation, respectively, in the Xenopus beta1 subunit were eliminated by site-directed mutagenesis, and the assembly efficiency of the mutants and the functional expression of Na+,K+ pumps were studied after expression in Xenopus oocytes. Our results show that lack of each one of the two most C-terminal disulfide bonds indeed permits short term but completely abolishes long term assembly of the beta subunit. On the other hand, lack of the most N-terminal disulfide bonds allows the expression of a small number of functional Na+,K+ pumps at the cell surface. Elimination of all three but not of one or two glycosylation sites produces beta subunits that remain stably expressed in the endoplasmic reticulum, in association with binding protein but not as irreversible aggregates. The assembly efficiency of nonglycosylated beta subunits is decreased but a reduced number of functional Na+,K+ pumps is expressed at the cell surface. The lack of sugars does not influence the apparent K+ or ouabain affinity of the Na+,K+ pumps. Thus, these data show that disulfide bond formation and N-glycosylation may play important but qualitatively distinct roles in the initial folding of oligomeric protein subunits. Moreover, the results suggest that an endoplasmic reticulum degradation pathway exists, which is glycosylation-dependent.

Intersubunit and intrasubunit contact regions of Na+/K(+)-ATPase revealed by controlled proteolysis and chemical cross-linking

To identify interfaces of alpha- and beta-subunits of Na+/K(+)-ATPase, and contact points between different regions of the same alpha-subunit, purified kidney enzyme preparations whose alpha-subunits were subjected to controlled proteolysis in different ways were solubilized with digitonin to disrupt intersubunit alpha,alpha-interactions, and oxidatively cross-linked. The following disulfide cross-linked products were identified by gel electrophoresis, staining with specific antibodies, and N-terminal analysis. 1) In the enzyme that was partially cleaved at Arg438-Ala439, the cross-linked products were an alpha,beta-dimer, a dimer of N-terminal and C-terminal alpha fragments, and a trimer of beta and the two alpha fragments. 2) From an extensively digested enzyme that contained the 22-kDa C-terminal and several smaller fragments of alpha, two cross-linked products were obtained. One was a dimer of the 22-kDa C-terminal peptide and an 11-kDa N-terminal peptide containing the first two intramembrane helices of alpha (H1-H2). The other was a trimer of beta, the 11-kDa, and the 22-kDa peptides. 3) The cross-linked products of a preparation partially cleaved at Leu266-Ala267 were an alpha,beta-dimer and a dimer of beta and the 83-kDa C-terminal fragment. Assuming the most likely 10-span model of alpha, these findings indicate that (a) the single intramembrane helix of beta is in contact with portions of H8-H10 intramembrane helices of alpha; and (b) there is close contact between N-terminal H1-H2 and C-terminal H8-H10 segments of alpha; with the most probable interacting helices being the H1,H10-pair and the H2,H8-pair.

Topology of the Na,K-ATPase. Evidence for externalization of a labile transmembrane structure during heating

The topological organization of the Na,K-ATPase alpha subunit is controversial. Detection of extracellular proteolytic cleavage sites would help define the topology, and so attempts were made to find conditions and proteases that would permit digestion of Na,K-ATPase in sealed right-side-out vesicles from renal medulla. The beta subunit is predominantly extracellular and could mask the surface of the alpha subunit. Most of the tested proteases cleaved beta, and some digested it extensively. However, without further disruption of structure, there was still no digestion of the alpha subunit. Reduction (at 50 degrees C) of disulfide bonds that might stabilize the beta subunit fragments, or heating alone at 55 degrees C, permitted tryptic digestion of alpha at a site close to the C terminus, while simultaneously increasing digestion of beta. A 90-kDa N-terminal fragment of alpha was recovered, but the C-terminal fragment was further digested. Heating and reduction resulted in the extracellular exposure of a protein kinase A phosphorylation site, Ser-938, and the C terminus, both of which have been proposed to be located on the intracellular surface. At the same time, access to a distant protein kinase C phosphorylation site was not increased. The data suggest that the harsh treatment simultaneously resulted in alteration of the beta subunit and the extrusion of a segment of alpha that normally spans the membrane, without causing complete denaturation or opening the sealed vesicles. Preincubation with Rb+ was protective, consistent with prior evidence that it stabilizes the protein segments in the C-terminal third of alpha. We conclude that this portion of the alpha subunit contains a transmembrane structure with unique lability to heating.

Identification of antigenic sites on the Na+/K(+)-ATPase beta-subunit: their sequences and the effects of thiol reduction upon their structure

In contrast to the catalytic (alpha) subunit of the Na+/K(+)-ATPase holoenzyme, the glycoprotein (beta) subunit has proven to be a poor antigen for monoclonal antibody (Mab) production. However, in this work six Mabs directed against the beta-subunit of the lamb kidney holoenzyme have been isolated. These Mabs all recognize the holoenzyme, but their 'in solution' binding affinities for deglycosylated enzyme or isolated beta are generally at least 10-fold higher. Species specificity mapping, antibody patterns of binding to beta-fragments and competition binding studies indicated that there were only three distinct epitopes, with two antibodies binding in the NH2-terminal half (epitopes I and II) and 4 Mabs binding at the same or overlapping site (III) in the -COOH terminal half of beta. DNA sequence analysis of isolated collections of bacteriophage M13 that contain a 15 amino-acid 'epitope library' insert in the pIII protein, which enables them to bind to the antibodies, revealed the residues KYRDS (amino acids 111-115) and LETYP (amino acids 197-201) to be the deduced sequences for the epitopes of Mabs M19-P7-E5 (II) and M17-P5-F11 (III), respectively. The epitope I site was not, however, identified. Further studies showed that antibody binding to these three determinant sites had no affect on the Na+/K(+)-ATPase and K(+)-stimulated p-nitrophenylphosphatase (pNPPase) activities of either holoenzyme or deglycosylated enzyme, nor any affect on the cation- (Na+, K+ or Mg2+) and ouabain-induced conformational changes monitored with FITC-labeled deglycosylated enzyme. Interestingly, anti-beta Mab access to the three epitopes was increased following beta-mercaptoethanol inactivation of the holoenzyme, but this thiol reduction abolished the binding of two conformation-sensitive anti-alpha Mabs to the enzyme. These results are consistent with the previous suggestion of Kirley ((1990) J. Biol. Chem. 265, 4227-4232) that the beta-disulfide linkages not only maintain beta-structure but they are critical for maintaining alpha-conformation and holoenzyme activity.

Expression of functional (Na+ + K+)-ATPase from cloned cDNAs

Functional (Na+ + K+)-ATPase is formed in Xenopus oocytes injected with alpha- and beta-subunit-specific mRNAs derived from cloned Torpedo californica cDNAs. Both the mRNAs are required for the expression of functional (Na+ + K+)-ATPase.

Detailed structural analysis of exposed domains of membrane-bound Na+,K+-ATPase. A model of transmembrane arrangement

Exposed regions of the alpha- and beta-subunits of membrane-bound Na+,K+-ATPase were in turn hydrolyzed with trypsin. Resistance of the beta-subunit to proteolysis was shown to be due mainly to the presence of disulfide bridge(s) in the molecule. A model for the spatial organisation of the enzyme in the membrane was proposed on the basis of detailed structural analysis of extramembrane regions of both subunits.

Structure of the extra-membranous domain of the beta-subunit of (Na,K)-ATPase revealed by the sequences of its tryptic peptides

Membrane bound dog kidney (Na,K)-ATPase was digested with trypsin. The peptides that were recovered in the supernatant were purified and sequenced. By comparing these results with the sequence of alpha- and human beta-subunits, the location of each of the peptides could be allotted. Both accessibility to trypsin and the facility of release into the water phase indicated that these peptides were derived from the exposed surface of the intact enzyme. The sequence, GXGXXG, reported in the Torpedo californica beta-subunit [(1986) FEBS Lett. 196, 315-319] was likely a mere coincidence with the sequence of the dinucleotide-binding site, since the last glycine was replaced by proline in the sequence of the dog beta-subunit. A disulfide bridge was found within a peptide derived from the beta-subunit. A possible model for the beta-subunit structure is proposed.