Identification of three isozyme proteins of the catalytic subunit of the Na,K-ATPase in rat brain

Molecular genetic evidence indicates that there should be three different (Na+ + K+)-stimulated ATPase (Na,K-ATPase) alpha subunit isozymes in the brain where previously only two ("alpha" and "alpha(+)") were resolved as proteins. To detect and identify alpha 1, alpha 2, and alpha 3 isozymes, polypeptides made by cell-free translation (Schneider, J.W., Mercer, R.W., Gilmore-Hebert, M., Utset, M.F., Lai, C., Greene, A., and Benz, E.J., Jr. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 284-288) were analyzed by gel electrophoresis and proteolytic fingerprinting. Synthetic alpha 1 comigrated with tissue alpha 1, while alpha 2 and alpha 3 comigrated with the leading and trailing edges, respectively, of tissue "alpha(+)." Proteolytic fingerprints of newborn rat brain Na,K-ATPase labeled in vivo with L-[35S]methionine indicated the presence of alpha 1 and alpha 3, and a low level of alpha 2. Monoclonal antibodies were characterized by the electrophoretic mobility of their antigens and by their ability to recognize the Na,K-ATPases of kidney, brain, and skeletal muscle. The antibodies were used to assess isozyme expression in the brain. All three isozymes increased in abundance during development from the 18-day fetus to the adult. Small changes were seen in the relative level of expression of alpha 1 and alpha 3 at different developmental ages, while alpha 2 expression increased markedly between the neonate and adult. In adult brain, all three isozymes were found in all brain regions examined. We conclude that all three isozymes are expressed as proteins and that their expression and distribution must be under complex control. No single developmental age or macroscopic brain region provides an exclusive source of any of the isozymes.     

Fine specificity mapping and topography of an isozyme-specific epitope of the Na,K-ATPase catalytic subunit

An isozyme-specific domain of the catalytic subunit of the Na,K-ATPase has been identified using a monoclonal antibody, McK1. The antibody's specificity was confirmed by its ability to stain proteolytic fingerprints of the Na,K-ATPase. The antibody recognized the alpha I isozyme of the rat Na,K-ATPase, but not the alpha II or alpha III isozymes. It recognized native and sodium dodecyl sulfate-denatured Na,K-ATPase and specifically stained basolateral membranes of the renal tubule. It bound to rat alpha I with highest affinity, but also cross-reacted with mouse, monkey, and human alpha I. It did not cross-react with sheep, pig, chicken, Torpedo, or dog alpha I. Fine specificity mapping was used to deduce the most likely antibody binding sites, based on comparison of eight amino acid sequences from cDNA clones. Two potential binding sites were found at widely separated locations. Limited tryptic digestion of the native enzyme was then used to demonstrate that the binding site was close to the N-terminal end of the Na,K-ATPase. The binding site is predicted to include the following essential amino acid sequence: Asp-Lys-Lys-Ser-Lys-Lys in rat alpha I or Asp-Lys-Lys-Gly-Lys-Lys in human alpha I. The antibody was found to bind to opened, but not to sealed right-side-out vesicles isolated from the rat renal medulla, demonstrating that the N-terminal end of the Na,K-ATPase is exposed at the interior of the cell.     

Effects of tetradecyl sulfate on electrophoretic resolution of kidney Na,K-ATPase catalytic subunit isoforms

Inclusion of sodium tetradecyl sulfate in the Laemmli polyacrylamide gel electrophoresis system produces resolution of the kidney Na,K-ATPase catalytic subunit into a doublet and sharpens demarcation of catalytic subunit isoforms in NA,K-ATPase from brain.     

Distinct role of the N-terminal tail of the Na,K-ATPase catalytic subunit as a signal transducer

Mounting evidence suggests that the ion pump, Na,K-ATPase, can, in the presence of ouabain, act as a signal transducer. A prominent binding motif linking the Na,K-ATPase to intracellular signaling effectors has, however, not yet been identified. Here we report that the N-terminal tail of the Na,K-ATPase catalytic alpha-subunit (alphaNT-t) binds directly to the N terminus of the inositol 1,4,5-trisphosphate receptor. Three amino acid residues, LKK, conserved in most species and most alpha-isoforms, are essential for the binding to occur. In wild-type cells, low concentrations of ouabain trigger low frequency calcium oscillations that activate NF-kappaB and protect from apoptosis. All of these effects are suppressed in cells overexpressing a peptide corresponding to alphaNT-t but not in cells overexpressing a peptide corresponding to alphaNT-t deltaLKK. Thus we have identified a well conserved Na,K-ATPase motif that binds to the inositol 1,4,5-trisphosphate receptor and can trigger an anti-apoptotic calcium signal.     

Identification of two isoforms of the catalytic subunit of Na,K-ATPase in myocytes from adult rat heart

The present study demonstrates that two forms of the alpha catalytic subunit of the Na,K-ATPase are present in rat heart and originate from cardiomyocytes. They were resolved on sodium dodecyl sulfate-polyacrylamide gel electrophoresis after reduction and alkylation of the sulfhydryl groups. The two forms were identified on immunoblots using two specific antisera against either the alpha subunit from Bufo marinus kidney and the alpha and beta subunits from lamb kidney. Comparison of the two forms to the alkylated Na,K-ATPase from rat kidney (containing one catalytic subunit) and from rat brain (containing alpha and alpha + subunits) suggested that, in rat cardiac myocytes, the form with a fast migration rate (alpha F) corresponds to the alpha subunit of low ouabain affinity and the one with a slow migration rate (alpha S), to a subunit of high ouabain affinity. Thus, the existence of two isoforms of the catalytic subunit in cardiac myocytes accounts well for the biphasic ouabain inhibition of the Na,K-ATPase activity and for the biphasic inotropic responsiveness to cardiac glycosides of the rat heart.     

Regions of the catalytic alpha subunit of Na,K-ATPase important for functional interactions with FXYD 2

The gamma modulator (FXYD 2) is a member of the FXYD family of single transmembrane proteins that modulate the kinetic behavior of Na,K-ATPase. This study concerns the identification of regions in the alpha subunit that are important for its functional interaction with gamma. An important effect of gamma is to increase K+ antagonism of cytoplasmic Na+ activation apparent as an increase in KNa' at high [K+]. We show that although gamma associates with alpha1, alpha2, and alpha3 isoforms, it increases the KNa' of alpha1 and alpha3 but not alpha2. Accordingly, chimeras of alpha1 and alpha2 were used to identify regions of alpha critical for the increased KNa'. As with alpha1 and alpha2, all chimeras associate with gamma. Kinetic analysis of alpha2front/alpha1back chimeras indicate that the C-terminal (Lys907-Tyr1018) region of alpha1, which includes transmembrane (TM)9 close to gamma, is important for the increase in KNa'. However, similar experiments with alpha1front/alpha2back chimeras indicate a modulatory role of the loop between TMs 7 and 8. Thus, as long as the alpha1 L7/8 loop is present, replacement of TM9 of alpha1 with that of alpha2 does not abrogate the gamma effect on KNa'. In contrast, as long as TM9 is that of alpha1, replacement of L7/8 of alpha1 with that of alpha2 does not abolish the effect. It is suggested that structural association of the TM regions of alpha and FXYD 2 is not the sole determinant of this effect of FXYD on KNa' but is subject to long range modulation by the extramembranous L7/8 loop of alpha.     

Distinct regulatory effects of the Na,K-ATPase gamma subunit

The two variants of the gamma subunit of the rat renal sodium pump, gamma(a) and gamma(b), have similar effects on the Na,K-ATPase. Both increase the affinity for ATP due to a shift in the enzyme's E(1) <--> E(2) conformational equilibrium toward E(1). In addition, both increase K(+) antagonism of cytoplasmic Na(+) activation. To gain insight into the structural basis for these distinct effects, extramembranous N-terminal and C-terminal mutants of gamma were expressed in rat alpha1-transfected HeLa cells. At the N terminus, the variant-distinct region was deleted (gammaNDelta7) or replaced by alanine residues (gammaN7A). At the C terminus, four (gamma(a)CDelta4) or ten (gamma(a)CDelta10) residues were deleted. None of these mutations abrogates the K(+)/Na(+) antagonism as evidenced in a similar increase in K'(Na) seen at high (100 mm) K(+) concentration. In contrast, the C-terminal as well as N-terminal deletions (gammaNDelta7, gamma(a)CDelta4, and gamma(a)CDelta10) abolished the decrease in K'(ATP) seen with wild-type gamma(a) or gamma(b). It is concluded that different regions of the gamma chain mediate the distinct functional effects of gamma, and the effects can be long-range. In the transmembrane region, the impact of G41R replacement was analyzed since this mutation is associated with autosomal dominant renal Mg(2+)-wasting in man (Meij, I. C., Koenderink, J. B., van Bokhoven, H., Assink, K. F. H., Groenestege, W. T., de Pont, J. J. H. H. M., Bindels, R. J. M., Monnens, L. A. H., Van den Heuvel, L. P. W. J., and Knoers, N. V. A. M. (2000) Nat. Genet. 26, 265-266). The results show that Gly-41 --> Arg prevents trafficking of gamma but not alphabeta pumps to the cell surface and abrogates functional effects of gamma on alphabeta pumps. These findings underscore a potentially important role of gamma in affecting solute transport, in this instance Mg(2+) reabsorption, consequent to its primary effect on the sodium pump.     

Expression of an ouabain-resistant Na,K-ATPase in CV-1 cells after transfection with a cDNA encoding the rat Na,K-ATPase alpha 1 subunit

We have used a gene transfer system to investigate the relationship between expression of the rat Na,K-ATPase alpha 1 subunit gene and ouabain-resistant Na,K-ATPase activity. A cDNA clone encoding the entire rat Na,K-ATPase alpha 1 subunit was inserted into the expression vector pSV2neo. This construct (pSV2 alpha 1) conferred resistance to 100 microM ouabain to ouabain-sensitive CV-1 cells. Hybridization analysis of transfected clones revealed the presence of both rat-specific and endogenous Na,K-ATPase alpha 1 subunit DNA and mRNA sequences. A single form of highly ouabain-sensitive 86Rb+ uptake was detected in CV-1 cells, whereas two distinct classes of ouabain-inhibitable uptake were observed in transfectants. One class exhibited the high ouabain sensitivity of the endogenous monkey Na,K-ATPase, while the second class showed the reduced ouabain sensitivity characteristic of the rodent renal Na,K-ATPase. Examination of the ouabain-sensitive, sodium-dependent ATPase activity of the transfectants also revealed a low affinity component of Na,K-ATPase activity characteristic of the rodent kidney enzyme. These results suggest that expression of the rat alpha 1 subunit gene is directly responsible for ouabain-resistant Na,K-ATPase activity in transfected CV-1 cells.     

Expression and functional role of the gamma subunit of the Na, K-ATPase in mammalian cells

The functional role of the gamma subunit of the Na,K-ATPase was studied using rat gamma cDNA-transfected HEK-293 cells and an antiserum (gammaC33) specific for gamma. Although the sequence for gamma was verified and shown to be larger (7237 Da) than first reported, it still comprises a single initiator methionine despite the expression of a gammaC33-reactive doublet on immunoblots. Kinetic analysis of the enzyme of transfected compared with control cells and of gammaC33-treated kidney pumps shows that gamma regulates the apparent affinity for ATP. Thus, gamma-transfected cells have a decreased K'ATP as shown in measurements of (i) K'ATP of Na,K-ATPase activity and (ii) K+ inhibition of Na-ATPase at 1 microM ATP. Consistent with the behavior of gamma-transfected cells, gammaC33 pretreatment increases K'ATP of the kidney enzyme and K+ inhibition (1 microM ATP) of both kidney and gamma-transfected cells. These results are consistent with previous findings that an antiserum raised against the pig gamma subunit stabilizes the E2(K) form of the enzyme (Therien, A. G., Goldshleger, R., Karlish, S. J., and Blostein, R. (1997) J. Biol. Chem. 272, 32628-32634). Overall, our data demonstrate that gamma is a tissue (kidney)-specific regulator of the Na,K-ATPase that can increase the apparent affinity of the enzyme for ATP in a manner that is reversible by anti-gamma antiserum.     

Development and regional distribution of two molecular forms of the catalytic subunit of the Na,K-ATPase in rat brain

Two molecular forms of the catalytic subunit of the Na,K-ATPase can be isolated from brain (1). Only the α form was detected in rat embryo brain at 13 days of gestation (E13). The α(+) form, which is characteristic of myelinated axons, appeared at E15 before myelination begins. Hence its expression is not dependent on prior myelination. Axonal transport of the α(+) form was demonstrated in 4 day-old rats. The ratio of α(+):α was 1:1 in adult retina, cortex and cerebellum and 10:1 in brain stem. Although α(+) is characteristic of myelinated axons, this regional difference was present not only in enzyme extracted from crude microsomes, that contain myelinated axon fragments, but also in enzyme from isolated synaptosomes. Hence, the α(+):α ratio is an inherent characteristic of the neuron and does not depend on regional differences in myelination.     

New evidence for ATP binding induced catalytic subunit interactions in pig kidney Na/K-ATPase

Pig kidney Na/K-ATPase preparations showed a positive cooperative effect for pNPP in Na-pNPPase activity. Measurements of the Na-pNPPase activity, Na-ATPase activity and the accumulation of phosphoenzyme (EP) under conditions of pNPP saturation showed several different ATP affinities. The presence of pNPP reduced both the maximum amount of EP and Na-ATPase activity to half showing a value of 4 and a 3,700-fold reduced ATP affinity for EP formation, and a 7 and 1,300-fold reduced affinity for Na-ATPase activity. The presence of low concentrations of ATP in the phosphorylation induced a 2-fold enhancement in Na-pNPPase activity despite a reduction in available pNPP sites. However, higher concentrations of ATP inhibited the Na-pNPPase activity and a much higher concentration of ATP increased both the phosphorylation and Na-ATPase activity to the maximum levels. The maximum Na-pNPPase activity was 1.7 and 3.4-fold higher without and with ATP, respectively, than the maximum Na-ATPase activity. These data and the pNPP dependent reduction in both Na-ATPase activity and the amount of enzyme bound ATP provide new evidence to show that ATP, pNPP and ATP with pNPP, respectively, induce different subunit interactions resulting a difference in the maximum Na(+)-dependent catalytic activity in tetraprotomeric Na/K-ATPase.     

Structure of the alpha 1 subunit of horse Na,K-ATPase gene

Genomic DNA for Na,K-ATPase alpha 1 subunit was obtained from libraries of horse kidney genomic DNA in Charon 4A and in EMBL3 bacteriophages by screening with the full sized cDNA probe of the alpha 1 subunit of rat Na,K-ATPase as probe. The gene spans 30 kb and consists of 23 exons and 22 intervening sequences. Intron-exon boundaries were analyzed. The protein-coding nucleotide sequence encodes 1016 amino acids with an Mr of 112,264. The putative amino acid sequence of horse alpha 1 is 96-97% homologous to those of other mammalian species.     

Maturation of the catalytic alpha-subunit of Na,K-ATPase during intracellular transport

The protease sensitivity of the catalytic alpha-subunit of Na,K-ATPase during intracellular transport along the exocytic pathway has been investigated in two amphibian epithelial cell lines. Controlled trypsinolysis followed by immunoprecipitation of cell homogenates or microsomal fractions from [35S]methionine pulse-chased A6 kidney cells revealed distinct cleavage patterns by SDS-PAGE. Shortly after synthesis (7-min pulse), the 98-kD alpha-subunit is fully sensitive to trypsin digestion and is cleaved into a 35-kD membrane-bound and a 27.5- kD soluble peptide. With a 15-min pulse, 10% of the newly synthesized polypeptide becomes resistant to trypsin digestion. With longer chase time, the proportion of protease-resistant alpha-subunit further increases. Concomitantly, the alpha-subunit acquires the ability to undergo cation-dependent conformational transitions, as reflected by distinct tryptic digest patterns in the presence of Na+ or K+. Similar results were obtained in TBM cells, a toad bladder cell line. Our data indicate that the catalytic subunit of Na,K-ATPase is structurally rearranged during intracellular transport from its site of synthesis to its site of action at the cell surface, a modification which might mark the functional maturation of the enzyme.     

Expression of Na,K-ATPase alpha subunit isoforms in the human ciliary body and cultured ciliary epithelial cells

We have analyzed the expression of Na,K-ATPase alpha subunit isoforms in the transporting ciliary processes of the human eye and in cultured cells derived from non-pigmented (NPE) and pigmented (PE) ciliary epithelium. Northern hybridization analysis shows that the mRNAs encoding all the three distinct forms of Na,K-ATPase alpha subunit [alpha 1, alpha 2, and alpha 3] are expressed in the human ciliary processes in vivo. Immunohistochemical analysis using antibodies specific for each of the three alpha subunit isoforms confirms that these polypeptides are present in the microsomal fraction from the human ciliary processes. The monoclonal antibody McB2, which is specific to the Na,K-ATPase alpha 2 subunit isoform, has been found to decorate specifically the basolateral membrane domains of NPE cells but not of the PE cells, suggesting its expression in vivo only in the ocular NPE ciliary epithelium. However, cultured cells derived from the NPE and PE layers exhibit a different pattern of expression of mRNA and protein for the Na,K-ATPase alpha subunit isoforms when compared to the tissue. Both the NPE and PE cells express alpha 1 and alpha 3 mRNA and polypeptide, whereas alpha 2 mRNA and polypeptide are undetectable in these cells. The established cell lines derived from the NPE layer express comparable levels of the alpha 1 and alpha 3 isoforms of Na,K-ATPase as detected in the primary culture. However, the established NPE cell lines are also distinguishable from the normal PE cells when analyzed by Western blot analysis with A x 2 antibodies. The results presented here clearly show that the NPE and PE cells in the ciliary body have a distinct expression of Na,K-ATPase alpha subunit isoforms as compared to cultured cells.     

The isoform-specific region of the Na,K-ATPase catalytic subunit: role in enzyme kinetics and regulation by protein kinase C

Comparisons of the primary structures of the Na,K-ATPase alpha-isoforms reveal the existence of regions of structural divergence, suggesting that they are involved in unique functions. One of these regions is the isoform-specific region (ISR), located near the ATP binding site in the major cytoplasmic loop. To evaluate its importance, we constructed mutants of the rodent wild-type alpha1 and alpha3 isoforms in which the ISR was replaced with irrelevant sequences, i.e., the analogous region from the rat gastric H,K-ATPase catalytic subunit or a region from the human c-myc oncogene. Opossum kidney (OK) cells were transfected with wild-type rat alpha1, alpha3, or their corresponding chimeras and selected in ouabain. Introduction of either mutant produced ouabain-resistant colonies, consistent with functional expression of the chimeric protein and indicating that the ISR is not essential for overall Na,K-ATPase function. The introduced chimeras were then characterized enzymatically by measuring the relative rate of K(+) and Li(+) deocclusions. Results showed that exchanges of both alpha1 and alpha3 ISRs significantly modified the sensitivity for the enzyme to either K(+) or Li(+). Subsequent treatment of the cells with phorbol esters revealed an altered Na,K-ATPase transport in response to protein kinase C activation for the alpha1 chimeras. No changes were observed for the alpha3 isoform, suggesting that it is not sensitive to PKC regulation. These results demonstrated that the ISR plays an important role in ion deocclusion and in the response to PKC (only for the alpha1 isoform).     

The gamma subunit modulates Na(+) and K(+) affinity of the renal Na,K-ATPase

The Na(+),K(+)-ATPase catalyzes the active transport of ions. It has two necessary subunits, alpha and beta, but in kidney it is also associated with a 7.4-kDa protein, the gamma subunit. Stable transfection was used to determine the effect of gamma on Na, K-ATPase properties. When isolated from either kidney or transfected cells, alphabetagamma had lower affinities for both Na(+) and K(+) than alphabeta. A post-translational modification of gamma selectively eliminated the effect on Na(+) affinity, suggesting three configurations (alphabeta, alphabetagamma, and alphabetagamma*) conferring different stable properties to Na, K-ATPase. In the nephron, segment-specific differences in Na(+) affinity have been reported that cannot be explained by the known alpha and beta subunit isoforms of Na,K-ATPase. Immunofluorescence was used to detect gamma in rat renal cortex. Cortical ascending limb and some cortical collecting tubules lacked gamma, correlating with higher Na(+) affinities in those segments reported in the literature. Selective expression in different segments of the nephron is consistent with a modulatory role for the gamma subunit in renal physiology.