Sodium transport defect of ouabain-resistant renal Na,K-ATPase

The murine renal Na,K-ATPase is resistant to cardiac glycosides. It is not yet known however whether altered active transport is associated with the drug-resistance. To investigate this problem Na,K-ATPases were purified from the outer medulla of both rat and rabbit kidneys and reconstituted identically into liposomes. The Na-stimulation of the Na,K-ATPase activity before reconstitution and of the Na-transport after reconstitution was measured. A Na-defect inherent in the ouabain-resistant rat Na,K-ATPase was discovered indicating a link between the cardiac glycoside sensitivity and the Na-transport.     

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.     

Antisera specific for the alpha 1, alpha 2, alpha 3, and beta subunits of the Na,K-ATPase: differential expression of alpha and beta subunits in rat tissue membranes

We have developed a panel of antibodies specific for the alpha 1, alpha 2, alpha 3, and beta subunits of the rat Na,K-ATPase. TrpE-alpha subunit isoform fusion proteins were used to generate three antisera, each of which reacted specifically with a distinct alpha subunit isotype. Western blot analysis of rat tissue microsomes revealed that alpha 1 subunits were expressed in all tissues while alpha 2 subunits were expressed in brain, heart, and lung. The alpha 3 subunit, a protein whose existence had been inferred from cDNA cloning, was expressed primarily in brain and copurified with ouabain-inhibitable Na,K-ATPase activity. An antiserum specific for the rat Na,K-ATPase beta subunit was generated from a TrpE-beta subunit fusion protein. Western blot analysis showed that beta subunits were present in kidney, brain, and heart. However, no beta subunits were detected in liver, lung, spleen, thymus, or lactating mammary gland. The distinct tissue distributions of alpha and beta subunits suggest that different members of the Na,K-ATPase family may have specialized functions.     

The alpha and beta subunits of lamb kidney Na,K-ATPase are both glycoproteins

We have determined the carbohydrate compositions of the protein components of lamb kidney Na,K-ATPase. The α subunit contains a total of about 16 monosaccharide residues per mol of protein, while the β subunit contains about 36 residues per mol. The γ protein, a proteolipid associated with the Na,K-ATPase, contains only traces of carbohydrate. A comparison of our results with those of others shows considerable variability in the carbohydrate compositions of α and β subunits from different species.     

Co-localization and polarized distribution of Na,K-ATPase alpha 3 and beta 2 subunits in photoreceptor cells.

Na,K-ATPase plays a central role in the visual sensitivity of photoreceptors by driving the dark current of vision. The alpha 3 and beta 2 isoforms of Na,K-ATPase were previously shown to be the major alpha and beta subunit mRNAs expressed in photoreceptors. Here we compared the distribution of beta-subunits of the enzyme in the retina and kidney, using electron microscopic immunocytochemistry with specific antibodies against alpha 3, beta 1, and beta 2 isoforms as well as with an antibody (Ax2) that binds to alpha 2 and/or alpha 3 isoforms. Both the alpha 3 and beta 2 isoforms were localized to photoreceptor inner segments at highest labeling density between the base of the connecting cilium and the outer limiting membrane (OLM). Quantitative analysis of Ax2 antibody binding to alpha 3 revealed a significant decrease in labeling density below the OLM and above the base of the connecting cilium. Although the beta 2-subunit has been reported to have adhesive functions in glial cells in cerebellum, we detected beta 2 in the photoreceptor, a cell of neural origin, but not in the Mueller cell, the glial cell of the retina. Moreover, anti-beta 2 antibodies bound maximally to portions of photoreceptor cells not involved in cell-cell contact.     

Site of synthesis of the alpha and beta subunits of the Na,K-ATPase in brine shrimp nauplii

Developing nauplii (embryos) of the brine shrimp Artemia salina are an excellent model system for studying the biogenesis of the sodium- and potassium-activated adenosine triphosphatase (Na,K-ATPase). The nauplii exhibit a burst of Na,K-ATPase synthesis between 6 and 32 h of development (Peterson, G. L., Churchill, L., Fisher, J. A., and Hokin, L. E. (1982) J. Exp. Zool. 221, 295-308). We have now determined the sites of synthesis of the alpha and beta subunits of the Na,K-ATPase in developing A. salina nauplii. Membrane-bound and free polysomes were isolated from nauplii, and RNA was extracted from the polysomes. The polysomal RNA was translated in vitro in a rabbit reticulocyte lysate, and the translation products were immunoprecipitated by anti-subunit antisera. The immunoprecipitated proteins were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and visualized by fluorography. Our data show that the alpha subunit precursor is synthesized on membrane-bound polysomes and the beta subunit precursor is synthesized on free polysomes. In addition, the alpha subunit precursor appears as two separate peptides on sodium dodecyl sulfate-polyacrylamide gels, which suggests that the two alpha subunit forms seen in mature brine shrimp Na,K-ATPase are products of two distinct messenger RNAs. The beta subunit precursor appears as a single discrete band, unlike the mature beta subunit, which appears as a diffuse band.     

Amplification of DNA sequences coding for the Na,K-ATPase alpha-subunit in ouabain-resistant C+ cells.

We have studied the mechanism of cellular resistance to cardiac glycosides in C+ cells. C+ cells were resistant to ouabain and overproduced plasma membrane-bound Na,K-ATPase relative to parental HeLa cells. Overexpression of Na,K-ATPase in C+ cells correlated with increased ATPase mRNA levels and amplification (approximately 100 times) of the ATPase gene. Growth of C+ cells in ouabain-free medium resulted in a marked decline in ATPase mRNA and DNA levels. However, when cells were reexposed to ouabain, they proliferated and ATPase mRNA and DNA sequences were reamplified. Restriction analysis of C+ and other human DNA samples revealed the occurrence of rearrangements in the region of the Na,K-ATPase gene in C+ cells. Furthermore, C+ cells expressed an ATPase mRNA species not found in HeLa cells. These results suggest that amplification of the gene coding for Na,K-ATPase results in overproduction of Na,K-ATPase polypeptides. Amplification of the ATPase gene or the expression of new ATPase mRNA sequences or both may also be responsible for acquisition of the ouabain-resistant phenotype.     

Structural basis for alpha1 versus alpha2 isoform-distinct behavior of the Na,K-ATPase

We showed earlier that the kinetic behavior of the alpha2 isoform of the Na,K-ATPase differs from the ubiquitous alpha1 isoform primarily by a shift in the steady-state E(1)/E(2) equilibrium of alpha2 in favor of E(1) form(s). The aim of the present study was to identify regions of the alpha chain that confer the alpha1/alpha2 distinct behavior using a mutagenesis and chimera approach. Criteria to assess shifts in conformational equilibrium included (i) K(+) sensitivity of Na-ATPase measured at micromolar ATP, under which condition E(2)(K(+)) --> E(1) + K(+) becomes rate-limiting, (ii) changes in K'(ATP) for low affinity ATP binding, (iii) vanadate sensitivity of Na,K-ATPase activity, and (iv) the rate of the partial reaction E(1)P --> E(2)P. We first confirmed that interactions between the cytoplasmic domains of alpha2 that modulate conformational shifts are fundamentally similar to those of alpha1, suggesting that the predilection of alpha2 for E(1) state(s) is due to differences in primary structure of the two isoforms. Kinetic behavior of the alpha1/alpha2 chimeras indicates that the difference in E(1)/E(2) poise of the two isoforms cannot be accounted for by their notably distinct N termini, but rather by the front segment extending from the cytoplasmic N terminus to the C-terminal end of the extracellular loop between transmembranes 3 and 4, with a lesser contribution of the alpha1/alpha2 divergent portion within the M4-M5 loop near the ATP binding domain. In addition, we show that the E(1) shift of alpha2 results primarily from differences in the conformational transition of the dephosphoenzyme, (E(2)(K(+)) --> E(1) + K(+)), rather than phosphoenzyme (E(1)P --> E(2)P).     

The alpha2 isoform of Na,K-ATPase mediates ouabain-induced cardiac inotropy in mice

Inhibition of Na,K-ATPase activity by cardiac glycosides is believed to be the major mechanism by which this class of drugs increases heart contractility. However, direct evidence demonstrating this is lacking. Furthermore it is unknown which specific alpha isoform of Na,K-ATPase is responsible for the effect of cardiac glycosides. Several studies also suggest that cardiac glycosides, such as ouabain, function by mechanisms other than inhibition of the Na,K-ATPase. To determine whether Na,K-ATPase, specifically the alpha2 Na,K-ATPase isozyme, mediates ouabain-induced cardiac inotropy, we developed animals expressing a ouabain-insensitive alpha2 isoform of the Na,K-ATPase using Cre-Lox technology and analyzed cardiac contractility after administration of ouabain. The homozygous knock-in animals were born in normal Mendelian ratio and developed normally to adulthood. Analysis of their cardiovascular function demonstrated normal heart function. Cardiac contractility analysis in isolated hearts and in intact animals demonstrated that ouabain-induced cardiac inotropy occurred in hearts from wild type but not from the targeted animals. These results clearly demonstrate that the Na,K-ATPase and specifically the alpha2 Na,K-ATPase isozyme mediates ouabain-induced cardiac contractility in mice.     

Covalent cross-links between the gamma subunit (FXYD2) and alpha and beta subunits of Na,K-ATPase: modeling the alpha-gamma interaction

This study describes specific intramolecular covalent cross-linking of the gamma to alpha and gamma to beta subunits of pig kidney Na,K-ATPase and rat gamma to alpha co-expressed in HeLa cells. For this purpose pig gammaa and gammab sequences were determined by cloning and mass spectrometry. Three bifunctional reagents were used: N-hydroxysuccinimidyl-4-azidosalicylic acid (NHS-ASA), disuccinimidyl tartrate (DST), and 1-ethyl-3-[3dimethylaminopropyl]carbodiimide (EDC). NHS-ASA induced alpha-gamma, DST induced alpha-gamma and beta-gamma, and EDC induced primarily beta-gamma cross-links. Specific proteolytic and Fe(2+)-catalyzed cleavages located NHS-ASA- and DST-induced alpha-gamma cross-links on the cytoplasmic surface of the alpha subunit, downstream of His(283) and upstream of Val(440). Additional considerations indicated that the DST-induced and NHS-ASA-induced cross-links involve either Lys(347) or Lys(352) in the S4 stalk segment. Mutational analysis of the rat gamma subunit expressed in HeLa cells showed that the DST-induced cross-link involves Lys(55) and Lys(56) in the cytoplasmic segment. DST and EDC induced two beta-gamma cross-links, a major one at the extracellular surface within the segment Gly(143)-Ser(302) of the beta subunit and another within Ala(1)-Arg(142). Based on the cross-linking and other data on alpha-gamma proximities, we modeled interactions of the transmembrane alpha-helix and an unstructured cytoplasmic segment SKRLRCGGKKHR of gamma with a homology model of the pig alpha1 subunit. According to the model, the transmembrane segment fits in a groove between M2, M6, and M9, and the cytoplasmic segment interacts with loops L6/7 and L8/9 and stalk S5.     

Regulation of alpha1 Na/K-ATPase expression by cholesterol

We have reported that α1 Na/K-ATPase regulates the trafficking of caveolin-1 and consequently alters cholesterol distribution in the plasma membrane. Here, we report the reciprocal regulation of α1 Na/K-ATPase by cholesterol. Acute exposure of LLC-PK1 cells to methyl β-cyclodextrin led to parallel decreases in cellular cholesterol and the expression of α1 Na/K-ATPase. Cholesterol repletion fully reversed the effect of methyl β-cyclodextrin. Moreover, inhibition of intracellular cholesterol trafficking to the plasma membrane by compound U18666A had the same effect on α1 Na/K-ATPase. Similarly, the expression of α1, but not α2 and α3, Na/K-ATPase was significantly reduced in the target organs of Niemann-Pick type C mice where the intracellular cholesterol trafficking is blocked. Mechanistically, decreases in the plasma membrane cholesterol activated Src kinase and stimulated the endocytosis and degradation of α1 Na/K-ATPase through Src- and ubiquitination-dependent pathways. Thus, the new findings, taken together with what we have already reported, revealed a previously unrecognized feed-forward mechanism by which cells can utilize the Src-dependent interplay among Na/K-ATPase, caveolin-1, and cholesterol to effectively alter the structure and function of the plasma membrane.     

Structure-function relationships in the Na,K-ATPase alpha subunit: site-directed mutagenesis of glutamine-111 to arginine and asparagine-122 to aspartic acid generates a ouabain-resistant enzyme

Na,K-ATPases from various species differ greatly in their sensitivity to cardiac glycosides such as ouabain. The sheep and human enzymes are a thousand times more sensitive than the corresponding ones from rat and mouse. To define the region of the alpha 1 subunit responsible for this differential sensitivity, chimeric cDNAs of sheep and rat were constructed and expressed in ouabain-sensitive HeLa cells. The construct containing the amino-terminal half of the rat alpha 1 subunit coding region and carboxyl-terminal half of the sheep conferred the ouabain-resistant phenotype to HeLa cells while the reverse construct did not. This indicates that the determinants involved in ouabain sensitivity are located in the amino-terminal half of the Na,K-ATPase alpha subunit. By use of site-directed mutagenesis, the amino acid sequence of the first extracellular domain (H1-H2) of the sheep alpha 1 subunit, Gln-Ala-Ala-Thr-Glu-Glu-Glu-Pro-Gln-Asn-Asp-Asn, was changed to that of the rat, Arg-Ser-Ala-Thr-Glu-Glu-Glu-Pro-Pro-Asn-Asp-Asp. When expressed in HeLa cells, this mutated sheep alpha 1 construct, like the rat/sheep chimera, was able to confer ouabain resistance to these cells. Furthermore, similar results were observed when HeLa cells were transfected with a sheep alpha 1 cDNA containing only two amino acid substitutions. This double mutation was a Gln-111----Arg and Asn-122----Asp change at the amino terminus and carboxyl terminus, respectively, of the H1-H2 extracellular region. The resistant cells, whether transfected with the rat alpha 1 cDNA, the rat/sheep chimera, or the mutant sheep alpha 1 cDNAs, exhibited identical biochemical characteristics including ouabain-inhibitable cell growth, 86Rb+ uptake, and Na,K-ATPase activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Na,K-ATPase alpha2 and Ncx4a regulate zebrafish left-right patterning

A conserved molecular cascade involving Nodal signaling that patterns the laterality of the lateral mesoderm in vertebrates has been extensively studied, but processes involved in the initial break of left-right (LR) symmetry are just beginning to be explored. Here we report that Na,K-ATPase alpha2 and Ncx4a function upstream of Nodal signaling to regulate LR patterning in zebrafish. Knocking down Na,K-ATPase alpha2 and Ncx4a activity in dorsal forerunner cells (DFCs), which are precursors of Kupffer's vesicle (KV), is sufficient to disrupt asymmetric gene expression in the lateral plate mesoderm and randomize the placement of internal organs, indicating that the activity of Na,K-ATPase alpha2 and Ncx4a in DFCs/KV is crucial for LR patterning. High-speed videomicroscopy and bead implantation experiments show that KV cilia are immobile and the directional fluid flow in KV is abolished in Na,K-ATPase alpha2 and Ncx4a morphants, suggesting their essential role in KV ciliary function. Furthermore, we found that intracellular Ca(2+) levels are elevated in Na,K-ATPase alpha2 and Ncx4a morphants and that the defects in ciliary motility, KV fluid flow and placement of internal organs induced by their knockdown could be suppressed by inhibiting the activity of Ca(2+)/calmodulin-dependent protein kinase II. Together, our data demonstrate that Na,K-ATPase alpha2 and Ncx4a regulate LR patterning by modulating intracellular calcium levels in KV and by influencing cilia function, revealing a previously unrecognized role for calcium signaling in LR patterning.     

Differential regulation of Na,K-ATPase alpha 1, alpha 2, and beta subunit mRNA and protein levels by thyroid hormone

The purpose of this study was to determine the effect of thyroid status on the Na,K-ATPase alpha isoforms and beta in rat heart, skeletal muscle, kidney, and brain at the levels of mRNA, protein abundance, and enzymatic activity. Northern and dot-blot analysis of RNA (euthyroid, hypothyroid, and triiodothyronine-injected hypothyroids = hyperthyroids) and immunoblot analysis of protein (euthyroid and hypothyroid) revealed isoform-specific regulation of Na,K-ATPase by thyroid status in kidney, heart, and skeletal muscle and no regulation of sodium pump subunit levels in the brain. In general, in the transition from euthyroid to hypothyroid alpha 1 mRNA and protein levels are unchanged in kidney and skeletal muscle and slightly decreased in heart, while alpha 2 mRNA and protein are decreased significantly in heart and skeletal muscle. In hypothyroid heart and skeletal muscle, the decrease in alpha 2 protein levels was much greater than the decrease in alpha 2 mRNA levels relative to euthyroid indicating translational or post-translational regulation of alpha 2 protein abundance by triiodothyronine status in these tissues. The regulation of beta subunit by thyroid status is tissue-dependent. In hypothyroid kidney beta mRNA levels do not change, but immunodetectable beta protein levels decrease relative to euthyroid, and the decrease parallels the decrease in Na,K-ATPase activity. In hypothyroid heart and skeletal muscle beta mRNA levels decrease; beta protein decreases in heart and was not detected in the skeletal muscle. These findings demonstrate that the euthyroid levels of expression of alpha 1 in heart, alpha 2 in heart and skeletal muscle, and beta in kidney, heart, and skeletal muscle are dependent on the presence of thyroid hormone.     

The alpha and beta subunits of the Na,K-ATPase can assemble at the plasma membrane into functional enzyme

Synthesis and assembly of most oligomeric plasma membrane proteins occurs in the ER. However, the role the ER plays in oligomerization is unknown. We have previously demonstrated that unassociated alpha and beta subunits of the Na,K-ATPase are targeted to the plasma membrane when individually expressed in baculovirus-infected Sf-9 cells. This unique property allows us to determine if assembly of these two polypeptides is restricted to the ER, or if it can also occur at the plasma membrane. To investigate the assembly of the Na,K-ATPase we have taken advantage of the ability of baculovirus-infected cells to fuse. Lowering the extracellular pH of the infected cells triggers an endogenously expressed viral protein to initiate plasma membrane fusion. When individual Sf-9 cells expressing either the Na,K-ATPase alpha or beta subunits are plated together and subjected to a mild acidic shock, they form large syncytia. In the newly continuous plasma membrane the separate alpha and beta polypeptides associate and assemble into functional Na,K-ATPase molecules. However, a hybrid ATPase molecule consisting of a Na,K-ATPase alpha subunit and a H,K- ATPase beta subunit, which efficiently assembles in the ER of coinfected cells, does not assemble at the plasma membrane of fused cells. When cells expressing the Na,K-ATPase alpha subunit are fused to cells coexpressing the Na,K-ATPase beta subunit and the H,K-ATPase beta subunit, the Na,K-ATPase alpha subunit selectively assembles with the Na,K-ATPase beta subunit. However, when cells are coinfected and expressing all three polypeptides, the Na,K-ATPase alpha subunit assembles with both beta subunits in the ER, in what appears to be a random fashion. These experiments demonstrate that assembly between some polypeptides is restricted to the ER, and suggests that the ability of the Na,K-ATPase alpha and beta subunits to leave the ER and assemble at the plasma membrane may represent a novel mechanism of regulation of activity.     

Rat-brain Na,K-ATPase beta-chain gene: primary structure, tissue-specific expression, and amplification in ouabain-resistant HeLa C+ cells.

We deduced the complete amino acid sequence of the rat brain Na,K-ATPase beta-subunit from cDNA. The rat brain beta-subunit exhibits a high degree of primary sequence and secondary structural homology with the human and Torpedo beta-subunit polypeptides. Analysis of rat tissue RNA reveals that the beta-subunit gene encodes four separate mRNA species which are expressed in a tissue-specific fashion. In ouabain-resistant HeLa C+ cells, beta-subunit DNA sequences are amplified (approximately 20-fold) and beta-subunit mRNAs are overproduced relative to levels in parental HeLa cells. These results suggest that the beta-subunit plays an important role in Na,K-ATPase structure-function and in the mechanism underlying cellular resistance to the cardiac glycosides.     

Configuration of subunits within crystals of Na, K-ATPase maintained in the frozen-hydrated state

Two-dimensional crystalline sheets of Na, K-ATPase were studied in the vitrified, frozen-hydrated state by electron microscopy and image processing. The technique of correlation averaging was used to determine the projected structure. The projection map shows asymmetry between the pair of "alpha beta" protomers comprising a dimer of Na, K-ATPase molecules. The two protomers differ in overall density as well as in shape. One protomer has an oblong shape, whereas the other with higher density has a head and a hook region. Such an asymmetry has not been reported by other laboratories. This asymmetry may either be due to the coexistence of two different conformations of the enzyme in the dimeric form or due to the simultaneous existence of two molecular species of Na, K-ATPase.     

Anomalous mobilities of Na,K-ATPase alpha subunit isoforms in SDS-PAGE: identification by N-terminal sequencing.

Three isoforms of the alpha subunit of Na,K-ATPase, alpha 1, alpha 2, and alpha 3 have been characterized at the DNA, mRNA and protein levels. In admixtures, isoforms migrate as doublets (i.e. alpha 1 and another band originally designated alpha +, comprising alpha 2 + alpha 3) when analyzed by SDS-PAGE. As deduced from cDNA sequences their masses range from 111.7 to 112.6 kDa. With conventional protein standards, however, SDS-PAGE yields nominal masses of 85-105 kDa. In this system, the presence of a doublet that reacted with a polyclonal anti-Na,K-ATPase antibody in the kidney was interpreted as indicating two molecular or conformational species of the kidney alpha sub-unit (Siegel, G.J. and Desmond, T.J. (1989) J. Biol. Chem. 264, 4751-4754). We report that Na,K-ATPase purified from dog, guinea pig and rat kidney medulla or from rat brain, can yield two distinct bands when analyzed by SDS-PAGE or STS-PAGE, migrating between 85 and 105 kDa. An additional band migrating at 117 and 120 kDa appears often in enzyme purified from rat and guinea pig kidney medulla. The apparent molecular weights and relative intensities of these bands vary with temperature and duration of incubation during sample preparation. N-terminal sequencing and monospecific antibody probes revealed that the two distinct bands obtained from the kidney enzyme consist only of the alpha 1 isoform. The band appearing at 117-120 kDa also contains only the alpha 1 N-terminal sequence. In contrast, as reported earlier (Sweadner, K.J. (1979) J. Biol. Chem. 254, 6060-6067), the doublet seen in brain preparations consists of alpha 1 and alpha 2 or (alpha 2 + alpha 3). We conclude that monospecific antibody probes or N-terminal sequencing must be used to identify Na,K-ATPase isoforms by SDS- or STS-PAGE. In addition, gel conditions that may affect the mobilities of the isoforms are discussed.     

Differences in phosphorylation of the two large subunits of brine shrimp Na,K-ATPase

Analysis of purified Na,K-ATPase from brine shrimp nauplii revealed two molecular forms of the alpha subunit separable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis [G.L. Peterson, R.D. Ewing, S.R. Hootman, and F.P. Conte (1978) J. Biol. Chem. 253:4762]. The molecular form with lower mobility is designated alpha 1 and the one with higher mobility, alpha 2, in a neutral or alkaline gel system. Differences in Na+-dependent, K+-sensitive phosphorylation of these two molecular forms have been investigated by directly measuring the radioactivity present in each phosphoprotein after separation of the two forms by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In the presence of Na+,Mg2+, and ATP, when the ATP concentration is above 1 microM, both alpha subunits are phosphorylated, although the phosphoprotein content of alpha 1 is considerably greater than that of alpha 2. Below 1 microM ATP, the phosphoprotein content of alpha 2 is even further reduced. These striking differences in phosphorylation at low ATP concentrations are not due to a greater instability of the alpha 2 phosphoprotein during the long electrophoresis times or during fixation, staining, and destaining. The proportion of total phosphoprotein content in alpha 2, as well as the relationship between phosphoprotein content and ATP concentration, is unchanged when the radioactive analysis is performed on frozen gels that have been electrophoresed for shorter times, even though the actual amount of phosphorylation is 15 times greater than with fixed gels. Since the concentration of alpha 1 and alpha 2 vary during development [G.L. Peterson, L. Churchill, J.A. Fisher, and L.E. Hokin (1982) J. Exp. Zool. 221:295], the differences in phosphorylation may be relevant to differences in Na,K-ATPase activity during different development stages.