Polarized distribution of Na, K-ATPase α-subunit isoforms in electrocyte membranes

We have previously demonstrated that Na⁺, K⁺-ATPase activity is present in both differentiated plasma membranes from Electrophorus electricus (L.) electrocyte. Considering that the α subunit is responsible for the catalytic properties of the enzyme, the aim of this work was to study the presence and localization of α isoforms (α1 and α2) in the electrocyte. Dose-response curves showed that non-innervated membranes present a Na⁺, K⁺-ATPase activity 2.6-fold more sensitive to ouabain (I₅₀=1.0±0.1 μM) than the activity of innervated membranes (I₅₀=2.6±0.2 μM). As depicted in [³H]ouabain binding experiments, when the [³H]ouabain-enzyme complex was incubated in a medium containing unlabeled ouabain, reversal of binding occurred differently: the bound inhibitor dissociated 32% from Na⁺, K⁺-ATPase in non-innervated membrane fractions within 1 h, while about 50% of the ouabain bound to the enzyme in innervated membrane fractions was released in the same time. These data are consistent with the distribution of α1 and α2 isoforms, restricted to the innervated and non-innervated membrane faces, respectively, as demonstrated by Western blotting from membrane fractions and immunohistochemical analysis of the main electric organ. The results provide direct evidence for a distinct distribution of Na⁺, K⁺-ATPase α-subunit isoforms in the differentiated membrane faces of the electrocyte, a characteristic not yet described for any polarized cell.     

Cytoplasmatic domain of Na,K-ATPase α-subunit is responsible for the aggregation of the enzyme in proteoliposomes

We studied the thermal dependence of amide I′ infrared absorption and fluorescence emission of Trp residues in the Na,K-ATPase of rabbit kidney. We studied the whole enzyme solubilized with detergent, the whole enzyme reconstituted in proteoliposomes and the protein fraction that remained in the lipid membrane after the trypsin digestion of the proteoliposomes. Cooperative unfolding and aggregation with increasing temperature were observed in the whole protein, whether solubilized or reconstituted, but not in the fraction remaining after trypsinization. The protein influenced the physical state of the lipid, decreasing the temperature of the gel to liquid-crystalline phase transition and the degree of cooperativity. This study provides new information for the understanding of the processes controlling the association mechanisms that are important for enzyme function in natural membranes.     

Subcellular distribution of tissue kallikrein and Na,K-ATPase α-subunit in rat parotid striated duct cells

Intracellular protein distribution and sorting were examined in rat parotid striated duct cells, in which tissue kallikrein is apical, and Na,K-ATPase is basolateral. Electron-microscopic immunogold cytochemistry, with both polyclonal and monoclonal antibodies, demonstrated these enzymes at opposite poles of the cells and in distinct intracellular sites. Kallikrein was found within apical secretory granules, whereas Na,K-ATPase was present on basolateral cell membranes. In addition, kallikrein was localized throughout cisternae of all Golgi profiles, whereas Na,K-ATPase (-subunit) was found only in small peripheral vesicles and/or lateral cisternal extensions of a basal subset of Golgi profiles. These differences in the subcellular distribution of the two marker antigens were most clearly seen with double immunogold labelling. Our results suggest that kallikrein, an apical, regulated secretory protein, and Na,K-ATPase, a basolateral, constitutively transported membrane protein, are segregated at (or prior to) the level of the Golgi apparatus rather than in the trans-Golgi network (TGN), as was expected.Abbreviations ATP adenosine tri-phosphate - HBSS Hanks' balanced salt solution - GaM goat anti-mouse - GaR goat anti-rabbit - PBS phosphate-buffered saline - RaM rabbit anti-mouse - RER rough endoplasmic reticulum - TGN trans-Golgi network     

Asymmetric orientation of amino groups in the α-subunit and the β-subunit of (Na+ + K+)-ATPase in tight right-side-out vesicles of basolateral membranes from outer medulla

The orientation of amino groups in the membrane in the α- and β-subunits of (Na⁺ + K⁺)-ATPase was examined by labeling with Boldon-Hunter reagent, N-succinimidyl 3-(4-hydroxy,5-[¹²⁵I]iodophenyl)propionate), in right-side-out vesicles or in open membrane fragments from the thick ascending limbs of the Henles loop of pig kidney. Sealed right-side-out vesicles of basolateral membranes were separated from open membrane fragments by centrifugation in a linear metrizamide density gradient. After labeling, (Na⁺ + K⁺)-ATPase was purified using a micro-scale version of the ATP-SDS procedure. Distribution of label was analyzed after SDS-gel electrophoresis of α-subunit, β-subunit and proteolytic fragments of α-subunit. Both the α- and the β-subunit of (Na⁺ + K⁺)-ATPase are uniformly labeled, but the distribution of labeled residues on the two membrane surfaces differs markedly. All the labeled residues in the β-subunit are located on the extracellular surface. In the α-subunit, 65–80% of modified groups are localized to the cytoplasmic surface and 20–35% to the extracellular membrane surface. Proteolytic cleavage provides evidence for the random distribution of ¹²⁵I-labeling within the α-subunit. The preservation of (Na⁺ + K⁺)-ATPase activity and the observation of distinct proteolytic cleavage patterns of the E₁- and E₂-forms of the α-subunit show that the native enzyme structure is unaffected by labeling with Bolton-Hunter reagent. Bolton-Hunter reagent was shown not to permeate into sheep erythrocytes under the conditions of the labeling experiment. The data therefore allow the conclusion that the mass distribution is asymmetric, with all the labeled amino groups in the β-subunit being on the extracellular surface, while the α-subunit exposes 2.6-fold more amino groups on the cytoplasmic than on the extracellular surface.     

Identification of a region of the polypeptide chain of Na,K-ATPase α-subunit interacting with 67-kDa melittin-like protein

It was shown earlier that a 67-kDa protein purified from mouse kidney using polyclonal antibodies against melittin (a peptide from bee venom) interacted with Na,K-ATPase from rabbit kidney. In this study, a 43-kDa proteolytic fragment of Na,K-ATPase α-subunit interacting with the 67-kDa melittin-like protein was found. The α-subunit was hydrolyzed by trypsin in the presence of 0.5 mM ouabain (E2-conformation of Na,K-ATPase). A proteolytic fragment interacting with the 67-kDa melittin-like protein that was identified by mass-spectrometry is a region of the cytoplasmic domain of Na,K-ATPase α-subunit located between amino acid residues 591 and 775. The fragment includes a conservative DPPRA motif that occurs in many P-type ATPases. It was shown earlier that this motif of H,K-ATPase from gastric mucosa binds to melittin. We suggest that namely this motif of P-type ATPases is able to interact with proteins containing melittin-like modules.     

A Specific and Essential Role for Na,K-ATPase α3 in Neurons Co-expressing α1 and α3

Most neurons co-express two catalytic isoforms of Na,K-ATPase, the ubiquitous α1, and the more selectively expressed α3. Although neurological syndromes are associated with α3 mutations, the specific role of this isoform is not completely understood. Here, we used electrophysiological and Na⁺ imaging techniques to study the role of α3 in central nervous system neurons expressing both isoforms. Under basal conditions, selective inhibition of α3 using a low concentration of the cardiac glycoside, ouabain, resulted in a modest increase in intracellular Na⁺ concentration ([Na⁺]_i) accompanied by membrane potential depolarization. When neurons were challenged with a large rapid increase in [Na⁺]_i, similar to what could be expected following suprathreshold neuronal activity, selective inhibition of α3 almost completely abolished the capacity to restore [Na⁺]_i in soma and dendrite. Recordings of Na,K-ATPase specific current supported the notion that when [Na⁺]_i is elevated in the neuron, α3 is the predominant isoform responsible for rapid extrusion of Na⁺. Low concentrations of ouabain were also found to disrupt cortical network oscillations, providing further support for the importance of α3 function in the central nervous system. The α isoforms express a well conserved protein kinase A consensus site, which is structurally associated with an Na⁺ binding site. Following activation of protein kinase A, both the α3-dependent current and restoration of dendritic [Na⁺]_i were significantly attenuated, indicating that α3 is a target for phosphorylation and may participate in short term regulation of neuronal function.     

Localization of α1,2,3-subunit isoforms of Na,K-ATPase in cultured neonatal and adult rat myocardium: The immunofluorescence and immunocytochemical study

By indirect immunofluorescence and preembedding peroxidase-diaminobenzidine technique the localization of polyclonal and monoclonal antibodies against 1, 2 and 3 isoforms of the Na,K-ATPase were studied in rat myocardium.The 1-subunit was identified predominantly on sarcolemma of cultured myocytes, neonatal, as well as adult cardiocytes. The 2 signal was localized around nuclei of cultured cardiocytes, very weak signals were seen in neonatal and more intense signal, were dispersed throughout the adult myocytes. The 3-subunit immunoreactivity was weak and localized in cell processes connecting individual cultured cells, on sarcolemma and intercalated discs of neonatal cells and very weak in adult working myocytes. Cytochemically demonstrated ouabain resistant Na,K-ATPase localized in junctional sarcoplasmic reticulum may represent 1 isoenzyme which is directly involved in modulation of action potential fluxes.     

Association of Renal Na,K-ATPase α-Subunit with the β- and γ-Subunits Based on Cryoelectron Microscopy

Na,K-ATPase transports Na(+) and K(+) across cell membranes and consists of alpha- and beta-subunits. Na,K-ATPase also associates with small FXYD proteins that regulate the activity of the pump. We have used cryoelectron microscopy of two-dimensional crystals including data to 8 A resolution to determine the three-dimensional (3-D) structure of renal Na,K-ATPase containing FXYD2, the gamma-subunit. A homology model for the alpha-subunit was calculated from a Ca(2+)-ATPase structure and used to locate the additional beta- and gamma-subunits present in the 3-D map of Na,K-ATPase. Based on the 3-D map, the beta-subunit is located close to transmembrane helices M8 and M10 and the gamma-subunit is adjacent to helices M2 and M9 of the alpha-subunit.     

Genes encoding the H,K-ATPase α and Na,K-ATPase α3 subunits are linked on mouse Chromosome 7 and human Chromosome 19

We have used linkage analysis and fluorescence in situ hybridization to determine the chromosomal organization and location of the mouse (Atp4a) and human (ATP4A) genes encoding the H,K-ATPase subunit. Linkage analysis in recombinant inbred (BXD) strains of mice localized Atp4a to mouse Chromosome (Chr) 7. Segregation of restriction fragment length polymorphisms in backcross progeny of Mus musculusxMus spretus mating confirmed this assignment and indicates that Atp4a and Atp1a3 (gene encoding the murine Na,K-ATPase 3 subunit) are linked and separated by a distance of 2 cM. Analysis of the segregation of simple sequence repeats suggested the gene order centromere-D7Mit21-D7Mit57/Atpla3-D7Mit72/Atp4a. A human Chr 19-enriched cosmid library was screened with both H,K-ATPase and Na,K-ATPase 3 subunit cDNA probes to isolate the corresponding human genes (ATP4A and ATP1A3, respectively). Fluorescence in situ hybridization with gene-specific cosmid clones localized ATP4A to the q13.1 region, and proximal to ATP1A3, which maps to the q13.2 region, of Chr 19. These results indicate that ATP4A and ATP1A3 are linked in both the mouse and human genomes.     

Hypertension from chronic central sodium chloride in mice is mediated by the ouabain-binding site on the Na,K-ATPase α₂-isoform

A chronic increase in the concentration of sodium chloride in the cerebrospinal fluid (CSF) (↑CSF [NaCl]) appears to be critically important for the development of salt-dependent hypertension. In agreement with this concept, increasing CSF [NaCl] chronically by intracerebroventricular (icv) infusion of NaCl-rich artificial CSF (aCSF-HiNaCl) in rats produces hypertension by the same mechanisms (i.e., aldosterone-ouabain pathway in the brain) as that produced by dietary sodium in salt-sensitive strains. We first demonstrate here that icv aCSF-HiNaCl for 10 days also causes hypertension in wild-type (WT) mice. We then used both WT and gene-targeted mice to explore the mechanisms. In WT mice with a ouabain-sensitive Na,K-ATPase α(2)-isoform (α2(S/S)), mean arterial pressure rose by ~25 mmHg within 2 days of starting aCSF-HiNaCl (0.6 nmol Na/min) and remained elevated throughout the study. Ouabain (171 pmol/day icv) increased blood pressure to a similar extent. aCSF-HiNaCl or ouabain given at the same rates subcutaneously instead of intracerebroventricularly had no effect on blood pressure. The pressor response to icv aCSF-HiNaCl was abolished by an anti-ouabain antibody given intracerebroventricularly but not subcutaneously, indicating that it is mediated by an endogenous ouabain-like substance in the brain. We compared the effects of icv aCSF-HiNaCl or icv ouabain on blood pressure in α2(S/S) versus knockout/knockin mice with a ouabain-resistant endogenous α(2)-subunit (α2(R/R)). In α2(R/R), there was no pressor response to icv aCSF-HiNaCl in contrast to WT mice. The α2(R/R) genotype also lacked a pressor response to icv ouabain. These data demonstrate that chronic ↑CSF [NaCl] causes hypertension in mice and that the blood pressure response is mediated by the ouabain-like substance in the brain, specifically by its binding to the α(2)-isoform of the Na,K-ATPase.     

The expression of Na+/K+-ATPase β-subunit cRNA injected into Xenopus oocytes is affected by coinjection with α-subunit cRNA

The cRNA for Torpedo californica Na⁺/K⁺-ATPase -subunit (cRNA) was injected into Xenopus oocytes alone or with the cRNA for the Na⁺/K⁺-ATPase -subunit (cRNA). When cRNA was injected alone, the amount of the -subunit that accumulated in oocytes increased with increasing amounts of injected cRNA. When cRNA and cRNA were injected simultaneously, less -subunit accumulated than when cRNA was injected alone, whereas the Na⁺/K⁺-ATPase activity increased markedly. The decrease in the accumulation of the -subunit was dose-dependent upon the cRNA. The mutant -subunit unable to assemble with the -subunit accumulated in oocytes independently of cRNA, suggesting that post-translational control mechanisms may serve to reduce the accumulation of the -subunit.This work was supported by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science, Sports and Culture of Japan (No. 05259226, No. 06454149).     

A domain of the α-subunit of rabbit phosphorylase kinase shows homologies with regions of rabbit α-tropomyosin,human EGF receptor,and the α chain of bovine S-100 protein

Sequence comparison of the -subunit of phosphorylase kinase with -tropomyosin revealed 32% identity, and 49% similarity, between the region of -tropomyosin coded by exon 5 and a 39 amino acid segment of the kinase subunit. A subsequence of the -subunit segment and a sequence overlapping the same -subunit region are homologous with: (a) a region of the cytoplasmic domain of EGF receptor (50% identity) and (b) a Ca²⁺-binding domain of the chain of S-100 protei (50% identity) respectively. Statistical analysis shows that these homologies are significant. The biological implication of the above similarities is discussed.     

Na,K-ATPase Activity in Mouse Muscle is Regulated by AMPK and PGC-1α

Methyl-β-cyclodextrins (MβCDs) are molecules that are extensively used to remove and to load cholesterol (Chol) from artificial and natural membranes; however, the mechanism of Chol extraction by MβCD from pure lipids or from complex mixtures is not fully understood. One of the outstanding questions in this field is the capability of MβCD to remove Chol from lipid domains having different packing. Here, we investigated the specificity of MβCD to remove Chol from coexisting macrodomains with different lipid packing. We used giant unilamellar vesicles (GUVs) made of 1,2-dioleoylphosphatidylcholine:1,2-dipalmitoylphatidylcholine:free cholesterol, 1:1:1 molar ratio at 27°C. Under these conditions, individual GUVs present Chol distributed into l _o and l _d phases. The two phases can be distinguished and visualized using Laurdan generalized polarization and two-photon excitation fluorescence microscopy. Our data indicate that MβCD removes Chol preferentially from the more disordered phase. The process of selective Chol removal is dependent on the MβCD concentration. At high concentrations, MβCD also removes phospholipids.     

Regulation and Identification of Na,K-ATPase α1 Subunit Phosphorylation in Rat Parotid Acinar Cells

The stimulation of fluid and electrolyte secretion in salivary cells results in ionic changes that promote rapid increases in the activity of the Na,K-ATPase. In many cell systems, there are conflicting findings concerning the regulation of the phosphorylation of the Na,K-ATPase α subunit, which is the catalytic moiety. Initially, we investigated the phosphorylation sites on the α1 subunit in native rat parotid acinar cells using tandem mass spectrometry and identified two new phosphorylation sites (Ser²²², Ser⁴⁰⁷), three sites (Ser²¹⁷, Tyr²⁶⁰, Ser⁴⁷) previously found from large scale proteomic screens, and two sites (Ser²³, Ser¹⁶) known to be phosphorylated by PKC. Subsequently, we used phospho-specific antibodies to examine the regulation of phosphorylation on Ser²³ and Ser¹⁶ and measured changes in ERK phosphorylation in parallel. The G-protein-coupled muscarinic receptor mimetic carbachol, the phorbol ester phorbol 12-myristate 13-acetate, the Ca²⁺ ionophore ionomycin, and the serine/threonine phosphatase inhibitor calyculin A increased Ser²³ α1 phosphorylation. Inhibition of classical PKC proteins blocked carbachol-stimulated Ser²³ α1 subunit phosphorylation but not ERK phosphorylation, which was blocked by an inhibitor of novel PKC proteins. The carbachol-initiated phosphorylation of Ser²³ α1 subunit was not modified by ERK or PKA activity. The Na,K-ATPase inhibitor ouabain reduced and enhanced the carbachol-promoted phosphorylation of Ser²³ and Ser¹⁶, respectively, the latter because ouabain itself increased Ser¹⁶ phosphorylation; thus, both sites display conformational-dependent phosphorylation changes. Ouabain-initiated phosphorylation of Ser¹⁶ α1 was not blocked by PKC inhibitors, unlike carbachol- or phorbol 12-myristate 13-acetate-initiated phosphorylations, suggesting that this site was also a substrate for a kinase other than PKC.     

Progesterone modulation of transmembrane helix-helix interactions between the α-subunit of Na/K-ATPase and phospholipid N-methyltransferase in the oocyte plasma membrane

Background  

Progesterone binding to the surface of the amphibian oocyte initiates the meiotic divisions. Our previous studies with Rana pipiens oocytes indicate that progesterone binds to a plasma membrane site within the external loop between the M1 and M2 helices of the α-subunit of Na/K-ATPase, triggering a cascade of lipid second messengers and the release of the block at meiotic prophase. We have characterized this site, using a low affinity ouabain binding isoform of the α1-subunit.     

Na,K-ATPase α2 activity in mammalian skeletal muscle T-tubules is acutely stimulated by extracellular K+

The Na,K-ATPase α2 isoform is the predominant Na,K-ATPase in adult skeletal muscle and the sole Na,K-ATPase in the transverse tubules (T-tubules). In quiescent muscles, the α2 isozyme operates substantially below its maximal transport capacity. Unlike the α1 isoform, the α2 isoform is not required for maintaining resting ion gradients or the resting membrane potential, canonical roles of the Na,K-ATPase in most other cells. However, α2 activity is stimulated immediately upon the start of contraction and, in working muscles, its contribution is crucial to maintaining excitation and resisting fatigue. Here, we show that α2 activity is determined in part by the K⁺ concentration in the T-tubules, through its K⁺ substrate affinity. Apparent K⁺ affinity was determined from measurements of the K_1/2 for K⁺ activation of pump current in intact, voltage-clamped mouse flexor digitorum brevis muscle fibers. Pump current generated by the α2 Na,K-ATPase, Ip, was identified as the outward current activated by K⁺ and inhibited by micromolar ouabain. Ip was outward at all potentials studied (−90 to −30 mV) and increased with depolarization in the subthreshold range, −90 to −50 mV. The Q₁₀ was 2.1 over the range of 22–37°C. The K_1/2,K of Ip was 4.3 ± 0.3 mM at −90 mV and was relatively voltage independent. This K⁺ affinity is lower than that reported for other cell types but closely matches the dynamic range of extracellular K⁺ concentrations in the T-tubules. During muscle contraction, T-tubule luminal K⁺ increases in proportion to the frequency and duration of action potential firing. This K_1/2,K predicts a low fractional occupancy of K⁺ substrate sites at the resting extracellular K⁺ concentration, with occupancy increasing in proportion to the frequency of membrane excitation. The stimulation of preexisting pumps by greater K⁺ site occupancy thus provides a rapid mechanism for increasing α2 activity in working muscles.     

The maltase, glucoamylase and transglucosylase activities of acid α-glucosidase from rabbit muscle

1. The maltase and glucoamylase activities of acid alpha-glucosidase purified from rabbit muscle exhibited marked differences in certain physicochemical properties. These included pH stability, inactivation by thiol-group reagents, inhibition by alphaalpha-trehalose, methyl alpha-d-glucoside, sucrose, turanose, polyols, glucono-delta-lactone and monosaccharides, pH optimum and the kinetics and pH-dependence of cation activation. 2. The results are interpreted in terms of the existence of at least two specific substrate-binding sites or sub-sites. One site is specific for the binding of maltose and probably other oligosaccharides. The second site binds polysaccharides such as glycogen. 3. The sites appear to be in close proximity, since glycogen and maltose are mutually inhibitory substrates and interact directly in transglucosylation reactions. 4. Acid alpha-glucosidase exhibited intrinsic transglucosylase activity. The enzyme catalysed glucosyl-transfer reactions from [(14)C]maltose (donor substrate) to polysaccharides (glycogen and pullulan) and to maltose itself (disproportionation). The pH optimum was 5.1, with a shoulder or secondary activity peak at pH5.4. The glucose transferred to glycogen was attached by alpha-1,4- and alpha-1,6-linkages. Three major oligosaccharide products of enzyme action on maltose (disproportionation) were detected. 5. The kinetics of enzyme action on [(14)C]maltose showed that the rate of transglucosylation increased in a sigmoidal fashion as a function of substrate concentration, approximately in parallel with a decrease in the rate of glucose release. 6. The results are interpreted to imply competitive interaction at a specific binding site between maltose and water as glucosyl acceptors. 7. The results are discussed in terms of the possible existence of multiple subgroups of glycogen-storage disease type II.     

Thyroidal enhancement of rat myocardial Na,K-ATPase: Preferential expression of α2 activity and mRNA abundance

Summary In hypothyroid rat myocardium, the low-ouabain-sensitivity Na,K-ATPase activity had aK _i =10^–4 m and accounted for 95% of the enzyme activity, while the high-ouabain-sensitivity activity contributed 5% to the total activity, with aK _i =3×10⁷ m. mRNA₁ was 7.2- and 5.5-fold more abundant than mRNA₂ and mRNA, respectively, in hypothyroid ventricles while mRNA₃ was undetectable. Administration of T₃ increased total Na,K-ATPase activity 1.6-fold; the low-ouabain-sensitivity activity increased 1.5-fold while high-ouabain-sensitivity activity was stimulated 3.2-fold. T₃ increased the number of high-affinity ouabain-binding sites 2.9-fold with no change inK _d (2×10^–7 m). The abundances of mRNA₁, mRNA₂, and mRNA (per unit RNA) following T₃ treatment increased 3.6-, 10.6-, and 12.7-fold, respectively. The larger increments in subunit mRNA abundances than in Na,K-ATPase activity suggests the involvement of translational and/or post-translational regulatory steps in Na,K-ATPase biogenesis in response to T₃. It is concluded that T₃ enhances myocardial Na,K-ATPase subunit mRNA abundances and Na,K-ATPase activity, and that the expression of the high- and low-ouabain-sensitivity activities are probably a reflection of the abundances of the 2 and 1 isoforms, respectively. The physiological role played by the subunit remains uncertain.