Reversible inhibition of (Na+, K+) ATPase by Mg2+, adenosine triphosphate, and K+.

Adenosine triphosphate (ATP) hydrolysis catalyzed by the plasma membrane (Na+,K+)ATPase isolated from several sources was inhibited by Mg+, provided that K+ and ATP were also present. Phosphorylation of the adenosine triphosphatase (ATPase) by ATP and by inorganic phosphate was also inhibited, as was p-nitrophenyl phosphatase activity. (Ethylenedinitrilo)tetraacetic acid (EDTA) and catecholamines protected from and reversed the inhibition of ATP hydrolysis by Mg2+, K+ and ATP. EDTA was protected by chelation of Mg2+ but catecholamines acted by some other mechanism. The specificities of various nucleotides as inhibitors (in conjunction with Mg2+ and K+) and as substrates for the (Na+, K+) ATPase were strikingly different. ATP, ADP, beta,gamma-CH2-ATP and alpha,beta-CH2-ADP were active as inhibitors, whereas inosine, cytidine, uridine, and guanosine triphosphates (ITP, CTP, UTP, and GTP) and adenosine monophosphate (AMP) were not. On the other hand, ATP and CTP were substrates and beta,gamma-NH-ATP was a competitive inhibitor of ATP hydrolysis, but not an inhibitor in conjunction with Mg2+ and K+. The Ca2+-ATPase from sarcoplasmic reticulum and F1, the Mg2+-ATPase from the inner mitochondrial membrane, were also inhibited by Mg2+. Catecholamines reversed inhibition of the Ca2+-ATPase, but not that of F1.     

Rat brain has the alpha 3 form of the (Na+,K+)ATPase

Multiple forms of the catalytic subunit of the (Na+,K+)ATPase have been identified in rat brain. While two of them (alpha 1 and alpha 2) have been well characterized, the third form (alpha 3) of these catalytic subunits only recently has been described by cDNA cloning; the corresponding polypeptide has not been isolated. In this paper it is shown that rat brain contains the alpha 3 chain. The catalytic subunits of the (Na+, K+)ATPase from rat brain axolemma were purified by SDS-PAGE and subjected to formic acid cleavage. Amino acid sequence analysis of the resulting fragments revealed that axolemma has the alpha 3 form of the catalytic subunit. In addition, alpha 3-specific antiserum was raised in rabbits immunized with a synthetic peptide. Immunoblotting with this antiserum revealed that the alpha 3 form of the (Na+,K+)ATPase is present also in whole brain microsomes. In SDS-PAGE, the mobilities of the three catalytic subunits of brain (Na+, K+)ATPase follow the order alpha 1 greater than alpha 2 greater than alpha 3. Determination of the ouabain-inhibitable ATPase activity indicates that if the alpha 3 form of the (Na+,K+)ATPase is able to hydrolyze ATP, it is present in a form of the enzyme with a high affinity for this cardiac glycoside and is similar to the alpha 2 form in this respect.     

Molecular weight of (Na+,K+)ATPase from shark rectal gland.

The (Na+,k+)ATPase from the rectal gland of Carcharhinus obscurus has been solubilized in Lubrol WX as an active complex containing 379,900 g of protein and 61 mol of phospholipid. This detergent-lipid-protein complex contains two catalytic subunits of molecular weight 106,400 and four glycopeptide subunits of protein molecular weight 36,600. The latter subunit has a total molecular weight of 51,700 when the carbohydrate is included. Attempts to dissociate this active enzyme complex to smaller size by increasing the detergent concentration led to inactivation. Thus, the smallest active particle in the presence of Lubrol WX contains the two polypeptide subunits in a mole ratio of 2:4 under conditions where the micellar form of detergent is present at a 70:1 molar ratio. This large excess of Lubrol WX eliminates any possibility of artificial togetherness as the result of statistical considerations.     

Quantitative immunoelectron microscopic localization of (Na+,K+)ATPase in rat parotid gland

Distribution of (Na+,K+)ATPase on the cell membranes of acinar and duct cells of rat parotid gland was investigated quantitatively by immunoelectron microscopy using the post-embedding protein A-gold technique. In acinar cells, ATPase was localized predominantly on the basolateral plasma membranes. A small but significant amount of (Na+,K+)ATPase was, however, detected on the luminal plasma membranes, especially on the microvillar region of the acinar cells; the surface density on the luminal membrane was approximately one third of that on the basolateral membranes. In duct cells, many gold particles were found on the basolateral membrane, especially along the basal infoldings of the plasma membranes, whereas no significant gold particles were found on the luminal plasma membranes, suggesting unilateral distribution of ATPase in duct cells. We suggest that in acinar cells sodium ion is not only transported paracellularly but is also actively transported intracellularly into the luminal space by the (Na+,K+)ATPase located on the luminal plasma membranes, and that water is passively transported to the luminal space to form a plasma-like isotonic primary saliva, while in the duct cells the same ion is selectively re-absorbed intracellularly by (Na+,K+)ATPase found in abundance along the many infoldings of the basal plasma membranes, thus producing the hypotonic saliva.     

Interactions of ouabain and vanadate with (Na+,K+)ATPase and isolated cardiac muscle

The interactions of ouabain and vanadate with (Na⁺,K⁺)ATPase were investigated at different potassium concentrations. Also, the contractile effects of a mixture of these two inhibitors were compared to those produced by ouabain or vanadate alone. The results from the enzyme and contractile studies suggested that inhibition of sarcolemmal (Na⁺,K⁺)ATPase was involved in mediating the positive inotropic effect of vanadate.     

The lateral mobility of the (Na+,K+)-dependent ATPase in Madin-Darby canine kidney cells

Fluorescence microphotolysis (recovery after photobleaching) was used to determine the lateral mobility of the (Na+,K+)ATPase and a fluorescent lipid analogue in the plasma membrane of Madin-Darby canine kidney (MDCK) cells at different stages of development. Fluorescein-conjugated Fab' fragments prepared from rabbit anti-dog (Na+,K+)ATPase antibodies (IgG) and 5-(N-hexadecanoyl)aminofluorescein (HEDAF) were used to label the plasma membrane of confluent and subconfluent cultures of MDCK cells. Fractional fluorescence recovery was 50% and 80-90% for the protein and lipid probes, respectively, and was independent of developmental stage. The estimated diffusion constants of the mobile fraction were approximately 5 X 10(-10) cm2/s for the (Na+,K+)ATPase and approximately 2 X 10(-9) cm2/s for HEDAF. Only HEDAF diffusion showed dependency on developmental stage in that D for confluent cells was approximately twice that for subconfluent cells. These results indicate that (Na+,K+)ATPase is 50% immobilized in all developmental stages, whereas lipids in confluent MDCK cells are more mobile than in subconfluent cells. They suggest, furthermore, that the degree of immobilization of the (Na+,K+)ATPase is insufficient to explain its polar distribution, and they support restricted mobility of the ATPase through the tight junctions as the likely mechanism for preventing the diffusion of this protein into the apical domain of the plasma membrane in confluent cell cultures.     

Kinetic studies on the (Na+ + K+)-dependent ATPase evidence for coexisting sites for Na+, K+ and Mg2+

Na+-ATPase activity of a dog kidney (Na+ + K+)-ATPase enzyme preparation was inhibited by a high concentration of NaCl (100 mM) in the presence of 30 microM ATP and 50 microM MgCl2, but stimulated by 100 mM NaCl in the presence of 30 microM ATP and 3 mM MgCl2. The K0.5 for the effect of MgCl2 was near 0.5 mM. Treatment of the enzyme with the organic mercurial thimerosal had little effect on Na+ -ATPase activity with 10 mM NaCl but lessened inhibition by 100 mM NaCl in the presence of 50 microM MgCl2. Similar thimerosal treatment reduced (Na+ + K+)-ATPase activity by half but did not appreciably affect the K0.5 for activation by either Na+ or K+, although it reduced inhibition by high Na+ concentrations. These data are interpreted in terms of two classes of extracellularly-available low-affinity sites for Na+: Na+-discharge sites at which Na+-binding can drive E2-P back to E1-P, thereby inhibiting Na+-ATPase activity, and sites activating E2-P hydrolysis and thereby stimulating Na+-ATPase activity, corresponding to the K+-acceptance sites. Since these two classes of sites cannot be identical, the data favor co-existing Na+-discharge and K+-acceptance sites. Mg2+ may stimulate Na+-ATPase activity by favoring E2-P over E1-P, through occupying intracellular sites distinct from the phosphorylation site or Na+-acceptance sites, perhaps at a coexisting low-affinity substrate site. Among other effects, thimerosal treatment appears to stimulate the Na+-ATPase reaction and lessen Na+-inhibition of the (Na+ + K+)-ATPase reaction by increasing the efficacy of Na+ in activating E2-P hydrolysis.     

(Na+,K+)ATPase levels in preadipocyte cell lines established from genetically-obese and non-obese mice

Monomethylethanolamine and dimethylethanolamine stimulatd the SAM phospholipid N-methylation activity by a Ca⁺² dependent reaction. Presumably these bases are converted into their corresponding membranous phospholipid which become substrates for a phospholipid methyl transferase also present in these membranes.     

A transport model for the (Na+/K+)ATPase in liposomes including the (Na+/K+)-channel function

(Na+/K+)ATPase liposomes of various degrees of reconstitution are formed by varying the amount of phosphatidylcholine added to the soluble (Na+/K+)ATPase before vesicles are formed by cholate removal. In the presence of ATP, the reconstituted sodium pump effectuates (Na+/K+) antiport. In the absence of ATP, the reconstituted sodium pump forms a (Na+/K+) channel. The stable plateaus formed by (1) the active Na+ transport, (2) the active K+ transport, (3) the 'passive' Na+ flux, and (4) the 'passive' K+ flux are determined in the optimally and the partially reconstituted liposomes. The activities of all four vectorial functions vary in a tightly correlated fashion, suggesting that they are mediated by the same transport-active configuration of (Na+/K+)ATPase. A transport model which includes the active and the passive (Na+/K+) fluxes mediated by the sodium pump in liposomes is outlined.     

Quantitative immunoelectron microscopic localization of (Na+,K+)ATPase on rat exocrine pancreatic cells

Distribution of (Na+,K+)ATPase in rat exocrine pancreatic cells was investigated quantitatively by immunoelectron microscopy using the post-embedding protein A-gold technique. We found that in acinar and duct cells (Na+,K+)ATPase exists on both the luminal and the basolateral surfaces, with higher particle density on the luminal surface (4.4 times in the acinar cells and 5.6 times in the duct cells). According to Bolender (J Cell Biol 61:269, 1974), the luminal surface represents only 5% of the total cell surface of an average pancreatic acinar cell. It is roughly estimated, therefore, that approximately 80% of the plasma membrane (Na+,K+)ATPase in the acinar cells exists on the basolateral surface. When the acinar and duct cells were compared, more than twice as many particles were found on acinar cells than on duct cells. The enzyme existed on all the cell surfaces, preferentially on the microvilli or on the cell membrane folds, and no clustering was detected. We suggest that the (Na+,K+)ATPase on the basolateral surface is mainly responsible for the extrusion of a large number of sodium ions that are incorporated into the cytoplasm accompanying the secondary active transport of various organic substances and inorganic ions, whereas that on the luminal surface is responsible for active extrusion of sodium ions that are partially responsible for the fluid secretion of the pancreatic cells.     

Fluorescent properties of (Na+/K+)ATPase

1. The effect of ouabain on the molecular properties of (Na+/K+)-ATPase has been studied in purified preparations of the enzyme, isolated from the microsomal fraction of outer red medulla of porcine kidney, according to a modification of the method described by Jorgensen. 2. Ouabain, a specific inhibitor of (Na+/K+)-ATPase, binds at the potassium site of the enzyme, thus generating an increase in its stability towards the common denaturing agents, such as exposure to different concentration of guanidinium chloride (GdmC1) or to acidic solutions.     

The (Na+, K+)ATPase of rat kidney: purification, biosynthesis, and processing

(Na+, K+)ATPase was purified from rat renal outer medulla by concanavalin A- and wheat germ agglutinin-lectin Sepharose affinity chromatographies. The antibody, which was raised in rabbits, markedly inhibited ATPase activity. The monospecificity of this antibody was assayed by the Ouchterlony double immunodiffusion and Western blotting tests. The endoplasmic reticulum (ER)-rich, and Golgi-rich subfractions were prepared from the rat kidney microsomal fraction by sucrose density gradient centrifugation. On the immunoblot, the molecular weight of the alpha subunit in both fractions was 95 kilodalton (Kd); whereas, that of the beta subunit was 50 Kd in the ER-rich fraction and 54 Kd in the Golgi-rich fraction. When treated with endoglucosidase H, the 50 Kd component was converted to 38 Kd, but the 54 Kd component was endoglucosidase H resistant. These results suggest that the beta subunit (38 Kd) is glycosylated cotranslationally in the ER (50 Kd) then is converted to the mature type subunit (54 Kd) in the Golgi apparatus.