Affinity labeling of two nucleotide sites on Na,K-ATPase using 2'(3')-O-(2,4,6-trinitrophenyl)8-azidoadenosine 5'-[alpha-32P]diphosphate (TNP-8N3-[alpha-32P]ADP) as a photoactivatable probe. Label incorporation before and after blocking the high affinity ATP site with fluorescein isothiocyanate.

ATP and its analogues act on the minimal functional unit of Na, K-ATPase, the alpha beta protomer, with high and low affinity effects. Fluorescein isothiocyanate (FITC) irreversibly blocks the high affinity, or catalytic, ATP site, and yet the surviving K+-phosphatase activity of soluble FITC-modified alphabeta protomers can be photoinactivated by 2'(3')-O-trinitrophenyl (TNP)-8N3-ADP (Ward, D. G., and Cavieres, J. D. (1998) J. Biol. Chem. 273, 14277-14284). We have now used TNP-8N3-[alpha-32P]ADP as a photoaffinity label for Na,K-ATPase. The native enzyme can be photolabeled at 5 microM TNP-8N3-[alpha-32P]ADP, and ATP or FITC treatment prevents labeling of the alpha chain. At 25 microM, however, TNP-8N3-[alpha-32P]ADP can be incorporated in the FITC-modified alpha chain, concurrently with the inactivation of the K+-phosphatase activity, to an extrapolated level of 0.5-1.2 mol of 32P-probe per mol of alpha chain. Photoinactivation and labeling are prevented by TNP-ADP, vanadate, or strophanthidin and are promoted by Na+ or Mg2+, but not K+. The cation effects suggest that the fluorescein-modified enzyme incorporates the TNP-8N3-[alpha-32P]ADP. Mg complex preferentially, and the free probe when in the E1 enzyme form and after occupation of a low-affinity Na+ site. Partial trypsinolysis reveals that the point of TNP-8N3-[alpha-32P]ADP attachment is on the C-terminal 58-kDa fragment of the FITC-modified alpha chain. The affinity labeling of the fluorescein enzyme by TNP-8N3-[alpha-32P]ADP endorses the view that two nucleotide sites can be occupied simultaneously in each alpha subunit of Na,K-ATPase.

Photoinactivation of fluorescein isothiocyanate-modified Na,K-ATPase by 2'(3')-O-(2,4,6-trinitrophenyl)8-azidoadenosine 5'-diphosphate. Abolition of E1 and E2 partial reactions by sequential block of high and low affinity nucleotide sites.

The Na,K-ATPase activity of the sodium pump exhibits apparent multisite kinetics toward ATP, a feature that is inherent to the minimal enzyme unit, the alpha beta protomer. We have argued that this should arise from separate catalytic and noncatalytic sites on the alpha beta protomer as fluorescein isothiocyanate (FITC) blocks a high affinity ATP site on all alpha subunits and yet the modified Na, K-ATPase retains a low affinity response to nucleotides (Ward, D. G., and Cavieres, J. D. (1996) J. Biol. Chem. 271, 12317-12321). We now find that 2'(3')-O-(2,4,6-trinitrophenyl)8-azido-adenosine 5'-diphosphate (TNP-8N3-ADP), a high affinity photoactivatable analogue of ATP, can inhibit the K+-phosphatase activity of the FITC-modified enzyme during assays in dimmed light. The inhibition occurs with a Ki of 140 microM at 20 mM K+; it requires the adenine ring as 2'(3')-O-(2,4 6-trinitrophenyl) (TNP)-UDP or TNP-uridine are less potent and 2,4,6-trinitrobenzene-sulfonate is ineffective. Under irradiation with UV light, TNP-8N3-ADP inactivates the K+-phosphatase activity of the fluorescein-enzyme and also its phosphorylation by [32P]Pi. The photoinactivation process is stimulated by Na+ or Mg2+, and is inhibited by K+ or excess TNP-ADP. In the presence of 50 mM Na+ and 1 mM Mg2+, TNP-8N3-ADP photoinactivates with a K0.5 of 15 microM. Furthermore, TNP-8N3-ADP photoinactivates the FITC-modified, solubilized alpha beta protomers, even more effectively than the membrane-bound fluorescein-enzyme. These results strongly suggest that catalytic and allosteric ATP sites coexist on the alpha beta protomer of Na,K-ATPase.

Binding of 2'(3')-O-(2,4-6-trinitrophenyl) ADP to soluble alpha beta protomers of Na, K-ATPase modified with fluorescein isothiocyanate. Evidence for two distinct nucleotide sites.

The overall reaction of well-defined solubilized protomers of Na,K-ATPase (one alpha plus one beta subunit) retains the dual ATP dependence observed with the membrane-bound enzyme, with distinctive ATP effects in the submicromolar and submillimolar ranges (Ward, D. G., and Cavieres, J. D. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 5332-5336). We have now found that the K+/-phosphatase activity of the alpha beta protomers is still inhibited by 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-diphosphate (TNP-ADP). What is most significant is that the TNP-ADP effect can be observed clearly with protomeric enzyme whose high affinity ATP site has been blocked covalently with fluorescein isothiocyanate. We conclude that nucleotides can bind at two discrete sites in each protomeric unit of Na,K-ATPase.

Irreversible effects of calcium ions on the plasma membrane calcium pump.

The calcium pump of human red cells can be irreversibly activated by preincubation of the membranes in the presence of calcium ions, with a pattern reminiscent of that produced by controlled trypsin attack. With 1 mM Ca2+, the activity of the basal enzyme increases three to fourfold over 30 to 60 min, to levels about half those obtained in the presence of calmodulin. On the whole, the effect occurs slowly, with a very low Ca2+ affinity at 37 degrees C and is unaffected by serine-protease inhibitors. The activation caused by 1 mM Ca2+ is little affected by leupeptin (a thiol-protease inhibitor) and that obtained at 10 microM Ca2+ is not inhibited. Preincubations at 0 degrees C also lead to activation, to a level up to half that seen at 37 degrees C, and the effect is not affected by leupeptin or antipain. No activation is observed by preincubating soluble purified Ca,Mg-ATPase in Ca(2+)-containing solutions at 37 degrees C. Instead, calcium ions protect the detergent-solubilized enzyme from thermal inactivation, the effect being half-maximal between 10 and 20 microM Ca2+. We conclude that the activation of the membrane-bound Ca,Mg-ATPase by Ca2+ should result from an irreversible conformational change in the enzyme and not from attack by a membrane-bound protease, and that this change presumably arises from the release of inhibitory particles existing in the original membrane preparations.

Solubilized alpha beta Na,K-ATPase remains protomeric during turnover yet shows apparent negative cooperativity toward ATP.

A prominent feature of the Na,K-ATPase reaction is an ATP dependence that suggests high- and low-affinity ATP requirements during the enzymic cycle. As only one ATP-binding domain has been identified in the alpha subunit and none has been identified in the beta subunit, it has seemed likely that the apparent negative cooperativity results from subunit interactions in an (alpha beta)2 diprotomer. To test this possibility, we have examined the behavior of solubilized alpha beta protomers of Na,K-ATPase down to 50 nM [gamma-32P]ATP. Active-enzyme analytical ultracentrifugation shows that the protomer is the active species and that no oligomerization occurs during turnover. However, we find that dual ATP effects can be clearly demonstrated and that nonhydrolyzable ATP analogs can stimulate the Na,K-ATPase activity of the soluble protomer. We conclude that the apparent negative cooperativity is inherent to the alpha beta protomer and that this should explain some of the complexities found with membrane-bound Na,K-ATPase and, perhaps, other P-type cation pumps.

The molecular size required varies according to the reaction step round the sodium pump cycle.

Progress along the path of the sodium pump cycle requires a stepwise recruitment of additional subunits for maximal activity. These results show that whereas a particle the size of the alpha beta protomer presents Na+,K+-ATPase activity at 10 microM ATP, an additional subunit, perhaps a second alpha-chain, is required to obtain the much greater Na+,K+-ATPase activity resulting from the occupation of low-affinity ATP sites at physiological ATP concentrations. A non-phosphorylating ATP analogue, however, will modestly stimulate the Na+,K+-ATPase activity acting at an alternative low-affinity site or step on the alpha beta protomer.

Fast reversal of the initial reaction steps of the plasma membrane (Ca2+ + Mg2+)-ATPase.

Calmodulin-depleted red cell membranes catalyse a Ca2+, Mg2+-dependent ATP-[3H]ADP exchange at 37 degrees C. The Ca2+, Mg2+-dependent exchange, measured at 20 microM CaCl2, 1.5 mM MgCl2, 1.5 mM ADP and 1.5 mM ATP, is comparable to the (Ca2+ + Mg2+)-ATPase activity, between 0.3 and 0.8 mmol/litre original cells per h. EDTA-washed membranes present a Ca2+-dependent ATP-ADP exchange whose rate is not more than 7% of that found in a Mg2+-containing medium, while their Ca2+-dependent ATPase is essentially zero. Addition of 1.5 mM MgCl2 to the medium restores both activities to the levels found with membranes not treated with EDTA. Calmodulin (16 micrograms/ml) produces an eight-fold stimulation of the Ca2+-dependent ATP-ADP exchange, slightly less than it stimulates the Ca2+-dependent ATP hydrolysis. The effect of 1.5 mM MgCl2 on the exchange is greater in the presence than in the absence of calmodulin. It is proposed that the reversal of the initial phosphorylation of the Ca2+ pump, occurring at a fast rate at 37 degrees C, involves a conformational change in the phosphoenzyme. Thus, it would be an ADP-liganded phosphoenzyme of the form EP(ADP) that would experience the fast conformational transition at 37 degrees C. The great difficulty in producing an overall reversal of the Ca2+ pump should then be due to one or more reaction steps later than and including Ca2+ release and dephosphorylation.

Calmodulin and the target size of the (Ca2+ + Mg2+)-ATPase of human red-cell ghosts.

An average target size of 251 kDa has been obtained for the (Ca2+ + Mg2+)-ATPase of calmodulin-depleted erythrocyte ghosts by radiation inactivation with 16 MeV electrons. This is close to twice the size of the purified calcium-pump polypeptide. When calmodulin was included during the ATPase assay, a component of about 1 MDa appeared in addition to the activated dimer.

Sodium-sodium exchange through the sodium pump: the roles of ATP and ADP.

1. We have developed a procedure for preparing resealed red cell ghosts that contain ADP but very little ATP. 2. The procedure involves (i) lysis of the cells in a very large volume of lysing solution, (ii) resuspension of the ghosts in a small volume, (iii) the incorporation into the ghosts, before they are resealed, of the adenylate kinase inhibitor P1,P5-di(adenosine-5'-)pentaphosphate (AP5A) and of hexokinase, and (iv) the removal of traces of ATP, formed by residual adenylate kinase activity, by the addition of glucose. 3. Measurements of sodium efflux from ghosts prepared in this way show that sodium-sodium exchange through the sodium pump does not occur in the absence of ATP even if ADP is present. 4. The beta:gamma imido analogue of ATP (AMP.PNP), which is incapable of phosphorylating sodium, potassium-ATPase, cannot replace ATP in supporting sodium-sodium exchange. 5. These findings support the hypothesis that the outward movement of sodium ions through the sodium pump is associated with the transfer of a phosphoryl group from ATP to the enzyme, and that the inward movement of sodium ions through the pump is associated with the return of a phosphoryl group from the phosphoenzyme to ADP.

The interaction of monovalent cations with the sodium pump of low-potassium goat erythrocytes.

1. The activation by Na ions and the effect of the anti-L antibody on the sodium pump of low-potassium type (LK) erythrocytes, have been studied by measuring ouabain-sensitive ATPase activity of red cell membranes of LK goats. The experimental data were first corrected for incomplete occupation of the external K sites of the pump, using a saturation function obtained from influx experiments.2. Double-reciprocal plots of the corrected rates against Na concentration at various fixed K concentrations, yield a pattern of competitive K inhibition when it is assumed that three equivalent sodium sites take part in the internal activation of LK-(Na+K)-ATPase. The dissociation constant of Na at each site (K(m)) lies between 10 and 20 mM and that of K as competitive inhibitor (K(i)), between 1.5 and 4.5 mM.3. The maximal rate of hydrolysis of LK goat (Na + K)-ATPase is not different from those usually obtained with the high-potassium type (HK) red cell enzyme. Then, the low pumping rate of LK erythrocytes in physiological conditions is only reflecting the poor Na affinity, both absolute and relative, at the internal Na sites of their sodium pumps.4. The stimulation of the ouabain-sensitive ATPase activity by sensitization of the membranes with anti-L serum, is mediated by a threefold reduction of the K(m)/K(i) ratio at each site. K(m) decreases by a factor of 10, but there is also a smaller diminution of K(i). The maximal rate of hydrolysis, however, is unchanged by the anti-L treatment. The least-squares fitting of the pooled data by the rate equation, converges better with less than three and more than two equivalent sodium sites.5. The affinity sequence at two external K sites of the LK goat erythrocyte sodium pump, determined in the presence of 100 mM external Na, is Rb > K > Cs. It is obtained from the concentration dependence in influx experiments, and is the same as reported for human red cells.6. Cubic-root Dixon plots of the corrected ouabain-sensitive ATPase activity against the concentration of K and its congeners, show the sequence Tl > K > Rb > Na > Cs for the affinities at the internal cation sites of the LK sodium pump. Anti-L treatment decreases the relative magnitude of Na and Cs selectivities, it being not certain whether a Rb-Na transition then occurs.7. The results are discussed in terms of possible mechanisms whereby the sodium pump of LK and HK red cells may adjust the properties of their cation sites upon translocation of monovalent cations.

Thallium and the sodium pump in human red cells.

1. Thallium (Tl) inhibits the ouabain-sensitive K influx in human red cells in high-Na medium. At 1 mM external K concentration [K(o)], the ouabain-sensitive K influx decreases steadily with increasing Tl concentration, up to 0.9 mM outside; at 0.17 mM-K(o), however, Tl stimulates the ouabain-sensitive K influx below 0.1 mM-Tl(o) and inhibits it at higher concentrations.2. In a K-free medium in which all except 5 mM-Na is replaced by choline, and into which red cells show zero control ouabain-sensitive Na efflux, Tl is able to support ouabain-sensitive Na efflux up to 2.1 m-mole/l. cells.hr following a sigmoid activation curve which is half-maximal between 0.03 and 0.05 mM-Tl(o) and that follows two-site kinetics up to 0.1 mM-Tl(o). Beyond 0.15 mM-Tl(o), the Tl-activated ouabain-sensitive Na efflux attained is inhibited slightly.3. When the ouabain-sensitive Na efflux is measured at 5 mM-Na(o) and 5 mM-K(o), increasing concentrations of Tl have little effect on it, 0.9 mM-Tl(o) inhibiting by some 14%; in similar conditions, the ouabain-sensitive K influx is inhibited by about 40%.4. The dependence of ouabain-sensitive K influx on external K concentration at 5 mM-Na(o), which follows a slightly sigmoid curve in the absence of Tl, changes to hyperbolic at 0.06 mM-Tl(o) at the same time that ouabain-sensitive K influx is inhibited. The fitted V(max) values for ouabain-sensitive K influx are the same in the presence and in the absence of 0.06 mM-Tl(o).5. In high-Na cells, loaded by nystatin treatment, the ouabain-sensitive K influx measured at 0.2 mM-Na(o) follows a hyperbolic curve between 0.05 and 0.4 mM-K(o), and is inhibited by Tl in a strictly competitive fashion.6. The effects of Tl on ouabain-sensitive Na efflux and ouabain-sensitive K influx are interpreted in terms of a high-affinity substitution for K at the external K sites of the Na pump and suggest that in human red cells Tl can be actively transported inwards in exchange for internal Na.7. Thallium can inhibit about 25% of the ouabain-insensitive Na efflux into 5 mM-Na(o) and part of this inhibition occurs with a high Tl-affinity; the ouabain-insensitive K influx is inhibited by Tl both in high-Na and in 5 mM-Na medium, but with a different concentration dependence than the ouabain-insensitive Na efflux.