Effect on the equilibrium between the Na+-form and the K+-form of the (Na+ + K+)-ATPase of modification of the enzyme with pyridoxal 5-phosphate

An increase in pH shifts the equilibrium between the K+-form and the Na+-form of the (Na+ + K+)-ATPase towards the Na+-form. pK for the proton effect on the equilibrium is decreased by modification of the enzyme with pyridoxal 5-phosphate. The reactivity of the enzyme towards pyridoxal 5-phosphate is increased by an increase in pH. Modification by pyridoxal 5-phosphate of epsilon-amino groups on lysine, which has a pK of about 8 with the enzyme in the K+-form and of about 7.4 in the Na+-form, shifts the equilibrium between E1Na+ and E2 towards E2, and the equilibrium between E2(K+occ) and E2 towards E2, but has no effect on the overall equilibrium between E1Na+ and E2(K+occ). An additional modification of epsilon-amino groups on lysine, which has a pK of 9.5-10 with the enzyme in the K+-form and of about 7.7 with the enzyme in the Na+-form, shifts the equilibrium between E2(K+occ) and E1Na+ towards E1Na+; this is due to a shift in the equilibrium between E2(K+occ) and E2 towards E2, but with no effect on the equilibrium between E1Na+ and E2. The results show that the transition from the K+-form to the Na+-form decreases the pK of lysine epsilon-amino groups on the enzyme, and that the protonation of these groups influences the equilibrium between the two conformations.     

The effect of K+ on the equilibrium between the E2 and the K+-occluded E2 conformation of the (Na+ + K+)-ATPase

The rate of the transition from the E2 form to the E1 form of (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) has been monitored by the fluorescence changes of eosin. The equilibrium between E1 and E2 is poised towards E2 in the absence of added cations. A stopped-flow tracing of the transition from E2 in the presence of 2 microM K+ (contamination) to E1 (in 150 mM Na+) is multiexponential with a large, rapidly decaying component (t 1/2 about 50 ms) and a smaller component which has a t 1/2 of about 2 s. KCl in microM concentrations decreases the amplitude of the rapidly decaying component and increases the amplitude of the slow component. The stopped-flow tracings can be satisfactorily fitted by a sum of three exponentials. An apparent Kd for K+ of about 5 microM is obtained for the conversion of the rapidly decaying component to the slowly decaying component. The experiments show that the E2 form is a mixture of at least two enzyme conformations. One E2 conformation - without K+ bound, (E2) - is transferred rapidly to the E1 conformation when Na+ is added, whereas the other E2-conformation--with K+ bound with an apparent high affinity, Kocc E2--is transferred slowly to the E1 conformation.     

Defective conformational response in a selectively trypsinized (Na+ + K+)-ATPase studied with tryptophan fluorescence

1. Monitoring protein conformations of purified (Na+ + K+)-ATPase with intrinsic fluorescence we have examined if altered conformational responses accompany the defective catalytic and transport processes in selectively modified 'invalid' (Na+ + K+)-ATPase which is obtained by graded tryptic digestion of the Na+ form of the protein. 2. The protein fluorescence intensity of the K+ form (E2K) of both control and invalid (Na+ + K+)-ATPase is 2--3% higher than that of the Na+ form (E1Na). By varying the NaCl concentration we found evidence for different fluorescence intensities of the two phosphoenzymes; E2P has the same fluorescence intensity as E2K and the intensity of E1P is similar to that of E1Na. The fraction of phosphoenzyme present as E2P can therefore be determined as the amplitude of the fluorescence change accompanying phosphorylation in the absence of K+ divided by the amplitude of the full response to K+. 3. Titration of the fluorescence responses of the invalid (Na+ + K+)-ATPase shows that the tryptic split alters the noise of the equilibria between the cation-bound conformations, E1Na and E2K, and between the phosphoforms, E1P and E2P, in the direction of the E1 forms. 4. Vanadate binds to the Mg2+-bound form of E2K and prevents further changes in fluorescence intensity of the protein. The conformative responses of invalid (Na+ + K+)-ATPase are insensitive to vanadate in agreement with the reduced vanadate binding affinity of this enzyme. 5. The defective conformative response of the invalid (Na+ + K+)-ATPase in relation to its catalytic defects, reduced Na+ transport, and insensitivity to vanadate suggest that the transitions between Na+ forms (E1) and K+ forms (E2) of the protein are coupled to the catalytic and transport reactions of the (Na+ + K+)-pump.     

A kinetic model for the Ca2+ + Mg2+-activated ATPase of sarcoplasmic reticulum.

The Ca2+ + Mg2+-activated ATPase of sarcoplasmic reticulum exhibits complex kinetics of activation with respect to ATP. ATPase activity is pH-dependent, with similar pH-activity profiles at high and low concentrations of ATP. Low concentrations of Ca2+ in the micromolar range activate the ATPase, whereas activity is inhibited by Ca2+ at millimolar concentrations. The pH-dependence of this Ca2+ inhibition and the effect of the detergent C12E8 (dodecyl octaethylene glycol monoether) on Ca2+ inhibition are similar to those observed on activation by low concentrations of Ca2+. On the basis of these and other studies we present a kinetic model for the ATPase. The ATPase is postulated to exist in one of two conformations: a conformation (E1) of high affinity for Ca2+ and MgATP and a conformation (E2) of low affinity for Ca2+ and MgATP. Ca2+ binding to E2 and to the phosphorylated form E2P are equal. Proton binding at the Ca2+-binding sites in the E1 and E2 conformations explains the pH-dependence of Ca2+ effects. Binding of MgATP to the phosphorylated intermediate E1'PCa2 and to E2 modulate the rates of the transport step E1'PCa-E2'PCa2 and the return of the empty Ca2+ sites to the outside surface of the sarcoplasmic reticulum, as well as the rate of dephosphorylation of E2P. Only a single binding site for MgATP is postulated.     

Tryptophan fluorescence of (Na+ + K+)-ATPase as a tool for study of the enzyme mechanism.

1. The protein fluorescence intensity of (Na+ + K+)-ATPase is enhanced following binding of K+ at low concentrations. The properties of the response suggest that one or a few tryptophan residues are affected by a conformational transition between the K-bound form E2 . (K) and a Na-bound form E1 . Na. 2. The rate of the conformational transition E2 . (K) leads to E . Na has been measured with a stopped-flow fluorimeter by exploiting the difference in fluorescence of the two states. In the absence of ATP the rate is very slow, but it is greatly accelerated by binding of ATP to a low affinity site. 3. Transient changes in tryptophan fluorescence accompany hydrolysis of ATP at low concentrations, in media containing Mg2+, Na+ and K+. The fluorescence response reflects interconversion between the initial enzyme conformation, E1 . Na and the steady-state turnover intermediate E2 . (K). 4. The phosphorylated intermediate, E2P can be detected by a fluorescence increase accompanying hydrolysis of ATP in media containing Mg2+ and Na+ but no K+. 5. The conformational states and reaction mechanism of the (Na+ + K+)-ATPase are discussed in the light of this work. The results permit a comparison of the behaviour of the enzyme at both low and high nucleotide concentrations.     

Sodium ion discharge from pig kidney Na+, K+-ATPase Na+-dependency of the E1P-E2P equilibrium in the absence of KCl

The two phosphoenzymes (E1P and E2P) of Na+,K+-ATPase were measured as ADP-sensitive and K+-sensitive fractions. The sum of these fractions was nearly 1 in the range of 50 to 1,200 mM NaCl. The effects of Na+ on the levels of E1P and E2P, on the rate constant of E2P leads to E1P transition (k2), on the rate constant of E2P dephosphorylation (k3), on the rate constant of E1P leads to E2P transition (k1) and on the apparent equilibrium constant between E1P and E2P (Kapp) were examined. k1 was found to decrease with increasing Na+ concentration, whereas k2 increased. Kapp was found to be directly proportional to the third power of Na+ concentration. k3 increased with increasing Na+ concentration and saturated at about 1 M NaCl. These results are consistent with a simple model in which ATP hydrolysis occurs through effectively only two phosphoenzyme intermediates in the absence of K+ and three sodium ions are discharged cooperatively from the enzyme during the E1P leads to E2P conversion.     

A model for the phosphorylation of the Ca2+ + Mg2+-activated ATPase by phosphate.

We have shown that changes in fluorescence intensity for the Ca2+ + Mg2+-activated ATPase of sarcoplasmic reticulum labelled with fluorescein isothiocyanate following the addition of Ca2+ can give the ratio of the two conformations (E1 and E2) of the ATPase. We show that the fluorescence response to Ca2+ is unaffected by Mg2+, phosphate or K+, implying that these ions bind equally well to the E1 and E2 conformations. A model is presented for phosphorylation of the ATPase by phosphate as a function of pH, Mg2+, K+ and Ca2+.     

Kinetics of Na+-ATPase: influence of Na+ and K+ on substrate binding and hydrolysis

An analysis of the influence of Na+ and K+ on the kinetics of Na+-ATPase in broken membrane preparations from bovine brain is presented with particular emphasis on the effect of the cations on the binding and splitting of the substrate MgATP and on the derivation of a detailed kinetic model for that interaction. It was found that the enzyme in the absence of Na+ and K+, but in the presence of 7 mM free Mg2+, at pH 7.4 (37 degrees C) exhibits an ouabain-sensitive ATPase activity. The simplest model quantitatively compatible with all the data involves two different, interconvertible (conformational) forms of the enzyme, E1 and E'1, with the following properties: The E1 form does not bind K+ but has three independent and equivalent high-affinity sites (Kd = 5.6 mM) for Na+. It binds and hydrolyzes substrate only when two or three sodium ions are bound to it. The E'1 form binds and hydrolyzes the substrate only in the absence of monovalent cations. It is competitively inhibited by K+ (Kd = 0.23 mM), and this inhibition is further enhanced by binding of Na+ to the K+-bound form at two equivalent, independent sites (Kd = 12 mM). It is suggested that the E'1 form is the Mg2+-induced conformational state of the enzyme observed by others, which differs from the usually encountered E1 and E2 forms. The model allows the calculation of ATP-binding and ADP-releasing rate constants for the E1-form for later comparison with corresponding rate constants for the (na+ + K+)-ATPase (following paper).     

The mechanism of inhibition of the Ca2+-ATPase by mastoparan. Mastoparan abolishes cooperative ca2+ binding.

The amphiphilic peptide mastoparan, isolated from wasp venom, is a potent inhibitor of the sarcoplasmic reticulum Ca2+-ATPase. At pH 7. 2, ATPase activity is inhibited with an inhibitory constant (Ki) of 1 +/- 0.13 microM. Mastoparan shifts the E2-E1 equilibrium toward E1 and may affect the regulatory ATP binding site. The peptide also decreases the affinity of the ATPase for Ca2+ and abolishes the cooperativity of Ca2+ binding. In the presence of mastoparan, the two Ca2+ ions bind independently of one another. Our results appear to support the model that describes the relationship between the two Ca2+ binding sites as "side-by-side," because this model allows the possibility of independent Ca2+ entry to the two sites. Mastoparan shifts the steady-state equilibrium between E1'Ca2 and E1'Ca2.P toward E1'Ca2.P, by possibly affecting the conformational change that follows ATP binding. The peptide also causes a reduction in the levels of phosphoenzyme formed from [32P]Pi. Some analogues of mastoparan were also tested and were found to cause inhibition of the Ca2+-ATPase in the range of 2-4 microM. The inhibitory action of mastoparan and its analogues appears dependent on their ability to form alpha-helices in membranes.     

Conformational transitions between Na+-bound and K+-bound forms of (Na+ + K+)-ATPase, studied with formycin nucleotides.

1. Fluorescence measurements have shown that formycin triphosphate (FTP) or formycin diphosphate (FDP) bound to (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) in Na+-containing media can be displaced by the following ions (listed in order of effectiveness): Tl+, K+, Rb+, NH4+, Cs+. 2. The differences between the nucleotide affinities displayed by the enzyme in predominantly Na+ and predominantly K+ media in the absence of phosphorylation, are thought to reflect changes in enzyme conformation. These changes can therefore be monitored by observing the changes in fluorescence that accompany net binding or net release of formycin nucleotides. 3. The transition from a K+-bound form (E2-(K)) to an Na+-bound form (E1-Na) is remarkably slow at low nucleotide concentrations, but is accelerated if the nucleotide concentration is increased. This suggests that the binding of nucleotide to a low-affinity site on E2-(K) accelerates its conversion to E1-Na; it supports the hypothesis that during the normal working of the pump, ATP, acting at a low affinity site, accelerates the conversion of dephosphoenzyme, newly formed by K+-catalysed hydrolysis of E2P, to a form in which it can be phosphorylated in the presence of Na+. 4. The rate of the reverse transformation, E1-Na to E2-(K), varies roughly linearly with the K+ concentration up to the highest concentration at which the rate can be measured (15 mM). Since much lower concentrations of K+ are sufficient to displace the equilibrium to the K-form, we suggest that the sequence of events is: (i) combination of K+ with low affinity (probably internal) binding sites, followed by (ii) spontaneous conversion of the enzyme to a form, E2-(K), containing occluded K+. 5. Mg2+ or oligomycin slows the rate of conversion of E1-Na to E2-(K) but does not significantly affect the rate of conversion of E2-(K) to E1-Na. 6. In the light of these and previous findings, we propose a model for the sodium pump in which conformational changes alternate with trans-phosphorylations, and the inward and outward fluxes of both Na+ and K+ each involve the transfer of a phosphoryl group as well as a change in conformation between E1 and E2 forms of the enzyme or phosphoenzyme.     

The sided action of Na+ and of K+ on reconstituted shark (Na+ + K+)-ATPase engaged in Na+-Na+ exchange accompanied by ATP hydrolysis. I. The ATP activation curve

The ATP hydrolysis dependent Na+-Na+ exchange of reconstituted shark (Na+ + K+)-ATPase is electrogenic with a transport stoichiometry as for the Na+-K+ exchange, suggesting that translocation of extracellular Na+ is taking place via the same route as extracellular K+. The preparation thus offers an opportunity to compare the sided action of Na+ and K+ on the affinity for ATP in a reaction in which the intermediary steps in the overall reaction seems to be the same without and with K+. With Na+ but no K+ on the two sides of the enzyme, the ATP-activation curve is hyperbolic and the affinity for ATP is high. Extracellular K+ in concentrations of 50 microM (the lowest tested) and up gives biphasic ATP activation curves, with both a high- and a low-affinity component for ATP. Cytoplasmic K+ also gives biphasic ATP-activation curves, however, only when the K+ concentration is 50 mM or higher (Na+ + K+ = 130 mM). The different ATP-activation curves are explained from the Albers-Post scheme, in which there is an ATP-dependent and an ATP-independent deocclusion of E2(Na2+) and E2(K2+), respectively, and in which the dephosphorylation of E2-P is rate limiting in the presence of Na+ (but no K+) extracellular, whereas in the presence of extracellular K+ it is the deocclusion of E2(K2+) which is rate limiting.     

A model for the reaction pathways of the K+-dependent phosphatase activity of the (Na+ + K+)-dependent ATPase

(Na+ + K+)-dependent ATPase preparations from rat brain, dog kidney, and human red blood cells also catalyze a K+ -dependent phosphatase reaction. K+ activation and Na+ inhibition of this reaction are described quantitatively by a model featuring isomerization between E1 and E2 enzyme conformations with activity proportional to E2K concentration: (formula; see text) Differences between the three preparations in K0.5 for K+ activation can then be accounted for by differences in equilibria between E1K and E2K with dissociation constants identical. Similarly, reductions in K0.5 produced by dimethyl sulfoxide are attributable to shifts in equilibria toward E2 conformations. Na+ stimulation of K+ -dependent phosphatase activity of brain and red blood cell preparations, demonstrable with KCl under 1 mM, can be accounted for by including a supplementary pathway proportional to E1Na but dependent also on K+ activation through high-affinity sites. With inside-out red blood cell vesicles, K+ activation in the absence of Na+ is mediated through sites oriented toward the cytoplasm, while in the presence of Na+ high-affinity K+ -sites are oriented extracellularly, as are those of the (Na+ + K+)-dependent ATPase reaction. Dimethyl sulfoxide accentuated Na+ -stimulated K+ -dependent phosphatase activity in all three preparations, attributable to shifts from the E1P to E2P conformation, with the latter bearing the high-affinity, extracellularly oriented K+ -sites of the Na+ -stimulated pathway.     

Small conductance Ca2+-activated K+ channels and calmodulin: cell surface expression and gating

Small conductance Ca2+-activated K+ channels (SK channels) are heteromeric complexes of pore-forming alpha subunits and constitutively bound calmodulin (CaM). The binding of CaM is mediated in part by the electrostatic interaction between residues Arg-464 and Lys-467 of SK2 and Glu-84 and Glu-87 of CaM. Heterologous expression of the double charge reversal in SK2, SK2 R464E/K467E (SK2:64/67), did not yield detectable surface expression or channel activity in whole cell or inside-out patch recordings. Coexpression of SK2:64/67 with wild type CaM or CaM1,2,3,4, a mutant lacking the ability to bind Ca2+, rescued surface expression. In patches from cells coexpressing SK2:64/67 and wild type CaM, currents were recorded immediately following excision into Ca2+-containing solution but disappeared within minutes after excision or immediately upon exposure to Ca2+-free solution and were not reactivated upon reapplication of Ca2+-containing solution. Channel activity was restored by application of purified recombinant Ca2+-CaM or exposure to Ca2+-free CaM followed by application of Ca2+-containing solution. Coexpression of the double charge reversal E84R/E87K in CaM (CaM:84/87) with SK2:64/67 reconstituted stable Ca2+-dependent channel activity that was not lost with exposure to Ca2+-free solution. Therefore, Ca2+-independent interactions with CaM are required for surface expression of SK channels, whereas the constitutive association between the two channel subunits is not an essential requirement for gating.     

Difference between neuronal and nonneuronal (Na+ + K+)-ATPases in their conformational equilibrium

Several experiments were carried out to study the difference between two isozymes (alpha(+) and alpha) of (Na+ + K+)-ATPase in the conformational equilibrium. Rat brain (Na+ + K+)-ATPase was much more thermolabile than the kidney enzyme. Both enzymes were protected from heat inactivation not only by Na+ and K+, but also by choline in varying degrees, though there was a difference between the two enzymes in the protection by the ligands. The brain enzyme was partially protected from N-ethylmaleimide (NEM) inactivation by both Na+ and K+, but the effects of the ligands on NEM inactivation of the kidney enzyme were more complex. Though ligands differentially affected the thermostability and NEM sensitivity of the two enzymes, the effects were not simply related to the conformational states. The sensitivity of phosphoenzyme (EP) formed in the presence of ATP, Na+, and Mg2+ to ADP or K+ and K+-p-nitrophenyl phosphatase (pNPPase) was then studied as a probe of the differences in the conformational equilibrium between the two isozymes. The EP of the brain enzyme was partially sensitive to ADP, while those of the heart and kidney enzymes were not. At physiological Na+ concentrations the percentages of E1P formed by the brain and kidney enzymes were determined to be about 40-50 and 10-20% of the total EP, respectively. The hydrolytic activity of pNPP in the presence of Li+, a selective activator at catalytic sites of the reaction, was much higher in the kidney enzyme than in the brain enzyme. The inhibition of K+-stimulated pNPPase by ATP and Na+ was greater in the latter enzyme than in the former. These results suggest that neuronal and nonneuronal (Na+ + K+)-ATPases differ in their conformational equilibrium: the E1 or E1P may be more stable in the alpha(+) than in the alpha during the turnover, and conversely the E2 or E2P may be more stable in the latter than in the former.     

Cytoplasmic K+ effects on phosphoenzyme of Na,K-ATPase proteoliposomes and on the Na+-pump activity

Three phosphorylated reaction intermediates (EP) of Na,K-ATPase, and ADP-sensitive K+-insensitive EP (E1P), an ADP- and K+-sensitive EP (E*P), and a K+-sensitive ADP-insensitive EP (E2P), have been discovered at present. By using Na,K-ATPase proteoliposomes (PL) prepared from the electric eel enzyme, we found in this study that E*P existed even in the presence of K+ on both sides of the PL and that there was a sidedness difference in K+ sites between E*P and E2P. Cytoplasmic K+ (K+cyt) accelerated the conversion of E*P to E2P but did not dephosphorylate the E2P. Although the extracellular K+ accelerated the dephosphorylation of E2P, it did not interact with E*P directly. This K+cyt effect was also verified by the activation of Na+-pump in the Na+-K+ exchange mode. In the presence of K+cyt, both the ATP hydrolysis and Na+ uptake rates of the PL containing K+ inside vesicles increased sigmoidally with the concentrations of ATP and cytoplasmic Na+ (Na+cyt). However, in the absence of K+cyt, these Na+-pump reactions in PL containing K+ inside vesicles had only a hyperbolic curve. These results imply that the E*P to E2P conversion is one of the rate-limiting steps of the Na+-pump in the presence of a high concentration of ATP and that K+cyt may control this reaction step by enhancing the conversion rate of E*P to E2P.     

Tryptic and chymotryptic cleavage sites in sequence of alpha-subunit of (Na+ + K+)-ATPase from outer medulla of mammalian kidney

Localization of selective proteolytic splits in alpha-subunit of (Na+ + K+)-ATPase is important for understanding the mechanism of active Na+,K+-transport. Proteolytic fragments of alpha-subunit from pig kidney were purified by chromatography in NaDodSO4 on TSK 3000 SW columns. NH2-terminal amino acid sequences of fragments as determined in a gas phase sequenator were unambiguously located within the total sequence of alpha-subunit from sheep kidney (Shull, C.E., et al. (1985) Nature 316, 691-695) and pig kidney (Ovchinnikov, Y.A., et al. (1985) Proc. Acad. Sci. USSR 285, 1490-1495). The primary chymotryptic split in the E1-form is located between Leu-266 and Ala-267 while the tryptic cleavage site appears to be between Arg-262 and Ile-263 (Bond 3). Tryptic cleavage in the initial fast phase of inactivation of the E1-form is located between Lys-30 and Glu-31 (Bond 2). In the E2-form, primary tryptic cleavage is between Arg-438 and Ala-439 (Bond 1). Chymotryptic cleavage between Leu-266 and Ala-267 stabilizes the E1-form of the protein without affecting the sites for binding of cations or nucleotides. Titration of fluorescence responses demonstrates the importance of the NH2-terminal for E1-E2 transition. Protonation of His-13 facilitates transition from E1- to E2-forms of the protein. Removal of His-13 after cleavage of bond 2 can explain the increase in apparent affinity of the cleaved enzyme for Na+ and the shift in poise of E1-E2 equilibrium in direction of E1-forms. The NH2-terminal sequence in renal alpha-subunit is not conserved in alpha + from rat neurolemma or in alpha-subunit from Torpedo or brine shrimp. A regulatory function of the NH2-terminal part of the alpha-subunit may thus be a unique feature of the alpha-subunit in (Na+ + K+)-ATPase from mammalian kidney.     

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.     

Conformational transitions in the Ca2+ + Mg2+-activated ATPase and the binding of Ca2+ ions.

We have studied the fluorescence of the Ca2+ + Mg2+-activated ATPase of sarcoplasmic reticulum labelled with fluorescein isothiocyanate. The change in intensity of fluorescein fluorescence caused by addition of Ca2+ to the labelled ATPase can be interpreted in terms of a two-conformation model for the ATPase, one conformation (E1) having a high affinity for Ca2+, the other (E2) a low affinity. Effects of Ca2+ as a function of pH allow an estimate of the effect of pH on the E1/E2 ratio, consistent with kinetic studies. A model is presented for binding of Ca2+ to the ATPase as a function of pH that is consistent both with the data on the E1/E2 equilibrium and with literature data on Ca2+ binding.     

Ligand-dependent reactivity of (Na+ + K+)-ATPase with showdomycin

Showdomycin inhibited pig brain (Na+ + K+)-ATPase with pseudo first-order kinetics. The rate of inhibition by showdomycin was examined in the presence of 16 combinations of four ligands, i.e., Na+, K+, Mg2+ and ATP, and was found to depend on the ligands added. Combinations of ligands were divided into five groups in terms of the magnitude of the rate constant; in the order of decreasing rate constants these were: (1) Na+ + Mg2+ + ATP, (2) Mg2+, Mg2+ + K+, K+ and none, (3) Na+ + Mg2+, Na+, K+ + Na+ and Na+ + K+ + Mg2+, (4) Mg2+ + K+ + ATP, K+ + ATP and Mg2+ + ATP, (5) K+ + Na + + ATP, Na+ + ATP, Na+ + K+ + Mg2+ + ATP and ATP. The highest rate was obtained in the presence of Na+, Mg2+ and ATP. The apparent concentrations of Na+, Mg2+ and ATP for half-maximum stimulation of inhibition (KS0.5) were 3 mM, 0.13 mM and 4 MicroM, respectively. The rate was unchanged upon further increase in Na+ concentration from 140 to 1000 mM. The rates of inhibition could be explained on the basis of the enzyme forms present, including E1, E2, ES, E1-P and E2-P, i. e., E2 has higher reactivity with showdomycin than E1, while E2-P has almost the same reactivity as E1-P. We conclude that the reaction of (Na+ + K+)- ATPase proceeds via at least four kinds of enzyme form (E1, E2, E1 . nucleotide and EP), which all have different conformations.     

Ca2+ Binding to Site I of the Cardiac Ca2+ Pump Is Sufficient to Dissociate Phospholamban

Phospholamban (PLB) inhibits the activity of SERCA2a, the Ca²⁺-ATPase in cardiac sarcoplasmic reticulum, by decreasing the apparent affinity of the enzyme for Ca²⁺. Recent cross-linking studies have suggested that PLB binding and Ca²⁺ binding to SERCA2a are mutually exclusive. PLB binds to the E2 conformation of the Ca²⁺-ATPase, preventing formation of E1, the conformation that binds two Ca²⁺ (at sites I and II) with high affinity and is required for ATP hydrolysis. Here we determined whether Ca²⁺ binding to site I, site II, or both sites is sufficient to dissociate PLB from the Ca²⁺ pump. Seven SERCA2a mutants with amino acid substitutions at Ca²⁺-binding site I (E770Q, T798A, and E907Q), site II (E309Q and N795A), or both sites (D799N and E309Q/E770Q) were made, and the effects of Ca²⁺ on N30C-PLB cross-linking to Lys³²⁸ of SERCA2a were measured. In agreement with earlier reports with the skeletal muscle Ca²⁺-ATPase, none of the SERCA2a mutants (except E907Q) hydrolyzed ATP in the presence of Ca²⁺; however, all were phosphorylatable by P_i to form E2P. Ca²⁺ inhibition of E2P formation was observed only in SERCA2a mutants retaining site I. In cross-linking assays, strong cross-linking between N30C-PLB and each Ca²⁺-ATPase mutant was observed in the absence of Ca²⁺. Importantly, however, micromolar Ca²⁺ inhibited PLB cross-linking only to mutants retaining a functional Ca²⁺-binding site I. The dynamic equilibrium between Ca²⁺ pumps and N30C-PLB was retained by all mutants, demonstrating normal regulation of cross-linking by ATP, thapsigargin, and anti-PLB antibody. From these results we conclude that site I is the key Ca²⁺-binding site regulating the physical association between PLB and SERCA2a.