ADP-insensitive EP Research Articles

Deletions of Any Single Residues in Glu40-Ser48 Loop Connecting A Domain and the First Transmembrane Helix of Sarcoplasmic Reticulum Ca2+-ATPase Result in Almost Complete Inhibition of Conformational Transition and Hydrolysis of Phosphoenzyme Intermediate

Possible roles of the Glu40-Ser48 loop connecting A domain and the first transmembrane helix (M1) in sarcoplasmic reticulum Ca(2+)-ATPase (SERCA1a) were explored by mutagenesis. Deletions of any single residues in this loop caused almost complete loss of Ca(2+)-ATPase activity, while their substitutions had no or only slight effects. Single deletions or substitutions in the adjacent N- and C-terminal regions of the loop (His32-Asn39 and Leu49-Ile54) had no or only slight effects except two specific substitutions of Asn39 found in SERCA2b in Darier's disease pedigrees. All the single deletion mutants for the Glu40-Ser48 loop and the specific Asn39 mutants formed phosphoenzyme intermediate (EP) from ATP, but their isomeric transition from ADP-sensitive EP (E1P) to ADP-insensitive EP (E2P) was almost completely or strongly inhibited. Hydrolysis of E2P formed from Pi was also dramatically slowed in these deletion mutants. On the other hand, the rates of the Ca(2+)-induced enzyme activation and subsequent E1P formation from ATP were not altered by the deletions and substitutions. The results indicate that the Glu40-Ser48 loop, with its appropriate length (but not with specific residues) and with its appropriate junction to A domain, is a critical element for the E1P to E2P transition and formation of the proper structure of E2P, therefore, most likely for the large rotational movement of A domain and resulting in its association with P and N domains. Results further suggest that the loop functions to coordinate this movement of A domain and the unique motion of M1 during the E1P to E2P transition.

Val200 Residue in Lys189–Lys205 Outermost Loop on the A Domain of Sarcoplasmic Reticulum Ca2+-ATPase Is Critical for Rapid Processing of Phosphoenzyme Intermediate after Loss of ADP Sensitivity

Possible roles of the Lys(189)-Lys(205) outermost loop on the A domain of sarcoplasmic reticulum Ca(2+)-ATPase were explored by mutagenesis. Both nonconservative and conservative substitutions of Val(200) caused very strong inhibition of Ca(2+)-ATPase activity, whereas substitutions of other residues on this loop reduced activity only moderately. All of the Val(200) mutants formed phosphoenzyme intermediate (EP) from ATP. Isomerization from ADP-sensitive EP (E1P) to ADP-insensitive EP (E2P) was not inhibited in the mutants, and a substantially larger amount of E2P actually accumulated in the mutants than in wild-type sarcoplasmic reticulum Ca(2+)-ATPase at steady state. In contrast, decay of EP formed from ATP in the presence of Ca(2+) was strongly inhibited in the mutants. Hydrolysis of E2P formed from P(i) in the absence of Ca(2+) was also strongly inhibited but was faster than the decay of EP formed from ATP, indicating that the main kinetic limitation of the decay comes after loss of ADP sensitivity but before E2P hydrolysis. On the basis of the well accepted mechanism of the Ca(2+)-ATPase, the limitation is likely associated with the Ca(2+)-releasing step from E2P.Ca(2). On the other hand, the rate of activation of dephosphorylated enzyme on high affinity Ca(2+) binding was not altered by the substitutions. In light of the crystal structures, the present results strongly suggest that Val(200) confers appropriate interactions of the Lys(189)-Lys(205) loop with the P domain in the Ca(2+)-released form of E2P. Results further suggest that these interactions, however, do not contribute much to domain organization in the dephosphorylated enzyme and thus would be mostly lost on E2P hydrolysis.

Formation of the ADP-insensitive phosphoenzyme intermediate in the sarcoplasmic reticulum Ca2+-ATPase of which both Cys344 and Cys364 are modified by N-ethylmaleimide.

Sarcoplasmic reticulum vesicles were pretreated with N-ethylmaleimide under the conditions in which both Cys344 and Cys364 (SHD) of the Ca2+-ATPase are selectively modified. Effects of the modification on the transition of the phosphoenzyme intermediate (EP) from ADP-sensitive form to ADP-insensitive form and on the formation of ADP-insensitive EP from Pi were examined without added K+. At pH 7.0-8.0 in totally aqueous media, the EP transition and the EP formation from Pi were almost completely inhibited by the SHD modification. The formation of ADP-insensitive EP from ATP and from Pi in the SHD-modified enzyme occurred to some extent at pH 6.0-6.5 and were greatly increased by addition of dimethyl sulfoxide at pH 6. 0-8.0. The inhibition by the SHD modification of the EP formation from Pi in the absence of dimethyl sulfoxide was attributed to a decrease in the equilibrium constant for the EP formation from the enzyme-Pi-Mg complex. When 40% (v/v) dimethyl sulfoxide was present, almost all the phosphorylation sites in the SHD-modified enzyme were phosphorylated with ATP at pH 6.0 or with Pi at pH 6.0-7.0, and all the EP formed was ADP-insensitive. These results lead to the possibility that the previously reported exclusion of water from the catalytic site upon the EP transition and upon the EP formation from the enzyme-Pi-Mg complex is inhibited by the SHD modification. The present study has revealed the conditions in which the enzyme is released from the inhibition by this modification. The modification of SHD, which brackets the phosphorylation site (Asp351), may provide a useful tool for the analysis of conformational changes at the phosphorylation site occurring in the catalytic cycle.

Fluorometric study on conformational changes in the catalytic cycle of sarcoplasmic reticulum Ca(2+)-ATPase.

Changes in the fluorescence of N-acetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (EDANS), being attached to Cys-674 of sarcoplasmic reticulum Ca(2+)-ATPase without affecting the catalytic activity, as well as changes in the intrinsic tryptophan fluorescence were followed throughout the catalytic cycle by the steady-state measurements and the stopped-flow spectrofluorometry. EDANS-fluorescence changes reflect conformational changes near the ATP binding site in the cytoplasmic domain, while tryptophan-fluorescence changes most probably reflect conformational changes in or near the transmembrane domain in which the Ca2+ binding sites are located. Formation of the phosphoenzyme intermediates (EP) was also followed by the continuous flow-rapid quenching method. The kinetic analysis of EDANS-fluorescence changes and EP formation revealed that, when ATP is added to the calcium-activated enzyme, conformational changes in the ATP binding site occur in three successive reaction steps; conformational change in the calcium.enzyme.substrate complex, formation of ADP-sensitive EP, and transition of ADP-sensitive EP to ADP-insensitive EP. In contrast, the ATP-induced tryptophan-fluorescence changes occur only in the latter two steps. Thus, we conclude that conformational changes in the ATP binding site in the cytoplasmic domain are transmitted to the Ca(2+)-binding sites in the transmembrane domain in these latter two steps.

The Tryptophan Fluorescence Change upon Conformational Transition of the Phosphoenzyme Intermediate in Sarcoplasmic Reticulum Ca2+-ATPase Is Revealed in the Absence of K+ and the Presence of Lasalocid

ATP-induced changes in the tryptophan fluorescence of the Ca(2+)-ATPase were determined with sarcoplasmic reticulum vesicles at pH 7.0 and 0 degrees C by steady-state measurements in the presence of Ca2+ and the absence of K+ with and without added lasalocid (a carboxylic ionophore, 50 microM), which was previously shown to cause a predominant accumulation of the ADP-insensitive form of the phosphoenzyme intermediate (EP) (Kawashima, T., Hara, H., and Kanazawa, T. (1990) J. Biol. Chem. 265, 10993-10999). When ATP was added in the absence of lasalocid, the fluorescence decreased by 1.7%. The addition of lasalocid quenched 71% of the fluorescence but did not reduce the ATP-induced fluorescence drop. The fluorescence drop and the EP formation were also determined in the presence of lasalocid by stopped-flow spectrometry and continuous-flow rapid quenching. The observed fluorescence drop was biphasic. The first phase coincided with the formation of EP, which was largely ADP-sensitive in this early stage of the reaction. The second phase was much slower than the first phase and coincided with the accumulation of ADP-insensitive EP. When the transition of EP from the ADP-sensitive form to the ADP-insensitive form was blocked by N-ethylmaleimide treatment, the second phase disappeared, and the fluorescence drop entirely coincided with the formation of ADP-sensitive EP. These findings demonstrate that the first phase of the fluorescence drop is attributed to the formation of ADP-sensitive EP, the second phase being attributed to the transition of EP from the ADP-sensitive form to the ADP-insensitive form. The present results reveal the conditions that definitely discriminate these two phases.

CCCP activation of the reconstituted NaK-pump

In the NaK-ATPase proteoliposomes (PLs), the NaK-pump activity, Na+ uptake, and ATP hydrolysis were apparently enhanced by carbonyl cyanide m-chlorophenyl hydrazone (CCCP) and other ionophores without ion gradients. These ionophore effects were not cation specific. Without ionophores, the PL's ATPase activity fell to its steady-state value within 3 sec at 15 degrees C. This decrease in activity disappeared in the presence of CCCP. Since CCCP is believed to enhance proton mobility across the lipid bilayer and dissipate membrane potential (Vm), we postulated that a Vm build-up partially inhibits the PLs by changing the conformation of the NaK-pump, and that CCCP eliminated this partial inhibition. Since this activation required extracellular K+ and high ATP concentration in the PLs, CCCP must affect the conversion between the phosphorylated forms of NaK-ATPase (EP); this step has been suggested by Goldschlegger et al. (1987) to be the voltage-sensitive step (J. Physiol. (London) 387:331-355). Although cytoplasmic K+ accelerated the change of ADP- and K(+)-sensitive EP (E*P) to K(+)-sensitive ADP-insensitive EP (E2P), CCCP did not complete with cytoplasmic K+ when cytoplasmic Na+ was saturated. When the PLs were phosphorylated with 20 microM ATP and 20 microM palmitoyl CoA instead of with high concentration of ATP, CCCP increased the E*P content and decreased the ADP-sensitive K(+)-insensitive EP (E1P). The results described above suggest that CCCP affects the E1P to E*P change in the E1P----E*P----E2P conversion and that this reaction step is inhibited by Vm.

Selective inhibition by lasalocid of hydrolysis of the ADP-insensitive phosphoenzyme in the catalytic cycle of sarcoplasmic reticulum Ca2(+)-ATPase.

The effect of a carboxylic ionophore (lasalocid) on the sarcoplasmic reticulum Ca2(+)-ATPase was investigated. The purified enzyme was preincubated with lasalocid in the presence of Ca2+ and the absence of K+ at pH 7.0 and 0 degrees C for 2 h. The Ca2(+)-dependent ATPase activity was strongly inhibited by this preincubation, whereas the activity of the contaminant Mg2(+)-ATPase was unaffected. The steady-state level of the phosphoenzyme (EP) intermediate remained constant over the wide range of lasalocid concentrations. The Ca2(+)-induced enzyme activation was unaffected. The kinetics of phosphorylation of the Ca2(+)-activated enzyme by ATP as well as the rate of conversion of ADP-sensitive EP to ADP-insensitive EP were also unaffected. Accumulation of ADP-insensitive EP was greatly enhanced, and almost all of the EP accumulating at steady state was ADP-insensitive. Hydrolysis of ADP-insensitive EP was strongly inhibited. A similar strong inhibition of the Ca2(+)-dependent ATPase activity by lasalocid was found with sarcoplasmic reticulum vesicles. To examine the effect of lasalocid on the conformational change in each reaction step, the Ca2(+)-ATPase of sarcoplasmic reticulum vesicles was labeled with a fluorescent probe (N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine) without a loss of catalytic activity and then preincubated with lasalocid as described above. The conformational changes involved in hydrolysis of ADP-insensitive EP and in the reversal of this hydrolysis were appreciably retarded by lasalocid. The conformational changes involved in other reaction steps were unaffected. These results demonstrate that hydrolysis of ADP-insensitive EP in the catalytic cycle of this enzyme is selectively inhibited by lasalocid.

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.

Conformational changes in the vicinity of the N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine attached to the specific thiol of sarcoplasmic reticulum Ca2+-ATPase throughout the catalytic cycle.

In the previous experiment (Suzuki, H., Obara, M., Kuwayama, H., and Kanazawa, T. (1987) J. Biol. Chem. 262, 15448-15456), the Ca2+-ATPase of sarcoplasmic reticulum vesicles was labeled with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine without a loss of the catalytic activity. The main labeled site was Cys674. A large monophasic fluorescence drop occurred upon ATP binding to the catalytic site of the Ca2+-activated enzyme in the presence of K+. The present results show that this fluorescence drop is biphasic in the absence of K+. The first and rapid phase of this drop accounts for most of the fluorescence drop. This phase reflects a conformational change in the enzyme.ATP complex. The second and slow phase, being much smaller than the first phase, coincides with phosphoenzyme (EP) isomerization from the ADP-sensitive form to the ADP-insensitive form. This phase disappears when accumulation of ADP-insensitive EP is inhibited by K+ or when EP isomerization is prevented by the N-ethylmaleimide treatment. These results show that this phase reflects a conformational change upon EP isomerization. When free Ca2+ is chelated after EP formation from ATP, the fluorescence intensity is restored to the initial level without Ca2+. This restoration coincides with EP decomposition. This suggests that the fluorescence restoration reflects a conformational change upon hydrolysis of ADP-insensitive EP. This probability is supported by the concurrent occurrence of the Pi-induced fluorescence drop and EP formation from Pi. The results demonstrate that the fluorescence drop upon ATP binding is predominant in the fluorescence change throughout the catalytic cycle.

Phosphorylated intermediates of Na,K-ATPase proteoliposomes controlled by bilayer cholesterol. Interaction with cardiac steroid.

Fragmental Na,K-ATPase from the electric eel forms three phosphorylated intermediates (EP) with MgATP and Na+: ADP-sensitive K+-insensitive EP (E1P), ADP- and K+-sensitive EP (E*P), and K+-sensitive ADP-insensitive EP (E2P). The EP composition varied with the Na+ concentration. In the reconstituted Na,K-ATPase proteoliposomes (PL), the EP composition of the inside-out form was controlled not only by the intravesicular (extracellular) Na+ concentration, but also by the temperature and the cholesterol content of the lipid bilayer. When the lipid bilayer of PL contained less than 30 mol % cholesterol, the E*P content did not change significantly while the E2P content increased with an elevation in temperature (3-20 degrees C). In contrast, when the lipid bilayer contains more than 35 mol % cholesterol, the E*P content increased while the E2P content stayed less than 10% under the same temperature change. These observations suggest that a high cholesterol content in the lipid bilayer interferes with the E*P to E2P conversion. This cholesterol effect was reversed by ionophores (monensin, nigericin, and A23187). Therefore, E1P-rich EP, E*P-rich EP, or E2P-rich EP could be obtained in the PL under a constant Na+ concentration by using various concentrations of cholesterol and ionophores. The reaction between the proteoliposomal EPs and digitoxigenin (lipid-soluble cardiac steroid) occurred in a single turnover, thereby avoiding unphysiologically high Na+ concentrations. The increase in the ADP- and K+-insensitive EP, which indicated formation of the digitoxigenin-Na,K-ATPase complex, was equivalent to the decrease in the E*P under six different sets of conditions, without any significant change in the E1P and E2P contents. This result indicated that E*P is the active intermediate of the Na,K-ATPase for cardiac steroid binding. Although the E2P has been thought to be the active form for binding, it cannot bind with the cardiac steroid in the presence of Na+ and in the absence of free Mg2+.

Coincidence of H+ binding and Ca2+ dissociation in the sarcoplasmic reticulum Ca-ATPase during ATP hydrolysis.

H+ and Ca2+ concentration changes in the reaction medium following MgATP addition at pH 6.0 were determined with the partially purified Ca-ATPase from sarcoplasmic reticulum vesicles in the presence of 25-50 microM CaCl2 and 5 mM MgCl2 at 4 degrees C. Previously, we showed a sequential occurrence of H+ binding and H+ dissociation in the Ca-ATPase during ATP hydrolysis and further suggested that the H+ binding takes place inside the vesicles (Yamaguchi, M., and Kanazawa, T. (1984) J. Biol. Chem. 259, 9526-9531). The present results demonstrate that the H+ binding occurred coincidently with Ca2+ dissociation from the enzyme upon conversion of the phosphoenzyme (EP) intermediate from the ADP-sensitive form to the ADP-insensitive form in the catalytic cycle of ATP hydrolysis. As KCl decreased in the medium, the extent of the H+ binding increased almost proportionately with the extent of either the Ca2+ dissociation or the accumulation of ADP-insensitive EP. Both the H+ binding and the Ca2+ dissociation were prevented by a modification of the specific SH group of the enzyme essential for the conversion of ADP-sensitive EP to ADP-insensitive EP. In the late stage of the reaction, H+ dissociation from the enzyme occurred coincidently with Ca2+ binding to the dephosphoenzyme which was formed by EP decomposition. These results are consistent with the possibility that the H+ ejection during the Ca2+ uptake with the intact vesicles previously shown by several investigators takes place through a Ca2+/H+ exchange directly mediated by the membrane-bound Ca-ATPase.

Calcium fluxes across the membrane of sarcoplasmic reticulum vesicles.

The relationship between calcium exchange across the membrane of sarcoplasmic reticulum vesicles and phosphoenzyme (EP) was examined in calcium transport reactions using a limited amount of ATP as substrate. Rapid calcium influx and efflux (approximately 385 nmol.(mg.min)-1), measured in reactions in which ATP concentration fell from 20 microM, was accompanied by a shift in the equilibrium between an ADP-sensitive EP and an ADP-insensitive EP toward the former. Rapid exchange between ATP and ADP (approximately 1500 nmol.(mg.min)-1) was also observed under conditions where no significant incorporation of Pi into ATP took place, suggesting that ATP in equilibrium ADP exchange can occur without Cao in equilibrium Cai exchange. Ca2+ permeability during the calcium transport reaction was estimated in reactions carried out with acetylphosphate, which produces a hydrolytic product that does not participate in the backward reaction of the calcium pump. Under conditions where the calcium content exceeded 43 nmol.mg-1, a level that may reflect the binding of calcium ions to sites inside the sarcoplasmic reticulum, the rate constant for Ca2+ efflux was 0.33 min-1. These data allow the rate of passive Ca2+ efflux to be estimated as approximately 17 nmol.(mg.min)-1 at the time when calcium content was maximal and a rapid Cao in equilibrium Cai was observed. It is concluded that the majority of the rapid Ca2+ efflux is mediated by partial backward reactions of the calcium pump ATPase.

Changes in affinity for calcium ions with the formation of two kinds of phosphoenzyme in the Ca2+,Mg2+-dependent ATPase of sarcoplasmic reticulum.

The amount of Ca2+ bound to the Ca2+,Mg2+-dependent ATPase of deoxycholic acid-treated sarcoplasmic reticulum was measured during ATP hydrolysis by the double-membrane filtration method [Yamaguchi, M. & Tonomura, Y. (1979), J. Biochem. 86, 509--523]. The maximal amount of phosphorylated intermediate (EP) was adopted as the amount of active site of the ATPase. In the absence of ATP, 2 mol of Ca2+ bound cooperatively to 1 mol of active site with high affinity and were removed rapidly by addition of EGTA. AMPPNP did not affect the Ca2+ binding to the ATPase in the presence of MgCl2. Under the conditions where most EP and ADP sensitive at steady state (58 microM Ca2+, 50 microM EGTA, and 20 mM MgCl2 at pH 7.0 and 0 degrees C), bound Ca2+ increased by 0.6--0.7 mol per mol active site upon addition of ATP. The time course of decrease in the amount of bound 45Ca2+ on addition of unlabeled Ca2+ + EGTA was biphasic, and 70% of bound 45Ca2+ was slowly displaced with a rate constant similar to that of EP decomposition. Similar results were obtained for the enzyme treated with N-ethylmaleimide, which inhibits the step of conversion of ADP-sensitive EP to the ADP-insensitive one. Under the conditions where most EP was ADP insensitive at steady state (58 microM Ca2+, 30 microM EGTA, and 20 mM MgCl2 at pH 8.8 and 0 degrees C), the amount of bound Ca2+ increased slightly, then decreased slowly by 1 mol per mol of EP formed after addition of ATP. Under the conditions where about a half of EP was ADP sensitive (58 microM Ca2+, 25 microM EGTA, and 1 mM MgCl2 at pH 8.8 and 0 degrees C), the amount of bound Ca2+ did not change upon addition of ATP. These findings suggest that the Ca2+ bound to the enzyme becomes unremovable by EGTA upon formation of ADP-sensitive EP and is released upon its conversion to ADP-insensitive EP.

Reaction mechanism of (Ca2+, Mg2+)-ATPase of sarcoplasmic reticulum vesicles. I. Phosphoenzyme with bound Ca2+ which is exposed to the external medium.

Sarcoplasmic reticulum vesicles were phosphorylated with [gamma-32P]ATP in the presence of external Ca2+ without added Mg2+. The phosphoenzyme (EP) formed had tightly bound Ca2+ and was dephosphorylated by ADP. When the external Ca2+ was chelated after phosphorylation, Ca2+ dissociated from the EP and ADP addition no longer induced dephosphorylation. Subsequent addition of CaCl2 caused rapid recombination of Ca2+ and restoration of the ADP sensitivity. These findings show that the dissociation and recombination of Ca2+ took place on the outer surface of the membranes, indicating the existence of EP with bound Ca2+ which was exposed to the external medium (Caout.EP). The Ca2+ affinity of the Ca2+ binding site in Caout.EP was comparable to that of the high affinity Ca2+ binding site in the dephosphoenzyme (E). This shows that phosphorylation is not accompanied by an appreciable reduction in the Ca2+ affinity of the Ca2+ binding site, provided this site is exposed to the external medium. The transition from ADP-sensitive EP to ADP-insensitive induced by Ca2+ chelation was unaffected by Mg2+ in the medium. Mg2+ did not activate hydrolysis of the ADP-sensitive EP with bound Ca2+, whereas it markedly accelerated hydrolysis of the ADP-insensitive EP without bound Ca2+.

Binding of Monovalent Cations to Na+,K+-Dependent ATPase Purified from Porcine Kidney

We measured the amounts of Rb+ ions (a K+ congener) as well as Na+ and K+ ions bound to the ATPase during the ATPase reaction at pH 7.5 and 0 degrees C. The affinity of the Na+-binding sites for three Na+ ions decreased markedly but that of the K+-binding sites for two K+ or Rb+ ions increased markedly upon formation of an ADP-insensitive phosphorylated intermediate. Furthermore, the present experiment did not give any indication of a change in the Hill coefficient of 2, and showed an increase in the affinity of the K+-binding sites for Rb+ ions of about 28 times upon the formation of an ADP-insensitive EP. The enzyme state with a high affinity for Rb+ was maintained after the disappearance of EP. When the ATPase was treated with N-ethylmaleimide (NEM), almost all the EP formed was ADP-sensitive. The formation of an ADP-sensitive EP with the NEM-treated enzyme induced no change in the affinities of the ATPase for Na+ and Rb+ ions.

Kinetic Studies on the ADP-ATP Exchange Reaction Catalyzed by Na+, K+-dependent ATPase

The kinetic properties of the [3H]ADP-ATP exchange reaction catalyzed by Na+, K+-dependent ATPase [EC 3.6.1,3] were investigated, using NaI-treated microsomes from bovine brain, and the following results were obtained. 1. The rates of the Na+-dependent exchange reaction in the steady state were measured in a solution containing 45 micronM free Mg2+, 100 mMNaCl, 80 micronM ATP, and 160 micronM ADP at pH 6.5 and 4-5 degrees. The rate and amount of decrease in phosphorylated intermediate on adding ADP, i.e., the amount of ADP-sensitive EP, were measured while varying one of the reaction parameters and fixing the others mentioned above. Plots of the exchange rate and the amount of ADP-sensitive EP against the logarithm of free Mg2+ concentration gave bell-shaped curves with maximum values at 50-60 micronM free Mg2+. Plots of the exchange rate and the amount of ADP-sensitive EP against pH also gave bell-shaped curves with maximum values at pH 6.9-7. They both increased with increase in the concentration of NaCl to maximum values at 150-200 mM NaCl, and then decreased rapidly with increase in the NaCl concentration above 200 mM. The dependences of the exchange rate and the amount of ADP-sensitive EP on the concentration of ADP followed the Michaelis-Menten equation, and the Michaelis constants Km, for both were 43 micronM. The dependence of the exchange rate on the ATP concentration also followed the Michaelis-Menten equation, and the Km value was 30 micronM. The amount of ADP-sensitive EP increased with increase in the ATP concentration, and reached a maximum value at about 5 micronM ATP. 2. The N+-dependent [3H]ADP-ATP exchange reaction was started by adding [3H]ADP to EP at low Mg2+-concentration. The reaction consisted of a rapid initial phase and a slow steady phase. The amount of [3H]ATP formed during the rapid initial phase, i.e. the size of the ATP burst, was equal to that of ADP-sensitive EP, and was proportional to the rate in the steady state. At high Mg2+ concentration, the rate of Na+-dependent exchange in the steady state was almost zero, and EP did not show any ADP sensitivity. However, rapid formation of [3H]ATP was observed in the pre-steady state, and the size of the ATP burst increased with increase in the KCl concentration. From these findings, we concluded that an enzyme-ATP complex (E2ATP) formed at low Mg2+ concentration is in equilibrium with EP + ADP, that the rate-limiting step for the exchange reaction is the release of ATP from the enzyme-ATP complex, that the ADP-insensitive EP (formula: see text) produced at high Mg2+ concentration is in equilibrium with the enzyme-ATP complex, and that the equilibrium shifts towards the enzyme-ATP complex on adding KCl. Actually, the ratio of the size of the ATP burst to the amount of EP was equal to the reciprocal of the equilibrium constant of step (formula: see text), determined by a method previously reported by us.

The pre-steady state of Na+-K+-dependent ATPase after addition of Na+ ions. Transition of the phosphorylated intermediate from an ADP-sensitive to an ADP-insensitive form.

Na+-K+-Dependent ATPase [EC 3.6.1.3] was preincubated with ATP in the presence of a high concentration of MgCl2, and the phosphorylated intermediate, EP, was formed by adding a high concentration of NaCl. The following results showed that EP was converted from an ADP-sensitive to an ADP-insensitive form by a single turnover of the ATPase reaction. 1. After initiating the reaction by adding NaCl, almost all the EP was at first sensitive to added ADP, but its sensitivity to ADP decreased with increase in the time interval between the additions of NaCl and of ADP. 2. Both in the presence and absence of KCl, the time course of the replacement of ADP-sensitive EP by ADP-insensitive EP coincided with the time course of the decomposition of EP after addition of EDTA.