Evidence for a relationship between activity and the tetraprotomeric assembly of solubilized pig gastric H/K-ATPase

Activity-oligomeric assembly relationships using octaethylene glycol dodecyl ether (C12E8) solubilized pig gastric H/K-ATPase (unmodified H/K-ATPase) or H/K-ATPase modified with Fluorescein 5'-isothiocyanate (FITC-H/K-ATPase) were examined. The amount of oligomeric species in FITC-H/K-ATPase, which retained little H/K-ATPase activity was estimated by a single-molecule detection technique using total internal reflection fluorescence microscopy. Solubilization of the FITC-H/K-ATPase reduced the potassium-dependent p-nitrophenyl phosphatase (K-pNPPase) activity to around 5% of the level of the membrane-bound enzyme with the formation of 50% protomer and 40% diprotomer. The solubilization of unmodified H/K-ATPase also reduced both the K-pNPPase and H/K-ATPase activities to around 5%. However, solubilization with increasing concentrations of potassium acetate induced significant and similar increases in K-pNPPase activity (K0.5 = 35 mM) with an increase in the amount of the tetraprotomer of FITC-H/K-ATPase, and the K-pNPPase (K0.5 = 28 mM) and H/K-ATPase (K0.5 = 40 mM) activities of the unmodified H/K-ATPase. The correlation coefficient between the proportion of tetraprotomer and the proportion of the K-pNPPase activity for the same FITC-H/K-ATPase preparation was estimated to be 0.93. Similar coefficients were also obtained between the proportion of tetraprotomer in the FITC-H/K-ATPase and the proportion of K-pNPPase and H/K-ATPase activities in the unmodified H/K-ATPase, with value of 0.85 and 0.86, respectively. Such positive correlations were not obtained between these activities and other oligomeric species. These data, the first direct comparison of oligomeric assembly and enzyme activity both stabilized by K+ in C12E8-solubilized gastric H/K-ATPase, provide strong evidence that the catalytic unit of C12E8-solubilized gastric H/K-ATPase is a tetraprotomer.     

Inactivation of Na,K-ATPase following Co(NH3)4ATP binding at a low affinity site in the protomeric enzyme unit

The Na(+)-dependent or E1 stages of the Na,K-ATPase reaction require a few micromolar ATP, but submillimolar concentrations are needed to accelerate the K(+)-dependent or E2 half of the cycle. Here we use Co(NH(3))(4)ATP as a tool to study ATP sites in Na,K-ATPase. The analogue inactivates the K(+) phosphatase activity (an E2 partial reaction) and the Na,K-ATPase activity in parallel, whereas ATP-[(3)H]ADP exchange (an E1 reaction) is affected less or not at all. Although the inactivation occurs as a consequence of low affinity Co(NH(3))(4)ATP binding (K(D) approximately 0.4-0.6 mm), we can also measure high affinity equilibrium binding of Co(NH(3))(4)[(3)H]ATP (K(D) = 0.1 micro m) to the native enzyme. Crucially, we find that covalent enzyme modification with fluorescein isothiocyanate (which blocks E1 reactions) causes little or no effect on the affinity of the binding step preceding Co(NH(3))(4)ATP inactivation and only a 20% decrease in maximal inactivation rate. This suggests that fluorescein isothiocyanate and Co(NH(3))(4)ATP bind within different enzyme pockets. The Co(NH(3))(4)ATP enzyme was solubilized with C(12)E(8) to a homogeneous population of alphabeta protomers, as verified by analytical ultracentrifugation; the solubilization did not increase the Na,K-ATPase activity of the Co(NH(3))(4)ATP enzyme with respect to parallel controls. This was contrary to the expectation for a hypothetical (alphabeta)(2) membrane dimer with a single ATP site per protomer, with or without fast dimer/protomer equilibrium in detergent solution. Besides, the solubilized alphabeta protomer could be directly inactivated by Co(NH(3))(4)ATP, to less than 10% of the control Na,K-ATPase activity. This suggests that the inactivation must follow Co(NH(3))(4)ATP binding at a low affinity site in every protomeric unit, thus still allowing ATP and ADP access to phosphorylation and high affinity ATP sites.     

Solubilized (Na+ + K+)-ATPase from shark rectal gland and ox kidney--an inactivation study

The bi-exponential time-course of detergent inactivation at 37 degrees C of C12E8-solubilized (Na+ + K+)-ATPase from shark rectal glands and ox kidney was investigated. The data for shark enzyme, obtained at detergent/protein weight ratios between 2 and 16, are interpreted in terms of a simple model where the membrane bound enzyme is solubilized predominantly as (alpha-beta)2 diprotomers at low detergent concentrations and as alpha-beta protomers at high C12E8 (octaethyleneglycoldodecylmonoether) concentrations. It is observed that the protomers are inactivated 15-fold more rapidly than the diprotomers, and that the rate of inactivation of both oligomers is proportional to the detergent/protein ratio. Inactivation of kidney enzyme was biexponential with a very rapid inactivation of up to 40% of the enzyme activity. The observed rate of inactivation of the slower phase varied with the detergent/protein ratio, but the inactivation pattern for the kidney enzyme could not readily be accommodated within the model for inactivation of the shark enzyme. The rates of inactivation at 37 degrees C were about the same in KCl and NaCl, i.e., in the E2(K) and E1 X Na forms, for both enzymes.     

Isolation and characterization of a monoclonal antibody against pig kidney sodium- and potassium-activated ATPase

A hybridoma cell line producing mouse monoclonal antibody against pig kidney Na,K-ATPase was established. The antibody, named 38 (mAb38, IgG1), was purified from mouse ascites fluid by chromatography on a protein A-Sepharose column. Antigens immobilized on microplate wells with p-benzoquinone were used for titer assays. mAb38 cross-reacted with both dodecyloctaethyleneglycol monoether (C12E8)-solubilized enzyme and membranous sodium dodecyl sulfate (SDS)-treated enzyme from kidney with high affinity (50% binding = 0.6 nM). However, the antibody bound to neither alpha- nor beta-subunit separated by preparative SDS-polyacrylamide gel electrophoresis (PAGE). The stoichiometry of antibody binding to the purified enzyme was estimated to be about 0.86 mol of IgG per mol of alpha beta-protomer. Na,K-ATPase proteins were recovered from a column of mAb38-coupled Affi-Gel by elution with pH 3 buffer when C12E8-solubilized kidney enzyme or detergent extracts of brain microsomes were applied to it, confirming that the mAb is directed to Na,K-ATPase. mAb38 at saturation level concentrations had no effect on kidney Na,K-ATPase activity or on ouabain-sensitive Rb uptake in erythrocytes. In an immunofluorescence study, the antibody bound to intact erythrocytes much more strongly than control IgG1 (mAb50c), but the extent of the antibody binding to inside-out vesicles under hypotonic conditions was lower than that of the control. Most of the antibody binding activity remained when the kidney enzyme was treated with sialidase. These results suggest that this mAb38 was raised against an intact conformation of a cell-surface-exposed site of Na,K-ATPase.     

Minimum enzyme unit for Na+/K+-ATPase is the alpha beta-protomer. Determination by low-angle laser light scattering photometry coupled with high-performance gel chromatography for substantially simultaneous measurement of ATPase activity and molecular weight

The oligomeric state of canine renal NA+/K+ -ATPase solubilized by octaethylene glycol n-dodecyl ether (C12E8) was studied by means of low-angle laser light scattering photometry coupled with high-performance gel chromatography (HPGC). At around 0 degree C the solubilized enzyme was separated into the (alpha beta)2-diprotomeric and alpha beta-protomeric protein components with Mr values of 302,000 +/- 10,000 and 156,000 +/- 4,000, respectively, in approximately equal quantities. As the temperature of chromatography was increased toward 20 degrees C, the two protein components converged into a single major component. The Mr of this component depended on the monovalent cation included in the elution buffer, and was 255,000 or 300,000 in the presence of 0.1 M NaCl or 0.1 M KCl, respectively. A computer simulation technique showed that the solubilized enzyme was in a dissociation-association equilibrium of 2 protomers = diprotomer at 20 degrees C, and the difference in apparent Mr of the solubilized enzyme between the two species of monovalent cation was interpreted by an association constant (Ka) in the presence of 0.1 M KCl that was about 50-fold larger than in the presence of 0.1 M NaCl. In order to measure ATPase activity and Mr of the solubilized enzyme simultaneously, a TSKgel G3000SW column had been equilibrated and was eluted with an elution buffer containing 0.30 mg/ml C12E8 and 60 microgram/ml phosphatidylserine (bovine brain) as well as the ligands necessary for the enzyme to exhibit the activity at pH 7.0 and 20 degrees C. The solubilized enzyme was always eluted as a single protein component irrespective of the the amount of the protein applied to the column, ranging between 240 and 10 microgram. The Mr of the protein component, however, decreased from 214,000 and 158,000 with the decrease of the protein amount. The specific ATPase activity, however, remained constant at a level of 64 +/- 4% of that of the membrane-bound enzyme even in the range of protein concentration sufficiently low as to allow the enzyme to exist only in the protomeric form. Thus, the alpha beta-protomer is concluded to be the minimum functional unit for the ATPase activity. The value of Ka obtained from the concentration-dependent dissociation curve was 5 . 10(5) M-1 for the enzyme turning over, and 1.1 . 10(7) M-1 for the enzyme inhibited with ouabain. It was discussed, based on the values of Ka obtained, that the enzyme would exist as the diprotomer or the higher oligomer in the membrane.     

Na/K-ATPase as an oligomeric ensemble

Differences in the kinetic behavior and properties of monomeric and oligomeric forms of membrane-bound Na/K-ATPase are analyzed. It is concluded that enzyme molecules within oligomeric complexes are affected by extrinsic signals that result in change of enzyme activity, whereas the individual (protomeric) state is insensitive to these signals. Some of the major factors of such regulation are microviscosity of the lipid environment, reactive oxygen species, and intracellular protein kinases.     

Properties of oligomycin-induced occlusion of Na+ by detergent-solubilized Na,K-ATPase from pig kidney or shark rectal gland.

Oligomycin induces occlusion of Na+ in membrane-bound Na,K-ATPase. Here it is shown that Na,K-ATPase from pig kidney or shark rectal gland solubilized in the nonionic detergent C12E8 is capable of occluding Na+ in the presence of oligomycin. The apparent affinity for Na+ is reduced for both enzymes upon solubilization, and there is an increase in the sigmoidicity of binding curves, which indicates a change in the cooperativity between the occluded ions. A high detergent/protein ratio leads to a decreased occlusion capacity. De-occlusion of Na+ by addition of K+ is slow for solubilized Na,K-ATPase, with a rate constant of about 0.1 s-1 at 6 degrees C. Stopped-flow fluorescence experiments with 6-carboxyeosin, which can be used to monitor the E1Na-form in detergent solution, show that the K(+)-induced de-occlusion of Na+ correlates well with the fluorescence decrease which follows the transition from the E1Na-form to the E2-form. There is a marked increase in the rate of fluorescence change at high detergent/protein ratios, indicating that the properties of solubilized enzyme are subject to modification by detergent in other respects than mere solubilization of the membrane-bound enzyme. The temperature dependence of the rate of de-occlusion in the range 2 degrees C to 12 degrees C is changed slightly upon solubilization, with activation energies in the range 20-23 kcal/mol for membrane-bound enzyme, increasing to 26-30 kcal/mol for solubilized enzyme. Titrations of the rate of transition from E1Na to E2K with oligomycin can be interpreted in a model with oligomycin having an apparent dissociation constant of about 2.5 microM for C12E8-solubilized shark Na,K-ATPase and 0.2 microM for solubilized pig kidney Na,K-ATPase.     

Mechanism of allosteric effects of ATP on the kinetics of P-type ATPases

The roles of allosteric effects of ATP and protein oligomerisation in the mechanisms of P-type ATPases belong to the most controversial and least well understood topics in the field. Recent crystal structural and kinetic data, however, now allow certain hypotheses to be definitely excluded and consistent hypotheses to be developed. The aim of this review is to critically discuss recent results and, in the light of them, to present a set of conclusions which could form the basis of future research. The major conclusions are: (1) at saturating ATP concentrations P-type ATPases function as monomeric enzymes, (2) the catalytic units of P-type ATPases only possess a single ATP binding site, (3) at non-saturating ATP concentrations P-type ATPases exist as diprotomeric (or higher oligomeric) complexes, (4) protein–protein interactions within a diprotomeric complex enhances the enzymes’ ATP binding affinity, (5) ATP binding to both protomers within a diprotomeric complex causes it to dissociate into two separate monomers. The physiological role of protein–protein interactions within a diprotomer may be to enhance ATP binding affinity so as to scavenge ATP and maximize the ion pumping rate under hypoxic or anoxic conditions. For the first time a structural basis for the well-known ATP allosteric acceleration of the E2 → E1 transition is presented. This is considered to be due to a minimization of steric hindrance between neighbouring protomers because of the ability of ATP to induce a compact conformation of the enzymes’ cytoplasmic domains.     

Kinetic properties of C12E8-solubilized (Na+ + K+)-ATPase

The properties of the rectal gland (Na+ + K+)-ATPase (ATP phosphohydrolase, EC 3.6.1.8) solubilized in octaethyleneglycol dodecylmonoether ( C12E8 ) have been investigated. The kinetic properties of the solubilized enzyme resemble those of the membrane-bound enzyme to a large extent. The main difference is that Km for ATP for the (Na+ + K+)-ATPase is about 30 microM for the solubilized enzyme and about 100 microM for the membrane-bound enzyme. The Na+-form (E1) and the K+-form (E2) can also be distinguished in the solubilized enzyme, as seen from tryptic digestion, the intrinsic fluorescence and eosin fluorescence responses to Na+ and K+. The number of vanadate-binding sites is unchanged upon solubilization, and it is shown that vanadate binding is much more resistant to detergent inactivation than the enzymatic activities. The number of phosphorylation sites on the 95-100% pure supernatant enzyme is about 3.8 nmol/mg, and is equal to the number of vanadate sites. Inactivation of the enzyme by high concentrations of detergent can be shown to be related to the C12E8 /protein ratio, with a weight ratio of about 4 being a threshold for the onset of inactivation at low ionic strength. At high ionic strength, more C12E8 is required both for solubilization and inactivation. It is observed that the commercially available detergent polyoxyethylene 10-lauryl ether is much less deleterious than C12E8 , and its advantages in the assay of detergent-solubilized (Na+ + K+)-ATPase are discussed. The results show that (Na+ + K+)-ATPase can be solubilized in C12E8 in an active form, and that most of the kinetic and conformational properties of the membrane-bound enzyme are conserved upon solubilization. C12E8 -solubilized (Na+ + K+)-ATPase is therefore a good model system for a solubilized membrane protein.     

Occlusion of Rb+ by detergent-solubilized (Na+ + K+)-ATPase from shark salt glands

Occlusion of Rb+ by C12E8-solubilized (Na+ + K+)-ATPase from shark salt glands has been measured. The rate of de-occlusion at room temperature is about 1 s-1, which is the same as for the membrane-bound enzyme. The amount of Rb+ occluded is 3 moles Rb+ per mole membrane-bound shark enzyme, whereas only about 2 moles Rb+ are occluded by the C12E8-solubilized enzyme.     

Na,K-ATPase: radiation inactivation studies

Na,K-ATPase from duck salt gland and ox brain in the membrane-bound or solubilized form was studied by the radiation inactivation technique using ATP, CTP, GTP or p-NPP as substrates. The values of radiation inactivation size (RIS) were compared with the target size (TS) for the alpha-subunit of the enzyme obtained by an independent method as well as with analytical centrifugation data obtained for C12E8-solubilized enzyme. It was concluded that during ATP (CTP) hydrolysis the enzyme operates as an oligomeric structure; the complex formation requires the presence of K+ and adenosine triphosphate binding to the sites with a low affinity for the nucleotide. Specially designed experiments revealed that the degree of enzyme oligomerization increases with an increase in the microviscosity of the membrane lipid environment.     

Effect of phospholipid, detergent and protein-protein interaction on stability and phosphoenzyme isomerization of soluble sarcoplasmic reticulum Ca-ATPase

The purpose of the present study was to elucidate the separate roles of lipid, detergent and protein-protein interaction for stability and catalytic properties of sarcoplasmic reticulum Ca-ATPase solubilized in the non-ionic detergent octa(ethylene glycol) monododecyl ether (C12E8). The use of large-zone high-performance liquid chromatography permitted us to define the self-association state of Ca-ATPase peptide at various detergent, phospholipid and protein concentrations, and also during enzymatic turnover with ATP. Conditions were established for monomerization of Ca-ATPase in the presence of a high concentration of phospholipid relative to detergent. The lipid-saturated monomeric preparation was relatively resistant to inactivation in the absence of Ca2+, whereas delipidated enzyme in monomeric or in oligomeric form was prone to inactivation. Kinetics of phosphoenzyme turnover were examined in the presence and absence of Mg2+. Dephosphorylation rates were sensitive to Mg2+, irrespective of whether the peptide was present in soluble monomeric form or was membrane-bound. C12E8-solubilized monomer without added phospholipid was, however, characterized by a fast initial phase of dephosphorylation in the absence of Mg2+. This was not observed with monomer saturated with phospholipid or with monomer solubilized in myristoylglycerophosphocholine or deoxycholate. The mechanism underlying this difference was shown to be a C12E8-induced acceleration of conversion of ADP-sensitive phosphoenzyme (E1P) to ADP-insensitive phosphoenzyme (E2P). The phosphoenzyme isomerization rate was also found to be enhanced by low-affinity binding of ATP. This was demonstrated both in membrane-bound and in soluble monomeric Ca-ATPase. Our results indicate that a single peptide chain constitutes the target for modulation of phosphoenzyme turnover by Mg2+ and ATP, and that detergent effects, distinct from those arising from disruption of protein-protein contacts, are the major determinants of kinetic differences between C12E8-solubilized and membrane-bound enzyme preparations.     

Effect of free fatty acids and detergents on H,K-ATPase. The steady-state ATP phosphorylation level and the orientation of the enzyme in membrane preparations.

The effects of detergents and free fatty acids on the K(+)-activated ATPase activity and on the steady-state phosphorylation level of pig gastric H,K-ATPase were studied. Unsaturated free fatty acids inhibited the K(+)-activated ATPase activity, due to inactivation of the enzyme (long-term effects) and to a decrease in the K(+)-sensitive dephosphorylation rate (short-term effects). The degree of inhibition depended on the reaction conditions: the protein concentration, the temperature and the ligands used. No effect was observed when saturated- or methylated unsaturated fatty acids were tested. Free fatty acids and the detergent C12E8 increased the steady-state ATP phosphorylation level, indicating the presence of vesicular structures in the H,K-ATPase preparations. At higher concentrations these compounds inactivated H,K-ATPase, which was measured as a decrease in phosphorylation capacity. By combining the data from the ATP phosphorylation level in the absence and presence of C12E8 (without inactivation) and the data from the K(+)-activated ATPase activity with and without ionophore the tightness of vesicular preparations and the orientation of H,K-ATPase was determined. A rather simple method for the isolation of H,K-ATPase is reported, which yields highly purified H,K-ATPase preparations with a ATP phosphorylation capacity of 3.9 nmol P per mg protein or 0.57 mol P per mol alpha beta protomer. This number suggests that each alpha-subunit H,K-ATPase can be phosphorylated at the same time.     

Stabilizing effect of oligomerization on aldolase protomers in rabbit muscles

It is shown by the fluorimetric analysis that with the 1,2 M MgCl2-induced dissociation of rabbit muscle aldolase the tertiary structure of the resulted protomers (subunits) remains practically unchanged. Significant changes in the protomeric enzyme are provoked by subsequent addition of urea up to the concentration of 2,3 M, and are, evidently, manifested in a significant decrease in regularity of the hydrophobic part of aldolase and in possible transition of its Trp-147 into more polar environment. This transition is reflected in the longwave shift of the protein fluorescence maximum (lambda max) by 13 nm (from 320 to 333 nm). But the joint action of MgCl2 and urea does not lead to complete unfolding of the resulted protomeric enzyme. More deep structural alterations in the subunits occur on acidic dissociation, and lambda max shift in this case reaches 342 nm. Structural changes caused by MgCl2 and urea are concomitant with the increase of fluorescence quenchibility with NADH. Here a short-wave lambda max shift, being usually observed in native aldolase fluorescence quenching, is not registered. This mean that the photoselection of protein fluorophores does not occur. The results thus obtained produce an evidence that oligomerization endows aldolase protomers with enhanced stability.     

Glutaraldehyde crosslinking analysis of the C12E8 solubilized H,K-ATPase

A soluble porcine H,K-ATPase preparation was obtained with the nonionic detergent, C12E8. ATP hydrolysis by the soluble H,K-ATPase was stimulated with respect to the native preparation at pH 6.1, while the K(+)-phosphatase activity was comparable to the native enzyme. The soluble enzyme demonstrated characteristic ligand-dependent effects on ATP hydrolysis, including ATP activation of K(+)-stimulated hydrolysis with a K0.5 of 28 +/- 4 microM ATP, and inhibition with an IC50 of 2.1 mM ATP. The activation and inhibition of ATP hydrolysis by K+ was also observed with a K0.5 for activation of 2.8 +/- 0.4 mM KCl at 2.0 mM ATP (pH 6.1) and inhibition with an IC50 of 135 mM KCl at 0.05 mM ATP. 2-Methyl-8-(phenylmethoxy)imidazo[1,2a]pyridine-3-acetonitrile (SCH 28080), a specific inhibitor of the native H,K-ATPase, competitively inhibited the K(+)-stimulated activity with a Ki of 0.035 microM. The soluble enzyme was stable with a t0.5 for ATPase activity of 6 h between 4 and 11 degrees C. The demonstration of these related ligand responses in the catalytic reactions of the soluble preparation indicates that it is an appropriate medium for investigation of the subunit associations of the functional H,K-ATPase. Subunit associations of the active soluble enzyme were assessed following treatment with the crosslinking reagent, glutaraldehyde. The distribution of crosslinked particles was independent of the soluble protein concentration in the crosslinking buffer within the protein range 0.3 to 2.0 mg/ml or the detergent to protein ratio varied from 1 to 15 (w/w). The crosslinked pattern was unaffected by the presence or absence of K during crosslinking or nucleotide concentration. These observations suggest that crosslinking occurs in associated subunits that do not undergo rapid associations dependent upon enzyme turnover. Phosphorylation of the soluble enzyme with 0.1 mM MgATP produced a phosphoprotein at 94 kDa. A phosphoprotein obtained after glutaraldehyde treatment exhibited identical electrophoretic mobility to the crosslinked particle identified by silver stain. Glutaraldehyde treatment of soluble protein fractions resolved on a linear 10-35% glycerol gradient revealed several smaller peptides partially resolved from the crosslinked pump particle, but no active fraction enriched in the monomeric H,K-ATPase. This data indicates that the functional porcine gastric H,K-ATPase is organized as a structural dimer.     

The amino acid sequence of an active site peptide from the H,K-ATPase of gastric mucosa

The gastric H,K-ATPase is an active transport protein that is responsible for the maintenance of a large pH gradient across the secretory canaliculus of the mammalian parietal cell. Acid secretion across these epithelial cell membranes is coupled to the potassium-stimulated hydrolysis of ATP catalyzed by H,K-ATPase, but the mechanism of coupling between ion transport and ATP hydrolysis is unknown. In order to investigate the enzymatic mechanism of this coupling, a peptide derived from the ATP binding site of H,K-ATPase has been purified and its amino acid sequence has been determined. The peptide was identified by the incorporation of a fluorescent probe, fluorescein 5'-isothiocyanate (FITC), into the active site before trypsin digestion of the protein. The labeling of the enzyme by FITC was associated with the irreversible inhibition of enzymatic activity, and both the labeling of the tryptic peptide and inhibition of activity were prevented when the reaction was performed in the presence of ATP. At 100% inhibition of activity, 3.5 +/- 1.6 nmol of FITC were incorporated per mg of protein. The amino acid sequence of the active site peptide is His-Val-Leu-Val-Met-Lys-Gly-Ala-Pro-Glu-Gln-Leu-Ser-Ile-Arg, and FITC reacts with the lysine. This sequence is very similar to sequences of fluorescein-labeled peptides from the ATP binding sites of Na,K-ATPase and Ca2+-ATPase, and suggests that the active site structures of these ion transport ATPases are similar.     

Temperature dependence of the rates of conformational changes reported by fluorescein 5'-isothiocyanate modification of H+,K(+)- and Na+,K(+)-ATPases.

Stopped-flow fluorometry has been used to measure the forward and reverse rates of the conformational change from E1 to E2 in the fluorescein-modified proton and sodium pumps (1) as a function of Na+ and K+ concentrations to verify the proposed mechanism of ion interaction with the enzymes and (2) as a function of temperature to gain insight into the nature of the conformational transition. (1) The fluorescence changes caused by Na+ and K+ are consistent with rapid competitive binding of the two ions to the E1 conformations of the enzymes followed by rate-limiting transitions between E1K and E2K. (2) Reaction coordinate diagrams for the E1K to E2K transitions in the H,K-ATPase and Na,K-ATPase are qualitatively similar. Enthalpy barriers to reaction are partially compensated by increased entropy in the transition states. However, there are striking quantitative differences between the two enzymes. The E2K to E1K reaction of the H,K-ATPase is more than 2 orders of magnitude faster (tau 1/2 = 6 ms at 22 degrees C) than the reverse rate of the Na,K-ATPase transition (tau 1/2 = 1.6 s), explaining repeated failure to detect a K(+)-"occluded" form of the H,K-enzyme. The E2K conformer of the Na,K-ATPase is 3 orders of magnitude more stable than E1K, while the E1K and E2K conformations of the H,K-ATPase are nearly equivalent energetically.     

Conformational transitions of detergent-solubilized Na,K-ATPase are conveniently monitored by the fluorescent probe 6-carboxy-eosin.

6-carboxy-eosin is introduced as a sensitive, non-covalently bound fluorescent probe for monitoring conformational changes in detergent-solubilized Na,K-ATPase. The dissociation constant for 6-carboxy-eosin is about 0.1 microM in 20 mM NaCl at 6 degrees C (pH 7.0) for Na,K-ATPase solubilized in C12E8. It is shown that the slow conformational change from E2 (in K+) to E1 (in Na+) is 4-fold more rapid in the solubilized state than in the membrane-bound state, both for shark rectal gland and pig kidney Na,K-ATPase. The rate of the E1 to E2 transition is rapid and of the same order of magnitude both for the membrane-bound and the solubilized enzyme. All conformational transitions are considerably slower for pig kidney enzyme than for shark enzyme, both in the membrane-bound and in the solubilized state.     

Characterization of Na,K-ATPase and H,K-ATPase enzymes with glycosylation-deficient beta-subunit variants by voltage-clamp fluorometry in Xenopus oocytes

The role of N-linked glycosylation of beta-subunits in the functional properties of the oligomeric P-type ATPases Na,K- and H,K-ATPase has been examined by expressing glycosylation-deficient Asn-to-Gln beta-variants in Xenopus oocytes. For both ATPases, the absence of the huge N-linked oligosaccharide moiety on the beta-subunit does not affect alpha/beta coassembly, plasma membrane delivery or functional activity of the holoenzyme. Whereas this is in line with several previous glycosylation studies on Na,K-ATPase, this is the first report showing that the cell surface delivery and enzymatic activity of the gastric H,K-ATPase is unaffected by the lack of N-linked glycosylation. Sulfhydryl-specific labeling of introduced cysteine reporter sites with the environmentally sensitive fluorophore tetramethylrhodamine-6-maleimide (TMRM) upon expression in Xenopus oocytes enabled us to further investigate potential effects of the N-glycans on more subtle enzymatic properties, like the distribution between E 1P/E 2P states of the catalytic cycle and the kinetics of the E 1P/E 2P conformational transition under presteady state conditions. For both Na,K-ATPase and H,K-ATPase, we observed differences in neither the voltage-dependent E 1P/E 2P ratio nor the kinetics of the E 1P/E 2P transition between holoenzymes comprising glycosylated and glycosylation-deficient beta-subunits. We conclude that the N-linked glycans on these essential accessory subunits of oligomeric P-type ATPases are dispensable for proper folding, membrane stabilization of the alpha-subunit and transport function itself. Glycosylation is rather important for other cellular functions not relevant in the oocyte expression system, such as intercellular interactions or basolateral versus apical targeting in polarized cells, as demonstrated in other expression systems.     

Effect of digitonin on the activity of Na,K-ATPase from bovine brain

The kinetic properties of intact and digitonin-treated Na,K-ATPase from bovine brain were studied. The temperature dependence curve for the rate of ATP hydrolysis under optimal conditions (upsilon 0) in the Arrhenius plots shows a break at 19-20 degrees. The temperature dependence curves for Km' and Km" have breaks at the same temperatures, while the Arrhenius plot for V is linear. The value of the Hill coefficient (nH) for ATP at 37 degrees is variable depending on ATP concentration, i. e. it is less than 1 at ATP concentrations below 50 mkM and is increased up to 3.2 at higher concentrations of the substrate. At high ATP concentrations the value of nH depends on temperature, falling down to 2.1 at 23 degrees and then down to 1 within the temperature range of 21-19 degrees. A further decrease in temperature does not significantly affect the nH value. Digitonin irreversibly inhibits Na, K-ATPase. ATP hydrolysis is more sensitive to the effect of the detergent than is nNPP hydrolysis, i. e. after complete inhibition of the ATPase about 40% of the phosphatase activity are retained. Treatment of Na,K-ATPase by digitonin results in elimination of the breaks in the Arrhenius plots for upsilon 0, Km' and Km", whereas the temperature dependence plot of V remains linear. Simultaneously digitonin eliminates the positive cooperativity of the enzyme for ATP. It is assumed that Na, K-ATPase from bovine brain is an oligomer of the (alpha beta) 4 type. Digitonin changes the type of interaction between the protomers within the oligomeric complex by changing the lipid environment of the enzyme or the type of protein -- lipid interactions.