Thrombin plasticity

Thrombin is the final protease generated in the blood coagulation cascade. It has multiple substrates and cofactors, and serves both pro- and anti-coagulant functions. How thrombin activity is directed throughout the evolution of a clot and the role of conformational change in determining thrombin specificity are issues that lie at the heart of the haemostatic balance. Over the last 20 years there have been a great number of studies supporting the idea that thrombin is an allosteric enzyme that can exist in two conformations differing in activity and specificity. However, recent work has shown that thrombin in its unliganded state is inherently flexible in regions that are important for activity. The effect of flexibility on activity is discussed in this review in context of the zymogen-to-protease conformational transition. Understanding thrombin function in terms of ‘plasticity’ provides a new conceptual framework for understanding regulation of enzyme activity in general. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.     

Thrombin plasticity

Thrombin is the final protease generated in the blood coagulation cascade. It has multiple substrates and cofactors, and serves both pro- and anti-coagulant functions. How thrombin activity is directed throughout the evolution of a clot and the role of conformational change in determining thrombin specificity are issues that lie at the heart of the haemostatic balance. Over the last 20 years there have been a great number of studies supporting the idea that thrombin is an allosteric enzyme that can exist in two conformations differing in activity and specificity. However, recent work has shown that thrombin in its unliganded state is inherently flexible in regions that are important for activity. The effect of flexibility on activity is discussed in this review in context of the zymogen-to-protease conformational transition. Understanding thrombin function in terms of 'plasticity' provides a new conceptual framework for understanding regulation of enzyme activity in general. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.     

An ensemble view of thrombin allostery

Abstract Thrombin is the central protease of the coagulation cascade. Its activity is tightly regulated to ensure rapid blood clotting while preventing uncontrolled thrombosis. Thrombin interacts with multiple substrates and cofactors and is critically involved in both pro- and anticoagulant pathways of the coagulation network. Its allosteric regulation, especially by the monovalent cation Na+, has been the focus of research for more than 30 years. It is believed that thrombin can adopt an anticoagulant ('slow') conformation and, after Na+ binding, a structurally distinct procoagulant ('fast') state. In the past few years, however, the general view of allostery has evolved from one of rigid structural changes towards thermodynamic ensembles of conformational states. With this background, the view of the allosteric regulation of thrombin has also changed. The static view of the two-state model has been dismissed in favor of a more dynamic view of thrombin allostery. Herein, we review recent data that demonstrate that apo-thrombin is zymogen-like and exists as an ensemble of conformations. Furthermore, we describe how ligand binding to thrombin allosterically stabilizes conformations on the continuum from zymogen to protease.     

Thrombin is a Na(+)-activated enzyme.

The amidase activity of human alpha-thrombin has been studied at steady state as a function of the concentration of several chloride salts, at a constant ionic strength I = 0.2 M. All kinetic steps of the catalytic mechanism of the enzyme have been solved by studies conducted as a function of relative viscosity of the solution. Among all monovalent cations, Na+ is the most effective in activating thrombin catalysis. This effect is observed with different amide substrates and also with gamma-thrombin, a proteolytic derivative of the native enzyme which has little clotting activity but retains amidase activity toward small synthetic substrates. The specific effects observed as a function of Na+ concentration are indicative of a binding interaction of this monovalent cation with the enzyme. The basis of this interaction has been explored by measurements of substrate hydrolysis collected in a three-dimensional matrix of substrate concentration, relative viscosity, and Na+ concentration, keeping the ionic strength constant with an inert cation such as choline or tetraethylammonium. The data have globally been analyzed in terms of a kinetic linkage scheme where Na+ plays the role of an allosteric effector. The properties of the enzyme change drastically upon binding of Na+, with substrate binding and dissociation, as well as deacylation, occurring on a time scale which is 1 order of magnitude faster. The apparent association constants for Na+ binding to the various intermediate forms of the enzyme have all been resolved from analysis of experimental data and are in the range of 50-100 M-1 at 25 degrees C. Studies conducted at different temperatures, in the range 15-35 degrees C, have revealed the enthalpic and entropic components of Na+ binding to the enzyme. The results obtained from steady-state measurements are supported by independent measurements of the intrinsic fluorescence of the enzyme as a function of Na+ concentration at a constant ionic strength I = 0.2 M, over the temperature range 15-35 degrees C. These measurements are indicative of a drastic conformational change of the enzyme upon Na+ binding to a single site. The energetics of Na+ binding derived from analysis of fluorescence measurements agree very well with those derived independently from steady-state determinations. It is proposed that thrombin exists in two conformations, slow and fast, and that the slow-->fast transition is triggered by binding of a monovalent cation. The high specificity in thrombin activation found in the case of Na+ is the result of its higher affinity compared to all other monovalent cations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Thrombin

Thrombin is a Na+-activated, allosteric serine protease that plays opposing functional roles in blood coagulation. Binding of Na+ is the major driving force behind the procoagulant, prothrombotic and signaling functions of the enzyme, but is dispensable for cleavage of the anticoagulant protein C. The anticoagulant function of thrombin is under the allosteric control of the cofactor thrombomodulin. Much has been learned on the mechanism of Na+ binding and recognition of natural substrates by thrombin. Recent structural advances have shed light on the remarkable molecular plasticity of this enzyme and the molecular underpinnings of thrombin allostery mediated by binding to exosite I and the Na+ site. This review summarizes our current understanding of the molecular basis of thrombin function and allosteric regulation. The basic information emerging from recent structural, mutagenesis and kinetic investigation of this important enzyme is that thrombin exists in three forms, E*, E and E:Na+, that interconvert under the influence of ligand binding to distinct domains. The transition between the Na+ -free slow from E and the Na+ -bound fast form E:Na+ involves the structure of the enzyme as a whole, and so does the interconversion between the two Na+ -free forms E* and E. E* is most likely an inactive form of thrombin, unable to interact with Na + and substrate. The complexity of thrombin function and regulation has gained this enzyme pre-eminence as the prototypic allosteric serine protease. Thrombin is now looked upon as a model system for the quantitative analysis of biologically important enzymes.     

Sodium ions as the effector of catalytic action of alpha-thrombin

A process of thrombin interaction with synthetic and natural substrates in the presence of Na+ ions has been analyzed in the survey. Molecular bases of this interaction have been presented, interrelation between the structure and function of thrombin has been noted; the nature of the unique site of its active centre which determines high thrombin affinity for the substrates and increase of its catalytic activity defined by the term of "specificity to univalent cations" have been considered in detail. Na+ ions play the role of allosteric effector in realization of two informational states of thrombin which penform, respectively, two fundamental and competing functions in the process of hemostasis. The molecular basis of the process of Na+ binding with thrombin is rather simple and depends only on the single site which importance for the enzyme function is marked by numerous investigations of a number of authors, and it is shown that Na(+)-binding site is distributed in the other zone of thrombin molecule as compared to exosites I and II, which do not take part in Na(+)-binding and allosteric transduction. Considerable attention was given to conformational conversions of a thrombin molecule caused by Na+ ions binding. It was shown that the transition slow <--> fast of the enzyme forms leads to formation of the ion pair Arg-187: Asp-222, optimal orientation of Asp-189 and Ser-195 for binding of substrates and considerable shift of the lateral chain Glu-192 determined by the disturbance of the lattice of water molecules which connects Na(+)-binding site with aminoacid Ser-195 of the active centre of the enzyme. New data have been presented which indicate that the changes in the lattice of water molecules and allosteric nucleus of Na(+)-binding site of the enzyme are the basic link of raising the affinity between the thrombin and substrate and mechanism of the enzyme activation by Na(+)-ions. The survey touches some problems of creation of allosteric inhibitors of thrombin which can take essential effect on Na(+)-binding site and favor stabilization of the anticoagulant slow-form of thrombin, and of enzyme rational mutants with selective specificity in respect of protein C which display effective and safe anticoagulant and antithrombotic effects in vivo.     

Thrombin: a paradigm for enzymes allosterically activated by monovalent cations

Enzymes activated by monovalent cations are abundantly represented in plants and in the animal world. The mechanism, of activation involves formation of a ternary intermediate with the enzyme-substrate complex, or binding of the cation to an allosteric site in the protein. Thrombin is a Na+-activated enzyme with procoagulant, anticoagulant and signaling roles. The binding of Na+ influences allosterically thrombin function and offers a paradigm for regulatory control of protease activity and specificity. Here we review the molecular basis of thrombin allostery as recently emerged from mutagenesis and structural studies. The role of Na+ in blood coagulation and the evolution of serine proteases are also discussed.     

Regulation of Na+-K+-ATPase: effect of Mg and Ca ions

The participation of Mg2+ and Ca2+ in complicated mechanisms of Na+, K(+)-ATPase regulation is discussed in the survey. The regulatory actions of Mg2+ on Na+, K(+)-ATPase such as its participation in phosphorylation and dephosphorylation of the enzyme, ADP/ATP-exchange inhibition, cardiac glycosides and vanadate binding with the enzyme, conformational changes induction during ATPase cycle are reviewed in detail. Some current views of mechanisms of above mentioned Mg2+ regulatory effects are discussed. The experimental evidence of Ca2+ immediate influence on the functional activity of Na+, K(+)-ATPase (catalytic, transport and glycoside-binding) are given. It's noted that these effects are based on the conformational changes in the enzyme and also on the phase transition in membrane induced by Ca2+. Unimmediate action of Ca2+ on Na+, K(+)-ATPase is also discussed, especially due to its effect on other membrane systems functionally linked with Na(+)-pump (for instance, due to Na+/Ca(+)-exchanger activation). It's concluded that Mg2+ and Ca2+ as "universal regulators" of the cell effectively influence the functional activity and conformational states of Na+, K(+)-ATPase.     

Mechanisms and consequences of Na+,K+-pump regulation by insulin and leptin.

Hormonal control of the Na+,K+-pump modulates membrane potential in mammalian cells, which in turn drives ion coupled transport processes and maintains cell volume and osmotic balance. Na+,K+-pump regulation is particularly important in the musculoskeletal, cardiovascular and renal systems. Decreased Na+,K+-pump activity can result in a rise in intracellular Na+ concentrations which in turn increase Na+/Ca2+ exchange, thereby raising intracellular Ca2+ levels. In cardiac and skeletal muscle, this could interfere with normal contractile activity. Similarly, in vascular smooth muscle the result would be resistance to vasodilation. Inhibition of the Na+,K+-pump can also reduce the driving force for renal tubular Na+ reabsorption, elevating Na+ excretion. By virtue of decreasing the membrane potential, thus allowing more efficient depolarization of nerve endings and by increasing intracellular Ca2+, inhibition of the Na+,K+-pump can increase nervous tone. The ability of insulin to stimulate the Na+,K+-pump in various cells and tissues, and the physiological significance thereof, have been well documented. Much less is known about the effect of leptin on the Na+,K+-pump. We have shown that leptin inhibits Na+,K+-pump function in 3T3-L1 fibroblasts. Defects in insulin and leptin action are associated with diabetes and obesity, respectively, both of which are commonly associated with cardiovascular complications. In this review we discuss the mechanisms of Na+,K+-pump regulation by insulin and leptin and highlight how, when they fail, they may contribute to the pathophysiology of hypertension associated with diabetes and obesity.     

Inhibition of (Na+,K+)-ATPase by magnesium ions and inorganic phosphate and release of these ligands in the cycles of ATP hydrolysis

The kinetic data of magnesium and inorganic phosphate inhibition of the (Na+,K+)-dependent ATP hydrolysis are consistent with a model where both ligands act independently and their release in the ATPase cycle is an ordered process where inorganic phosphate is released first. The effects of magnesium on the stimulation of the ATPase activity by Na+, K+ and ATP, and the inhibition of that activity by inorganic phosphate, are consistent with Mg2+ acting both as a 'product' and as a dead-end inhibitor. The dead-end Mg-enzyme complex would be produced with an enzyme form located downstream in the reaction sequence from the point where Mg2+ acts as a 'product' inhibitor. In the absence of K+, Mg2+ inhibition was reduced when either Na+ or ATP concentrations were increased well beyond those concentrations needed to saturate their high-affinity sites. This ATP effect suggests that the dead-end Mg-enzyme complex formation is affected by the speed of the E2-E1 conformational change. The present model is consistent with the formation of an Mg-phosphoenzyme complex insensitive to K+ which could become K+-sensitive in the presence of high Na+ concentrations. These Mg-enzyme complexes appear as intermediaries in the Na+-ATPase activity found in the absence of external Na+ and K+. These results can be interpreted on the basis of Mg2+ binding to a single site in the enzyme molecule. In addition, these experiments provide kinetic evidence indicating that the stimulation by external Na+ of the ATPase activity in the absence of K+ is due to a K+-like action of Na+ on the external K+ sites.     

The Na+ binding channel of human coagulation proteases: novel insights on the structure and allosteric modulation revealed by molecular surface analysis

Thrombovascular diseases result from imbalanced haemostasis and comprise important health problems in the aging population worldwide. The activity of enzymes pertaining to the coagulation cascade of mammalians exhibit several control mechanisms in order to maintain a proper balance between bleeding and thrombosis. For instance, human coagulation serine proteases carrying a F225 or Y225 are allosteric modulated by the binding of Na+ in a water-filled channel connected to the primary specificity pocket (S1 subsite) of these enzymes. We have characterized the structure, topography and lipophilicity of this channel in the ligand-free fast (sodium-bound) and slow (sodium-free) forms of thrombin, in the sole available structure of activated protein C and in several structures of the coagulation factors VIIa, IXa and Xa, differing in the nature of the bound inhibitor and in the occupancy of exosite-I as well as the Ca2+ and Na+ binding sites. Opposite to thrombin, the aqueous channels in all other coagulation enzymes sheltering a Na+ binding site do not have an aperture on the enzyme surface opposite to the S1 subsite entrance. In these enzymes, the lack of the three-residue insertion in loop 1 (183-189) as found in thrombin allied to compensatory mutations in the positions 187-185 and 222 effects a constriction in the water-filled channel that ends up by segregating the ion binding site from the S1 subsite. We also disclosed major topographical changes on the thrombin's surface upon sodium release and transition to the slow form that culminate in the narrowing of the S1 subsite entrance and, strikingly, in the loss of communication between the primary specificity pocket and the exosite-I. Such observation is in accordance with existing experimental data demonstrating thermodynamic linkage between these distant regions on the thrombin surface. Conformational changes in F34, L40, R73 and T74 were the main responsible for this effect. A path by which these changes in the vicinity of exosite-I could be transmitted to the S1 subsite and, consequently, to the sodium binding site is proposed.     

Involvement of the Na+/H+ exchanger in membrane phosphatidylserine exposure during human platelet activation

Platelet membrane phosphatidylserine (PS) exposure that regulates the production of thrombin represents an important link between platelet activation and the coagulation cascade. Here, we have evaluated the involvement of the Na+/H+ exchanger (NHE) in this process in human platelets. PS exposure induced in human platelets by thrombin, TRAP, collagen or TRAP+ collagen was abolished in a Na+ -free medium. Inhibition of the Na+/H+ exchanger (NHE) by 5-(N-Ethyl-N-Isopropyl) Amiloride (EIPA) reduced significantly PS exposure, whereas monensin or nigericin, which mimic or cause activation of NHE, respectively, reproduced the agonist effect. These data suggest a role for Na+ influx through NHE activation in the mechanism of PS exposure. This newly identified pathway does not discount a role for Ca2+, whose cytosolic concentration varies together with that of Na+ after agonist stimulation. Ca2+ deprivation from the incubation medium only attenuated PS exposure induced by thrombin, measured from the uptake of FM1-43 (a marker of phospholipid scrambling independent of external Ca2+). Surprisingly, removal of external Ca2+ partially reduced FM1-43 uptake induced by A23187, known as a Ca2+ ionophore. The residual effect can be attributed to an increase in [Na+]i mediated by the ionophore due to a lack of its specificity. Finally, phosphatidylinositol 4,5-bisphosphate (PIP2), previously reported as a target for Ca2+ in the induction of phospholipid scrambling, was involved in PS exposure through a regulation of NHE activity. All these results would indicate that the mechanism that results in PS exposure uses redundant pathways inextricably linked to the physio-pathological requirements of this process.     

A 75-kDa Na+,K+-ATPase competitive inhibitor protein isolated from rat brain cytosol binds to a site different from the ouabain-binding site.

A Na+,K+-ATPase inhibitor protein has been purified to homogeneity from rat brain cytosol by ammonium sulphate precipitation, DEAE anion-exchange chromatography and hydroxyapatite adsorption column chromatography. The purified protein migrates as a single polypeptide band of 75 kDa on 7.5% SDS/PAGE. Amino acid composition data shows the presence of a high number of acidic amino acids in the molecule in relation to the pI value of 4.6. The inhibitor binds Na+,K+-ATPase reversibly and blocks ATP binding sites at micromolar concentrations with an I50 of approximately 700 nm. As a result, formation of the phosphorylated intermediate of Na+,K+-ATPase is hindered in the presence of the inhibitor. It does not affect p-nitrophenylphosphatase activity. Tryptophan fluorescence studies and CD analysis suggest conformational changes of Na+,K+-ATPase on binding to the inhibitor.     

Intracellular Na+ regulates dopamine and angiotensin II receptors availability at the plasma membrane and their cellular responses in renal epithelia

The balance and cross-talk between natruretic and antinatruretic hormone receptors plays a critical role in the regulation of renal Na+ homeostasis, which is a major determinant of blood pressure. Dopamine and angiotensin II have antagonistic effects on renal Na+ and water excretion, which involves regulation of the Na+,K+-ATPase activity. Herein we demonstrate that angiotensin II (Ang II) stimulation of AT1 receptors in proximal tubule cells induces the recruitment of Na+,K+-ATPase molecules to the plasmalemma, in a process mediated by protein kinase Cbeta and interaction of the Na+,K+-ATPase with adaptor protein 1. Ang II stimulation led to phosphorylation of the alpha subunit Ser-11 and Ser-18 residues, and substitution of these amino acids with alanine residues completely abolished the Ang II-induced stimulation of Na+,K+-ATPase-mediated Rb+ transport. Thus, for Ang II-dependent stimulation of Na+,K+-ATPase activity, phosphorylation of these serine residues is essential and may constitute a triggering signal for recruitment of Na+,K+-ATPase molecules to the plasma membrane. When cells were treated simultaneously with saturating concentrations of dopamine and Ang II, either activation or inhibition of the Na+,K+-ATPase activity was produced dependent on the intracellular Na+ concentration, which was varied in a very narrow physiological range (9-19 mm). A small increase in intracellular Na+ concentrations induces the recruitment of D1 receptors to the plasma membrane and a reduction in plasma membrane AT1 receptors. Thus, one or more proteins may act as an intracellular Na+ concentration sensor and play a major regulatory role on the effect of hormones that regulate proximal tubule Na+ reabsorption.     

The activity and reaction specificity of tyrosine phenol-lyase regulated by monovalent cations

This work was aimed at studying the effect of monovalent inorganic cations (Li+, Na+, K+, Rb+, Cs+, NH+4) on the catalytic and spectral characteristics of tyrosine phenol-lyase from Citrobacter intermedius. These cations were shown to influence the proportion of the beta-elimination reaction rate to the rate of side transamination reaction. Most of the monovalent cations are non-competitive activators of the beta-elimination reaction; Li+ exerts no effect on the enzyme activity in this reaction; Na+ is an inhibitor of the beta-elimination reaction. The activation of tyrosine phenol-lyase by monovalent cations stems from the creation of an active holoenzyme form (lambda max 420 nm) due to conformational rearrangements of the protein molecule.     

A slow interconversion between active and inactive states of the (Na-K)ATPase.

We have examined slow changes in the rate of ATP hydrolysis for purified dog kidney Na+ and K+ stimulated adenosine triphosphatase [(Na-K)ATPase] at various concentrations of free Mg2+, Mg-ATP, K+, and Na+. The effect of these ligands on the rate of ATP hydrolysis is explained by a rapid binding step determining the initial rate of turnover followed by a slow conformational change. Inactivation of enzyme stored in the presence of ethylenediaminetetraacetic acid occurs upon adding free Mg2+, Mg-ATP, and K+; reactivation may be achieved if the concentration of these ligands is reduced. Because of the slow conformational change, the affinities for ligands affecting inactivation are time dependent. A model is presented to explain the effects of free Mg2+ and Ma-ATP on (Na-K)ATPase activity.     

Conformational transitions in fluorescein-labeled (Na,K)ATPase reconstituted into phospholipid vesicles

Fluorescein-labeled (Na,K)ATPase reconstituted into phospholipid vesicles has been used to study conformational transitions. Addition of K+ or Na+ to the vesicle medium induces fluorescence changes characteristic of the E2(K) or E1Na states of fluorescein-labeled (Na,K)ATPase (Karlish, S.J.D. (1980) J. Bioenerg. Biomembr. 12, 111-136). The cation effects are exerted from the cytoplasmic surface of inside-out-oriented pumps. Equilibrium cation titrations and measurements of rates of conformational transitions have led to the following observations. 1) The rate of E2(K)----E1Na or E2(T1)----E1Na is 4-6-fold faster and E1K----E2(K) is about 2-fold slower in vesicles compared to enzyme. In equilibrium titrations the K0.5 for K+ is higher and that for Na+ is lower for vesicles compared to enzyme. The conformational equilibrium E(1)2K----E2(2K) is apparently shifted toward E(1)2K in vesicles compared to enzyme. 2) Diffusion potentials, positive-outside, induced with valinomycin or Li+ ionophore AS701, do not affect the rates of E2(T1)----E1Na or E1K----E2(K), or equilibrium cation titrations. This demonstrates that the conformational transitions E(1)2K----E2(2K) are voltage-insensitive steps, confirming a prediction based on transport experiments. 3) In vesicles containing choline, K+, Na+, or Li+, the rate of E2(T1)----E1Na increases in the order given. Vesicles with reconstituted fluorescein-labeled (Na,K)ATPase provide a convenient system for correlating directly properties of conformational transitions with cation transport.     

Purification of Na+,K+-ATPase expressed in Pichia pastoris reveals an essential role of phospholipid-protein interactions

Na+,K+-ATPase (porcine alpha/his10-beta) has been expressed in Pichia Pastoris, solubilized in n-dodecyl-beta-maltoside and purified to 70-80% purity by nickel-nitrilotriacetic acid chromatography combined with size exclusion chromatography. The recombinant protein is inactive if the purification is done without added phospholipids. The neutral phospholipid, dioleoylphosphatidylcholine, preserves Na+,K+-ATPase activity of protein prepared in a Na+-containing medium, but activity is lost in a K+-containing medium. By contrast, the acid phospholipid, dioleoylphosphatidylserine, preserves activity in either Na+- or K+-containing media. In optimal conditions activity is preserved for about 2 weeks at 0 degrees C. Both recombinant Na+,K+-ATPase and native pig kidney Na+,K+-ATPase, dissolved in n-dodecyl-beta-maltoside, appear to be mainly stable monomers (alpha/beta) as judged by size exclusion chromatography and sedimentation velocity. Na+,K+-ATPase activities at 37 degrees C of the size exclusion chromatography-purified recombinant and renal Na+,K+-ATPase are comparable but are lower than that of membrane-bound renal Na+,K+-ATPase. The beta subunit is expressed in Pichia Pastoris as two lightly glycosylated polypeptides and is quantitatively deglycosylated by endoglycosidase-H at 0 degrees C, to a single polypeptide. Deglycosylation inactivates Na+,K+-ATPase prepared with dioleoylphosphatidylcholine, whereas dioleoylphosphatidylserine protects after deglycosylation, and Na+,K+-ATPase activity is preserved. This work demonstrates an essential role of phospholipid interactions with Na+,K+-ATPase, including a direct interaction of dioleoylphosphatidylserine, and possibly another interaction of either the neutral or acid phospholipid. Additional lipid effects are likely. A role for the beta subunit in stabilizing conformations of Na+,K+-ATPase (or H+,K+-ATPase) with occluded K+ ions can also be inferred. Purified recombinant Na+,K+-ATPase could become an important experimental tool for various purposes, including, hopefully, structural work.     

Purification and characterization of (Na+, K+)-ATPase. V. Conformational changes in the enzyme Transitions between the Na-form and the K-form studied with tryptic digestion as a tool.

1. Purified (Na+, K+)-ATPase consisting of membrane fragments was digested with trypsin. The time course of enzyme inactivation was related to the electrophoretic pattern of native and cleaved proteins remaining in the membrane. 2. Differences in both the inactivation kinetics and the cleavage of the large chain (mol. wt 98 000) allow distinction of two patterns of tryptic digestion of (Na+, K+)-ATPase seen with Na+ or K+ in the medium. 3. With K+, the inactivation of (Na+, K+)-ATPase is linear with time in semilogarithmic plots and the activity is lost in parallel with cleavage of the large chain to fragments with molecular weights 58 000 and 48 000. 4. With Na+, the inactivation curves are biphasic. In the initial phase of rapid inactivation, 50% of the activity is lost with minor changes in the composition of the large chain. In the final phase, the large chain is cleaved at a low rate to a fragment with a molecular weight of 78 000. 5. It is concluded that the regions of the large chain exposed in the presence of K+ are distinct from the regions exposed in presence of Na+ and that two conformations of (Na+, K+)-ATPase can be sensed with trypsin, a (t)K-form and a (t)Na-form. 6. Reaction of the (t)K-form with ATP cause transition to the (t)Na-form. Relatively high concentrations of ATP are required and Mg2+ is not necessary. Phosphorylation of (Na+, K+)-ATPase is accompanied by transition from the (t)Na-form to the (t)K-form. Previous kinetic data suggest that these conformational changes are accompanied by shifts in the affinities of the enzyme for Na+ and K+.     

(Na+ + K+)- and Na+-stimulated Mg2+-dependent ATPase activities in kidney of sea bass (Dicentrarchus labrax L.)

1. Sea bass kidney microsomal preparations contain two Mg2+ dependent ATPase activities: the ouabain-sensitive (Na+ + K+)-ATPase and an ouabain-insensitive Na+-ATPase, requiring different assay conditions. The (Na+ + K+)-ATPase under the optimal conditions of pH 7.0, 100 mM Na+, 25 mM K+, 10 mM Mg2+, 5 mM ATP exhibits an average specific activity (S.A.) of 59 mumol Pi/mg protein per hr whereas the Na+-ATPase under the conditions of pH 6.0, 40 mM Na+, 1.5 mM MgATP, 1 mM ouabain has a maximal S.A. of 13.9 mumol Pi/mg protein per hr. 2. The (Na+ + K+)-ATPase is specifically inhibited by ouabain and vanadate; the Na+-ATPase specifically by ethacrynic acid and preferentially by frusemide; both activities are similarly inhibited by Ca2+. 3. The (Na+ + K+)-ATPase is specific for ATP and Na+, whereas the Na+-ATPase hydrolyzes other substrates in the efficiency order ATP greater than GTP greater than CTP greater than UTP and can be activated also by K+, NH4+ or Li+. 4. Minor differences between the two activities lie in the affinity for Na+, Mg2+, ATP and in the thermosensitivity. 5. The comparison between the two activities and with what has been reported in the literature only partly agree with our findings. It tentatively suggests that on the one hand two separate enzymes exist which are related to Na+ transport and, on the other, a distinct modulation in vivo in different tissues.