Protection by GTP from the effects of aluminum on the sodium efflux in barnacle muscle fibers

The idea that guanine nucleotides act as chelators of Al3+ and that Al interrupts the mechanism by which GTP or Gpp(NH)p stimulates the Na efflux in single muscle fibers from the barnacle Balanus nubilus has been tested. As a rule, injection of GTP or Gpp(NH)p into unpoisoned and ouabain-poisoned fibers produces a rise in the 22Na efflux that is usually transitory in nature. Fibers preinjected with GTP show a fall in the Na efflux following the injection of AlCl3 in an equimolar concentration. If, however, the concentration of Al for injection is halved, then GTP is found to be fully protective. Fibers preinjected with AlCl3 show little or no response to the injection of GTP. This is also the case with ouabain-poisoned fibers. Ouabain-poisoned fibers preinjected with GTP also show little or no response to the injection of AlCl3. The stimulatory response to the injection of AlCl3 into fibers preinjected with 0.5 M GTP is dose-dependent. A graded response is also found when 0.5 M AlCl3 is injected into fibers preinjected with GTP in varying concentrations. Gpp(NH)p is fully protective against the inhibitory effect of Al injection in unpoisoned fibers. Further, Gpp(NH)p abolishes the biphasic effect of Al injection on the ouabain-insensitive Na efflux. To strengthen the argument that GTP acts as a chelator of Al, a solution mixture of 0.5 M GTP/0.5 M AlCl3 (pH 1-2) was injected into unpoisoned fibers. This is found to lead to a smaller fall in the resting Na efflux than that obtained by injecting AlCl3 alone or injecting AlCl3 after GTP. It is thus quite clear that the barnacle muscle fiber is a useful preparation for studies of this type.     

Influence of insulin on sodium efflux in barnacle muscle fibers

Summary The efflux of radiosodium in single muscle fibers from the barnacleBalanus nubilus was irresponsive to internal or external application of insulin. However, this was not the case with fibers isolated from a barnacle specimen pre-exposed overnight to a large dose of insulin. External application of insulin to pre-exposed fibers caused a decrease in the rate of decline of the radiosodium efflux and stopped the decline in the fractional rate constant for Na efflux. Such kinetics were interpreted as indicating that insulin acts either by releasing sequestered Na or abolishing the process of sequestration. Internal application of saline slowed the rate of decline but failed to completely abolish the mechanism of sequestration. Only in the presence of insulin was the fractional loss of Na each second constant. Internal application of insulin caused a prompt step-up in the rate of Na efflux, followed by a reduced efflux rate constant. This meant that injected insulin caused the release of sequestered Na, leading to partial saturation of the efflux. The response of the Na efflux to injected denatured insulin, though resembling that to native insulin was much smaller in size. Internal application of lysozyme produced a transitory step-up in the rate of Na efflux but failed to produce the kinetics observed with native or denatured insulin. Overnight exposure of the barnacle to a dose of denatured insulin failed to render the fiber sensitive to external and internal application of denatured or native insulinin vitro. Experiments with ouabain-poisoned fibers showed that external or internal application of native insulin caused stimulation of the remaining Na efflux. They also showed that a 10-fold increase in the concentration of ouabain failed to further reduce the ouabaininsensitive Na efflux. Microinjection of GTP into ouabain-poisoned fibers pre-exposed to insulin resulted in a striking rise in the remaining Na efflux. The magnitude of this effect was considerably greater than that in unexposed fibers. The response which was dose-dependent could be blunted by prior injection of CaCl₂. Similarly, the response to CaCl₂ injection could be blunted by prior injection of GTP. The evidence brought forward is compatible with the view that insulin acts by abolishing the mechanism of internal Na sequestration and by increasing the activity of the guanylate cyclase system.     

Mode of action of theophylline on sodium efflux in barnacle muscle fibers

Summary The response of the Na efflux in unpoisoned barnacle fibers to 10mm theophylline is biphasic; i.e., inhibition is followed by stimulation. The stimulatory response is unaffected by ouabain. Fibers pretreated with ouabain show no transitory inhibition when 10mm theophylline is applied, but show prompt stimulation the magnitude of which is comparable to that observed with unpoisoned fibers. The same holds true for lower concentrations of theophylline. Prior injection of 500mm EGTA completely abolishes the biphasic action of 10mm theophylline. External application of 10mm theophylline following removal of external Ca²⁺ fails to bring about a biphasic effect. Ca²⁺ restoration, however, results in a moderate rise in the Na efflux. External application of 10mm theophylline stimulates the Na efflux into Ca²⁺-free artificial seawater (ASW) when the test fibers are pretreated with ouabain. Injection of the protein inhibitor of Walsh leads to reduced stimulation by 10mm theophylline of the Na efflux in unpoisoned fibers. Injection of the protein inhibitor of Corbin into unpoisoned fibers leads to reduced stimulation by 10mm theophylline. Injection of cAMP into ouabainpoisoned fibers, following internal application of Corbin's inhibitor and external application of 10mm theophylline, fails to cause a marked rise in the ouabain-insensitive Na efflux. Injection of Corbin's inhibitor into ouabain-poisoned fibers, following the onset of peak stimulation by 10mm theophylline, fails to reduce the Na efflux. Fibers injected with 1mm and 100mm EGTA and exposed to 10mm theophylline show a marked reduction in the response of the ouabain-insensitive Na efflux to injected cAMP when the concentration of theophylline is 10mm. A poor response to injected cAMP is also seen in fibers bathed in Ca-free ASW containing 10mm theophylline. Theophylline (10mm) fails to cause an enhanced stimulation of the ouabain-insensitive Na efflux into Ca-free 3mm-HEPES ASW or 10mm-Ca²⁺-3mm-HEPES ASW following the addition of protons to the bathing medium. An enhanced response is similarly not observed with injected cAMP following the addition of theophylline to the bathing medium. Injection of 8-fluorotheophylline, 3-isobutyl-1-methylxanthine and doxantrazole leads to a marked reduction in the response of the ouabain-insensitive Na efflux to injected cAMP. Contraction always takes place upon injecting these substances. These results are in keeping with the theory that theophylline acts chiefly by reducing myoplasmic pCa (pCa-log₁₀[Ca²⁺]), and that a reduced pCa leads to stimulation of the ouabain-insensitive Na efflux as the result of activation of the cGMP-dependent protein kinase system by newly formed cGMP.     

Lack of effect on the sodium efflux of the microinjection of D-Ins(1,4,5)P3 into ouabain-poisoned barnacle muscle-fibers.

A study has been carried out using relatively intact mature muscle fibers from the barnacle Balanus nubilus to see whether D-Ins(1,4,5)P3 stimulates the ouabain-insensitive Na efflux following its microinjection and whether this is accompanied by a contraction of the fiber. Part of the impetus for a study of this type came from the on-going debate between Vergara, Rojas and co-workers and Lea and co-workers, the former group holding the view that skinned barnacle fibers and skeletal fibers in general are responsive to this isomer. The evidence brought forward indicates that the injection of D-Ins(1,4,5)P3 in concentrations in the range of 10(-2) M to 10(-6) M into cannulated unskinned fibers pretreated with ouabain fails to increase the residual efflux, and additionally fails to elicit a contraction. A similar picture emerges with the use of non-hydrolyzable DL-Ins(1,4,5)P3[S]3, analog following its injection in a concentration of 0.5 microM. Higher concentrations of the analog were unavailable for use. This work also involved verification of the idea that an effect might be obtainable in depolarized fibers. However, doubling or tripling K0+ and injection of the isomer or the analog simultaneously failed to support this idea. Since nothing is known as to whether D-Ins(1,4,5)P3 influences the behavior of the Na(+)-Ca2+ exchanger when operating in the reverse mode, experiments were done to check this possibility. ATPNa2 which is though to activate Na(+)-Ca2+ exchange was injected prior to the isomer or the analog but no significant results were obtained. A similar line of reasoning was followed, that of activating the L-type Ca2+ channel by injecting GTPNa2 which in addition is known to activate adenylate cyclase. Again, neither the isomer nor the analog were effective. Thus, the only conclusion possible is that in relatively intact, mature barnacle fibers there is no coupling between the phosphoinositide signalling pathway and two other key systems, viz. the Na(+)-Ca2+ exchanger when operating in the reverse mode and the L-type Ca2+ channel. Equally clear is that for some unknown reason the ouabain-insensitive Na efflux and the contractile apparatus are insensitive to D-Ins(1,4,5)P3[S]3.     

Concerning the stimulation by injected cyclic AMP of the sodium efflux in barnacle muscle fibres and its transient nature

The efflux of 22Na in ouabain-poisoned barnacle muscle fibres and its transitory response to injected cAMP has been studied by using a new xanthine derivative, 1-propyl-3-methyl-7-(5-hydroxy-hexyl)-xanthine (PMX). Injection of PMX prior to cAMP fails to significantly alter the behaviour of the ouabain-insensitive Na efflux towards the nucleotide. By contrast, injection of PMX following peak stimulation by injected cAMP stops the rate constant for 22Na efflux from falling. This effect of PMX is not mimicked by injected HEPES. (a). Injection of Mg2+ following PMX brings about almost complete reversal of the sustained stimulatory response. (b). Injection of trace metals, e.g. Fe and Zn, following PMX brings about complete reversal of the sustained stimulatory response. (c). Injection of RI or RII subunits following PMX brings about partial reversal of the sustained stimulatory response. Partial reversal is also seen with externally applied imipramine (50 microM). These results support the view that the transitory nature of the response of the ouabain-insensitive Na efflux to injected cAMP is due to high phosphodiesterase activity in these fibres and that the major portion of the response itself is due to activation by cAMP of cAMP-dependent protein kinase.     

Ouabain binding to phospholipid-dependent adenosine triphosphatase.

The role of phospholipid in the binding of ouabain to the (Na+ + K+)-dependent adenosine triphosphatase was studied. Enzyme preparations obtained from rabbit kidney were treated with Lubrol WX to remove the phospholipid component essential for ATPase activity. Reconstituted enzyme samples were prepared by the addition of phosphatidylserine and sedimentation of an enzymically active lipid-protein complex. The binding of ouabain to both kinds of preparations was measured under equilibrium conditions with the use of 3H-labelled ouabain and initial ouabain concentrations in the range 0.01-1 micrometer. The main findings were: (i) (Mg2+ + Pi) promoted binding of significant quantities of ouabain only to the reconstituted enzyme; (ii) the absence of added Na+, (Mg2+ + ATP) similarly promoted binding only to the reconstituted samples; (iii) the addition of Na+ in the presence of (Mg2+ + ATP) increased the amount of ouabain bound to the reconstituted enzyme when the ouabain concentration was below about 0.1 micrometer, but it had no effect when the ouabain concentration was about 1 micrometer; (iv) (Mg2+ + ATP) induced ouabain binding to the depleted enzyme only when Na+ was also added; (v) the amount of ouabain bound to both depleted and reconstituted enzymes was the same in the presence of (Mg2+ + ATP + Na+); (vi) the reconstituted enzyme appeared to have a greater affinity for Na+ than did the depleted enzyme.     

Sensitivity of the sodium efflux in barnacle muscle fibers to the microinjection of ATP

Sodium efflux in barnacle muscle fibers is promptly stimulated by internal application of ATP. This response is markedly augmented by pretreatment of the barnacle fiber with ouabain. ArP is found to be considerably less effective than ATP. It is suggested that the stimulatory response of the ouabain-insensitive Na efflux to the microinjection of ATP may be due to a significant rise in the sarcoplasmic cAMP concentration caused by the catalytic action of an adenyl cyclase system.     

Sensitivity to injected cholera toxin of the sodium efflux in single barnacle muscle fibers

A study has been made of the effect of microinjected cholera toxin (CT) on the efflux in single barnacle muscle fibers. Characteristically, injected CT causes sustained stimulation of the ouabain-insensitive Na efflux but only after a lag phase. An effect is seen with as little as a 10(-7) M-solution of CT. Sustained stimulation after a lag phase is also seen following injection of subunit A fragment. Enrichment of fibers with NAD+ fails to enhance the response to CT. Prior injection of GTP or its non-hydrolyzeable analogue, Gpp(NH)p, markedly reduces the response to CT, whilst prior injection of CT reduces the response to guanine nucleotides. Evidence is also brought forward that omission of external Ca2+ reversibly reduces the response to CT and that pre- or postinjection of EGTA markedly reduces the response to CT. In addition, fibers preinjected with CT show increased aequorin light emission. Whereas verapamil and Cd2+ are ineffective, both Mg2+ and trace metals, e.g. Fe and Zn, reverse the response to CT following injection. Prior injection of protein kinase inhibitor reduces the response to CT. As for calmodulin inhibitors, e.g. chlorpromazine, imipramine and mepacrine, they are effective in reducing the response to CT but not calmodulin antibody (IgG). Collectively, the above results are compatible with the view that sustained stimulation of the ouabain-insensitive Na efflux by injected CT is due to persistent activation of adenylate cyclase by the toxin and that a fall in myoplasmic pCa facilitates or augments this activation mechanism.     

Interactions of physiological ligands with the Ca pump and Na/Ca exchange in squid axons

We have studied the interaction of physiological ligands other than Nai and Cai with the Ca pump and Na/Ca exchange in internally dialyzed squid axons. The results show the following. (a) Internal Mg2+ is an inhibitor of the Nao-dependent Ca efflux. At physiological Mg2+i (4 mM), the inhibition amounts to approximately 50%. The inhibition is partial and noncompetitive with Cai, and is not affected by Nai or ATP. The ATP-dependent uncoupled efflux is unaffected by Mgi up to 20 mM. Both components of the Ca efflux require Mg2+i for their activation by ATP. (b) At constant membrane potential, Ki is an important cofactor for the uncoupled Ca efflux. (c) Orthophosphate (Pi) activates the Nao-dependent Ca efflux without affecting the uncoupled component. Activation by Pi occurs only in the presence of Mg-ATP or hydrolyzable ATP analogues. Pi under physiological conditions has no effect on the uncoupled component; nevertheless, at alkaline pH, it inhibits the Ca pump, probably by product inhibition. (d) ADP is a potent inhibitor of the uncoupled Ca efflux. The Nao-dependent component is inhibited by ADP only at much higher ADP concentrations. These results indicate that (a) depending on the concentration of Ca2+i, Na+i Mg2+i, and Pi, the Na/Ca carrier can operate under a low- or high-rate regime; (b) the interactions of Mg2+i, Pi, Na+i, and ATP with the carrier are not interdependent; (c) the effect of Pi on the carrier-mediated Ca efflux resembles the stimulation of the Nao-dependent Ca efflux by internal vanadate; (d) the ligand effects on the uncoupled Ca efflux are of the type seen in the Ca pump in red cells and the sarcoplasmic reticulum.     

Properties of sodium pumps in internally perfused barnacle muscle fibers

To study the properties of the Na extrusion mechanism, giant muscle fibers from barnacle (Balanus nubilus) were internally perfused with solutions containing tracer 22Na. In fibers perfused with solutions containing adenosine 5'-triphosphate (ATP) and 30 mM Na, the Na efflux into 10 mM K seawater was approximately 25-30 pmol/cm2.s; 70% of this efflux was blocked by 50-100 microM ouabain, and approximately 30% was blocked by removal of external K. The ouabain-sensitive and K-dependent Na effluxes were abolished by depletion of internal ATP and were sigmoid-shaped functions of the internal Na concentration ([Na]i), with half-maxima at [Na]i approximately or equal to 20 mM. These sigmoid functions fit the Hill equation with Hill coefficients of approximately 3.5. Ouabain depolarized ATP-fueled fibers by 1.5-2 mV ([Na]i greater than or equal to 30 mM) but had very little effect on the membrane potential of ATP-depleted fibers; ATP depletion itself caused a 2-2.5- mV depolarization. When fueled fibers were treated with 3,4- diaminopyridine or Ba2+ (to reduce the K conductance and increase membrane resistance), application of ouabain produced a 4-5 mV depolarization. These results indicate that an electrogenic, ATP- dependent Na-K exchange pump is functional in internally perfused fibers; the internal perfusion technique provides a convenient method for performing transport studies that require good intracellular solute control.     

Characterization of Na(+)-dependent Mg2+ efflux from Mg2(+)-loaded rat erythrocytes

Na(+)-dependent Mg2+ efflux from Mg2(+)-loaded rat erythrocytes was determined from the increase of extracellular Mg2+ concentration or decrease of intracellular Mg2+ content, as measured by means of atomic absorption spectrophotometry. Mg2+ efflux was specifically combined with the uptake of Na+ at a stoichiometric ratio of 2Na+:1Mg2+, indicating electroneutral Na+/Mg2+ antiport. Na+/Mg2+ antiport depended on intracellular ATP and was inhibited by amiloride and quinidine, but was insensitive to strophanthin. Net Mg2+ efflux was only occurring at increased concentration of intracellular Mg2+ ([Mg2+]i), and stopped when the physiological Mg2+ content was reached. Intracellular Mg2+ acted cooperatively with a Hill coefficient of 2.4, which may indicate gating of Na+/Mg2+ antiport at increased [Mg2+]i. At increased intracellular Na+ concentration, Na+ competed with intracellular Mg2+ for Mg2+ efflux and Na+ could leave the rat erythrocyte via this transport system. Na+/Mg2+ antiport was working asymmetrically with respect to extra- and intracellular Na+ and Mg2+, and did not perform net Mg2+ uptake.     

An ATP-dependent Na+/Mg2+ countertransport is the only mechanism for Mg extrusion in squid axons

The components of magnesium efflux in squid axons have been studied under internal dialysis and voltage clamp conditions. The present report rules out the existence of an ATP-dependent, Nao- and Mgo-independent Mg2+ efflux (ATP-dependent Mg2+ pump) leaving the Mg2+-Na+ exchange system as the only mechanism for Mg2+ extrusion. The main features of the Mg2+ efflux are: (1) The efflux is completely dependent on ATP. (2) The efflux can be activated either by external Na+ (forward Mg2+-Na+ exchange) or external Mg2+ (Mg2+-Mg2+ exchange). (3) The mobility of the Mg2+ exchanger in the Na+o-loaded form is greater than that in the Mg2+-loaded one. (4) In variance with the Na+-Ca2+ exchange mechanism, Mg2+-Mg2+ exchange is not activated by external monovalent cations. (5) ATP gamma S replaces ATP in activating Mg2+-Na+ exchange suggesting that a phosphorylation/dephosphorylation process regulates this transport mechanism.     

Increased sensitivity to injected 5'-guanylylimidodiphosphate of the sodium efflux in barnacle muscle fibres preexposed to aldosterone

1. A study has been made of the response to injected Gpp(NH)p of the ouabain-insensitive Na efflux in barnacle muscle fibres preexposed to aldosterone. 2. The response to injected Gpp(NH)p is not only greater in size than in unexposed fibres but also sustained. 3. Injection of MgCl2 following peak stimulation causes a partial reversal of the response. 4. Injection of ATPNa2 (and 5'-App(NH)p) leads to a sustained stimulatory response which is not significantly greater than that seen in unexposed fibres. 5. MgCl2 injection causes complete reversal of this response. 6. The response of preexposed fibres to injected CaCl2 in varying concentration and to injected cholera toxin is not significantly different from that seen in unexposed fibres. 7. This is also true of Gpp(NH)p when it is injected after peak stimulation by cholera toxin. 8. Prior application of verapamil (10(-4)M) drastically reduces the response to injected Gpp(NH)p. 9. The residual response is sustained but markedly reduced by injected Mg2+, Fe or Zn. 10. Injection of PKI following Gpp(NH)p reduces the response, provided PKI is also injected before Gpp(NH)p. By contrast, injection of R11 subunits causes a partial reversal if injected only once. 11. Imipramine and trifluoperazine, when applied externally (5 X 10(-5)M), cause almost complete reversal of the response. 12. The suggestion is made that the response to injected Gpp(NH)p is mainly due to activation of Ca2+-channels resulting in activation of the calmodulin/Ca-dependent form of adenylate cyclase and that the primary site of aldosterone action is at the level of the calmodulin form of adenylate cyclase.     

Effects of magnesium and ATP on pre-steady-state phosphorylation kinetics of the Na+,K(+)-ATPase.

The aim of the present work was to elucidate the role played by ATP and Mg2+ ions in the early steps of the Na+,K(+)-ATPase cycle. The approach was to follow pre-steady-state phosphorylation kinetics in Na(+)-containing K(+)-free solutions under variable ATP and MgCl2 concentrations. The experiments were performed with a rapid mixing apparatus at 20 +/- 2 degrees C. The concentrations of free and complexes species of Mg2+ and ATP were calculated on the basis of a dissociation constant of 0.091 +/- 0.004 mM, estimated with Arsenazo III under identical conditions. A simplified scheme were ATP binds to the ENa enzyme, which is phosphorylated to MgEPNa and consequently dephosphorylated returning to the ENa form, was used. In the absence of ADP and phosphate four rate constants are relevant: k1 and k-1, the on and off rate constants for ATP binding; k2, the transphosphorylation rate constant and k3, the constant that governs the dephosphorylation rate. The values obtained were: k1 = 0.025 +/- 0.003 microM-1 ms-1 for both free ATP and ATPMg; k-1 = 0.038 +/- 0.004 ms-1 for free ATP and 0.009 +/- 0.002 ms-1 for ATPMg; k2 = 0.199 +/- 0.005 ms-1; k3 = 0.0019 +/- 0.0002 ms-1. The model that seems best to explain the data is one where (i) the role of true substrate can be played equally well by free ATP or ATPMg, and (ii) free Mg2+, an essential activator, acts by binding to a specific Mg2+ site on the enzyme molecule.     

In squid axons intracellular Mg2+ is essential for ATP-dependent Na+ efflux in the absence and presence of strophanthidin

The effect on Na+ efflux of removal of intracellular Mg2+ was studied in squid giant axons dialyzed without internal Ca2+. In the absence of Mg2i+, ATP was unable to stimulate any efflux of Na+ above the baseline of about 1 pmol . cm-2 . s-1. This behavior was observed in otherwise normal axons and in axons poisoned with 50 microM strophanthidin in the sea water. Reinstatement of 4 mM MgCl2 in excess to ATP in the dialysis solution brought about the usual response of Na+ efflux to ATP, external K+ and strophanthidin. The present experiments show that, regardless of the mechanism for the ATP-dependent Na+ efflux in strophanthidin-poisoned axons, this type of flux shares with the active Na+ extrusion the need for the simultaneous presence of intracellular ATP and Mg2+.     

Enhancement (by ATP, insulin, and lack of divalent cations) of ouabain inhibition of cation transport and ouabain binding in frog skeletal muscle; effect of insulin and ouabain on sarcolemmal (Na + K)MgATPase.

Using small, intact frog muscles, the basic properties of Na+ and K+ transport were shown to resemble those of the (Na+ + K+)Mg2+ATPase (EC 3.6.1.3) isolated from skeletal muscle. (a) External K+ is essential for Na+ exit and K+ entry after the muscles are Na+-loaded and K+-depleted; (b) the ouabain concentration causing maximum inhibition of recovery is the same for transport as for the inhibition of the isolated enzyme. Ouabain causes a decrease in the sorbitol space and causes muscle fibre swelling. Absence of Ca2+ and Mg2+ inhibits recovery of normal Na+ and K+ concentrations and increases the sorbitol space. Insulin stimulates K+ uptake and Na+ loss in intact muscles but has no effect on the isolated sarcolemmal (Na+ + K+)Mg2+ATPase. Absence of divalent cations, addition of external ATP and of insulin enhance the ouabain inhibition of recovery. Bound ouabain was measured using [3H]ouabain and [14C]sorbitol (to measure the extracellular space). The process of binding was slowly reversible and was saturable within a range of ouabain concentrations from 1.48 X 10(-7) to 5.96 X 10(-7) M. From the nonexchangeable ouabain bound, the density of glycoside receptors was estimated to be 650 molecules per square micrometre of membrane surface. The absence of divalent cations, addition of external ATP and of insulin significantly enhanced the amount of ouabain bound. Substitution of Na+ and K+ by choline greatly reduced the bound ouabain.     

Solvent effects on ouabain binding to the (Na+,K+)-ATPase of rat brain

The effects of the solvents deuterated water (2H2O) and dimethyl sulfoxide (Me2SO) on [3H]ouabain binding to (Na+,K+)-ATPase under different ligand conditions were examined. These solvents inhibited the type I ouabain binding to the enzyme (i.e., in the presence of Mg2+ + ATP + Na+). In contrast, both solvents stimulated type II (i.e., Mg2+ + Pi-, Mg2+-, or Mn2+-dependent) binding of the drug. The solvent effects were not due to pH changes in the reaction. However, pH did influence ouabain binding in a differential manner, depending on the ligands present. For example, changes in pH from 7.05 to 7.86 caused a drop in the rate of binding by about 15% in the presence of Mg2+ + Na+ + ATP, 75% in the Mg2+ + Pi system, and in the presence of Mn2+ an increase by 24% under similar conditions. Inhibitory or stimulatory effects of solvents were modified as various ligands, and their order of addition, were altered. Thus 2H2O inhibition of type I ouabain binding was dependent on Na+ concentration in the reaction and was reduced as Na+ was elevated. Contact of the enzyme with the Me2SO, prior to ligands for type I binding, resulted in a greater inhibition of ouabain binding than that when enzyme was exposed to Na+ + ATP first and then to Me2SO. Likewise, the stimulation of type II binding was greater when appropriate ligands acted on enzyme prior to addition of the solvent. Since Me2SO and 2H2O inhibit type I ouabain binding, it is proposed that this reaction is favored under conditions which promote loss of H2O, and E1 enzyme conformation; the stimulation of type II ouabain binding in the presence of the solvents suggests that this type of binding is favored under conditions which promote the presence of H2O at the active enzyme center and E2 enzyme conformation. This postulation of a role of H2O in modulating enzyme conformations and ouabain interaction with them is in concordance with previous observations.     

Incorporation of Na+ - Ca2+ antiporter and of (Na+ + K+)-ATPase into liposomes and demonstration of their non-identity

(Na+ + K+)-ATPase was isolated from the grey matter of brain and incorporated into liposomes. Most of the reconstituted enzyme was oriented 'inside-out' with respect to its in vivo orientation and externally added ATP promoted Na+ uptake that was inhibitable by internally trapped ouabain. Using the same proteoliposomes, an Na+ - Ca2+ exchange system was observed as indicated by the following pieces of evidence. (1) The Na+ gradient provided the only readily apparent driving force for acceleration of Ca2+ accumulation into proteoliposomes. (2) The antiporter was specific for Ca2+, high Mg2+ excess did not inhibit Ca2+ antiport. (3) The Na+ efflux was dependent on the extravesicular Ca2+ concentration. (4) The Na+ efflux was not inhibited by tetrodotoxin. The demonstrated Na+ - Ca2+ exchange could not be related to (Na+ + K+)-ATPase protein, since it was not purified with (Na+ + K+)-ATPase, as followed from transport studies with liposomes containing (Na+ + K+)-ATPase of different specific activity. The results strongly indicate that plasma membranes isolated from the grey matter of brain contain an Na+ - Ca2+ exchange system and that the proteoliposomes are suitable for further purification of the carrier molecule.     

Studies on ouabain-complexed (Na+ +K+)-ATPase carried out with vanadate

Vanadate is able to promote the binding of ouabain to (Na+ +K+)-ATPase and it is shown that vanadate is trapped in the enzyme-ouabain complex. Also ouabain-bound enzyme, the formation of which was facilitated by (Mg2+ +Na+ +ATP) or (Mg2+ +Pi), is accessible to vanadate when washed free of competing ligands used for the promotion of ouabain binding. For vanadate binding to (Na+ +K+)-ATPase and to enzyme-ouabain complexes a divalent cation (Mg2+ or Mn2+) is indispensable, indicating that the cation does not remain attached to the ouabain-bound enzyme. K+ further increases vanadate binding in the absence of ouabain, but seems to have no additional role in case of vanadate binding to enzyme-ouabain complexes. Mn2+ is more efficient than Mg2+ in promoting binding of vanadate and ouabain to (Na+ +K+)-ATPase. That K+ in combination with Mn2+, in analogy with the effect in combination with Mg2+, increases the equilibrium binding level of vanadate and decreases that of ouabain does not seem to favour the hypothesis of selection of a special E2-subconformation by Mn2+. The vanadate-trapped enzyme-ouabain complex was examined for simultaneous nucleotide binding which could demonstrate a two-substrate mechanism per functional unit of the enzyme. The acceleration by (Na+ +ATP) of ouabain release from the (Mg2+ +Pi)-facilitated enzyme-ouabain complex does not, as anticipated, support such a mechanism. On the other hand, the deceleration of vanadate release as well as of ouabain release from a (Mg2+ +vanadate)-promoted complex could be consistent with a two-substrate mechanism working out-of-phase.     

Ouabain-binding and phosphorylation of (Na+ + K+) ATPase treated with N-ethylmaleimide or oligomycin.

Ouabain-binding and phosphorylation of (Na+ mk+)-ATPase (EC 3.6.1.3) of the plasma membranes from kidney were investigated after treatment with N-ethylmaleimide or oligomycin. Either of these inhibitors brought about the following changes: the phosphoenzyme, formed in the presence of Na+, Mg2+ and ATP became essentially insensitive to splitting by K+ but was split by ADP. One mole of this ADP-sensitive phosphoenzyme bound one mole of ouabain but the enzyme-ouabain complex was less stable than in the native enzyme primarily because the rate of its dissociation increased. Ouabain was bound to the ADP-sensitive phosphoenzyme in the presence of Mg2+ alone and addition of inorganic phosphate enhanced both the rate of formation and the steady-state level of the enzyme-ouabain complex. The inhibitors did not affect the properties of this second type of complex. Both in the native enzyme and in the enzyme treated with the two inhibitors inorganic phosphate enhanced ouabain binding by phosphorylating the active center of the enzyme as shown (a) by mapping the labeled peptides from the enzyme after peptic digestion, (b) by inhibition of this phosphorylation with Na+ and (c) by the 1:1 stoichiometric relation between this phosphorylation and the amount of bound ouabain. Unlike the phosphoenzyme, the binding of ouabain remained sensitive to K+ in the enzyme treated with the inhibitors. K+ slowed ouabain-binding either in the presence of Na+, Mg2+ and ATP or of Mg2+ and inorganic phosphate. A higher concentration of K+ was needed to slow ouabain-binding either in the presence of Na+, Mg2+ and ATP or of Mg2+ and inorganic phosphate. A higher concentration of K+ was needed to slow ouabain-binding than to stimulate dephosphorylation. This finding is interpreted as being an indication of separate sites for K+ on the enzyme: a site(s) with high K+-affinity which stimulates dephosphorylation, another site(s) with moderate K+-affinity which inhibits ouabain-binding. Inhibitors may enhance formation of the ADP-sensitive phosphoenzyme by blocking interaction between K+ and the site(s) with high affinity.