Soybean nodule xanthine dehydrogenase: a kinetic study

Xanthine dehydrogenase was purified from soybean nodules and the kinetic properties were studied at pH 7.5. Km values of 5.0 +/- 0.6 and 12.5 +/- 2.5 microM were obtained for xanthine and NAD+, respectively. The pattern of substrate dependence suggested a Ping-Pong mechanism. Reaction with hypoxanthine gave Km's of 52 +/- 3 and 20 +/- 2.5 microM for hypoxanthine and NAD+, respectively. The Vmax for this reaction was twice that for the xanthine-dependent reaction. The pH dependence of Vmax gave a pKa of 7.6 +/- 0.1 for either xanthine or hypoxanthine oxidation. In addition the Km for xanthine had a pKa of 7.5 consistent with the protonated form of xanthine being the true substrate. Km for hypoxanthine varied only 2.5-fold between pH 6 and 10.7. Product inhibition studies were carried out with urate and NADH. Both products gave mixed inhibition with respect to both substrates. Xanthine dehydrogenase was able to use APAD+ as an electron acceptor for xanthine oxidation, with a Km at pH 7.5 of 21.2 +/- 2.5 microM and Vmax the same as that obtained with NAD+. Reduction of APAD+ by NADH was also catalyzed by xanthine dehydrogenase with a Km of 102 +/- 15 microM; Vmax was approximately 2.5 times that for the xanthine-dependent reaction, and was independent of pH between 6 and 9. Reaction with group-specific reagents indicated the possibility of an essential histidyl group. A thiol-modifying reagent did not cause inactivation of the enzyme. A role for the histidyl side chain in catalysis is proposed.     

The NADPH:O2 oxidoreductase of human neutrophils. Stoichiometry of univalent and divalent reduction of O2

The ratio of superoxide production to oxidation of NADPH affected by the NADPH:O2 oxidoreductase of human neutrophils is strongly influenced by pH, NADPH substrate concentration, aging of the enzyme, or its exposure to excess deoxycholate. Freshly prepared enzyme exhibited a Km for NADPH of 52 microM as determined by assaying NADPH oxidase activity, or approximately 33 microM by measurement of superoxide formation. In the range of 100-150 microM NADPH at pH 7.6 and in the presence of 0.06% deoxycholate, the univalent flux of electron equivalents given up by NADPH to O2 was 99%. Following storage of the oxidoreductase overnight on ice, its Km for NADPH rose to 125 microM as determined by monitoring oxidation of NADPH but was unaltered when measured in terms of superoxide production. Concomitantly, its capacity to affect univalent reduction of O2 fell approximately 20-30% under the same assay conditions. Univalent flux rates of less than 40% were observed with exposure of the enzyme to concentrations of deoxycholate in excess of 0.1% or to pH values below 6.0 or above 8.0. The capacity of the enzyme to carry out univalent reduction fell with increasing NADPH concentrations in a manner resembling that previously reported with increasing concentrations of xanthine in the case of xanthine oxidase (Fridovich, I. (1970) J. Biol. Chem. 245, 4053-4057). The reduced form of the neutrophil oxidoreductase, like xanthine oxidase, thus appears to be capable of conducting both 1- and 2-electron transfer steps in reducing O2. Its capacity to affect univalent reduction of O2 depends upon the concentration of electron donor (NADPH) supplied as well as conditions of storage and assay of the native enzyme.     

Inhibition of xanthine oxidase by uric acid and its influence on superoxide radical production.

The inhibition of xanthine oxidase by its reaction product, uric acid, was studied by steady state kinetic analysis. Uric acid behaved as an uncompetitive inhibitor of xanthine oxidase with respect to the reducing substrate, xanthine. Under 50 microM xanthine and 210 microM oxygen, the apparent K(i) for uric acid was 70 microM. Uric acid-mediated xanthine oxidase inhibition also caused an increase in the percentage of univalent reoxidation of the enzyme (superoxide radical production). Steady-state rate equations derived by the King-Altman method support the formation of an abortive-inhibitory enzyme-uric acid complex (dead-end product inhibition). Alternatively, inhibition could also depend on the reversibility of the classical ping-pong mechanism present in xanthine oxidase-catalyzed reactions.     

Substrate inhibition in a human variant of hypoxanthine-guanine phosphoribosyltransferase

Hypoxanthine-guanine phosphoribosyltransferase from a young man with purine overproduction and decreased purine salvage in fibroblast cultures was found to have low activity at concentrations of purine substrates at which the enzyme from normal individuals showed near maximal activity. The low enzyme activity was not associated with changes in the values of the Km(app) and Vmax(app) for any of the enzyme substrates. However, the enzyme activity was susceptible to substrate inhibition by hypoxanthine and guanine. The values obtained for the true Km, true Vmax, and true Ki for hypoxanthine were 26 +/- 10 microM, 1761 +/- 382 microunits/mg of protein, and 80 +/- 20 microM, respectively. The pattern of the substrate inhibition, as seen on a plot of 1/v versus hypoxanthine concentration, was characteristic of that associated with the formation of a dead-end complex between the inhibitory substrate and an enzyme form with which it normally does not react. The nature of this enzyme form and that of the dead-end complex was determined from double inhibition experiments, which indicated that hypoxanthine interacted with an enzyme-PPi intermediate to form an enzyme-hypoxanthine-PPi dead-end complex. The trapping of the enzyme in this inactive form explains the low activity at high purine base concentrations. Further information as to the nature of the reaction mechanism was obtained from plots of the reciprocal of enzyme activity versus the reciprocal of PP-ribose-P concentration at different fixed hypoxanthine concentrations. A pattern characteristic of uncompetitive substrate inhibition was obtained. This is indicative of an ordered sequential binding of substrates on the enzyme; PP-ribose-P binding before hypoxanthine. Thus, the variant enzyme showed an ordered sequential reaction mechanism, with the inhibitory substrate forming a dead-end complex with an enzyme-PPi intermediate.     

Xanthine:NAD+ oxidoreductase in the liver of grass snake Natrix natrix

The enzyme hydroxylating oxypurines in the liver of grass snake (Natrix natrix, Colubridae) was found to be a stable xanthine:NAD+ oxidoreductase (EC 1.2.1.37). The Michaelis constants for NAD+ and xanthine amounted to 14.4 and 12.3 microM, respectively. The enzyme affinity to hypoxanthine is lower than that to xanthine, but the former substrate is hydroxylated faster than the latter. The enzyme is only slowly and slightly (up to 22%) inhibited by NADH accumulating during xanthine hydroxylation. The above data and the time-course of hypoxanthine----xanthine----uric acid hydroxylation indicated that the kinetic properties of the snake liver enzyme provide in this uricotelic animal fast elimination of superfluous nitrogen derived from protein catabolism.     

Xanthine:NAD+ oxidoreductase from embryo liver of hen Gallus gallus

1. Xanthine:NAD+ oxidoreductase from chick embryo liver is unconvertible to the O2-dependent form, as is the enzyme from the adult hen. The Km for NAD+ (approximately 3 microM) of the embryonic enzyme is equal to, and the Km for xanthine (approximately 5 microM) is 2.5-fold lower, when compared with respective Km values of the "adult" hen enzyme. The inhibition of embryonic enzyme by NADH begins at 10 microM NADH and attains 13% at 35 microM NADH (respective data for the "adult" enzyme: 50 microM and 20% at 80 microM NADH). 2. The course of hypoxanthine----xanthine----uric acid hydroxylation catalyzed by the embryonic and "adult" enzymes is similar, however the rate of the first reaction is 2-fold lower for the embryonic enzyme. Under conditions of the limited nutritional system in the developing chick embryo, the low rate of hypoxanthine hydroxylation may promote reutilization of hypoxanthine for nucleotide synthesis.     

Purification and properties of xanthine dehydrogenase from Streptomyces cyanogenus.

Xanthine dehydrogenase has been purified to a homogeneous state from cell-free extracts of a strain of Streptomyces. The enzyme has a molecular weight of 125,000 and consists of two subunits with a molecular weight of 67,000. The isoelectric point is at pH 4.4. The enzyme exhibits absorption maxima at 273, 355, and 457 nm and contains FAD, iron, and labile sulfide in a molar ratio of 1 : 7 : 1 per subunit. Little molybdenum could be detected. The enzyme is most active at pH 8.7 and at 40 degrees C, and is stable between pH 7 and 12 (at 4 degrees C for 24 h) and below 55 degrees C (at pH 9 for 10 min). The activity is stimulated by K+ at a concentration of 50 mM or more and also by keeping the enzyme at pH 9 to 11. The activity is inhibited by cyanide, Tiron, and p-chloromercuribenzoate and by adenine and urate. Among the compounds tested, hypoxanthine, guanine, xanthine 2-hydroxypurine, and 6,8-dihydroxypurine are oxidized at considerable rates; hypoxanthine is the best substrate. NAD+ is the preferred electron acceptor. Km values of the enzyme for hypoxanthine, guanine, xanthine, and NAD+ are 0.055, 0.015, 0.15, and 0.11 mM, respectively. Marked differences in the properties of this enzyme compared to others are the activity towards guanine, which has a higher affinity for the enzyme than hypoxanthine and xanthine, and a higher reactivity with hypoxanthine than xanthine. The organism has been identified as Streptomyces cyanogenus.     

Purification and characterization of Escherichia coli xanthine-guanine phosphoribosyltransferase produced by plasmid pSV2gpt

The enzyme xanthine-guanine phosphoribosyltransferase from Escherichia coli cells harboring the plasmid pSV2gpt has been purified 30-fold to near homogeneity by single-step GMP-agarose affinity chromatography. It has a Km value of 2.5, 42 and 182 microM for the substrates guanine, xanthine and hypoxanthine, respectively, with guanine being the most preferred substrate. The enzyme exhibits a Km value of 38.5 microM for PRib-PP with guanine as second substrate and of 100 microM when xanthine is used as the second substrate. It is markedly inhibited by 6-thioguanine, GMP and to a lesser extent by some other purine analogues. Thioguanine has been found to be the most potent inhibitor. The subunit molecular weight of xanthine-guanine phosphoribosyltransferase was determined to be 19 000. The in situ activity assay on a nondenaturing polyacrylamide gel electrophoresis gel has indicated that a second E. coli phosphoribosyltransferase preferentially uses hypoxanthine as opposed to guanine as a substrate, and it does not use xanthine.     

Tunicamycin Inhibits Biosynthesis of Acid Mucopolysaccharides in Cultures of Chick Embryo Fibroblasts

Enterobacter cloacae KY 3074 grown in a medium containing xanthine, hypoxanthine, guanine, or their nucleosides and nucleotides produced xanthine oxidase. The purified enzyme preparation showed a major protein band and a few minor bands in acrylamide gel electrophoresis. Molecular oxygen was the most effective electron acceptor. Ferricyanide and 2,6-dichlorophenolindophenol also served as electron acceptors, but NAD and NADP did not. Xanthine and hypoxanthine were good substrates, and guanine was also an effective substrate. The activity was inhibited by Ag²⁺, Cu²⁺, PCMB, and ascorbate. The spectrum of the Enterobacter enzyme resembled that of some known xanthine oxidizing enzymes, and this suggests a similarity in the prosthetic groups of these enzymes. The molecular weight of the native enzyme and subunit was 128,000 and 69,000, respectively.     

Kinetic properties of spermine synthase from bovine brain.

Phosphofructokinase (EC 2.7.1.11) from a citric acid-producing strain of Aspergillus niger was partially purified by the application of affinity chromatography on Blue Dextran--Sepharose and the use of fructose 6-phosphate and glycerol as stabilizers in the working buffer. The resulting preparation was still impure, but free of enzyme activities interfering with kinetic investigations. Kinetic studies showed that the enzyme exhibits high co-operativity with fructose 6-phosphate, but shows Michaelis--Menten kinetics with ATP, which inhibits at concentrations higher than those for maximal activity. Citrate and phosphoenolpyruvate inhibit the enzyme; citrate increases the substrate (fructose 6-phosphate) concentration for half-maximal velocity, [S]0.5, and the Hill coefficient, h. The inhibition by citrate is counteracted by NH4+, AMP and phosphate. Among univalent cations tested only NH4+ activates by decreasing the [S]0.5 for fructose 6-phosphate and h, but has no effect on Vmax. AMP and ADP activate at low and inhibit at high concentrations of fructose 6-phosphate, thereby decreasing the [S]0.5 for fructose 6-phosphate. Phosphate has no effect in the absence of citrate. The results indicate that phosphofructokinase from A. niger is a distinct species of this enzyme, with some properties similar to those of the yeast enzyme and in some other properties resembling the mammalian enzyme. The results of determinations of activity at substrate and effector concentrations resembling the conditions that occur in vivo support the hypothesis that the apparent insensitivity of the enzyme to citrate during the accumulation of citric acid in the fungus is due to counteraction of citrate inhibition by NH4+.     

Characterization of Streptococcus pneumoniae 5-enolpyruvylshikimate 3-phosphate synthase and its activation by univalent cations.

The aroA gene (Escherichia coli nomenclature) encoding 5-enolpyruvylshikimate-3-phosphate (EPSP) synthase from the gram-positive pathogen Streptococcus pneumoniae has been identified, cloned and overexpressed in E. coli, and the enzyme purified to homogeneity. It was shown to catalyze a reversible conversion of shikimate 3-phosphate (S3P) and phosphoenolpyruvate (PEP) to EPSP and inorganic phosphate. Activation by univalent cations was observed in the forward reaction, with NH+4, Rb+ and K+ exerting the greatest effects. Km(PEP) was lowered by increasing [NH+4] and [K+], whereas Km(S3P) rose with increasing [K+], but fell with increasing [NH+4]. Increasing [NH+4] and [K+] resulted in an overall increase in kcat. Glyphosate (GLP) was found to be a competitive inhibitor with PEP, but the potency of inhibition was profoundly affected by [NH+4] and [K+]. For example, increasing [NH+4] and [K+] reduced Ki(GLP versus PEP) up to 600-fold. In the reverse reaction, the enzyme catalysis was less sensitive to univalent cations. Our analysis included univalent cation concentrations comparable with those found in bacterial cells. Therefore, the observed effects of these metal ions are more likely to reflect the physiological behavior of EPSP synthase and also add to our understanding of how to inhibit this enzyme in the host organism. As there is a much evidence to suggest that EPSP synthase is essential for bacterial survival, its discovery in the serious gram-positive pathogen S. pneumoniae and its inhibition by GLP indicate its potential as a broad-spectrum antibacterial target.     

A kinetic study of hypoxanthine oxidation by milk xanthine oxidase.

The course of the reaction sequence hypoxanthine----xanthine----uric acid catalysed by xanthine:oxygen oxidoreductase from milk was investigated on the basis of u.v. spectra taken during the course of hypoxanthine and xanthine oxidations. It was found that xanthine accumulated in the reaction mixture when hypoxanthine was used as a substrate. The time course of the concentrations of hypoxanthine, xanthine intermediate and uric acid product was simulated numerically. The mathematical model takes into account the competition of substrate, intermediate and product and the accumulation of the intermediate at the enzyme. This type of analysis permits the kinetic parameters of the enzyme for hypoxanthine and xanthine to be obtained.     

Purification and properties of purine hydroxylase II from Aspergillus nidulans

Purine hydroxylase II from Aspergillus nidulans has been purified to near homogeneity. The enzyme has a pI of 5.7, a molecular weight of 300,000, and two subunits with molecular weight of 153,000 each. The enzyme contains 2 FAD, 2 molybdenum atoms, and 4 (2 Fe-2S) iron-sulfur centers per molecule and exhibits broad specificity for reducing and oxidizing substrates. Among the more notable characteristics are the ability to oxidize hypoxanthine and nicotinic acid but not xanthine and virtually complete inactivity with oxygen. Moreover, while the enzyme is inactivated by borate and methanol, it is very resistant to cyanide and arsenite and it not inactivated by allopurinol. At infinite concentrations of reducing and oxidizing substrates, the Km for hypoxanthine was 119 microM, for nicotinic acid was 136 microM, and for NAD+ was 525 microM.     

A general method for relieving substrate inhibition in lactate dehydrogenases.

The mutation S163L in human heart lactate dehydrogenase removes substrate inhibition while only modestly reducing the turnover rate for pyruvate. Since this is the third enzyme to show this behaviour, we suggest that the S163L mutation is a general method for the removal of substrate inhibition in L-LDH enzymes. Engineering such enzymatic properties has clear industrial applications in the use of these enzymes to produce enantiomerically pure alpha-hydroxy acids. The mutation leads to two principal effects. (1) Substrate inhibition is caused by the formation of a covalent adduct between pyruvate and the oxidized form of the cofactor. The inability of S163L mutants to catalyse the formation of this inhibitory adduct is demonstrated. However, NMR experiments show that the orientation of the nicotinamide ring in the mutant NAD+ binary complex is not perturbed. (2) The mutation also leads to a large increase in the KM for pyruvate. The kinetic and binding properties of S163L LDH mutants are accounted for by a mechanism which invokes a non-productive, bound form of the cofactor. Molecular modelling suggests a structure for this non-productive enzyme-NADH complex.     

Adenosine-5'-phosphosulfate kinase from Penicillium chrysogenum: ligand binding properties and the mechanism of substrate inhibition.

[35S]Adenosine-5'-phosphosulfate (APS) binding to Penicillium chrysogenum APS kinase was measured by centrifugal ultrafiltration. APS did not bind to the free enzyme with a measurable affinity even at low ionic strength where substrate inhibition by APS is quite marked. However, APS bound with an apparent Kd of 0.54 microM in the presence of 5 mM MgADP. In the presence of 0.1 M (NH4)2SO4, Kd,app was increased to 2.1 +/- 0.7 microM. Bound [35S]APS was displaced by low concentrations of 3'-phosphoadenosine-5'-phosphosulfate (PAPS), or iso-(2') PAPS, or (less efficiently) by adenosine-3,5'-diphosphate (PAP) or adenosine-5'-monosulfate (AMS). The results support our conclusion that substrate inhibition of the fungal enzyme by APS results from the formation of a dead end E. MgADP.APS complex. That is, APS binds to the subsite vacated by PAPS in the compulsory (or predominately) ordered product release sequence (PAPS before MgADP). Radioligand displacement was used to verify the Kd for APS dissociation from E.MgADP.APS and to determine the Kd values for the dissociation of iso-PAPS (13 +/- 5 microM), PAP (4.8 mM), or AMS (5.2 mM) from their respective ternary enzyme.MgADP.ligand complexes. Incubation of the fungal enzyme with [gamma-32P]MgATP did not yield a phosphoenzyme that survives gel filtration or gel electrophoresis.     

Purification and substrate inactivation of xanthine dehydrogenase from Chlamydomonas reinhardtii.

Xanthine dehydrogenase (XDH) from the unicellular green alga Chlamydomonas reinhardtii has been purified to electrophoretic homogeneity by a procedure which includes several conventional steps (gel filtration, anion exchange chromatography and preparative gel electrophoresis). The purified protein exhibited a specific activity of 5.7 units/mg protein (turnover number = 1.9 .10(3) min-1) and a remarkable instability at room temperature. Spectral properties were identical to those reported for other xanthine-oxidizing enzymes with absorption maxima in the 420-450 nm region and a shoulder at 556 nm characteristic of molybdoflavoproteins containing iron-sulfur centers. Chlamydomonas XDH was irreversibly inactivated upon incubation of enzyme with its physiological electron donors xanthine and hypoxanthine, in the absence of NAD+, its physiological electron acceptor. As deduced from spectral changes in the 400-500 nm region, xanthine addition provoked enzyme reduction which was followed by inactivation. This irreversible inactivation also took place either under anaerobic conditions or whenever oxygen or any of its derivatives were excluded. Adenine, 8-azaxanthine and acetaldehyde which could act as reducing substrates of XDH were also able to inactivate it upon incubation. The same inactivating effect was observed with NADH and NADPH, electron donors for the diaphorase activity associated with xanthine dehydrogenase. In addition, partial activities of XDH were differently affected by xanthine incubation. We conclude that xanthine dehydrogenase inactivation by substrate is due to an irreversible process affecting mainly molybdenum center and that sequential and uninterrupted electron flow from xanthine to NAD+ is essential to maintain the enzyme in its active form.     

IMP dehydrogenase from the intracellular parasitic protozoan Eimeria tenella and its inhibition by mycophenolic acid

Mycophenolic acid (MA) was demonstrated to be an effective inhibitor of the growth of the intracellular parasitic protozoan Eimeria tenella in tissue culture and guanine was shown to reverse this inhibition as expected for an inhibitor of IMP dehydrogenase (IMP:NAD+ oxidoreductase, EC 1.1.1.205). A high performance liquid chromatography study of the intracellular nucleotide pools labeled with [3H]hypoxanthine was carried out in host cells lacking hypoxanthine-guanine phosphoribosyltransferase, and the depletion of guanine nucleotides demonstrated that the intracellular parasite enzyme was being inhibited by the drug. Kinetic studies carried out on the enzyme derived from E. tenella oocysts demonstrated substrate inhibition by NAD and mycophenolic acid inhibition similar to that found for mammalian enzymes, but different from that for bacterial enzymes. The inhibition by mycophenolic acid was not time-dependent and was immediately reversed upon dilution. As found previously for other IMP dehydrogenases, an Ordered Bi-Bi mechanism prevails with IMP on first followed by NAD, NADH off first, and then XMP. The kinetic patterns are consistent with substrate inhibition at high concentrations of NAD due to the formation of an E X XMP X NAD complex. Uncompetitive inhibition by MA versus IMP, NAD, and K+ was found and this was interpreted as evidence for the formation of an E X XMP X MA complex. A speculative mechanism for the inhibition of the enzyme is offered which is consistent with the fact that E X XMP X MA readily forms, whereas E X IMP X MA does not.     

Development of a biosensor for assaying postmortem nucleotide degradation in fish tissues

An enzyme sensor system has been developed to assess the freshness level in fish tissue. The system was designed to measure the K value, the concentration ratio of [Hx + HxR] and [Hx + HxR + IMP], where Hx, HxR, and IMP are hypoxanthine, inosine and inosine-5'-monophosphate, respectively. The [Hx + HxR] concentration in tissue extract was measured by nucleoside phosphorylase and xanthine oxidase immobilized on a preactivated nylon membrane and attached to the tip of a polarographic electrode. The electrode amperometrically detected the products of degradation, hydrogen peroxide and uric acid. For determination of [IMP + HxR + Hx], IMP was first converted to HxR by nucleotidase immobilized on the wall of a polystyrene tube. The enzyme electrode consisting of nucleoside phosphorylase and xanthine oxidase provided excellent reproducible results for at least 40 repeated assays and immobilized nucleotidase was good for at least 40 assays as well. The K value for each sample could be determined in ca. 10 min. When applied to K value measurements in several fish meats, the results obtained agreed well with those obtained by the conventional enzymatic method.     

Demonstration of cooperating alpha subunits in working (Na+ + K+)-ATPase by the use of the MgATP complex analogue cobalt tetrammine ATP

The MgATP complex analogue cobalt-tetrammine-ATP [Co(NH3)4ATP] inactivates (Na+ + K+)-ATPase at 37 degrees C slowly in the absence of univalent cations. This inactivation occurs concomitantly with incorporation of radioactivity from [alpha-32P]Co(NH3)4ATP and from [gamma-32P]Co(NH3)4ATP into the alpha subunit. The kinetics of inactivation are consistent with the formation of a dissociable complex of Co(NH3)4ATP with the enzyme (E) followed by the phosphorylation of the enzyme: (Formula: see text). The dissociation constant of the enzyme-MgATP analogue complex at 37 degrees C is Kd = 500 microM, the inactivation rate constant k2 = 0.05 min-1. ATP protects the enzyme against the inactivation by Co(NH3)4ATP due to binding at a site from which it dissociates with a Kd of 360 microM. It is concluded, therefore, that Co(NH3)4ATP binds to the low-affinity ATP binding site of the E2 conformational state. K+, Na+ and Mg2+ protect the enzyme against the inactivation by Co(NH3)4ATP. Whilst Na+ or Mg2+ decrease the inactivation rate constant k2, K+ exerts its protective effect by increasing the dissociation constant of the enzyme.Co(NH3)4ATP complex. The Co(NH3)4ATP-inactivated (Na+ + K+)-ATPase, in contrast to the non-inactivated enzyme, incorporates [3H]ouabain. This indicates that the Co(NH3)4ATP-inactivated enzyme is stabilized in the E2 conformational state. Despite the inactivation of (Na+ + K+)-ATPase by Co(NH3)4ATP from the low-affinity ATP binding site, there is no change in the capacity of the high-affinity ATP binding site (Kd = 0.9 microM) nor of its capability to phosphorylate the enzyme Na+-dependently. Since (Na+ + K+)-ATPase is phosphorylated Na+-dependently from the high-affinity ATP binding site although the catalytic cycle is arrested in the E2 conformational state by specific modification of the low-affinity ATP binding site, it is concluded that both ATP binding sites coexist at the same time in the working sodium pump. This demonstration of interacting catalytic subunits in the E1 and E2 conformational states excludes the proposal that a single catalytic subunit catalyzes (Na+ + K+)-transport.     

Effect of NADH on hypoxanthine hydroxylation by native NAD+-dependent xanthine oxidoreductase of rat liver, and the possible biological role of this effect.

The course of the reaction sequence hypoxanthine leads to xanthine leads to uric acid, catalysed by the NAD+-dependent activity of xanthine oxidoreductase, was investigated under conditions either of immediate oxidation of the NADH formed or of NADH accumulation. The enzymic preparation was obtained from rat liver, and purified 75-fold (as compared with the 25000 g supernatant) on a 5'-AMP-Sepharose 4B column; in this preparation the NAD+-dependent activity accounted for 100% of total xanthine oxidoreductase activity. A spectrophotometric method was developed for continuous measurements of changes in the concentrations of the three purines involved. The time course as well as the effects of the concentrations of enzyme and of hypoxanthine were examined. NADH produced by the enzyme lowered its activity by 50%, resulting in xanthine accumulation and in decreases of uric acid formation and of hypoxanthine utilization. The inhibition of the Xanthine oxidoreductase NAD+-dependent activity by NADH is discussed as a possible factor in the regulation of IMP biosynthesis by the 'de novo' pathway or (from unchanged hypoxanthine) by ther salvage pathway.