Three hydroxylations incorporating molecular oxygen in the aerobic biosynthesis of ubiquinone in Escherichia coli.

The biosynthetic origin of the oxygen atoms of ubiquinone 8 from aerobically grown Escherichia coli was studied by 18O labeling. An apparatus was developed which allowed the growth of cells under a defined atmosphere. Mass spectral analysis of ubiquinone 8 from cells grown under highly enriched 18O2 showed that three oxygen atoms of the quinone are derived from molecular oxygen. It was established that the molecular oxygen is incorporated into the two methoxyl groups (at C-5 and C-6) and one of the carbonyl positions of the ubiquinone molecule by demonstrating that only one of the incorporated oxygens will exchange with water under acidic conditions that specifically catalyze the exchange of carbonyl, but not methoxyl, oxygens. That the C-4 carbonyl oxygen is derived from molecular oxygen was shown by the incorporation of three atoms of 18O2 into ubiquinone 8 biosynthesized from added 4-hydroxybenzoic acid. Comparison of ubiquinone 8 and menaquinone 8 from E. coli grown under 18O2 confirmed that the labeled carbonyl oxygen of the [18O2]ubiquinone 8 is incorporated biosynthetically and not by chemical exchange in the cell. It is concluded that the three hydroxylation reactions involved in the pathway for the aerobic biosynthesis of ubiquinone are all catalyzed by monooxygenases. The implications of this study for the anaerobic biosynthesis of ubiquinone 8 in E coli are discussed.     

Purine nucleoside phosphorylase cleaves the C--O bond of ribose 1-phosphate. Evidence from the 18O shift in 31P NMR.

An equilibrium mixture of highly enriched [18(O)]Pi (represents the mixture of [[18(O)4]Pi, [[18(O)3]Pi, [18(O)2]Pi as represented in the figures, unless otherwise specified), alpha-D-ribose 1-[16(O)]phosphate, and hypoxanthine plus inosine was equilibrated with calf spleen purine-nucleoside phosphorylase (EC 2.4.2.1). The 31P NMR spectrum clearly indicated the formation of alpha-D-ribose 1-[18(O)4]-phosphate and of [16(O)]Pi. Incubation for the same time span in the absence of alpha-D-ribose 1-phosphate left the [18(O)4]Pi isotopic distribution unchanged. The results clearly demonstrated that the C--O bond of alpha-D-ribose 1-phosphate is cleaved in the enzymatic reaction. It is unlikely that the enzyme catalyzes the exchange of oxygen between Pi and H2O. Several possible mechanistic pathways are ruled out by the results, which demand attack by a phosphate oxygen at the anomeric C-1' atom.     

A new synthesis of adenosine 5'-([gamma(R)-17O,18O]-gamma-thiotriphosphate) and its use to determine the stereochemical course of the activation of glutamate by glutamine synthetase

A new synthetic route to adenosine 5'-([gamma(R)-17O,18O]-gamma-thiotriphosphate) is described which combines chemical methods for introducing the heavy oxygen isotopes and enzymic methods for achieving the enantiospecificity. This material was used as a substrate for the activation of glutamate catalyzed by glutamine synthetase from Salmonella typhimurium. Analysis of the chirality of the [16O,17O,18O]thiophosphate produced showed that the reaction proceeds with inversion of configuration on phosphorus. This result, taken together with the positional isotope exchange studies of Midelfort and Rose [Midelfort, C. F., & Rose, I.A. (1976) J. Biol. Chem. 251, 5881-5887], demonstrates that the activation of glutamate to form gamma-glutamyl phosphate proceeds by a direct "in-line" transfer of the phosphoryl group.     

Characterization and crystal structure of cadmium(II) halide complexes with amino acids and their derivatives: VII. Crystal structures of aquadibromo(3-aminopropanoic acid)cadmium(II), dichloro(4-aminobutanoic acid)cadmium(II), diaquabis(aminohexanoic acid)cadmium(II) tetrachlorocadmium(II), and dibromo(azetidine-3-carboxylic acid)cadmium(II)

Seven cadmium complexes: [CdX2(Hapro)(H2O)n] (X: Cl(1), Br(2)), [CdX2(Hgaba)] (X: Cl(3), Br(4)), [Cd(Hahex)2(H2O)2][CdCl4] (5), and [CdX2(Haze-3)](H2O)n (X: Cl(6), Br(7)) have been prepared and investigated by means of IR and FT Raman spectra. The crystal and molecular structures of 2, 3, 5 and 7 were determined by a single-crystal X-ray diffraction method. In complex 2, the cadmium atom is in a distorted octahedral geometry, ligated by two carboxyl oxygen atoms of Hapro, a water molecule, and three bromine atoms; one is terminal and each of the other two is bridging two cadmium atoms to make a polymer. The structure of 3 consists of one-dimensional polymers bridged by two chlorine atoms and a carboxyl group. The carboxyl oxygen atoms of Hgaba coordinate forkedly to two cadmium atoms. The cadmium atom of [Cd(Hahex)2(H2O)2]2+ in complex 5 is in a distorted octahedral geometry, ligated by four carboxyl oxygen atoms of two molecules of Hahex and by two water molecules. [Cd(Hahex)2(H2O)2]2+ exists between two layers which are formed of infinite [CdCl4]2- chains. The carboxyl oxygen atoms of Hahex coordinate to the same cadmium atom. In complex 7, the cadmium atom is ligated by two carboxyl oxygen atoms and four bridging bromine atoms to make a polymer.     

Arachidonic acid epoxides. Demonstration through [18O]oxygen studies of an intramolecular transfer of the terminal hydroxyl group of (12S)-hydroperoxyeicosa-5,8,10,14-tetraenoic acid to form hydroxyepoxides

Purified 12-hydroperoxyeicosa - 5, 8, 10, 14 - tetrae noic acid (12-HPETE) containing deuterium atoms at 5, 6, 8, 9, 11, 12, 14, and 15 was prepared by incubating octadeuterated arachidonic acid with a platelet preparation in air or [18O]oxygen gas. A mixture of 12-HPETE containing 16O16O:18O18O (5:4) was subsequently prepared and incubated with hematin in phosphate buffer (pH 7.4); in another experiment the same mixture of 12-HPETE was incubated with a rat lung preparation (0-30% ammonium sulfate) which lacked epoxide hydratase activity. Gas chromatography-mass spectrometry negative ion chemical ionization analysis of the extracted products after conversion into pentafluorobenzyl-trimethylsilyl derivatives indicated that the products from both incubations, i.e. 12-hydroxyeicosa - 5,8,10,14 - tetraenoic acid (12 - HETE), 8 - hydroxy - 11,12-epoxyeicosa - 5,9,14 - trienoic acid (8H-11,12-EPETE), 10H - 11,12-epoxyeicosa - 5,8,14 - trienoic acid (10H-11,12-EPETE), and 8,11,12-trihydroxyeicosa-5,9,14-trienoic acid, all retained either two [16O]oxygen or two [18O]oxygen atoms of starting 12-HPETE and that no mixed species existed which contained one [16O]oxygen and one [18O]oxygen atom. These results demonstrate for the first time in the arachidonic acid series an intramolecular transfer of the terminal hydroxyl group of the hydroperoxide of 12-HPETE to the C-8 or C-10 alkyl positions to form the hydroxyepoxides 8H-11,12-EPETE and 10H-11,12-EPETE. This reaction carried out by both hematin in the absence of protein and the rat lung preparation is suggestive of a metal-hydroperoxide-olefin "cage" complex facilitating a concerted reaction in which the terminal hydroxyl group of the hydroperoxide is trapped by alkyl free radical centers.     

Facile oxygen exchanges of phosphoenolpyruvate and preparation of [18O]phosphoenolpyruvate

Phosphoenolpyruvate when heated in acidic solution exchanges its phosphoryl and carboxyl oxygens rapidly and its enolic oxygen much more slowly with oxygens from water. The incorporation of 18O into phosphoenolpyruvate was measured by gas chromatography-mass spectrometry and phosphorus-31 nuclear magnetic resonance after heating in H218O at 98 degrees C. The rates of exchange of all six oxygens of phosphoenolpyruvate with water increase with increasing acidity, and the phosphoryl oxygens exchange more rapidly than the carboxyl oxygens. The rate of exchange of each oxygen of the phosphoryl group is 16-fold greater than the hydrolysis rate at 1 N HCl. This provides a simple and useful method for the synthesis of [18O]phosphoenolpyruvate highly enriched in its phosphoryl-group oxygens. An enrichment of 89% was obtained with a 50% yield. The [18O]-phosphoenolpyruvate showed a binomial distribution of 18O in the phosphoryl-group oxygens. The exchange may be explained by the reversible formation of a transient cyclic phosphate and, for exchange of the enolic oxygen, a transient acyl phosphate. Preparation of [18O]phosphoenolypyruvate from [18O]Pi by a chemical synthesis from beta-chlorolactate was not satisfactory because of drastic loss of 18O during the procedures used. Some loss of 18O also occurred during an enzymic synthesis with KCNO, [18O]Pi, carbamate kinase, and pyruvate kinase.     

Phosphoglucoisomerase-catalyzed interconversion of hexose phosphates; comparison with phosphomannoisomerase

The isotopic discrimination, diastereotopic specificity and intramolecular hydrogen transfer characterizing the reaction catalyzed by phosphomannoisomerase are examined. During the monodirectional conversion of D-[2-3H]mannose 6-phosphate to D-fructose 6-phosphate and D-fructose 1,6-bisphosphate, the reaction velocity is one order of magnitude lower than with D-[U-14C]mannose 6-phosphate and little tritium (less than 6%) is transferred intramolecularly. Inorganic phosphate decreases the reaction velocity but favours the intramolecular transfer of tritium. Likewise, when D-[1-3H]fructose 6-phosphate prepared from D-[1-3H]glucose is exposed solely to phosphomannoisomerase, the generation of tritiated metabolites is virtually restricted to 3H2O and occurs at a much lower rate than the production of D-[U-14C]mannose 6-phosphate from D-[U-14C]fructose 6-phosphate. However, no 3H2O is formed when D-[1-3H]fructose 6-phosphate generated from D-[2-3H]glucose is exposed to phosphomannoisomerase, indicating that the diastereotopic specificity of the latter enzyme represents a mirror image of that of phosphoglucoisomerase. Advantage is taken of such a contrasting enzymic behaviour to assess the back-and-forth flow through the reaction catalyzed by phosphomannoisomerase in intact cells exposed to D-[1-3H]glucose, D-[5-3H]glucose or D-[6-3H]glucose. Relative to the rate of glycolysis, this back-and-forth flow amounted to approx. 4% in human erythrocytes and rat parotid cells, 9% in tumoral cells of the RINm5F line and 47% in rat pancreatic islets.     

Mechanism of formation of the ester linkage between heme and Glu310 of CYP4B1: 18O protein labeling studies

Cytochrome P450s in the CYP4 family covalently bind their heme prosthetic group to a conserved acidic I-helix residue via an autocatalytic oxidation. This study was designed to evaluate the source of oxygen atoms in the covalent ester link in CYP4B1 enzymes labeled with [18O]glutamate and [18O]aspartate. The fate of the heavy isotope was then traced into wild-type CYP4B1 or the E310D mutant-derived 5-hydroxyhemes. Glutamate-containing tryptic peptides of wild-type CYP4B1 were found labeled to a level of 11-13% 18O. Base hydrolysis of labeled protein released 5-hydroxyheme which contained 12.8 +/- 1.9% 18O. Aspartate-containing peptides of the E310D mutant were labeled with 6.0-6.5% 18O, but as expected, no label was transmitted to recovered 5-hydroxyheme. These data demonstrate that the oxygen atom in 5-hydroxyheme derived from wild-type CYP4B1 originates in Glu310. Stoichiometric incorporation of the heavy isotope from the wild-type enzyme supports a perferryl-initiated carbocation mechanism for covalent heme formation in CYP4B1.     

Examination of the mechanism of sucrose synthetase by positional isotope exchange

The mechanism of the sucrose synthetase reaction has been probed by the technique of positional isotope exchange. [beta-18O2, alpha beta-18O]UDP-Glc has been synthesized starting from oxygen-18-labeled phosphate and the combined activities of carbamate kinase, hexokinase, phosphoglucomutase, and uridine diphosphoglucose pyrophosphorylase. The oxygen-18 at the alpha beta-bridge position of the labeled UDP-Glc has been shown to cause a 0.014 ppm upfield chemical shift in the 31P NMR spectrum of both the alpha- and beta-phosphorus atoms in UDP-Glc relative to the unlabeled compound. The chemical shift induced by each of the beta-nonbridge oxygen-18 atoms was 0.030 ppm. Incubation of [beta-18O2, alpha beta-18O]UDP-Glc with sucrose synthetase in the presence and absence of 2,5-anhydromannitol did not result in any significant exchange of an oxygen-18 from the beta-nonbridge position to the anomeric oxygen of the glucose moiety. It can thus be concluded that either sucrose synthetase does not catalyze the cleavage of the scissile carbon-oxygen bond of UDP-Glc in the absence of fructose or, alternatively, the beta-phosphoryl group of the newly formed UDP is rotationally immobilized.     

31P and 13C NMR studies of oxygen transfer during catalysis by 3-deoxy-D-manno-octulosonate cytidylyltransferase from Escherichia coli

[18O]3-Deoxy-D-manno-octulosonate (KDO), labeled at the anomeric oxygen, was prepared by exchange with [18O]H2O and used to follow the route of oxygen transfer during cytidine 5'-monophosphate-3-deoxy-D-manno-octulosonate (CMP-KDO) formation catalyzed by 3-deoxy-D-manno-octulosonate cytidylyl-transferase (CMP-KDO synthetase). The 31P-NMR signal of the phosphoryl group of CMP-KDO (-5.85 ppm), which appeared as a single resonance when CMP-KDO formation took place with unenriched KDO, appeared as two peaks when CMP-KDO formation took place in the presence of a mixture of [16O]-and [18O]KDO. These results demonstrate the retention of 18O during CMP-KDO formation. Confirmation that the labeled oxygen in CMP-KDO was retained in the "bridge" position between CMP and KDO came from 13C-NMR studies of CMP-KDO formed in the presence of 90% [2-13C, 18O] KDO. The prominent C-2 KDO resonance in CMP-KDO, which is normally a doublet at 101.4 ppm (Kohlbrenner, W.E., and Fesik, S.W. (1985) J. Biol. Chem. 260, 14695-14700), appeared as four peaks when a mixture of [2-13C,16O]- and [2-13C, 18O]KDO was used, confirming the direct bonding of 18O to the C-2 of KDO in CMP-KDO. These results are consistent with a nucleophilic displacement mechanism for CMP-KDO formation.     

The mechanism of the attachment of esterifying alcohol in bacteriochlorophyll a biosynthesis.

The mechanism through which the C-17(3) carboxy group of bacteriochlorophyllide a is esterified to produce bacteriochlorophyll aphytyl of Rhodopseudomonas spheroides and bacteriochlorophyll ageranylgeranyl of Rhodospirillum rubrum was studied by using 5-aminolaevulinate labelled with 18O at its C-1 carboxy oxygen atoms. The latter species was prepared by an exchange reaction in which 5-aminolaevulinate hydrochloride was heated in H218O in an autoclave. A method for the determination of the 18O content of the C-1 oxygen atoms of 5-aminolaevulinate was developed. As a prelude to the mechanistic work, a systematic study was undertaken to establish the optimal conditions under which a significant proportion of the bacteriochlorophyll a of the two photosynthetic organisms originated from the exogenously added 5-aminolaevulinate. It was found that, when Rps. spheroides and Rsp. rubrum were grown in the presence of about 0.15mM- and 1.2mM-5-aminolaevulinate respectively, 30-40% of their chlorophyll was derived from the added precursor. In these conditions, 5-amino[1,4-18O3]laevulinate was incorporated into bacteriochlorophyll aphytyl and bacteriochlorophyll ageranylgeranyl by the relevant organisms. The samples of chlorophylls were then hydrolysed with alkali to obtain phytol and geranylgeraniol, which were converted into the corresponding trimethylsilyl derivatives and analysed by gas chromatography-mass spectrometry. The data were used to deduce that the alcohols contained 90-95% of the 18O originally present at each of the C-1 oxygen atoms of the precursor 5-aminolaevulinate. In the light of these results it is suggested that the ester bond at C-17(3) is formed, not by a chlorophyllase type of enzymic reaction, but by a process involving the nucleophilic attack by the C-17(3) carboxylate group of the chlorophyllide on the activated form of an isoprenyl alcohol.     

Measurement of the metabolism of energy substrates in individual bovine blastocysts

Individual blastocysts from cows were cultured for 3 h under 5% CO2 in air, in 4 microliters droplets of Ham's F-10 medium containing D-[5-3H]glucose, D-[1-14C]-glucose, D-[6-14C]glucose, [2-14C]pyruvate, or L-[U-14C]glutamine, and with or without 2,4-dinitrophenol (DNP) or phenazine ethosulphate (PES). The 14CO2 or 3H2O produced were collected by exchange with an outer bath of 400 microliter 25 mM-NaHCO3. All combinations of substrate and treatment (control, DNP or PES) produced measurable quantities of labelled product except for D-[6-14C]glucose in the presence of PES. Untreated and DNP-treated embryos developed normally during a subsequent 48-h culture period in fresh medium, but PES-treated embryos degenerated. Pyruvate and glutamine metabolism both increased markedly in the presence of DNP, indicating that the Krebs' cycle is active, and that glutamine can be used as an energy substrate. Conversely, DNP has no significant effect on glucose metabolism, indicating that glycolysis is blocked in the bovine blastocyst due to a lack or inhibition of pyruvate kinase. The production of 14CO2 from D-[1-14C]glucose increased significantly in the presence of PES, indicating that the activity of the pentose shunt is less than maximal.     

Anomeric specificity of D-glucose production by rat hepatocytes

The anomeric specificity of D-glucose metabolism in intact hepatocytes remains a matter of debate. This issue was further investigated in the present study, which is based on the quantification of the alpha- and beta-anomers of the 13C-enriched isotopomers of D-glucose generated by rat liver cells exposed to either D-[1-13C] fructose or D-[2-13C] fructose in the presence of D2O. The D-[1-13C]glucose/D-[6-13C]glucose paired ratios found in the cells exposed to D-[1-13C] fructose and the D-[2-13C]glucose/D-[5-13C]glucose paired ratios found in the cells exposed to D-[2-13C] fructose yielded a paired beta/alpha ratio averaging (mean +/- S.E.M.) 79.3 +/- 6.1%. In the case of the isotopomers of D-glucose formed by gluconeogenesis, the D-[2-13C]glucose/D-[5-13C]glucose and D-[3-13C]glucose/D-[4-13C]glucose paired ratios found in cells exposed to D-[1-13C] fructose, as well as the D-[1-13C]glucose/D-[6-13C]glucose and D-[3-13C]glucose/D-[4-13C]glucose paired ratios found in cells exposed to D-[2-13C]fructose, yielded an alpha/beta paired ratio averaging 75.0 +/- 5.8%. Last, in the cells exposed to D-[2-13C]fructose, the beta/alpha ratio for the C2-deuterated isotopomers of D-[2-13C]glucose represented 78.9 +/- 3.7% of that for the C5-deuterated isotopomers of D-[5-13C]glucose. The three values representative of the anomeric specificity of D-glucose production by liver cells were not significantly different from one another, with an overall mean value of 76.9 +/- 3.6%. These findings unambiguously document that the anomeric specificity of phosphoglucoisomerase is operative in intact hepatocytes, resulting in a preferential output of the alpha-anomer of 13C-enriched D-glucose under the present experimental conditions.     

Direct analysis of 18O in glucose by mass spectrometry

The direct analysis of both the position and abundance of ¹⁸O in d-glucose was accomplished by mass spectrometry of the pentaacetyl derivative. Synthetically prepared [1—¹⁸O]-, [2—¹⁸O]-, [3—¹⁸O]- and [6—¹⁸O]pentaacetylhexoses were prepared and used as standards to aid in the elucidation of fragmentation patterns. Ions were identified which contained specific oxygen atoms of glucose, permitting the measurement of ¹⁸O incorporated into these positions. This technique was used in the analysis of [4—¹⁸O] glucose prepared enzymatically.     

Phosphoglycerate mutase from wheat germ: studies with 18O-labeled substrate, investigations of the phosphatase and phosphoryl transfer activities, and evidence for a phosphoryl-enzyme intermediate.

From studies using unlabeled phospho-D-glycerate in solutions enriched in H2(18)O, and from experiments involving [18O]phospho-D-glycerate, it is shown that the intramolecular isomerization of 2- and 3-phospho-D-glycerate that is catalyzed by the phosphoglycerate mutase from wheat germ does not involve an intermediate 2,3-cyclic phosphate. It is also shown that phosphoglycerate mutase catalyzes the hydrolysis of the substrate analogues 2-phosphoglycolate, 2-phospho-D-lactate, 3-phosphohydroxypropionate, phosphoenolpyruvate, and phosphohydroxypyruvate. The substrates 3- and 2-phospho-D-glycerate are not hydrolyzed, nor are 2,3-bisphospho-D-glycerate, 2-phospho-L-lactate, 3-phospho-L-glycerate, or sn-glycerol 3-phosphate. Although no exchange of D-[14C]glycerate into phospho-D-glycerate can be detected, the enzyme catalyzes the transfer of the phosphoryl group from "unnatural" donors such as 2-phosphoglycolate, to the "natural" acceptor, D-glycerate. It is concluded that the intramolecular phosphoryl transfer catalyzed by the wheat germ phosphoglycerate mutase follows a pathway involving a phosphoryl-enzyme intermediate.     

Preparation of oxygen-18-labeled lipoxygenase metabolites of arachidonic acid

Plasma pseudocholinesterase and porcine liver esterase were used to catalyse the incorporation of the stable isotope oxygen-18 into the carboxyl moiety of lipoxygenase metabolites of arachidonic acid. This simple method produces eicosanoid products containing two oxygen-18 atoms; but the enzymes studied were found to display large substrate specificity in the efficiencies at which oxygen-18 could be incorporated into the lipoxygenase metabolites. Furthermore, [18O2]LTB4 was found not to back exchange during in vitro incubation with human neutrophils. The methods involved for stable isotope incorporation are simple, efficient and produce highly enriched species in a short time. By varying the type of esterase, the amount of esterase or the length of incubation highly enriched species of all eicosanoids tested could be prepared.     

Direct analysis of O in glucose by mass spectrometry

The direct analysis of both the position and abundance of ¹⁸O in d-glucose was accomplished by mass spectrometry of the pentaacetyl derivative. Synthetically prepared [1—¹⁸O]-, [2—¹⁸O]-, [3—¹⁸O]- and [6—¹⁸O]pentaacetylhexoses were prepared and used as standards to aid in the elucidation of fragmentation patterns. Ions were identified which contained specific oxygen atoms of glucose, permitting the measurement of ¹⁸O incorporated into these positions. This technique was used in the analysis of [4—¹⁸O] glucose prepared enzymatically.     

Oxygen-exchange studies on the pathways for magnesium adenosine 5'-triphosphate hydrolysis by actomyosin

At an intermediate stage in the hydrolysis of magnesium adenosine 5'-phosphate (MgATP) by myosin or actomyosin, there is an exchange of oxygen between water and the P gamma group of enzyme-bound nucleotide. Starting with [P gamma-18O]ATP as substrate, the exchange is revealed in the [18O]Pi species that are ultimately released as product into the reaction medium. An analysis of the distribution of these labeled Pi species, which contain 3, 2, 1, or none of the 18O atoms originally on the P gamma of ATP, is used to probe intermediate stages of the hydrolytic mechanism. In recent years, studies of this kind by several groups have shown that more than one pathway of hydrolysis operates. The work reported here demonstrates that two of these pathways are spurious; one is a "nonexchanging MgATPase" that is present in fresh myosin preparations; the other is an induced slow exchange that develops in myosin during storage (-20 degrees C) and subsequent aging (4 degrees C). However, after correction for these artifacts, two normal pathways for actomyosin hydrolysis remain. These normal pathways differ in the mode of interaction between actin and myosin in the course of hydrolysis; one is the Lymn-Taylor pathway where oxygen exchange occurs at a stage when actin and myosin are dissociated; the other is a pathway in which actin and myosin are associated during oxygen exchange. Each of these two pathways contributes an equal amount of Pi to the product pool. Thus, on average, each myosin head uses each of these pathways half the time. The findings suggest, e.g., that during contraction, myosin can dissociate from the actin filament only during every other cycle of MgATP hydrolysis or that only half the heads, at any one time, can exchange oxygen while free of the actin filament.     

Phosphoglucoisomerase-catalyzed interconversion of hexose phosphates: isotopic discrimination between hydrogen and deuterium

Summary The discrimination between the isotopes of hydrogen in the reaction catalyzed by yeast phosphoglucoisomerase is examined by NMR, as well as by spectrofluorometric or radioisotopic methods. The monodirectional conversion of D-glucose 6-phosphate to D-fructose 6-phosphate displays a lower maximal velocity with D-[2-²H]glucose 6-phosphate than unlabelled D-glucose 6-phosphate, with little difference in the affinity of the enzyme for these two substrates. About 72% of the deuterium located on the C₂ of D-[1-¹³C,2-²H]glucose 6-phosphate is transferred intramolecularly to the C₁ of D-[1-¹³C,1-²H]fructose 6-phosphate. The velocity of the monodirectional conversion of D-[U-¹⁴C]glucose 6-phosphate (or D-[2-³H]glucose 6-phosphate) to D-fructose 6-phosphate is virtually identical in H₂O and D₂O, respectively, but is four times lower with the tritiated than ¹⁴C-labelled ester. In the monodirectional reaction, the intramolecular transfer from the C₂ of D-[2-³H]glucose 6-phosphate is higher in the presence of D₂O than H₂O. Whereas prolonged exposure of D-[1-¹³C]glucose 6-phosphate to D₂O, in the presence of phosphoglucoisomerase, leads to the formation of both D-[1-¹³C,2-²H]glucose 6-phosphate and D-[1-¹³C,1-²H]fructose 6-phosphate, no sizeable incorporation of deuterium from D₂O on the C₁ of D-[1-¹³C]fructose 1,6-bisphosphate is observed when the monodirectional conversion of D-[1-¹³C]glucose 6-phosphate occurs in the concomitant presence of phosphoglucoisomerase and phosphofructokinase. The latter finding contrasts with the incorporation of hydrogen from ¹H₂O or tritium from ³H₂O in the monodirectional conversion of D-[2-³H]glucose 6-phosphate and unlabelled D-glucose 6-phosphate, respectively, to their corresponding ketohexose esters.     

Numbers and exchangeability with water of oxygen-17 atoms coupled to molybdenum (V) in different reduced forms of xanthine oxidase

The effect of using [17O]water (24-50% enriched) as solvent on the Mo(V) electron paramagnetic resonance spectra of different reduced forms of xanthine oxidase has been investigated. All the Mo(V) signals are affected. Procedures are described, based on the use of difference spectral techniques, that facilitate interpretation of such spectra. The number of coupled oxygen atoms may be determined by estimation of the fraction of the spectrum that remains unchanged by the isotope at a known enrichment. For a species having two coupled oxygen atoms, the use of two different isotope enrichments permits elimination from the difference spectra of the contribution of the two singly substituted species. From the application of these methods, it is concluded that not only the strength of the hyperfine coupling of oxygen ligands of molybdenum but also their number and their exchangeability with the solvent vary from one reduced form of the enzyme to another. The inhibited species from active xanthine oxidase has been studied in the most detail. It has two weakly coupled oxygen atoms [A(17O)av = 0.1-0.2 mT] that do not exchange with the solvent. A cyclic structure is proposed for this species in which two oxygen ligands of molybdenum are bonded to the carbon of the formaldehyde or other alcohol or aldehyde molecule that reacted in producing the signal. Structures of the other signal-giving species from active xanthine oxidase (Very Rapid and Rapid types 1 and 2) are discussed, as is corresponding information on species from the desulfo enzyme and from sulfite oxidase.