Transfer of exogenous cholesterol to microsomes of hepatocytes investigated with [3H]desmosterol tracer.

The molybdenum centre of spinach (Spinacia oleracea) nitrate reductase has been investigated by e.p.r. spectroscopy of molybdenum(V) in reduced forms of the enzyme. The resting enzyme gives no signals attributable to Mo(V). However, on reduction with NADH, Mo(V) signals appeared at relatively short reaction times but decreased again on prolonged exposure to excess of the substrate as the enzyme was further reduced. On brief treatment of such samples with nitrate, Mo(V) signals reappeared but disappeared again on longer exposure to excess nitrate as the enzyme became fully reoxidized. Detailed investigation of the signals carried out in both 1H2O and 2H2O revealed the presence of two signal-giving species, referred to as 'signal A' and 'signal B', analogous to corresponding signals from nitrate reductase from Escherichia coli and from liver sulphite oxidase. Signal A has gav. 1.9767 and shows coupling to a single proton, exchangeable with the solvent, with A(1H)av. 1.3mT, whereas signal B shows no more than weak coupling to protons. Investigation of interconversion between the two species indicated that decreasing the pH from 8.0 to 6.7 had little effect, but that signal A was favoured by the presence of Cl-. This suggests, by analogy with recent work on sulphite oxidase by Bray, Gutteridge, Lamy & Wilkinson [Biochem. J. (1983) 211, 227-236] that Cl- is a ligand of molybdenum in the species giving signal A.     

X-ray-absorption and electron-paramagnetic-resonance spectroscopic studies of the environment of molybdenum in high-pH and low-pH forms of Escherichia coli nitrate reductase.

Previous e.p.r. work [George, Bray, Morpeth & Boxer (1985) Biochem. J. 227, 925-931] has provided evidence for a pH- and anion-dependent transition in the structure of the Mo(V) centre of Escherichia coli nitrate reductase, with the low-pH form bearing both an anion and probably a hydroxy-group ligand. Initial e.x.a.f.s. measurements [Cramer, Solomonson, Adams & Mortenson (1984) J. Am. Chem. Soc. 106, 1467-1471] demonstrated the presence of sulphur (or chloride) ligands in the Mo(IV) and Mo(VI) oxidation states, as well as a variable number of terminal oxo (Mo = O) groups. To synthesize the e.p.r. and e.x.a.f.s. results better, we have conducted new e.p.r. experiments and complementary e.x.a.f.s. measurements under redox and buffer conditions designed to give homogeneous molybdenum species. In contrast with results on other molybdoenzymes, attempts to substitute the enzyme with 17O by dissolving in isotopically enriched water revealed only very weak hyperfine coupling to 17O. The significance of this finding is discussed. Experiments with different buffers indicated that buffer ions (e.g. Hepes) could replace the Cl- ligand in the low-pH Mo(V) enzyme form, with only a small change in e.p.r. parameters. E.x.a.f.s. studies of the oxidized and the fully reduced enzyme were consistent with the e.p.r. work in indicating a pH- and anion-dependent change in structure. However, in certain cases non-stoichiometric numbers of Mo = O interactions were determined, complicating the interpretation of the e.x.a.f.s. Uniquely for a molybdenum cofactor enzyme, a substantial proportion of the molecules in a number of enzyme samples appeared to contain no oxo groups. No evidence was found in our samples for the distant 'heavy' ligand atom reported in the previous e.x.a.f.s. study. The nature of the high-pH-low-pH transition is briefly discussed.     

Formamide as a substrate of xanthine oxidase.

Formamide is a substrate of xanthine oxidase. At pH 8.2 and 1.14 mM-O2, Vmax.(app.) is 3.1 s-1 and Km (app.) is 0.7 M. Mo(V) e.p.r. signals obtained by treating the enzyme with formamide were studied, and these provide new information about the ligation of molybdenum in the enzyme and about the enzymic mechanism. The substrate is the first compound that is not a nitrogen-containing heterocycle to give a Very Rapid signal. This supports the hypothesis that the Very Rapid signal, though it is not detectable with all substrates, represents an essential intermediate in turnover. Formamide also gives the Inhibited signal and is the first non-aldehyde substrate to do so. The Rapid type 1 signal obtained in the presence of formamide was examined in H2O enriched with 2H or with 17O. The single oxygen atom detectable in the signal is shown to be strongly and anisotropically coupled. This indicates that this atom remains as an oxo ligand of molybdenum in this signal-giving species. Other structural features of this species are discussed.     

Equilibria amongst different molybdenum (V)-containing species from sulphite oxidase. Evidence for a halide ligand of molybdenum in the low-pH species.

The interaction of chloride, fluoride and phosphate ions with the molybdenum centre of sulphite oxidase in the pH range 6.2 to 9.6 has been studied by e.p.r. of Mo(V) in the enzyme reduced by sulphite. Detailed studies were made from e.p.r. spectra recorded at about 120K and more limited studies from spectra of liquid samples at about 295K and also from enzyme activity measurements. Interconversion between low-pH and high-pH Mo(V) e.p.r. signal-giving species [described by Lamy, Gutteridge & Bray (1980) Biochem. J. 185, 397-403] is influenced by chloride concentration, a 10-fold increase in concentration (in the range of about 1 mM to 100 mM) causing an increase of about 1 pH unit in the apparent pK for the conversion. This suggests that chloride is a constituent of the low-pH species. In support of this, high concentrations of fluoride modified the e.p.r. spectrum. Partial conversion to a Mo(V) species, in which F- has presumably replaced Cl- and showing hyperfine coupling of A(19F)av. 0.5mT, is indicated. It is proposed that interconversion between high-pH and low-pH species is of the form: (formula; see text) No evidence that Cl- is essential for enzymic activity was found. Data relating to equilibria amongst low-pH, high-pH and also the phosphate species are presented. Depending on pH and on concentrations of Cl- and H2PO4-, one, two, or all three species may be present. Qualitatively, under appropriate conditions, the phosphate species tends to replace some or all of the low-pH species. Quantitative analysis by a computer procedure permitted an appropriate scheme to be deduced and equilibrium constants to be evaluated. Studies on the e.p.r. signals at 295K indicated that similar equilibria applied in liquid solution, but with some changes in the values of the constants. The structure of the molybdenum centre in its various states and the nature of the enzymic reaction are discussed.     

Evidence from electron-paramagnetic-resonance spectroscopy for a complex of sulphite ions with the molybdenum centre of sulphite oxidase.

Reduction of sulphite oxidase by sulphite at low pH values in Mes (4-morpholine-ethanesulphonic acid) buffer gives rise to a new molybdenum(V) electron-paramagnetic-resonance spectrum different from that obtained by photoreduction of the enzyme in the same medium. The spectrum is attributed to a sulphite complex of the enzyme, showing g-values of about 2.000, 1.972 and 1.963. The complex is analogous to that with the inhibitor phosphate in that it gives rise to no observable hyperfine coupling of Mo(V) to exchangeable protons.     

Electron-paramagnetic-resonance parameters of molybdenum(V) in sulphite oxidase from chicken liver.

A study has been made of e.p.r. signals due to Mo(V) in reduced sulphite oxidase (EC 1.8.3.1) from chicken liver. Reduction by SO3(2-), or photochemically in the presence of a deazaflavin derivative, produces spectra indistinguishable from one another. Three types of spectra from the enzyme were distingusihed and shown to correspond to single chemical species, since they could be simulated at both 9 and 35 GHz by using the same parameters. These were the low-pH form of the enzyme, with gav. 1.9805, the high-pH form, with gav. 1.9681 and a phosphate complex, with gav. 1.9741. The low-H form shows interaction with a single exchangeable proton, with A(1H)av. (hyperfine coupling constant) = 0.98 mT, probably in the form of an MoOH group. Parameters of the signals are compared with those for signals from xanthine oxidase and nitrate reductase. The signal from the phosphate complex of sulphite oxidase in unique among anion complexes of Mo-containing enzymes in showing no hyperfine coupling to protons. There is no evidence for additional weakly coupled protons or nitrogen nuclei in the sulphite oxidase signals. The possibility is considered that the enzymic mechanism involves abstraction of a proton and two electrons from HSO3- by a Mo = O group in the enzyme.     

Comparison of the molybdenum centres of native and desulpho xanthine oxidase. The nature of the cyanide-labile sulphur atom and the nature of the proton-accepting group.

The non-functional form of xanthine oxidase known as the desulpho enzyme was compared with the functional enzyme in various ways, to obtain information on the structure of the molybdenum centre and the mechanism of the catalytic reaction. The desulpho enzyme, like the functional one, possesses a site for the binding of anions, presumably as ligands of molybdenum. Evidence is presented that in the Mo(V) e.p.r. signal from the desulpho-enzyme, as in that from the functional enzyme, a weakly coupled proton, in addition to a strongly coupled proton, interacts with the metal. Measurements were carried out by e.p.r. on the rate at which the proton strongly coupled to molybdenum exchanged, on diluting enzyme samples with 2H2O. For the desulpho enzyme the exchange rate constant was 0.40s-1, at pH 8.2 and 12 degrees C, and for the functional enzyme it was 85 s-1. It is shown that the great majority of reported differences between the enzyme forms are consistent with functional enzyme containing an (Enzyme)-Mo=S grouping, replaced in the desulpho form by (Enzyme)-Mo=O. Protonation of these groups, with pK values of about 8 and 10 respectively, would give (Enzyme)-Mo-SH and (Enzyme)-Mo-OH, these being the forms observed by e.p.r. The accepting group in the functional enzyme, for the proton transferred from the substrate while molybdenum is reduced in the catalytic reaction [Gutteridge, Tanner & Bray (1978) Biochem J. 175 869-878], is thus taken to be Mo=S.     

Studies by electron-paramagnetic-resonance spectroscopy on the mechanism of action of xanthine dehydrogenase from Veillonella alcalescens.

E.p.r- (electron-paramagnetic-resonance) spectroscopy was used to compare chemical environment and reactivity of molybdenum, flavin and iron-sulphur centres in the enzyme xanthine dehydrogenase from Veillonella alcalescens (Micrococcus lactilyticus) with those of the corresponding centres in milk xanthine oxidase. The dehydrogenase is frequently contaminated with small but variable amounts of a species resistant to oxidation and giving a new molybdenum (V) e.p.r. signal, "Resting I". There is also a "desulpho" form of the enzyme giving a Slow Mo(V) signal, indistinguishable from that of the milk enzyme. Molybdenum of the active enzyme behaves in a manner analogous to that of the milk enzyme, giving a Rapid Mo(V) signal on partial reduction with substrates or dithionite. Detailed comparison shows that molybdenum in each enzyme must have the same ligand atoms arranged in the same manner. As with the milk enzyme, complex-formation between reduced dehydrogenase and purine substrate molecules, presumably interacting at the normal substrate-binding site, modifies the Rapid signal, confirming that such substrates interact near molybdenum. The dehydrogenase-flavin semiquinone signal is identical with that of the oxidase but, in contrast, there is only one iron-sulphur signal. The latter gives an e.p.r. spectrum similar to that of aldehyde oxidase.     

Complexes with halide and other anions of the molybdenum centre of nitrate reductase from Escherichia coli.

The interconversion of nitrate reductase from Escherichia coli between low-pH and high-pH Mo(V) e.p.r. signal-giving species was re-investigated [cf. Vincent & Bray (1978) Biochem. J. 171, 639-647]. The process cannot be described by a single pK value, since the apparent pK for interconversion is raised by the presence of various anions. The low-pH form of the enzyme exists as a series of complexes with different anion ligands of molybdenum. Each complex has specific and slightly different e.p.r. parameters, but all show strong coupling of Mo(V) to a single proton, exchangeable with the solvent, having A(1H)av. 1.0 to 1.3 mT. Complexes with Cl-, F- [A(19F)av. 0.7 mT], NO3- and NO2- give particularly well-defined spectra. The high-pH form of the enzyme is now shown to bear a coupled proton. Like that in the low-pH species, this proton is exchangeable with the solvent, but the coupling is much weaker, with A(1H)av. 0.3 mT. Thus, contrary to earlier assumptions, the proton detectable by e.p.r. is probably not identical with the proton whose dissociation controls interconversion between the two species; the latter proton could be located in the protein rather than on a ligand of molybdenum. Treatment of the enzyme with trypsin [Morpeth & Boxer (1985) Biochemistry 24, 40-46] did not affect its Mo(V) e.p.r. signals.     

Oxygen-17 splitting of the very rapid molybdenum(V) e.p.r. signal from xanthine oxidase. Rate of exchange with water of the coupled oxygen atom.

Studies have been carried out of effects of 17O substitution on a Mo(V) e.p.r. signal from xanthine oxidase, known as Very Rapid. This transient signal is believed to represent an intermediate in enzymic turnover. When Very Rapid was developed from enzyme equilibrate with 17O-enriched water, strong coupling of Mo(V) to a single oxygen atom was observed, with A(17O)1,2,3 1.34, 1.40, 1.36 mT. The isotropic character of the splittings is interpreted as favouring a structure of the type Mo--O--C. The rate of exchange with water of the oxygen atom detected in the signal was studied. In oxidized enzyme, which contains a terminal oxygen ligand, the exchange rate constant was 2--4 h-1 (pH 5.9--7.8 and about 20 degrees C). However, if the exchange was allowed to take place whilst the enzyme was turning over a substrate, then the process occurred within a few seconds. The present and previous results are interpreted as favouring an enzymic mechanism in which a terminal oxygen ligand reacts, as a nucleophile, with a substrate carbonium ion. To complete the reaction, product liberation, by hydrolysis of the enzyme-bound species, occurs in such a way as to cleave the Mo--O bond, thus explaining the fast oxygen exchange in the presence of the substrate.     

Heme-environment of horseradish peroxidase as observed by oxygen-17 superhyperfine interaction in EPR.

The presence of a water ligand on heme-iron in ferric hemoproteins can, in suitable cases, be detected by observing ¹⁷O superhyperfine interaction in the EPR spectra of solutions in H₂¹⁷O. Although no significant superhyperfine interaction is detectable in the EPR spectra of horseradish peroxidase itself, benzo-hydroxamic acid, which forms an outersphere complex with the enzyme analogous to an enzyme-peracid transition state, stabilizes an innersphere water ligand on the heme, as indicated by a ～1.3 gauss Fe³⁺-¹⁷O superhyperfine interaction in the EPR signal at g = 2, in the presence of 34–39% H₂¹⁷O at 8°K. These results indicate that the predominantly pentacoordinate Fe³⁺ ion in horseradish peroxidase is accessible to the solvent and that it acquires a water or hydroxyl ligand in the presence of benzohydroxamic acid.     

The molybdenum iron-sulphur protein from Desulfovibrio gigas as a form of aldehyde oxidase.

The molybdenum iron-sulphur protein originally isolated from Desulfovibrio gigas by Moura, Xavier, Bruschi, Le Gall, Hall & Cammack [(1976) Biochem. Biophys. Res. Commun. 72, 782-789] has been further investigated by e.p.r. spectroscopy of molybdenum(V). The signal obtained on extended reduction of the protein with sodium dithionite has been shown, by studies at 9 and 35 HGz in 1H2O and 2H2O and computer simulations, to have parameters corresponding to those of the Slow signal from the inactive desulpho form of various molybdenum-containing hydroxylases. Another signal obtained on brief reduction of the protein with small amounts of dithionite was shown by e.p.r. difference techniques to be a Rapid type 2 signal, like that from the active form of such enzymes. In confirmation that the protein is a molybdenum-containing hydroxylase, activity measurements revealed that it had aldehyde:2,6-dichlorophenol-indophenol oxidoreductase activity. No such activity towards xanthine or purine was observed. Salicylaldehyde was a particularly good substrate, and treatment of the protein with it also gave rise to the Rapid signal. Molybdenum cofactor liberated from the protein was active in the nit-1 Neurospora crassa nitrate reductase assay. It is concluded that the protein is a form of an aldehyde oxidase or dehydrogenase. From the intensity of the e.p.r. signals and from enzyme activity measurements, 10-30% of the protein in the sample examined appeared to be in the functional form. The evolutionary significance of the protein, which may represent a primitive form of the enzyme rather than a degradation product, is discussed briefly.     

The detection of messenger ribonucleic acid sequences in heterogeneous nuclear ribonucleic acid fractions of the oestrogen-stimulated rat uterus.

Active xanthine oxidase was labelled specifically with 33S in the cyanide-labile site of the molybdenum centre. The Very Rapid molybdenum (V) e.p.r. signal, generated from this, shows strong coupling of 33S to molybdenum, providing unambiguous evidence that, at least in the signal-giving species, this sulphur atom is a ligand of molybdenum. The structure of the signal-giving species is discussed.     

Rapid type 2 molybdenum(V) electron-paramagnetic resonance signals from xanthine oxidase and the structure of the active centre of the enzyme.

Rapid type 2 molybdenum(V) e.p.r. signals from reduced functional xanthine oxidase have been further investigated. These signals, which show strong coupling of two protons to molybdenum, have been obtained under a variety of new conditions: specifically either at pH 8.2 in the presence of borate ions, or at pH 10.1--10.7 with or without various other additions. Parameters of the signals were obtained with the help of computer simulations. In at least some of these signals, the coupled protons must be located on the enzyme rather than on bound species. The relationship between type 1 and type 2 Rapid signals is discussed. They may represent geometrical isomers, or alternatively, hydroxyl uptake as a ligand of molybdenum may be involved in formation of type 2 species.     

The structure of the inhibitory complex of alloxanthine (1H-pyrazolo[3,4-d]pyrimidine-4,6-diol) with the molybdenum centre of xanthine oxidase from electron-paramagnetic-resonance spectroscopy.

Studies were carried out on the inhibitory complex of alloxanthine (1H-pyrazolo[3,4-d]pyrimidine-4,5-diol) with xanthine oxidase, in extension of the work of Williams & Bray [Biochem. J. (1981) 195, 753-760]. By suitable regulation of the reaction conditions, up to 10% of the functional enzyme could be converted into the complex in the Mo(V) oxidation state. The e.p.r. spectrum of the complex was investigated in detail with the help of computer simulation and substitution with stable isotopes. Close structural analogy of the signal-giving species to that of the Very Rapid intermediate in enzyme turnover is shown by g-values (2.0279, 1.9593 and 1.9442) and by coupling to 33S in the cyanide-labile site of the enzyme [A(33S) 0.30, 3.10 and 0.70mT]. However, whereas in the Very Rapid signal there is strong coupling to 17O [Gutteridge & Bray, Biochem. J. (1980) 189, 615-623], instead, in the Alloxanthine signal there is strong coupling to a single nitrogen atom [A(14N) 0.35, 0.35, 0.32 mT]. This is presumed to originate from the 2-position of the heterocyclic ring system. From this work and from earlier kinetic studies it is concluded that alloxanthine, after being bound reversibly at the active centre, reacts slowly with it, in a specific manner, distinct from that in the normal catalytic reaction with substrates. This reaction involves elimination of an oxygen ligand of molybdenum and co-ordination, in this site, of alloxanthine via the N-2 nitrogen atom, to give a complex that is structurally but not chemically closely analogous to that of the Very Rapid species.     

Oestrogen-induced pS2 protein is similar to pancreatic spasmolytic polypeptide and the kringle domain.

The phosphate complex of sulphite oxidase in the Mo(V) oxidation state was investigated by e.p.r. spectroscopy. Third-derivative spectra reveal a wealth of structural detail previously unobserved in this spectrum. Most notable is the presence of hyperfine coupling from two inequivalent I = 1/2 nuclei, which we tentatively attribute to two 31P nuclei. Unresolved hyperfine interactions from at least one exchangeable 1H nucleus are also present.     

pH-jump studies at subzero temperatures on an intermediate in the reaction of xanthine oxidase with xanthine.

Xanthine oxidase is stable and active in aqueous dimethyl sulphoxide solutions of up to at least 57% (w/w). Simple techniques are described for mixing the enzyme in this solvent at--82 degrees C, with its substrate, xanthine. When working at high pH values under such conditions, no reaction occurred, as judged by the absence of e.p.r. signals. On warming to--60 degrees C, for 10 min, however, the Very Rapid molybdenum(V) e.p.r. signal was obtained. This signal did not change on decreasing the pH, while maintaining the sample in liquid nitrate reductase, caused its molybdenum(V) e.p.r. signal to change from the high-pH to the low-pH form. These findings are not compatible with the conclusions of Edmondson, Ballou, Van Heuvelen, Palmer & Massey [J. Biol. Chem. (1973) 248, 6135-6144], that the Very Rapid signal is in prototropic equilibrium with the Rapid signal, and should be important in understanding the mechanism of action of the enzyme. They emphasize the unique nature of the intermediate represented by the Very Rapid e.p.r. signal. The possible value of the pK for loss of an exchangeable proton from the Rapid signal is discussed.     

Isolation of ATPase I, the proton pump of chromaffin-granule membranes.

Cellobiose oxidase from the white-rot fungus Sporotrichum pulverulentum has been purified to homogeneity by a new procedure. The carbohydrate and amino acid compositions of the enzyme have been determined. Cellobiose oxidase contains FAD and cytochrome b prosthetic groups. Mr of the enzyme has been estimated at 74400 by sedimentation equilibrium. The enzyme is a monomer. Optical, fluorescence and e.p.r. spectra of oxidized and reduced cellobiose oxidase have been determined. A preliminary investigation of the substrate specificity of cellobiose oxidase reveals that disaccharides and even some insoluble polysaccharides are substrates, but not monosaccharides. Strong substrate inhibition is seen at high concentrations of cellobiose. This effect is particularly marked when oxygen is the electron acceptor. Cellobiose oxidase is unusual among flavoproteins, since it stabilizes the red anionic flavin semiquinone and forms a sulphite adduct, yet appears to produce the superoxide anion as its primary reduced oxygen product.     

Biology of the molybdenum cofactor

The transition element molybdenum (Mo) is an essential micronutrient for plants where it is needed as a catalytically active metal during enzyme catalysis. Four plant enzymes depend on molybdenum: nitrate reductase, sulphite oxidase, xanthine dehydrogenase, and aldehyde oxidase. However, in order to gain biological activity and fulfil its function in enzymes, molybdenum has to be complexed by a pterin compound thus forming the molybdenum cofactor. In this article, the path of molybdenum from its uptake into the cell, via formation of the molybdenum cofactor and its storage, to the final modification of the molybdenum cofactor and its insertion into apo-metalloenzymes will be reviewed.     

Studies by electron paramagnetic resonance spectroscopy of xanthine oxidase enriched with molybdenum-95 and with molybdenum-97

Investigations have been carried out on the nature of the species from the enzyme xanthine oxidase that give rise to two molybdenum (V) electron paramagnetic resonance (EPR) signals. Isotopic enrichment with 95Mo, 97Mo, 33S, and 17O was employed. Computer simulations of the EPR spectra recorded at 9- and 35-GHz microwave frequencies were used to evaluate the various hyperfine couplings and angular relations between the principal axes of g and A, as well as the nuclear electric quadrupole interaction for 97Mo. The results support the presence of an oxo ligand in the Rapid and of both an oxo and a sulfido ligand in the Very Rapid signal-giving species.