Resonance Raman studies on xanthine oxidase: observation of Mo<Superscript>VI</Superscript>-ligand vibrations

Resonance Raman spectra were investigated for the sulfo and desulfo forms of cow's milk xanthine oxidase, with various visible excitation lines between 400 and 650 nm, and Mo(VI)-ligand vibrations were observed for the first time. The Mo(VI)=S stretch was identified at 474 and 462 cm(-1 )for the (32)S- and (34)S-sulfo forms, respectively, but was absent in the reduced state and in the desulfo form. The Mo(VI)=O stretch was weakly observed at 899 cm(-1 )for the sulfo form and shifted to 892 cm(-1) with very weak intensity for the dioxo desulfo form. In measurements of an excitation profile, the two bands at 474 and 899 cm(-1) showed maximum intensity at similar excitation wavelengths, suggesting that the Raman intensity of the metal-ligand modes is due to the Mo(VI)<--S charge transfer transition, and that this is the origin of the intrinsically weak features of the Mo(VI)-ligand Raman bands. When the sulfo form was regenerated from the desulfo form, the 899 cm(-1) band reappeared. However, the band at 899 cm(-1) showed no frequency shift when regeneration was conducted in H(2)(18)O, or after several turnovers in the presence of xanthine in H(2)(18)O. When the sulfo form was reduced and reoxidized in H(2)(18)O buffer, the 899 cm(-1) band reappeared without any frequency shift. These observations suggest that the oxo oxygen in the Mo center of xanthine oxidase is not labile. Low-frequency vibrations of the Mo center were observed together with those of the Fe(2)S(2) center with some overlaps, while FAD modes were observed clearly. The absence of dithiolene modes in XO is in contrast to the Mo(VI) centers of DMSO reductase and sulfite oxidase.     

Resonance Raman as a direct probe for the catalytic mechanism of molybdenum oxotransferases

 Recent studies of human sulfite oxidase and Rhodobacter sphaeroides DMSO reductase have demonstrated the ability of resonance Raman to probe in detail the coordination environment of the Mo active sites in oxotransferases via Mo=O, Mo-S(dithiolene), Mo-S(Cys) or Mo-O(Ser), dithiolene chelate ring and bound substrate vibrations. Furthermore, the ability to monitor the catalytically exchangeable oxo group via isotopic labeling affords direct mechanistic information and structures for the catalytically competent Mo(IV) and Mo(VI) species. The results clearly demonstrate that sulfite oxidase cycles between cis–di-oxo-Mo(VI) and mono-oxo-Mo(IV) states during catalytic turnover, whereas DMSO reductase cycles between mono-oxo-Mo(VI) and des-oxo-Mo(IV) states. In the case of DMSO reductase, ¹⁸O-labeling experiments have provided the first direct evidence for an oxygen atom transfer mechanism involving an Mo=O species. Of particular importance is that the active-site structures and detailed mechanism of DMSO reductase in solution, as determined by resonance Raman spectroscopy, are quite different to those reported or deduced in the three X-ray crystallographic studies of DMSO reductases from Rhodobacter species. Received: 16 June 1997 / Accepted: 20 August 1997     

Structure of the active site of sulfite oxidase. X-ray absorption spectroscopy of the Mo(IV), Mo(V), and Mo(VI) oxidation states

The active site of sulfite oxidase has been investigated by X-ray absorption spectroscopy at the molybdenum K-edge at 4 K. We have investigated all three accessible molybdenum oxidation states, Mo(IV), Mo(V), and Mo(VI), allowing comparison with the Mo(V) electron paramagnetic resonance data for the first time. Quantitative analysis of the extended X-ray absorption fine structure indicates that the Mo(VI) oxidation state possesses two terminal oxo (Mo = O) and approximately three thiolate-like (Mo-S-) ligands and is unaffected by changes in pH and chloride concentration. The Mo(IV) and Mo(V) oxidation states, however, each have a single oxo ligand plus one Mo-O- (or Mo-N less than) bond, most probably Mo--OH, and two to three thiolate-like ligands. Both reduced forms appear to gain a single chloride ligand under conditions of low pH and high chloride concentration.     

Redox centers of 4-hydroxybenzoyl-CoA reductase, a member of the xanthine oxidase family of molybdenum-containing enzymes

4-Hydroxybenzoyl-CoA reductase (4-HBCR) is a key enzyme in the anaerobic metabolism of phenolic compounds. It catalyzes the reductive removal of the hydroxyl group from the aromatic ring yielding benzoyl-CoA and water. The subunit architecture, amino acid sequence, and the cofactor/metal content indicate that it belongs to the xanthine oxidase (XO) family of molybdenum cofactor-containing enzymes. 4-HBCR is an unusual XO family member as it catalyzes the irreversible reduction of a CoA-thioester substrate. A radical mechanism has been proposed for the enzymatic removal of phenolic hydroxyl groups. In this work we studied the spectroscopic and electrochemical properties of 4-HBCR by EPR and M?ssbauer spectroscopy and identified the pterin cofactor as molybdopterin mononucleotide. In addition to two different [2Fe-2S] clusters, one FAD and one molybdenum species per monomer, we also identified a [4Fe-4S] cluster/monomer, which is unique among members of the XO family. The reduced [4Fe-4S] cluster interacted magnetically with the Mo(V) species, suggesting that the centers are in close proximity, (<15 A apart). Additionally, reduction of the [4Fe-4S] cluster resulted in a loss of the EPR signals of the [2Fe-2S] clusters probably because of magnetic interactions between the Fe-S clusters as evidenced in power saturation studies. The Mo(V) EPR signals of 4-HBCR were typical for XO family members. Under steady-state conditions of substrate reduction, in the presence of excess dithionite, the [4Fe-4S] clusters were in the fully oxidized state while the [2Fe-2S] clusters remained reduced. The redox potentials of the redox cofactors were determined to be: [2Fe-2S](+1/+2) I, -205 mV; [2Fe-2S] (+1/+2) II, -255 mV; FAD/FADH( small middle dot)/FADH, -250 mV/-470 mV; [4Fe-4S](+1/+2), -465 mV and Mo(VI)/(V)/(VI), -380 mV/-500 mV. A catalytic cycle is proposed that takes into account the common properties of molybdenum cofactor enzymes and the special one-electron chemistry of dehydroxylation of phenolic compounds.     

Model studies for molybdenum enzymes. The reduction of cytochrome c by molybdenum(V)-cysteine complexes.

The reduction of ferricytochrome c by two molybdenum(V)-cysteine complexes has been investigated as a model for electron transfer in the molybdenum enzymes sulfite oxidase and nitrate reductase. The reduction by the dioxo-bridged Mo(V)-cysteine complex, di-mu-oxo-bis-[oxo(L-cysteinato)molybdate(V)] (I), is relatively slow and its rate is first order in cyt cIII and zero order in I (k = (1.09 +/- 0.10) times 10(-3) sec minus 1, pH 7.5, 20 degrees). The reduction by the monoxo-bridged complex, mu-oxo-bis[oxodihydroxo(L-cysteinato)molybdate(V)] (II), is extremely rapid and its rate is first order in both reactants (k = (2.6 +/- 0.7) times 10(7) M minus 1 sec minus 1, pH 7.0, 25 degrees). Above pH 7.5, the reduction by II follows biphasic kinetics due to the fast reduction of a low pH form of cyt cIII and a slower reduction of a high pH form (at pH 10.0, 25 degrees, k = 2.9 times 10(6) M minus 1 sec minus 1 for the low pH form and k = 7.2 times 10(4) M minus 1 sec minus 1 for the high pH form). Reaction mechanisms for reductions by both I and II are proposed and the biological implications of the results, both for sulfite oxidase and mechanisms of electron transfer to cytochrome c, are discussed.     

Symphoria: the success of modeling the active site function of oxo-molybdoenzymes

The success of modeling the active site function of oxomolybdoenzymes have been claimed generally on the basis of reactivity of the synthetic analogues towards PPh(3) or DMSO (dimethyl sulfoxide). Here it has been shown that the success of modeling the active site function of these enzymes may not be determined by the ability of a model to undergo oxotransfer with PPh(3) or DMSO (except for the modeling of DMSO reductase) and one should adhere to the criteria accepted by the bioinorganic community. A critical evaluation of two of those criteria which requires a synthetic analogue (a) should react with the enzyme substrate (b) should follow the same rate law as does the enzyme, has been presented in this paper. We have shown that the fulfillment of criterion (b) and the inhibition phenomena to that effect both are dictated by symphoria (from sympherin in Greek: the bringing together of reactants into the proper spatial relationship) on the basis of kinetic studies of the reactivity of enzyme substrate the HSO(3)(-) and its analogues (anions of oxyacids of phosphorous) towards a functional model sulfite oxidase [Bu(4)N](2)[Mo(VI)O(2)(mnt)(2)] (mnt(2-)=1,2-dicyanoethylenedithiolate) but with the caveat that the mechanistic inference drawn from such studies may not be the same as in the case of native enzyme. In view of this ambiguity it has been pointed out that the fulfillment of this criterion is not a definitive conclusion towards our understanding of the structure-function relationship of an enzyme and, therefore, the criterion of a 'structural analogue' and 'functional analogue' have been revised subject to an amendment of criterion (a) to include substrate analogues. It has also been shown for the first time on the basis of kinetic studies that the effect of medium can lead to substrate - inhibitor type dualism and hence the effect of medium is also a factor that can play a key role for the success of modeling the active site function of an enzyme. Here we also provide the details of the inhibition mechanisms proposed in our earlier report with an indirect proof to that effect.     

Mechanisms of inactivation of molybdoenzymes by cyanide

The reduced forms of xanthine oxidase, xanthine dehydrogenase, aldehyde oxidase, and sulfite oxidase are inactivated by cyanide. Following gel filtration to remove excess of reductant and cyanide, the isolated enzymes remain inactive. Thiocyanate, a product of inactivation of the oxidized forms of the xanthine- and aldehyde-oxidizing enzymes by cyanide, is not released during inactivation of the reduced enzymes. Studies with [14C]cyanide show that, while stoichiometric binding is required for the onset of inactivation, its continued binding is not essential to maintenance of the inactivated state. Electron paramagnetic resonance and absorption spectroscopic studies on the isolated inactivated enzymes show that prosthetic groups other than molybdenum are fully oxidized but that the molybdenum centers are modified. Reactivation is accomplished by incubation with suitable oxidants. Aerobic reactivation of inactive sulfite oxidase required only 1 eq of ferricyanide/active site. However, under rigorously anaerobic conditions, 3 to 4 mol of ferricyanide/active site were reduced, indicating that the molybdenum centers in the inactive enzyme had been reduced below the levels attained by the native enzyme during catalysis.     

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.     

Mo and W bis-MGD enzymes: nitrate reductases and formate dehydrogenases

Molybdenum and tungsten are second- and third-row transition elements, respectively, which are found in a mononuclear form in the active site of a diverse group of enzymes that generally catalyze oxygen atom transfer reactions. Mononuclear Mo-containing enzymes have been classified into three families: xanthine oxidase, DMSO reductase, and sulfite oxidase. The proteins of the DMSO reductase family present the widest diversity of properties among its members and our knowledge about this family was greatly broadened by the study of the enzymes nitrate reductase and formate dehydrogenase, obtained from different sources. We discuss in this review the information of the better characterized examples of these two types of Mo enzymes and W enzymes closely related to the members of the DMSO reductase family. We briefly summarize, also, the few cases reported so far for enzymes that can function either with Mo or W at their active site.     

Spectroscopic studies of the molybdenum-containing dimethyl sulfoxide reductase from Rhodobacter sphaeroides f. sp. denitrificans.

Absorption and EPR spectroscopic properties of purified dimethyl sulfoxide (Me2SO) reductase from Rhodobacter sphaeroides f. sp. denitrificans have been examined. The absence of prosthetic groups other than the molybdenum center in the enzyme has made it possible to study its absorption properties. The enzyme displays multiple absorbance peaks in both the oxidized and the dithionite-reduced forms. The oxidized enzyme has absorbance peaks at 280, 350, 470, 550, and 720 nm while the dithionite-reduced enzyme has peaks at 280, 374, and 645 nm with a shoulder at 430 nm. A comparison of the absorbance spectrum of oxidized Me2SO reductase with that of the molybdenum fragment of rat liver sulfite oxidase shows that the 350 and 470 peaks are common to both proteins. EPR studies of the Mo(V) form of Me2SO reductase show a rhombic signal with g1 = 1.988, g2 = 1.977, g3 = 1.961, and g(ave) = 1.975. The signal shows evidence of coupling to an exchangeable proton with A1 = 1.05, A2 = 1.13, A3 = 0.98, and Aave = 1.05 millitesla. These parameters are similar to those of other Mo enzymes, however, the epr signal of this enzyme differs from those of other Mo hydroxylases in showing only a slight sensitivity to pH and no detectable anion effect. EPR potentiometric titrations of Me2SO reductase gave midpoint potentials of +144 mV for the Mo(VI)/Mo(V) couple and +160 mV for the Mo(V)/Mo(IV) couple at room temperature and +141 mV for the Mo(VI)/Mo(V) couple and +200 mV for the Mo(V)/Mo(IV) couple at 173 K.     

Crystal structure of the 100 kDa arsenite oxidase from Alcaligenes faecalis in two crystal forms at 1.64 A and 2.03 A

BACKGROUND: Arsenite oxidase from Alcaligenes faecalis NCIB 8687 is a molybdenum/iron protein involved in the detoxification of arsenic. It is induced by the presence of AsO(2-) (arsenite) and functions to oxidize As(III)O(2-), which binds to essential sulfhydryl groups of proteins and dithiols, to the relatively less toxic As(V)O(4)(3-) (arsenate) prior to methylation. RESULTS: Using a combination of multiple isomorphous replacement with anomalous scattering (MIRAS) and multiple-wavelength anomalous dispersion (MAD) methods, the crystal structure of arsenite oxidase was determined to 2.03 A in a P2(1) crystal form with two molecules in the asymmetric unit and to 1.64 A in a P1 crystal form with four molecules in the asymmetric unit. Arsenite oxidase consists of a large subunit of 825 residues and a small subunit of approximately 134 residues. The large subunit contains a Mo site, consisting of a Mo atom bound to two pterin cofactors, and a [3Fe-4S] cluster. The small subunit contains a Rieske-type [2Fe-2S] site. CONCLUSIONS: The large subunit of arsenite oxidase is similar to other members of the dimethylsulfoxide (DMSO) reductase family of molybdenum enzymes, particularly the dissimilatory periplasmic nitrate reductase from Desulfovibrio desulfuricans, but is unique in having no covalent bond between the polypeptide and the Mo atom. The small subunit has no counterpart among known Mo protein structures but is homologous to the Rieske [2Fe-2S] protein domain of the cytochrome bc(1) and cytochrome b(6)f complexes and to the Rieske domain of naphthalene 1,2-dioxygenase.     

Cell biology of molybdenum in plants and humans

The transition element molybdenum (Mo) needs to be complexed by a special cofactor in order to gain catalytic activity. With the exception of bacterial Mo-nitrogenase, where Mo is a constituent of the FeMo-cofactor, Mo is bound to a pterin, thus forming the molybdenum cofactor Moco, which in different variants is the active compound at the catalytic site of all other Mo-containing enzymes. In eukaryotes, the most prominent Mo-enzymes are nitrate reductase, sulfite oxidase, xanthine dehydrogenase, aldehyde oxidase, and the mitochondrial amidoxime reductase. The biosynthesis of Moco involves the complex interaction of six proteins and is a process of four steps, which also requires iron, ATP and copper. After its synthesis, Moco is distributed to the apoproteins of Mo-enzymes by Moco-carrier/binding proteins. A deficiency in the biosynthesis of Moco has lethal consequences for the respective organisms. In humans, Moco deficiency is a severe inherited inborn error in metabolism resulting in severe neurodegeneration in newborns and causing early childhood death. This article is part of a Special Issue entitled: Cell Biology of Metals.     

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.     

Structure of a xanthine oxidase-related 4-hydroxybenzoyl-CoA reductase with an additional [4Fe-4S] cluster and an inverted electron flow

The Mo-flavo-Fe/S-dependent heterohexameric protein complex 4-hydroxybenzoyl-CoA reductase (4-HBCR, dehydroxylating) is a central enzyme of the anaerobic degradation of phenolic compounds and belongs to the xanthine oxidase (XO) family of molybdenum enzymes. Its X-ray structure was established at 1.6 A resolution. The most pronounced difference between 4-HBCR and other structurally characterized members of the XO family is the insertion of 40 amino acids within the beta subunit, which carries an additional [4Fe-4S] cluster at a distance of 16.5 A to the isoalloxazine ring of FAD. The architecture of 4-HBCR and concomitantly performed electron transfer rate calculations suggest an inverted electron transfer chain from the donor ferredoxin via the [4Fe-4S] cluster to the Mo over a distance of 55 A. The binding site of 4-hydroxybenzoyl-CoA is located in an 18 A long channel lined up by several aromatic side chains around the aromatic moiety, which are proposed to shield and stabilize the postulated radical intermediates during catalysis.     

Electrochemical studies of arsenite oxidase: an unusual example of a highly cooperative two-electron molybdenum center

Arsenite oxidase from Alcaligenes faecalis, an unusual molybdoenzyme that does not exhibit a Mo(V) EPR signal during oxidative-reductive titrations, has been investigated by protein film voltammetry. A film of the enzyme on a pyrolytic graphite edge electrode produces a sharp two-electron signal associated with reversible reduction of the oxidized Mo(VI) molybdenum center to Mo(IV). That reduction or oxidation of the active site occurs without accumulation of Mo(V) is consistent with the failure to observe a Mo(V) EPR signal for the enzyme under a variety of conditions and is indicative of an obligate two-electron center. The reduction potential for the molybdenum center, 292 mV (vs SHE) at pH 5.9 and 0 degrees C, exhibits a linear pH dependence for pH 5-10, consistent with a two-electron reduction strongly coupled to the uptake of two protons without a pK in this range. This suggests that the oxidized enzyme is best characterized as having an L(2)MoO(2) rather than L(2)MoO(OH) center in the oxidized state and that arsenite oxidase uses a "spectator oxo" effect to facilitate the oxo transfer reaction. The onset of the catalytic wave observed in the presence of substrate correlates well with the Mo(VI/IV) potential, consistent with catalytic electron transport that is limited only by turnover at the active site. The one-electron peaks for the iron-sulfur centers are difficult to observe by protein film voltammetry, but spectrophotometric titrations have been carried out to measure their reduction potentials: at pH 6.0 and 20 degrees C, that of the [3Fe-4S] center is approximately 260 mV and that of the Rieske center is approximately 130 mV.     

Molybdenum cofactor deficiency in a patient previously characterized as deficient in sulfite oxidase

The metabolic status of a patient previously characterized as deficient in sulfite oxidase was reexamined applying new methodology which has been developed to distinguish between a defect specific to the sulfite oxidase protein and sulfite oxidase deficiency which arises as a result of molybdenum cofactor deficiency. Urothione, the metabolic degradation product of the molybdenum cofactor, was undetectable in urine samples from the patient. Analysis of molybdenum cofactor levels in fibroblasts by monitoring reconstitution of apo nitrate reductase in extracts of the Neurospora crassa mutant nit-1 revealed that cells from the patient were severely depleted. Quantitation of urinary oxypurines showed that hypoxanthine and xanthine were highly elevated while uric acid remained in the normal range. These results were interpreted to indicate a severe but incomplete deficiency of the molybdenum cofactor. The presence of very low levels of active cofactor, supporting the synthesis of low levels of active sulfite oxidase and xanthine dehydrogenase, could explain the metabolic patterns of sulfur and purine products and the relatively mild clinical symptoms in this individual.     

Reactions of molybdenum-sulphur compounds with cyanide: chemical evolution and deactivation of molybdoenzymes.

Reactions of molybdenum-sulphur compounds with cyanide are reported which may be relevant to (1) the chemical evolution of molybdoenzymes and (2) deactivation of molybdoenzymes by cyanide. (1) With aqueous cyanide MoS2 gave thio-bridged complex anions [(Mo(CN)6)2(mu-S)]6- and [(Mo(CN)4(mu-S))2]6-. Under prebiotic conditions such complexes could have been formed similarly from molybdenite and may have been precursors of molybdoenzymes. (2) Only those compounds which contained terminal sulphur bound to molybdenum (i.e., Mo = S groups), viz. oxothiomolybdates and the complex [(Mo(mu-S)(S)(Et2NCS2))2], reacted with cyanide; thiocyanate was formed and the molybdenum underwent two-electron reduction. That the cyanolysable sulphur of xanthine oxidase reacts in the same way with cyanide suggests the presence of a Mo = S group which could be a structural feature of the enzyme or could have been formed by initial cyanolysis of a bound persulphide or cysteine residue.     

Cell biology of molybdenum in plants

The transition element molybdenum (Mo) is of essential importance for (nearly) all biological systems as it is required by enzymes catalyzing important reactions within the cell. The metal itself is biologically inactive unless it is complexed by a special cofactor. With the exception of bacterial nitrogenase, where Mo is a constituent of the FeMo-cofactor, Mo is bound to a pterin, thus forming the molybdenum cofactor (Moco) which is the active compound at the catalytic site of all other Mo-enzymes. In plants, the most prominent Mo-enzymes are nitrate reductase, sulfite oxidase, xanthine dehydrogenase, aldehyde oxidase, and the mitochondrial amidoxime reductase. The biosynthesis of Moco involves the complex interaction of six proteins and is a process of four steps, which also includes iron as well as copper in an indispensable way. After its synthesis, Moco is distributed to the apoproteins of Mo-enzymes by Moco-carrier/binding proteins that also participate in Moco-insertion into the cognate apoproteins. Xanthine dehydrogenase and aldehyde oxidase, but not the other Mo-enzymes, require a final step of posttranslational activation of their catalytic Mo-center for becoming active.     

Molybdoenzymes and molybdenum cofactor in plants

The transition element molybdenum (Mo) is essential for (nearly) all organisms and occurs in more than 40 enzymes catalysing diverse redox reactions, however, only four of them have been found in plants. (1) Nitrate reductase catalyses the key step in inorganic nitrogen assimilation, (2) aldehyde oxidase(s) have been shown to catalyse the last step in the biosynthesis of the phytohormone abscisic acid, (3) xanthine dehydrogenase is involved in purine catabolism and stress reactions, and (4) sulphite oxidase is probably involved in detoxifying excess sulphite. Among Mo-enzymes, the alignment of amino acid sequences permits domains that are well conserved to be defined. With the exception of bacterial nitrogenase, Mo-enzymes share a similar pterin compound at their catalytic sites, the molybdenum cofactor. Mo itself seems to be biologically inactive unless it is complexed by the cofactor. This molybdenum cofactor combines with diverse apoproteins where it is responsible for the correct anchoring and positioning of the Mo-centre within the holo-enzyme so that the Mo-centre can interact with other components of the enzyme's electron transport chain. A model for the three-step biosynthesis of Moco involving the complex interaction of six proteins will be described. A putative Moco-storage protein distributing Moco to the apoproteins of Mo-enzymes will be discussed. After insertion, xanthine dehydrogenase and aldehyde oxidase, but not nitrate reductase and sulphite oxidase, require the addition of a terminal sulphur ligand to their Mo-site, which is catalysed by the sulphur transferase ABA3.     

The role of tyrosine 343 in substrate binding and catalysis by human sulfite oxidase

In the crystal structure of chicken sulfite oxidase, the residue Tyr(322) (Tyr(343) in human sulfite oxidase) was found to directly interact with a bound sulfate molecule and was proposed to have an important role in mediating the substrate specificity and catalytic activity of this molybdoprotein. In order to understand the role of this residue in the catalytic mechanism of sulfite oxidase, steady-state and stopped-flow analyses were performed on wild-type and Y343F human sulfite oxidase over the pH range 6-10. In steady-state assays of Y343F sulfite oxidase using cytochrome c as the electron acceptor, k(cat) was somewhat impaired ( approximately 34% wild-type activity at pH 8.5), whereas the K(m)(sulfite) showed a 5-fold increase over wild type. In rapid kinetic assays of the reductive half-reaction of wild-type human sulfite oxidase, k(red)(heme) changed very little over the entire pH range, with a significant increase in K(d)(sulfite) at high pH. The k(red)(heme) of the Y343F variant was significantly impaired across the entire pH range, and unlike the wild-type protein, both k(red)(heme) and K(d)(sulfite) were dependent on pH, with a significant increase in both kinetic parameters at high pH. Additionally, reduction of the molybdenum center by sulfite was directly measured for the first time in rapid reaction assays using sulfite oxidase lacking the N-terminal heme-containing domain. Reduction of the molybdenum center was quite fast (k(red)(Mo) = 972 s(-1) at pH 8.65 for wild-type protein), indicating that this is not the rate-limiting step in the catalytic cycle. Reduction of the molybdenum center of the Y343F variant by sulfite was more significantly impaired at high pH than at low pH. These results demonstrate that the Tyr(343) residue is important for both substrate binding and oxidation of sulfite by sulfite oxidase.