Effects of large-scale amino acid substitution in the polypeptide tether connecting the heme and molybdenum domains on catalysis in human sulfite oxidase

Sulfite oxidase (SO) is a molybdenum-cofactor-dependent enzyme that catalyzes the oxidation of sulfite to sulfate, the final step in the catabolism of the sulfur-containing amino acids, cysteine and methionine. The catalytic mechanism of vertebrate SO involves intramolecular electron transfer (IET) from molybdenum to the integral b-type heme of SO and then to exogenous cytochrome c. However, the crystal structure of chicken sulfite oxidase (CSO) has shown that there is a 32 ? distance between the Fe and Mo atoms of the respective heme and molybdenum domains, which are connected by a flexible polypeptide tether. This distance is too long to be consistent with the measured IET rates. Previous studies have shown that IET is viscosity dependent (Feng et al., Biochemistry, 2002, 41, 5816) and also dependent upon the flexibility and length of the tether (Johnson-Winters et al., Biochemistry, 2010, 49, 1290). Since IET in CSO is more rapid than in human sulfite oxidase (HSO) (Feng et al., Biochemistry, 2003, 42, 12235) the tether sequence of HSO has been mutated into that of CSO, and the resultant chimeric HSO enzyme investigated by laser flash photolysis and steady-state kinetics in order to study the specificity of the tether sequence of SO on the kinetic properties. Surprisingly, the IET kinetics of the chimeric HSO protein with the CSO tether sequence are slower than wildtype HSO. This observation raises the possibility that the composition of the non-conserved tether sequence of animal SOs may be optimized for individual species.     

Identification and biochemical characterization of Arabidopsis thaliana sulfite oxidase. A new player in plant sulfur metabolism

In mammals and birds, sulfite oxidase (SO) is a homodimeric molybdenum enzyme consisting of an N-terminal heme domain and a C-terminal molybdenum domain (EC ). In plants, the existence of SO has not yet been demonstrated, while sulfite reductase as part of sulfur assimilation is well characterized. Here we report the cloning of a plant sulfite oxidase gene from Arabidopsis thaliana and the biochemical characterization of the encoded protein (At-SO). At-SO is a molybdenum enzyme with molybdopterin as an organic component of the molybdenum cofactor. In contrast to homologous animal enzymes, At-SO lacks the heme domain, which is evident both from the amino acid sequence and from its enzymological and spectral properties. Thus, among eukaryotes, At-SO is the only molybdenum enzyme yet described possessing no redox-active centers other than the molybdenum. UV-visible and EPR spectra as well as apparent K(m) values are presented and compared with the hepatic enzyme. Subcellular analysis of crude cell extracts showed that SO was mostly found in the peroxisomal fraction. In molybdenum cofactor mutants, the activity of SO was strongly reduced. Using antibodies directed against At-SO, we show that a cross-reacting protein of similar size occurs in a wide range of plant species, including both herbacious and woody plants.     

Plant sulfite oxidase as novel producer of H2O2: combination of enzyme catalysis with a subsequent non-enzymatic reaction step

Sulfite oxidase (EC 1.8.3.1) from the plant Arabidopsis thaliana is the smallest eukaryotic molybdenum enzyme consisting of a molybdenum cofactor-binding domain but lacking the heme domain that is known from vertebrate sulfite oxidase. While vertebrate sulfite oxidase is a mitochondrial enzyme with cytochrome c as the physiological electron acceptor, plant sulfite oxidase is localized in peroxisomes and does not react with cytochrome c. Here we describe results that identified oxygen as the terminal electron acceptor for plant sulfite oxidase and hydrogen peroxide as the product of this reaction in addition to sulfate. The latter finding might explain the peroxisomal localization of plant sulfite oxidase. 18O labeling experiments and the use of catalase provided evidence that plant sulfite oxidase combines its catalytic reaction with a subsequent non-enzymatic step where its reaction product hydrogen peroxide oxidizes another molecule of sulfite. In vitro, for each catalytic cycle plant SO will bring about the oxidation of two molecules of sulfite by one molecule of oxygen. In the plant, sulfite oxidase could be responsible for removing sulfite as a toxic metabolite, which might represent a means to protect the cell against excess of sulfite derived from SO2 gas in the atmosphere (acid rain) or during the decomposition of sulfur-containing amino acids. Finally we present a model for the metabolic interaction between sulfite and catalase in the peroxisome.     

In vitro incorporation of nascent molybdenum cofactor into human sulfite oxidase

We were able to reconstitute molybdopterin (MPT)-free sulfite oxidase in vitro with the molybdenum cofactor (Moco) synthesized de novo from precursor Z and molybdate. MPT-free human sulfite oxidase apoprotein was obtained by heterologous expression in an Escherichia coli mutant with a defect in the early steps of MPT biosynthesis. In vitro reconstitution of the purified apoprotein was achieved using an incubation mixture containing purified precursor Z, purified MPT synthase, and sodium molybdate. In vitro synthesized MPT generated from precursor Z by MPT synthase remains bound to the synthase. Surprisingly, MPT synthase was found capable of donating bound MPT to MPT-free sulfite oxidase. MPT was not released from MPT synthase when either bovine serum albumin or Moco-containing sulfite oxidase was used in place of aposulfite oxidase. After the inclusion of sodium molybdate in the reconstitution mixture, active sulfite oxidase was obtained, revealing that in vitro MPT synthase and aposulfite oxidase are sufficient for the insertion of MPT into sulfite oxidase and the conversion of MPT into Moco in the presence of high concentrations of molybdate. The conversion of MPT into Moco by molybdate chelation apparently occurs concomitantly with the insertion of MPT into sulfite oxidase.     

Peroxisomal localization of sulfite oxidase separates it from chloroplast-based sulfur assimilation

Recently, we isolated the sulfite oxidase (SO) gene from Arabidopsis thaliana and characterized the purified SO protein. The purpose of the present study was to determine the subcellular localization of this novel plant enzyme. Immunogold electron-microscopic analysis showed the gold labels nearly exclusively in the peroxisomes. To verify this finding, green fluorescent protein was fused to full-length plant SO including the putative peroxisomal targeting signal 1 (PTS1) 'SNL' and expressed in tobacco leaves. Our results showed a punctate fluorescence pattern resembling that of peroxisomes. Co-labelling with MitoTracker-Red excluded that the observed fluorescence was due to mitochondrial sorting. By investigation of deleted or mutated PTS1, no functional peroxisomal targeting signal 2 (PTS2) could be detected in plant SO. This conclusion is supported by expression studies in Pichia pastoris mutants with defined defects either in PTS1- or PTS2-mediated peroxisomal import.     

Significance of plant sulfite oxidase

Sulfite oxidizing activities are known since years in animals, microorganisms, and also plants. Among plants, the only enzyme well characterized on molecular and biochemical level is the molybdoenzyme sulfite oxidase (SO). It oxidizes sulfite using molecular oxygen as electron acceptor, leading to the production of sulfate and hydrogen peroxide. The latter reaction product seems to be the reason why plant SO is localized in peroxisomes, because peroxisomal catalase is able to decompose hydrogen peroxide. On the other hand, we have indications for an additional reaction taking place in peroxisomes: sulfite can be nonenzymatically oxidized by hydrogen peroxide. This will promote the detoxification of hydrogen peroxide especially in the case of high amounts of sulfite. Hence we assume that SO could possibly serve as "safety valve" for detoxifying excess amounts of sulfite and protecting the cell from sulfitolysis. Supportive evidence for this assumption comes from experiments where we fumigated transgenic poplar plants overexpressing ARABIDOPSIS SO with SO(2) gas. In this paper, we try to explain sulfite oxidation in its co-regulation with sulfate assimilation and summarize other sulfite oxidizing activities described in plants. Finally we discuss the importance of sulfite detoxification in plants.     

Identification and characterization of a novel bacterial sulfite oxidase with no heme binding domain from Deinococcus radiodurans

An open reading frame (draSO) encoding a putative sulfite oxidase (SO) was identified in the sequence of chromosome II of Deinococcus radiodurans; the predicted gene product showed significant amino acid sequence homology to several bacterial and eukaryotic SOs, such as the biochemically and structurally characterized enzyme from Arabidopsis thaliana. Cloning of the Deinococcus SO gene was performed by PCR amplification from the bacterial genomic DNA, and heterologous gene expression of a histidine-tagged polypeptide was obtained in a molybdopterin-overproducing strain of Escherichia coli. The recombinant protein was purified to homogeneity by nickel chelating affinity chromatography, and its main kinetic and chemical physical parameters were determined. Northern blot and enzyme activity analyses indicated that draSO gene expression is constitutive in D. radiodurans and that there is no increase upon exposure to thiosulfate and/or molybdenum(II).     

Xanthine oxidase/hydrogen peroxide generates sulfur trioxide anion radical (SO3.-) from sulfite (SO3(2-)).

In the presence of hydrogen peroxide (H2O2), xanthine oxidase has been found to catalyze sulfur trioxide anion radical (SO3.-) formation from sulfite anion (SO3(2-)). The SO3.- radical was identified by ESR (electron spin resonance) spin trapping, utilizing 5,5-dimethyl-l-pyrroline-l-oxide (DMPO) as the spin trap. Inactivated xanthine oxidase does not catalyze SO3.- radical formation, implying a specific role for this enzyme. The initial rate of SO3.- radical formation increases linearly with xanthine oxidase concentration. Together, these observations indicate that the SO3.- generation occurs enzymatically. These results suggest a new property of xanthine oxidase and perhaps also a significant step in the mechanism of sulfite toxicity in cellular systems.     

Mechanism of sulfite cytotoxicity in isolated rat hepatocytes

Sulfite (SO(3)(2-)) has been widely used as preservative and antimicrobial in preventing browning of foods and beverages. SO(2), a common air pollutant, also is capable of producing sulfite and bisulfite depending on the pH of solutions. A molybdenum-dependent mitochondrial enzyme, sulfite oxidase, oxidizes sulfite to inorganic sulfate and prevents its toxic effects. In the present study, sulfite toxicity towards isolated rat hepatocytes was markedly increased by partial inhibition of cytochrome a/a(3) by cyanide or by putting rats on a high-tungsten/low-molybdenum diet, which result in inactivation of sulfite oxidase. Sulfite cytotoxicity was accompanied by a rapid disappearance of GSSG followed by a slow depletion of reduced glutathione (GSH). Depleting hepatocyte GSH beforehand increased cytotoxicity of sulfite. On the other hand, dithiothreitol (DTT), a thiol reductant, added even 1h after the addition of sulfite to hepatocytes, prevented cell death and restored hepatocyte GSH levels. Sulfite cytotoxicity was also accompanied by an increase of oxygen uptake, reactive oxygen species (ROS) formation and lipid peroxidation. Cytochrome P450 inhibitors, metyrapone and piperonyl butoxide also prevented sulfite-induced cytotoxicity and lipid peroxidation. Desferroxamine and antioxidants also protected the cells against sulfite toxicity. These findings suggest that cytotoxicity of sulfite is mediated by free radicals as ROS formation increases by sulfite and antioxidants prevent its toxicity. Reaction of sulfite or its free radical metabolite with disulfide bonds of GSSG and GSH results in the compromise of GSH/GSSG antioxidant system leaving the cell susceptible to oxidative stress. Restoring GSH content of the cell or protein-SH groups by DTT can prevent sulfite cytotoxicity.     

A novel thermostable sulfite oxidase from Thermus thermophilus: characterization of the enzyme, gene cloning and expression in Escherichia coli

A novel sulfite oxidase has been identified from Thermus thermophilus AT62. Despite this enzyme showing significant amino-acid sequence homology to several bacterial and eukaryal putative and identified sulfite oxidases, the kinetic analysis, performed following the oxidation of sulfite and with ferricyanide as the electron acceptor, already pointed out major differences from representatives of bacterial and eukaryal sources. Sulfite oxidase from T. thermophilus, purified to homogeneity, is a monomeric enzyme with an apparent molecular mass of 39.1 kDa and is almost exclusively located in the periplasm fraction. The enzyme showed sulfite oxidase activity only when ferricyanide was used as electron acceptor, which is different from most of sulfite-oxidizing enzymes from several sources that use cytochrome c as co-substrate. Spectroscopic studies demonstrated that the purified sulfite oxidase has no cytochrome like domain, normally present in homologous enzymes from eukaryotic and prokaryotic sources, and for this particular feature it is similar to homologous enzyme from Arabidopsis thaliana. The identified gene was PCR amplified on T. thermophilus AT62 genome, expressed in Escherichia coli and the recombinant protein identified and characterized.     

The octahaem SirA catalyses dissimilatory sulfite reduction in Shewanella oneidensis MR-1

Shewanella oneidensis MR-1 is a metal reducer that uses a large number of electron acceptors including thiosulfate, polysulfide and sulfite. The enzyme required for thiosulfate and polysulfide respiration has been recently identified, but the mechanisms of sulfite reduction remained unexplored. Analysis of MR-1 cultures grown anaerobically with sulfite suggested that the dissimilatory sulfite reductase catalyses six-electron reduction of sulfite to sulfide. Reduction of sulfite required menaquinones but was independent of the intermediate electron carrier CymA. Furthermore, the terminal sulfite reductase, SirA, was identified as an octahaem c cytochrome with an atypical haem binding site. The sulfite reductase of S. oneidensis MR-1 does not appear to be a sirohaem enzyme, but represents a new class of sulfite reductases. The gene that encodes SirA is located within a 10-gene locus that is predicted to encode a component of a specialized haem lyase, a menaquinone oxidase and copper transport proteins. This locus was identified in the genomes of several Shewanella species and appears to be linked to the ability of these organisms to reduce sulfite under anaerobic conditions.     

Structural insights into sulfite oxidase deficiency

Sulfite oxidase deficiency is a lethal genetic disease that results from defects either in the genes encoding proteins involved in molybdenum cofactor biosynthesis or in the sulfite oxidase gene itself. Several point mutations in the sulfite oxidase gene have been identified from patients suffering from this disease worldwide. Although detailed biochemical analyses have been carried out on these mutations, no structural data could be obtained because of problems in crystallizing recombinant human and rat sulfite oxidases and the failure to clone the chicken sulfite oxidase gene. We synthesized the gene for chicken sulfite oxidase de novo, working backward from the amino acid sequence of the native chicken liver enzyme by PCR amplification of a series of 72 overlapping primers. The recombinant protein displayed the characteristic absorption spectrum of sulfite oxidase and exhibited steady state and rapid kinetic parameters comparable with those of the tissue-derived enzyme. We solved the crystal structures of the wild type and the sulfite oxidase deficiency-causing R138Q (R160Q in humans) variant of recombinant chicken sulfite oxidase in the resting and sulfate-bound forms. Significant alterations in the substrate-binding pocket were detected in the structure of the mutant, and a comparison between the wild type and mutant protein revealed that the active site residue Arg-450 adopts different conformations in the presence and absence of bound sulfate. The size of the binding pocket is thereby considerably reduced, and its position relative to the cofactor is shifted, causing an increase in the distance of the sulfur atom of the bound sulfate to the molybdenum.     

Structures of the Mo(V) forms of sulfite oxidase from Arabidopsis thaliana by pulsed EPR spectroscopy

The Mo(V) center of plant sulfite oxidase from Arabidopsis thaliana (At-SO) has been studied by continuous wave and pulsed EPR methods. Three different Mo(V) EPR signals have been observed, depending on pH and the technique used to generate the Mo(V) oxidation state. At pH 6, reduction by sulfite followed by partial reoxidation with ferricyanide generates an EPR spectrum with g-values similar to the low-pH (lpH) form of vertebrate SOs, but no nearby exchangeable protons can be detected. On the other hand, reduction of At-SO with Ti(III) citrate at pH 6 generates a Mo(V) signal with large hyperfine splittings from a single exchangeable proton, as is typically observed for lpH SO from vertebrates. Reduction of At-SO with sulfite at high pH generates the well-known high-pH (hpH) signal common to all sulfite oxidizing enzymes. It is proposed that, depending on the conformation of Arg374, the active site of At-SO may be in "closed" or "open" forms that differ in the degree of accessibility of the Mo center to substrate and water molecules. It is suggested that at low pH the sulfite-reduced At-SO has coordinated sulfate and is in the "closed form". Reoxidation to Mo(V) by ferricyanide leaves bound sulfate trapped at the active site, and consequently, there are no ligands with exchangeable protons. Reduction with Ti(III) citrate injects an electron directly into the active site to generate the [Mo(V)[triple bond]O(OH)]2+ unit that is well-known from model chemistry and which has a single exchangeable proton with a large isotropic hyperfine interaction. At high pH, the active site is in the "open form", and water can readily exchange into the site to generate the hpH SO.     

Role of conserved tyrosine 343 in intramolecular electron transfer in human sulfite oxidase

Tyrosine 343 in human sulfite oxidase (SO) is conserved in all SOs sequenced to date. Intramolecular electron transfer (IET) rates between reduced heme (Fe(II)) and oxidized molybdenum (Mo(VI)) in the recombinant wild-type and Y343F human SO were measured for the first time by flash photolysis. The IET rate in wild-type human SO at pH 7.4 is about 37% of that in chicken SO with a similar decrease in k(cat). Steady-state kinetic analysis of the Y343F mutant showed an increase in K(m)(sulfite) and a decrease in k(cat) resulting in a 23-fold attenuation in the specificity constant k(cat)/K(m)(sulfite) at the optimum pH value of 8.25. This indicates that Tyr-343 is involved in the binding of the substrate and catalysis within the molybdenum active site. Furthermore, the IET rate constant in the mutant at pH 6.0 is only about one-tenth that of the wild-type enzyme, suggesting that the OH group of Tyr-343 is vital for efficient IET in SO. The pH dependences of IET rate constants in the wild-type and mutant SO are consistent with the previously proposed coupled electron-proton transfer mechanism.     

Sulfite sensitivity and sulfite oxidase actiivty inDrosophila melanogaster

The relationship between sulfite oxidase (SO) and sulfite sensitivity inDrosophila melanogaster is addressed. Significant improvements to the SO assay have provided an investigative tool which can be applied to further studies of this molybdoenzyme. Using the second-instar larval stage ofD. melanogaster, we have shown a direct relationship between measured levels of sulfite oxidase activity and the organism's ability to withstand a sulfite challenge. Implementation of a sulfite-testing procedure confirmed the documented instability of sulfite in solution and may explain some of the conflicting results reported in the SO literature. Results of the tungstate-addition experiments confirm thatDrosophila SO is a molybdoenzyme and its activity was shown to be governed by three of the four loci known to affect more than one molybdoenzyme. The ability ofD. melanogaster to withstand the application of exogenous sulfites is shown to be dependent on sulfite oxidase activity.     

Gasometric measurement of sulfite oxidation

In the commonly used sulfite method the consumption of sulfite is determined by iodometry. Since however, the addition of organic substances may interfere with iodometry (e.g. due to chemical reactions with iodine) the gasometric measurement of sulfite oxidation has been developed for analysis of how different culture media may influence the oxygen transfer rate. The striking decrease of sulfite oxidation rate due to addition of culture media to the sulfite solution suggests that adsorption of orgnic components in the gas liquid interface may account for an additional diffusion barrier and thus for a decrease of the oxygen transfer coefficient which in addition gives an explanation for differences between values found by the sulfite method and by aerobic cultivations. Consequently identical values of oxygen transfer rate have been obtained for both systems whenever the sulfite system has been properly adjusted to the aerobic cultivation conditions. In so far, the gasometric sulfite method proved to be a unique tool for rapid determination of factors influencing oxygen transfer rate in fermentation processes which may give rise to a reappraisal as to the relevance of the sulfite method for oxygen transfer optimization.     

A Novel Role for Arabidopsis Mitochondrial ABC Transporter ATM3 in Molybdenum Cofactor Biosynthesis

The molybdenum cofactor (Moco) is a prosthetic group required by a number of enzymes, such as nitrate reductase, sulfite oxidase, xanthine dehydrogenase, and aldehyde oxidase. Its biosynthesis in eukaryotes can be divided into four steps, of which the last three are proposed to occur in the cytosol. Here, we report that the mitochondrial ABC transporter ATM3, previously implicated in the maturation of extramitochondrial iron-sulfur proteins, has a crucial role also in Moco biosynthesis. In ATM3 insertion mutants of Arabidopsis thaliana, the activities of nitrate reductase and sulfite oxidase were decreased to ∼50%, whereas the activities of xanthine dehydrogenase and aldehyde oxidase, whose activities also depend on iron-sulfur clusters, were virtually undetectable. Moreover, atm3 mutants accumulated cyclic pyranopterin monophosphate, the first intermediate of Moco biosynthesis, but showed decreased amounts of Moco. Specific antibodies against the Moco biosynthesis proteins CNX2 and CNX3 showed that the first step of Moco biosynthesis is localized in the mitochondrial matrix. Together with the observation that cyclic pyranopterin monophosphate accumulated in purified mitochondria, particularly in atm3 mutants, our data suggest that mitochondria and the ABC transporter ATM3 have a novel role in the biosynthesis of Moco.     

The kinetic behavior of chicken liver sulfite oxidase.

A comprehensive kinetic study of sulfite oxidase has been undertaken over the pH range 6.0-10.0, including conventional steady-state work as well as rapid kinetic studies of both the reaction of oxidized enzyme with sulfite and reduced enzyme with cytochrome c (III). A comparison of the pH dependence of kcat, kred, and kox indicates that kred is principally rate limiting above pH 7, but that below this pH the pH dependence of kcat is influenced by that of kox. The pH independence of kred is consistent with our previous proposal concerning the reaction mechanism, in which attack of the substrate lone pair of electrons on a Mo(VI)O2 unit initiates the catalytic sequence. The pH dependence of kred/Kdsulfite indicates that a group on the enzyme having a pKa of approximately 9.3 must be deprotonated for effective reaction of oxidized enzyme with sulfite, possibly Tyr 322, which from the crystal structure of the enzyme constitutes part of the substrate binding site. There is no evidence for the HSO3-/SO32- pKa of approximately 7 in the pH profile for kred/Kdsulfite, suggesting that enzyme is able to oxidize the two equally well. By contrast, kcat/Kmsulfite and kred/Kdsulfite exhibit distinct pH dependence (the former is bell-shaped, the latter sigmoidal), again consistent with the oxidative half-reaction contributing to the kinetic barrier to catalysis at low pH. The pH dependence of kcat/Km(cyt c) (reflecting the second-order rate of reaction of free enzyme with free cytochrome) is bell-shaped and closely resembles that of kox/Kd(cyt c), reflecting the importance of the oxidative half-reaction in the low substrate concentration regime. The pH profile for kox/Kd(cyt c) indicates that two groups with a pKa of approximately 8 are involved in the reaction of free reduced enzyme with cytochrome c, one of which must be deprotonated and the other protonated. These results are consistent with the known electrostatic nature of the interaction of cytochrome c with its physiological partners.     

Rhodobacter capsulatus XdhC is involved in molybdenum cofactor binding and insertion into xanthine dehydrogenase

Rhodobacter capsulatus xanthine dehydrogenase (XDH) is a cytoplasmic enzyme with an (alphabeta)2 heterodimeric structure that is highly identical to homodimeric eukaryotic xanthine oxidoreductases. The crystal structure revealed that the molybdenum cofactor (Moco) is deeply buried within the protein. A protein involved in Moco insertion and XDH maturation has been identified, which was designated XdhC. XdhC was shown to be essential for the production of active XDH but is not a subunit of the purified enzyme. Here we describe the purification of XdhC and the detailed characterization of its role for XDH maturation. We could show that XdhC binds Moco in stoichiometric amounts, which subsequently can be inserted into Moco-free apo-XDH. A specific interaction between XdhC and XdhB was identified. We show that XdhC is required for the stabilization of the sulfurated form of Moco present in enzymes of the xanthine oxidase family. Our findings imply that enzyme-specific proteins exist for the biogenesis of molybdoenzymes, coordinating Moco binding and insertion into their respective target proteins. So far, the requirement of such proteins for molybdoenzyme maturation has been described only for prokaryotes.