1.8.5.3: respiratory dimethylsulfoxide reductase
This is an abbreviated version!
For detailed information about respiratory dimethylsulfoxide reductase, go to the full flat file.
Word Map on EC 1.8.5.3
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1.8.5.3
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rhodobacter
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sphaeroides
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molybdoenzyme
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molybdopterin
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capsulatus
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dithiolene
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pyranopterins
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narghi
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tord
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bismolybdopterin
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mo-containing
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high-g
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menaquinol
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wiv
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frdabcd
- 1.8.5.3
- rhodobacter
- sphaeroides
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molybdoenzyme
- molybdopterin
- capsulatus
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dithiolene
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pyranopterins
- narghi
- tord
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bismolybdopterin
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mo-containing
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high-g
- menaquinol
- wiv
- frdabcd
Reaction
Synonyms
dimethyl sulfoxid reductase, dimethyl sulfoxide reductase, dimethyl sulfoxide/trimethylamine N-oxide reductase, dimethyl sulfoxie reductase, dimethylsulfoxide reductase, dms, DmsA, DmsABC, DmsABC sulfoxide reductase, DmsC, DMSO reductase, DMSOR, dorA, More, respiratory dimethyl sulfoxide reductase
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Cofactor
Cofactor on EC 1.8.5.3 - respiratory dimethylsulfoxide reductase
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[4Fe-4S]-center
role for the cluster in directing molybdenum cofactor assembly during enzyme maturation. The cluster is predicted to be in close proximity to the molybdo-bis(pyranopterin guanine dinucleotide) cofactor, which provides the site of dimethyl sulfoxide reduction
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presence of a monooxo molybdenum cofactor containing two molybdopterin guanine dinucleotides that asymmetrically coordinate the molybdenum through their dithiolene groups. One of the pterins exhibits different coordination modes to the molybdenum between the oxidized and reduced states, whereas the side chain oxygen of Ser147 coordinates the metal in both states
bis(molybdopterin guanine dinucleotide)molybdenum cofactor
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protein contains 1 mol of molybdenum, 4 mol of organic phosphate, and 2 mol of guanine per mole of protein
bis(molybdopterin guanine dinucleotide)molybdenum cofactor
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the bis-molybdopterin guanine dinucleotide cofactor of the single chain protein has the molybdenum ion bound to the cis-dithiolene group of only one molybdopterin guanine dinucleotide molecule. Three additional ligands, two oxo groups and the oxygen of a serine side-chain, are bound to the molybdenum ion. The second molybdopterin system is not part of the ligand sphere of the metal center
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residues Pro80, Ser81, Cys102, and Tyr104 of electron transfer subunit DmsB are located at the DmsB-DmsC interface and are critical for the transfer of electrons from MQH2 to iron-sulfur cluster FS4
Fe-S center
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significant spin-spin interaction between the reduced [4Fe-4S] cluster of subunit DmsB and the Mo(V) of the Mo-bisMGD of subunit DmsA. This interaction is significantly modified in a DmsA-C38S mutant that contains a [3Fe-4S] cluster in DmsA
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reaction profile for oxygen atom transfer from dimethylsulfoxide to [Mo(IV)(OMe)(S2C2H2)2]1- compared to the corresponding reaction with [W(IV)(OMe)(S2C2H2)2]1-. Both reaction profiles involve two transition states separated by a well-defined intermediate. The second transition state TS2 is clearly rate-limiting for the Mo system, and the two transition states have a similar energy for the W system. The activation energy for oxygen atom transfer from dimethylsulfoxide to [W(IV)(OMe)(S2C2H2)2]1- is ca. 23 kJ per mol lower for the corresponding reaction with Mo, consistent with the significantly faster rate of reduction of dimethylsulfoxide by Rhodobacter capsulatus W-dimethylsulfoxide reductase than by its Mo counterpart. The geometrical constraints imposed by the protein on the metal centre of the Mo- and W-dimethylsulfoxide reductases facilitate oxygen atom transfer by favouring a trigonal prismatic geometry for the transition state TS2 that is close to that observed for the metal in the oxidised form of each of these enzymes. The major effect of different tautomers of a simplified form of the pyran ring-opened, dihydropterin state, a significant lowering of the activation barrier associated with TS2, is observed for a protonated form of a tautomer that involves conjugation between the pyrazine and metallodithiolene rings
molybdenum bis-molybdopterin guanine dinucleotide
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the molybdenum cofactor in dimethylsulfoxide reductase is bis(molybdopterin guanine dinucleotide) molybdenum. Protein contains 1 mol Mo and 2 mol GMP. Approximately 2 mol. electrons/2 mol molybdopterin guanine dinucleotide reduce 2,6-dichloroindophenol. Presence of one molybdopterin guanine dinucleotide moiety with a pyrazine ring at the oxidation level of a dihydropteridine and one molybdopterin guanine dinucleotide moiety with a pyrazine ring at the oxidation level of a fully aromatic pteridine
molybdenum cofactor
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residue W116 forms a hydrogen bond with a single oxo ligand bound to the molybdenum ion. Mutation of this residue to phenylalanine affects the UV/visible spectrum of the purified MoVI form of dimethylsulfoxide reductase resulting in the loss of the characteristic transition at 720 nm. W116 plays a critical role in stabilizing the hexacoordinate monooxo MoVI form of the enzyme and prevents the formation of a dioxo pentacoordinate MoVI species
molybdenum cofactor
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MoCo, the cofactor coordinates organic molybdopterin to molybdenum, over 50 different molybdopterin enzymes are known to catalyze a variety of chemistries in the cycling of C, N, S, As, and Se, all relying on the same basic cofactor, the MoCo. Kinetic consequences of the exchange of the endogenous ligand to molybdenum with other ligands within the cofactor of DMSO reductase family enzymes, overview. The mutant C176D of periplasmic nitrate reductase NapA (EC 1.9.6.1) is active with DMSO (and artificial cosubstrate methyl viologen), while the wild-type NapA is not
molybdenum cofactor
pterin-based cofactor MoCo, molybdenum is not active in cells until it forms the MoCo. The DMSO reductases family cofactor is the bis-molybdopterin-guanine dinucleotide (Bis-MGD) and it is composed by two pyranopterin molecules (instead of one pyranopterin as in sulfite oxidases and xanthine oxidases families), which are conjugated with nucleosides: cytosine or guanosine. In this family, the Mo atom in the MoCo is coordinated by four sulfur atoms of the pyranopterins rings and by an inorganic ion that could be selenium, oxygen, or sulfur atoms. In almost all cases, another ligand that has a role in coordination comes from an amino acid side chain that can be aspartate, serine, cysteine, and selenocysteine. Depending on this amino acid, the DMSO reductases can be classified in three types: cysteine or selenocysteine for type I, an aspartate for type II, and serine residue for type III. Enzyme DmsA is a type III enzyme
molybdenum cofactor
pterin-based cofactor MoCo, molybdenum is not active in cells until it forms the MoCo. The DMSO reductases family cofactor is the bis-molybdopterin-guanine dinucleotide (Bis-MGD) and it is composed by two pyranopterin molecules (instead of one pyranopterin as in sulfite oxidases and xanthine oxidases families), which are conjugated with nucleosides: cytosine or guanosine. In this family, the Mo atom in the MoCo is coordinated by four sulfur atoms of the pyranopterins rings and by an inorganic ion that could be selenium, oxygen, or sulfur atoms. In almost all cases, another ligand that has a role in coordination comes from an amino acid side chain that can be aspartate, serine, cysteine, and selenocysteine. Depending on this amino acid, the DMSO reductases can be classified in three types: cysteine or selenocysteine for type I, an aspartate for type II, and serine residue for type III. Enzyme DmsA is a type III enzyme. The Mo amino acid ligand in the MoCo of Halobacterium salinarum DmsA is an aspartate residue in all halophilic archaea instead of a serine residue
molybdenum cofactor
pterin-based cofactor MoCo, the unique cofactor contains the ligand pyranopterin ene-1,2-dithiolate. Mechanism for mature Moco formation, overview. Bacterial DMSO reductase family enzymes possess a bis-molybdopterin guanine dinucleotide (bis-MGD) cofactor that is obtained by adding GMP to the MPT terminal phosphates. Enzymes that belong to the DMSO reductase enzyme family possess two coordinated MPTs, with one of the MPTs adopting an SO family configuration and the other a more distorted XO enzyme family structure, role of MPT in catalysis
molybdenum cofactor
pterin-based cofactor MoCo, the unique cofactor contains the ligand pyranopterin ene-1,2-dithiolate. Mechanism for mature Moco formation, overview. Bacterial DMSO reductase family enzymes possess a bis-molybdopterin guanine dinucleotide (bis-MGD) cofactor that is obtained by adding GMP to the MPT terminal phosphates. Enzymes that belong to the DMSO reductase enzyme family possess two coordinated MPTs, with one of the MPTs adopting an SO family configuration and the other a more distorted XO enzyme family structure, role of MPT in catalysis
molybdenum cofactor
two desoxo molybdenum(V) complexes are synthesized and characterized as models for the paramagnetic high-g split intermediate observed in the catalytic cycle of dimethyl sulfoxide reductase (DMSOR), analysis of extended X-ray absorption fine structure (EXAFS) and electron paramagnetic resonance (EPR) data. A 6-coordinate [(PDT)2Mo(OH)(OSer)]- structure (PDT = pyranopterin dithiolene) is supported for a high-g split with four S donors from two PDT ligands, a coordinated hydroxyl ligand, and a serinate O donor. This geometry orients the redox orbital toward the substrate access channel for the two-electron reduction of substrates. Detailed overview
molybdenum cofactor
two desoxo molybdenum(V) complexes are synthesized and characterized as models for the paramagnetic high-g split intermediate observed in the catalytic cycle of dimethyl sulfoxide reductase (DMSOR), analysis of extended X-ray absorption fine structure (EXAFS) and electron paramagnetic resonance (EPR) data. A 6-coordinate [(PDT)2Mo(OH)(OSer)]- structure (PDT = pyranopterin dithiolene) is supported for a high-g split with four S donors from two PDT ligands, a coordinated hydroxyl ligand, and a serinate O donor. This geometry orients the redox orbital toward the substrate access channel for the two-electron reduction of substrates. Detailed overview
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CymA serves as a preferential electron transport protein for the type I and type VI DMSO reductases, in which type VI accepts electrons from CymA in a DmsE- and DmsF-independent manner. DmsE passes electrons to DmsA1 for DMSO reduction. In-frame deletion mutagenesis of dmsE (swp3461) and analysis
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additional information
kinetic and spectroscopic analysis of molybdenum-DMSO reductase and a tungsten-substituted form of DMSO reductase, overview. Partial reduction with sodium dithionite yields a well-resolved W(V) EPR signal of the so-called high-g split type that exhibits markedly greater g-anisotropy than the corresponding Mo(V) signal of the native form of the enzyme, with the g values shifted to higher magnetic field by as much as DELTAgave = 0.056. Deuteration of the enzyme confirms that the coupled proton is solvent-exchangeable, allowing to accurately simulate the tungsten hyperfine coupling. Global curve-fitting analysis of UV/vis absorption spectra observed in the course of the reaction of the tungsten-substituted enzyme with sodium dithionite affords a well-defined absorption spectrum for the W(V) species. The absorption spectrum for this species exhibits significantly larger molar extinction coefficients than either the reduced or the oxidized spectrum. This spectrum, in conjunction with those for fully oxidized W(VI) and fully reduced W(IV) enzyme, is used to deconvolute the absorption spectra seen in the course of turnover, in which the enzyme is reacted with sodium dithionite and DMSO, demonstrating that the W(V) is an authentic catalytic intermediate that accumulates to approximately 50% of the total enzyme in the steady state
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additional information
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kinetic and spectroscopic analysis of molybdenum-DMSO reductase and a tungsten-substituted form of DMSO reductase, overview. Partial reduction with sodium dithionite yields a well-resolved W(V) EPR signal of the so-called high-g split type that exhibits markedly greater g-anisotropy than the corresponding Mo(V) signal of the native form of the enzyme, with the g values shifted to higher magnetic field by as much as DELTAgave = 0.056. Deuteration of the enzyme confirms that the coupled proton is solvent-exchangeable, allowing to accurately simulate the tungsten hyperfine coupling. Global curve-fitting analysis of UV/vis absorption spectra observed in the course of the reaction of the tungsten-substituted enzyme with sodium dithionite affords a well-defined absorption spectrum for the W(V) species. The absorption spectrum for this species exhibits significantly larger molar extinction coefficients than either the reduced or the oxidized spectrum. This spectrum, in conjunction with those for fully oxidized W(VI) and fully reduced W(IV) enzyme, is used to deconvolute the absorption spectra seen in the course of turnover, in which the enzyme is reacted with sodium dithionite and DMSO, demonstrating that the W(V) is an authentic catalytic intermediate that accumulates to approximately 50% of the total enzyme in the steady state
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additional information
tungsten is present as cofactor in tungsten enzymes, sharing a lot of resemblances with the MoCo of DMSO reductases
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additional information
tungsten is present as cofactor in tungsten enzymes, sharing a lot of resemblances with the MoCo of DMSO reductases
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