Refine
Has Fulltext
- no (138) (remove)
Year of publication
Document Type
- Article (121)
- Review (13)
- Conference Proceeding (3)
- Other (1)
Language
- English (138)
Is part of the Bibliography
- yes (138)
Keywords
- Molybdenum cofactor (7)
- molybdenum cofactor (7)
- Molybdenum (4)
- Aldehyde oxidase (3)
- Aldehyde oxidoreductase (3)
- Bioelectrocatalysis (3)
- Biosensor (3)
- Direct electron transfer (3)
- Electron transfer (3)
- Moco biosynthesis (3)
- Molybdoenzymes (3)
- bis-MGD (3)
- molybdoenzyme (3)
- Biofuel cell (2)
- Bis-MGD (2)
- Chaperone (2)
- Drug metabolism (2)
- FNR (2)
- FeS cluster (2)
- Formate dehydrogenase (2)
- Human sulfite oxidase (2)
- L-Cysteine desulfurase (2)
- Molybdopterin (2)
- Sulfite oxidase (2)
- TMAO reductase (2)
- aldehyde oxidase (2)
- bioremediation (2)
- biosensor (2)
- enzyme catalysis (2)
- formate dehydrogenase (2)
- human sulfite oxidase (2)
- iron-sulfur clusters (2)
- l-cysteine desulfurase (2)
- molybdenum (2)
- persulfide (2)
- sulfite oxidase (2)
- tRNA (2)
- xanthine dehydrogenase (2)
- 2Fe-2S cluster (1)
- 5-methoxycarbonylmethyl-2-thiouridine (1)
- A-type carrier protein (1)
- ABC transporter (1)
- ABCB7 (1)
- Antimony doped tin dioxide (1)
- Aromatic aldehydes (1)
- Benzaldehyde (1)
- Bilirubin oxidase (1)
- Biocompatibility (1)
- Bioinformatic (1)
- Bioinorganic chemistry (1)
- CO2 reduction (1)
- CdS quantum dots (1)
- Copper (1)
- DFT (1)
- DNA polymerase (1)
- Dehydrogenase (1)
- Direct electrochemistry (1)
- Dithiolene (1)
- Dithiolene group (1)
- Drosophila melanogaster (1)
- EPR spectroscopy (1)
- Electron relay (1)
- Enzymatic fuel cell (1)
- Enzyme Kinetics (1)
- Enzyme catalysis (1)
- Enzyme electrode (1)
- Enzyme models (1)
- Escherichia coli (1)
- External stimuli (1)
- FMN (1)
- Fe-S cluster assembly (1)
- Fis (1)
- Fluorescence (1)
- FtsZ (1)
- FtsZ ring formation (1)
- GABA (1)
- Gene duplication (1)
- Glutamate (1)
- Glutamine (1)
- Gold nanoparticle (1)
- H2S biosynthesis (1)
- Hepatic clearance (1)
- IR (1)
- ISC (1)
- Immobilization (1)
- Ionic liquid (1)
- Isotope Effect (1)
- L-cysteine desulfurase (1)
- MOCS2 (1)
- Metal homeostasis (1)
- Metalloenzymes (1)
- Microscale electrode (1)
- Mitochondria (1)
- MoaA (1)
- Moco (1)
- Molybdenum-iron-iron-sulfur cluster (1)
- Molybdo-flavoenzymes (1)
- Molybdopterin guanine dinucleotide cofactor (1)
- Multi-cofactor enzymes (1)
- N-ligands (1)
- NIF (1)
- Nanoparticles (1)
- Ni electrodes (1)
- Nicotinamide (1)
- Non-CYP enzymes (1)
- Noninnocence (1)
- Nudix hydrolase (1)
- Osmium (1)
- Phenothiazine (1)
- Precursor Z (1)
- Protein voltammetry (1)
- Redox polymer (1)
- Redox proteins (1)
- Rhodobacter (1)
- RpoS (1)
- SUF (1)
- Self-powered biosensor (1)
- Shewanella (1)
- Solvation (1)
- Substrate specificities (1)
- Sulfite biosensor (1)
- Sulfur (1)
- Sulfur transfer (1)
- Sulfuration (1)
- Sulphite oxidase (1)
- Surface enhanced Raman spectroscopy (1)
- TMAO-reductase (1)
- Tellurite (1)
- TiO2 nanotubes (1)
- TorD family (1)
- Transfer RNA (tRNA) (1)
- TusA (1)
- Ultraviolet-visible Spectroscopy (UV-visible Spectroscopy) (1)
- Urothione (1)
- Walker A motif (1)
- X-ray absorption spectroscopy (1)
- X-ray crystallography (1)
- Xanthine (1)
- Xanthine Dehydrogenase (1)
- Xanthine Oxidase (1)
- Xanthine oxidoreductase (1)
- XdhC (1)
- Xenobiotics (1)
- aldehyde oxidase (AOX) (1)
- aldehyde oxidoreductase (1)
- amino alcohols (1)
- amperometry (1)
- anaerobic respiration (1)
- benzaldehyde (1)
- biocatalysis (1)
- bioelectrocatalysis (1)
- biosensors (1)
- biotin sulfoxide reductase (1)
- cPMP (1)
- carbon paper (1)
- cascade reactions (1)
- cell (1)
- cellular bioenergetics (1)
- chaperone (1)
- chimeric enzyme (1)
- chromium (1)
- cofactors (1)
- converting factor (1)
- crystal twinning (1)
- crystal-structure (1)
- cyclic voltammetry (1)
- cytosolic tRNA thiolation (1)
- decolorization (1)
- dendritic (1)
- direct electrochemistry (1)
- direct electron transfer (1)
- division (1)
- dndBCDE (1)
- drug metabolism (1)
- dyes (1)
- ecdysone (1)
- electrochemical biosensor (1)
- electrochemistry (1)
- electromagnetic field enhancement (1)
- electron transport chain (1)
- enzymatic biofuel cell (1)
- enzyme bioelectrocatalysis (1)
- enzyme evolution (1)
- enzymes (1)
- flavin adenine dinucleotide (FAD) (1)
- flavoprotein (1)
- formate oxidation (1)
- glutathione (1)
- human aldehyde oxidase (1)
- hydrogel (1)
- immobilized enzyme (1)
- in-vitro-synthesis (1)
- inhibition kinetics (1)
- in situ scanning (1)
- ionic strength (1)
- iron (1)
- iron regulation (1)
- iron regulatory protein (1)
- iron-sulfur cluster (1)
- iron-sulfur protein (1)
- lactams (1)
- macroporous ITO electrodes (1)
- magnetoreceptor (1)
- metal-containing enzyme (1)
- metalloenzyme (1)
- mitoflashes (1)
- molybdenum cofactor (Moco) (1)
- molybdenum cofactor (Moco)-binding chaperone (1)
- molybdenum cofactor deficiency (1)
- molybdo-enzymes (1)
- molybdo-flavoenzyme (1)
- molybdoenzyme maturation (1)
- molybdopterin synthase (1)
- moonlighting (1)
- mouse (1)
- multienzyme electrode (1)
- n-oxide reductase (1)
- nitrate reductase (1)
- overlapping reading frames (1)
- oxidase (1)
- oxygen radicals (1)
- oxygen scavenger (1)
- pH Dependence (1)
- pH responsive hydrogel (1)
- pH-dependent electrochemistry (1)
- periplasmic aldehyde oxidoreductase (1)
- periplasmic nitrate reductase (1)
- photocurrent (1)
- photonic crystals (1)
- polysulfide (1)
- protein structures (1)
- pyridoxal-50-phosphate (1)
- quiescent mitochondria (1)
- redox polymer (1)
- redox-active ligands (1)
- reduced graphene oxide (1)
- rhodobacter-capsulatus (1)
- ruthenium (1)
- self-assembled molecular monolayers (1)
- single nucleotide polymorphism (1)
- single-crystal gold electrodes (1)
- small angle X-ray scattering (1)
- specific chaperons (1)
- spectro-electrochemistry (1)
- spectroscopy (1)
- sulfonated polyanilines (1)
- sulfur (1)
- sulfur transfer (1)
- sulfurtransferase (1)
- surface-enhanced Raman spectroscopy (1)
- tRNA thio modifications (1)
- tRNA thiolation (1)
- temperature (1)
- thiocarboxylate (1)
- thionucleosides (1)
- trimethylamine N-oxide (1)
- trimethylamine N-oxide (TMAO) (1)
- tunnelling spectroscopy (1)
- viologen (1)
- xanthine oxidase (1)
- xenobiotic (1)
Biosensors for the detection of benzaldehyde and g-aminobutyric acid (GABA) are reported using aldehyde oxidoreductase PaoABC from Escherichia coli immobilized in a polymer containing bound low potential osmium redox complexes. The electrically connected enzyme already electrooxidizes benzaldehyde at potentials below −0.15 V (vs. Ag|AgCl, 1 M KCl). The pH-dependence of benzaldehyde oxidation can be strongly influenced by the ionic strength. The effect is similar with the soluble osmium redox complex and therefore indicates a clear electrostatic effect on the bioelectrocatalytic efficiency of PaoABC in the osmium containing redox polymer. At lower ionic strength, the pH-optimum is high and can be switched to low pH-values at high ionic strength. This offers biosensing at high and low pH-values. A “reagentless” biosensor has been formed with enzyme wired onto a screen-printed electrode in a flow cell device. The response time to addition of benzaldehyde is 30 s, and the measuring range is between 10–150 µM and the detection limit of 5 µM (signal to noise ratio 3:1) of benzaldehyde. The relative standard deviation in a series (n = 13) for 200 µM benzaldehyde is 1.9%. For the biosensor, a response to succinic semialdehyde was also identified. Based on this response and the ability to work at high pH a biosensor for GABA is proposed by coimmobilizing GABA-aminotransferase (GABA-T) and PaoABC in the osmium containing redox polymer.
A Biosensor for aromatic aldehydes comprising the mediator dependent PaoABC-Aldehyde oxidoreductase
(2013)
A novel aldehyde oxidoreductase (PaoABC) from Escherichia coli was utilized for the development of an oxygen insensitive biosensor for benzaldehyde. The enzyme was immobilized in polyvinyl alcohol and currents were measured for aldehyde oxidation with different one and two electron mediators with the highest sensitivity for benzaldehyde in the presence of hexacyanoferrate(III). The benzaldehyde biosensor was optimized with respect to mediator concentration, enzyme loading and pH using potassium hexacyanoferrate(III). The linear measuring range is between 0.5200 mu M benzaldehyde. In correspondence with the substrate selectivity of the enzyme in solution the biosensor revealed a preference for aromatic aldehydes and less effective conversion of aliphatic aldehydes. The biosensor is oxygen independent, which is a particularly attractive feature for application. The biosensor can be applied to detect contaminations with benzaldehyde in solvents such as benzyl alcohol, where traces of benzaldehyde in benzyl alcohol down to 0.0042?% can be detected.
An unusual behavior of the periplasmic aldehyde oxidoreductase (PaoABC) from Escherichia coil has been observed from electrochemical investigations of the enzyme catalyzed oxidation of aromatic aldehydes with different mediators under different conditions of ionic strength. The enzyme has similarity to other molybdoenzymes of the xanthine oxidase family, but the catalytic behavior turned out to be very different. Under steady state conditions the turnover of PaoABC is maximal at pH 4 for the negatively charged ferricyanide and at pH 9 for a positively charged osmium complex. Stopped-flow kinetic measurements of the catalytic half reaction showed that oxidation of benzaldehyde proceeds also above pH 7. Thus, benzaldehyde oxidation can proceed under acidic and basic conditions using this enzyme, a property which has not been described before for molybdenum hydroxylases. It is also suggested that the electron transfer with artificial electron acceptors and PaoABC can proceed at different protein sites and depends on the nature of the electron acceptor in addition to the ionic strength. (C) 2013 Elsevier B.V. All rights reserved.
Catalytic bio-chemo and bio-bio tandem oxidation reactions for amide and carboxylic acid synthesis
(2014)
A catalytic toolbox for three different water-based one-pot cascades to convert aryl alcohols to amides and acids and cyclic amines to lactams, involving combination of oxidative enzymes (monoamine oxidase, xanthine dehydrogenase, galactose oxidase and laccase) and chemical oxidants (TBHP or Cul(cat)/H2O2) at mild temperatures, is presented. Mutually compatible conditions were found to afford products in good to excellent yields.
Molybdoenzymes are complex enzymes in which the molybdenum cofactor (Moco) is deeply buried in the enzyme. Most molybdoenzymes contain a specific chaperone for the insertion of Moco. For the formate dehydrogenase FdsGBA from Rhodobacter capsulatus the two chaperones FdsC and FdsD were identified to be essential for enzyme activity, but are not a subunit of the mature enzyme. Here, we purified and characterized the FdsC protein after heterologous expression in Escherichia coli. We were able to copurify FdsC with the bound Moco derivate bis-molybdopterin guanine dinucleotide. This cofactor successfully was used as a source to reconstitute the activity of molybdoenzymes.
Structured summary of protein interactions:
FdsC and FdsC bind by molecular sieving (View interaction)
FdsD binds to RcMobA by surface plasmon resonance (View interaction)
FdsC binds to RcMobA by surface plasmon resonance (View interaction)
FdsC binds to FdsA by surface plasmon resonance (View interaction)
The homodinuclear ruthenium(II) complex [{Ru(l-N4Me2)}(2)(-tape)](PF6)(4) {[1](PF6)(4)} (l-N4Me2=N,N-dimethyl-2,11-diaza[3.3](2,6)-pyridinophane, tape=1,6,7,12-tetraazaperylene) can store one or two electrons in the energetically low-lying * orbital of the bridging ligand tape. The corresponding singly and doubly reduced complexes [{Ru(l-N4Me2)}(2)(-tape(.-))](PF6)(3) {[2](PF6)(3)} and [{Ru(l-N4Me2)}(2)(-tape(2-))](PF6)(2) {[3](PF6)(2)}, respectively, were electrochemically generated, successfully isolated and fully characterized by single-crystal X-ray crystallography, spectroscopic methods and magnetic susceptibility measurements. The singly reduced complex [2](PF6)(3) contains the -radical tape(.-) and the doubly reduced [3](PF6)(2) the diamagnetic dianion tape(2-) as bridging ligand, respectively. Nucleophilic aromatic substitution at the bridging tape in [1](4+) by two sulfite units gave the complex [{Ru(l-N4Me2)}(2){-tape-(SO3)(2)}](2+) ([4](2+)). Complex dication [4](2+) was exploited as a redox mediator between an anaerobic homogenous reaction solution of an enzyme system (sulfite/sulfite oxidase) and the electrode via participation of the low-energy *-orbital of the disulfonato-substituted bridging ligand tape-(SO3)(2)(2-) (E-red1=-0.1V versus Ag/AgCl/1m KCl in water).
The NADH:ubiquinone oxidoreductase (respiratory complex I) is the main entry point for electrons into the Escherichia coli aerobic respiratory chain. With its sophisticated setup of 13 different subunits and 10 cofactors, it is anticipated that various chaperones are needed for its proper maturation. However, very little is known about the assembly of E. coli complex I, especially concerning the incorporation of the iron-sulfur clusters. To identify iron-sulfur cluster carrier proteins possibly involved in the process, we generated knockout strains of NfuA, BolA, YajL, Mrp, GrxD and IbaG that have been reported either to be involved in the maturation of mitochondrial complex I or to exert influence on the clusters of bacterial complex. We determined the NADH and succinate oxidase activities of membranes from the mutant strains to monitor the specificity of the individual mutations for complex I. The deletion of NfuA, BolA and Mrp led to a decreased stability and partially disturbed assembly of the complex as determined by sucrose gradient centrifugation and native PAGE. EPR spectroscopy of cytoplasmic membranes revealed that the BolA deletion results in the loss of the binuclear Fe/S cluster N1b.
The trafficking and delivery of sulfur to cofactors and nucleosides is a highly regulated and conserved process among all organisms. All sulfur transfer pathways generally have an L-cysteine desulfurase as an initial sulfur mobilizing enzyme in common, which serves as a sulfur donor for the biosynthesis of sulfur-containing biomolecules like iron sulfur (Fe-S) clusters, thiamine, biotin, lipoic acid, the molybdenum cofactor (Moco), and thiolated nucleosides in tRNA. The human L-cysteine desulfurase NFS1 and the Escherichia coli homologue IscS share a level of amino acid sequence identity of similar to 60%. While E. coli IscS has a versatile role in the cell and was shown to have numerous interaction partners, NFS1 is mainly localized in mitochondria with a crucial role in the biosynthesis of Fe-S clusters. Additionally, NFS1 is also located in smaller amounts in the cytosol with a role in Moco biosynthesis and mcm(5)s(2)U34 thio modifications of nucleosides in tRNA. NFS1 and IscS were conclusively shown to have different interaction partners in their respective organisms. Here, we used functional complementation studies of an E. coli iscS deletion strain with human NFS1 to dissect their conserved roles in the transfer of sulfur to a specific target protein. Our results show that human NFS1 and E. coli IscS share conserved binding sites for proteins involved in Fe-S cluster assembly like IscU, but not with proteins for tRNA thio modifications or Moco biosynthesis. In addition, we show that human NFS1 was almost fully able to complement the role of IscS in Moco biosynthesis when its specific interaction partner protein MOCS3 from humans was also present.
In Escherichia coli, two different systems that are important for the coordinate formation of Fe–S clusters have been identified, namely, the ISC and SUF systems. The ISC system is the housekeeping Fe–S machinery, which provides Fe–S clusters for numerous cellular proteins. The IscS protein of this system was additionally revealed to be the primary sulfur donor for several sulfur-containing molecules with important biological functions, among which are the molybdenum cofactor (Moco) and thiolated nucleosides in tRNA. Here, we show that deletion of central components of the ISC system in addition to IscS leads to an overall decrease in Fe–S cluster enzyme and molybdoenzyme activity in addition to a decrease in the number of Fe–S-dependent thiomodifications of tRNA, based on the fact that some proteins involved in Moco biosynthesis and tRNA thiolation are Fe–S-dependent. Complementation of the ISC deficient strains with the suf operon restored the activity of Fe–S-containing proteins, including the MoaA protein, which is involved in the conversion of 5′GTP to cyclic pyranopterin monophosphate in the fist step of Moco biosynthesis. While both systems share a high degree of similarity, we show that the function of their respective l-cysteine desulfurase IscS or SufS is specific for each cellular pathway. It is revealed that SufS cannot play the role of IscS in sulfur transfer for the formation of 2-thiouridine, 4-thiouridine, or the dithiolene group of molybdopterin, being unable to interact with TusA or ThiI. The results demonstrate that the role of the SUF system is exclusively restricted to Fe–S cluster assembly in the cell.
We studied two pathways that involve the transfer of persulfide sulfur in humans, molybdenum cofactor biosynthesis and tRNA thiolation. Investigations using human cells showed that the two-domain protein MOCS3 is shared between both pathways. MOCS3 has an N-terminal adenylation domain and a C-terminal rhodanese-like domain. We showed that MOCS3 activates both MOCS2A and URM1 by adenylation and a subsequent sulfur transfer step for the formation of the thiocarboxylate group at the C terminus of each protein. MOCS2A and URM1 are beta-grasp fold proteins that contain a highly conserved C-terminal double glycine motif. The role of the terminal glycine of MOCS2A and URM1 was examined for the interaction and the cellular localization with MOCS3. Deletion of the C-terminal glycine of either MOCS2A or URM1 resulted in a loss of interaction with MOCS3. Enhanced cyan fluorescent protein and enhanced yellow fluorescent protein fusions of the proteins were constructed, and the fluorescence resonance energy transfer efficiency was determined by the decrease in the donor lifetime. The cellular localization results showed that extension of the C terminus with an additional glycine of MOCS2A and URM1 altered the localization of MOCS3 from the cytosol to the nucleus.
Aldehyde oxidase (AOX) is a xanthine oxidase (XO)-related enzyme with emerging importance due to its role in the metabolism of drugs and xenobiotics. We report the first crystal structures of human AOX1, substrate free (2.6-angstrom resolution) and in complex with the substrate phthalazine and the inhibitor thioridazine (2.7-angstrom resolution). Analysis of the protein active site combined with steady-state kinetic studies highlight the unique features, including binding and substrate orientation at the active site, that characterize human AOX1 as an important drug-metabolizing enzyme. Structural analysis of the complex with the noncompetitive inhibitor thioridazine revealed a new, unexpected and fully occupied inhibitor-binding site that is structurally conserved among mammalian AOXs and XO. The new structural insights into the catalytic and inhibition mechanisms of human AOX that we now report will be of great value for the rational analysis of clinical drug interactions involving inhibition of AOX1 and for the prediction and design of AOX-stable putative drugs.
Aldehyde oxidases (AOXs) are homodimeric proteins belonging to the xanthine oxidase family of molybdenum-containing enzymes. Each 150-kDa monomer contains a FAD redox cofactor, two spectroscopically distinct [2Fe-2S] clusters, and a molybdenum cofactor located within the protein active site. AOXs are characterized by broad range substrate specificity, oxidizing different aldehydes and aromatic N-heterocycles. Despite increasing recognition of its role in the metabolism of drugs and xenobiotics, the physiological function of the protein is still largely unknown. We have crystallized and solved the crystal structure of mouse liver aldehyde oxidase 3 to 2.9 angstrom. This is the first mammalian AOX whose structure has been solved. The structure provides important insights into the protein active center and further evidence on the catalytic differences characterizing AOX and xanthine oxidoreductase. The mouse liver aldehyde oxidase 3 three-dimensional structure combined with kinetic, mutagenesis data, molecular docking, and molecular dynamics studies make a decisive contribution to understand the molecular basis of its rather broad substrate specificity.
The control of bioelectrocatalytic processes by external stimuli for the indirect detection of non-redox active species was achieved using an esterase and a redox enzyme both integrated within a redox hydrogel. The poly( vinyl) imidazole Os(bpy)(2)Cl hydrogel displays pH-responsive properties. The esterase catalysed reaction leads to a local pH decrease causing protonation of imidazole moieties thus increasing hydrogel solvation and mobility of the tethered Os-complexes. This is the key step to enable improved electron transfer between an aldehyde oxidoreductase and the polymer-bound Os-complexes. The off-on switch is further integrated in a biofuel cell system for self-powered signal generation.
The xanthine oxidase (XO) family comprises molybdenum-dependent enzymes that usually form homodimers (or dimers of heterodimers/trimers) organized in three domains that harbor two [2Fe-2S] clusters, one FAD, and a Mo cofactor. In this work, we crystallized an unusual member of the family, the periplasmic aldehyde oxidoreductase PaoABC from Escherichia coli. This is the first example of an E. coli protein containing a molybdopterin-cytosine-dinucleotide cofactor and is the only heterotrimer of the XO family so far structurally characterized. The crystal structure revealed the presence of an unexpected [4Fe-4S] cluster, anchored to an additional 40 residues subdomain. According to phylogenetic analysis, proteins containing this cluster are widely spread in many bacteria phyla, putatively through repeated gene transfer events. The active site of PaoABC is highly exposed to the surface with no aromatic residues and an arginine (PaoC-R440) making a direct interaction with PaoC-E692, which acts as a base catalyst. In order to understand the importance of R440, kinetic assays were carried out, and the crystal structure of the PaoC-R440H variant was also determined.
The Escherichia coli L-cysteine desulfurase IscS mobilizes sulfur from L-cysteine for the synthesis of several biomolecules such as iron-sulfur (FeS) clusters, molybdopterin, thiamin, lipoic acid, biotin, and the thiolation of tRNAs. The sulfur transfer from IscS to various biomolecules is mediated by different interaction partners (e.g. TusA for thiomodification of tRNAs, IscU for FeS cluster biogenesis, and ThiI for thiamine biosynthesis/tRNA thiolation), which bind at different sites of IscS. Transcriptomic and proteomic studies of a Delta tusA strain showed that the expression of genes of the moaABCDE operon coding for proteins involved in molybdenum cofactor biosynthesis is increased under aerobic and anaerobic conditions. Additionally, under anaerobic conditions the expression of genes encoding hydrogenase 3 and several molybdoenzymes such as nitrate reductase were also increased. On the contrary, the activity of all molydoenzymes analyzed was significantly reduced in the Delta tusA mutant. Characterization of the Delta tusA strain under aerobic conditions showed an overall low molybdopterin content and an accumulation of cyclic pyranopterin monophosphate. Under anaerobic conditions the activity of nitrate reductase was reduced by only 50%, showing that TusA is not essential for molybdenum cofactor biosynthesis. We present a model in which we propose that the direction of sulfur transfer for each sulfur-containing biomolecule is regulated by the availability of the interaction partner of IscS. We propose that in the absence of TusA, more IscS is available for FeS cluster biosynthesis and that the overproduction of FeS clusters leads to a modified expression of several genes.
Background: In Moco biosynthesis, sulfur is transferred from L-cysteine to MPT synthase, catalyzing the conversion of cPMP to MPT.
Results: The rhodanese-like protein YnjE is a novel protein involved in Moco biosynthesis.
Conclusion: YnjE enhances the rate of conversion of cPMP to MPT and interacts with MoeB and IscS. S
ignificance: To understand the mechanism of sulfur transfer and the role of rhodaneses in the cell.
Human aldehyde oxidase (hAOX1) is mainly present in the liver and has an emerging role in drug metabolism, since it accepts a wide range of molecules as substrates and inhibitors. Herein, we employed an integrative approach by combining NMR, X-ray crystallography, and enzyme inhibition kinetics to understand the inhibition modes of three hAOX1 inhibitors-thioridazine, benzamidine, and raloxifene. These integrative data indicate that thioridazine is a noncompetitive inhibitor, while benzamidine presents a mixed type of inhibition. Additionally, we describe the first crystal structure of hAOX1 in complex with raloxifene. Raloxifene binds tightly at the entrance of the substrate tunnel, stabilizing the flexible entrance gates and elucidating an unusual substrate-dependent mechanism of inhibition with potential impact on drug-drug interactions. This study can be considered as a proof-of-concept for an efficient experimental screening of prospective substrates and inhibitors of hAOX1 relevant in drug discovery.
Dendritic polyglycerol-poly(ethylene glycol)-based polymer networks for biosensing application
(2014)
This work describes the formation of a new dendritic polyglycerol-poly(ethylene glycol)-based 3D polymer network as a matrix for immobilization of the redox enzyme periplasmatic aldehyde oxidoreductase to create an electrochemical biosensor. The novel network is built directly on the gold surface, where it simultaneously stabilizes the enzyme for up to 4 days. The prepared biosensors can be used for amperometric detection of benzaldehyde in the range of 0.8-400 mu M.
Mechanism of substrate and inhibitor binding of Rhodobacter capsulatus xanthine dehydrogenase
(2009)
Rhodobacter capsulatus xanthine dehydrogenase (XDH) is an (alpha beta)(2) heterotetrameric cytoplasmic enzyme that resembles eukaryotic xanthine oxidoreductases in respect to both amino acid sequence and structural fold. To obtain a detailed understanding of the mechanism of substrate and inhibitor binding at the active site, we solved crystal structures of R. capsulatus XDH in the presence of its substrates hypoxanthine, xanthine, and the inhibitor pterin-6- aldehyde using either the inactive desulfo form of the enzyme or an active site mutant (E(B)232Q) to prevent substrate turnover. The hypoxanthine-and xanthine-bound structures reveal the orientation of both substrates at the active site and show the importance of residue GluB-232 for substrate positioning. The oxygen atom at the C-6 position of both substrates is oriented toward Arg(B)-310 in the active site. Thus the substrates bind in an orientation opposite to the one seen in the structure of the reduced enzyme with the inhibitor oxypurinol. The tightness of the substrates in the active site suggests that the intermediate products must exit the binding pocket to allow first the attack of the C-2, followed by oxidation of the C-8 atom to form the final product uric acid. Structural studies of pterin-6-aldehyde, a potent inhibitor of R. capsulatus XDH, contribute further to the understanding of the relative positioning of inhibitors and substrates in the binding pocket. Steady state kinetics reveal a competitive inhibition pattern with a K-i of 103.57 +/- 18.96 nM for pterin-6-aldehyde.