The Mechanism of Assembly and Cofactor Insertion into Rhodobacter capsulatus Xanthine Dehydrogenase

Schumann, Sarah; Saggu, Miguel; Möller, Nadine; Anker, Stefan D.; Lendzian, Friedhelm; Hildebrandt, Peter; Leimkühler, Silke

doi:10.1074/jbc.m709894200

Cited by 39 publications

(36 citation statements)

References 30 publications

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“…Both recombinant and native mAOX3 were compared in detail on the basis of their spectroscopic properties. The EPR spectra of mAOX3 were found to be very similar to those from the mAOX1 protein, showing a rhombic signal for FeSI (Schumann et al, 2008). There are essentially no differences in the g values and line widths for the native and the recombinant enzymes.…”

Section: Discussionmentioning

confidence: 58%

Characterization and Crystallization of Mouse Aldehyde Oxidase 3: From Mouse Liver toEscherichia coliHeterologous Protein Expression

et al. 2011

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ABSTRACT:Aldehyde oxidase (AOX) is characterized by a broad substrate specificity, oxidizing aromatic azaheterocycles, such as N 1 -methylnicotinamide and N-methylphthalazinium, or aldehydes, such as benzaldehyde, retinal, and vanillin. In the past decade, AOX has been recognized increasingly to play an important role in the metabolism of drugs through its complex cofactor content, tissue distribution, and substrate recognition. In humans, only one AOX gene (AOX1) is present, but in mouse and other mammals different AOX homologs were identified. The multiple AOX isoforms are expressed tissue-specifically in different organisms, and it is believed that they recognize distinct substrates and carry out different physiological tasks. AOX is a dimer with a molecular mass of approximately 300 kDa, and each subunit of the homodimeric enzyme contains four different cofactors: the molybdenum cofactor, two distinct [2Fe-2S] clusters, and one FAD. We purified the AOX homolog from mouse liver (mAOX3) and established a system for the heterologous expression of mAOX3 in Escherichia coli. The purified enzymes were compared. Both proteins show the same characteristics and catalytic properties, with the difference that the recombinant protein was expressed and purified in a 30% active form, whereas the native protein is 100% active. Spectroscopic characterization showed that FeSII is not assembled completely in mAOX3. In addition, both proteins were crystallized. The best crystals were from native mAOX3 and diffracted beyond 2.9 Å. The crystals belong to space group P1, and two dimers are present in the unit cell.

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Section: Discussionmentioning

confidence: 58%

Characterization and Crystallization of Mouse Aldehyde Oxidase 3: From Mouse Liver toEscherichia coliHeterologous Protein Expression

et al. 2011

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“…The arginine is located close to FeSI, and when this mutation was introduced in the Rhodobacter capsulatus xdhB gene and the corresponding RcXDH-R135C was characterized, the purified protein also existed in two forms, a monomeric inactive form and a dimeric active form (Leimkühler et al, 2003). Further analyses of the monomer/dimer behavior of R. capsulatus XDH resulted in a model in which it was proposed that dimerization requires that the two FeS clusters are assembled correctly before Moco can be inserted and the protein can dimerize via the Moco domain (Schumann et al, 2008). Thus, amino acid exchanges in proximity to the FeS clusters influence the structure of the protein in a manner that dimerization is no longer effective.…”

Section: Characterization Of Single Nucleotide Polymorphisms Of Haox1mentioning

confidence: 99%

The Impact of Single Nucleotide Polymorphisms on Human Aldehyde Oxidase

et al. 2012

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ABSTRACT:Aldehyde oxidase (AO) is a complex molybdo-flavoprotein that belongs to the xanthine oxidase family. AO is active as a homodimer, and each 150-kDa monomer binds two distinct [2Fe2S] clusters, FAD, and the molybdenum cofactor. AO has an important role in the metabolism of drugs based on its broad substrate specificity oxidizing aromatic aza-heterocycles, for example, was obtained with a purity of 95% and a yield of 50 g/l E. coli culture. Site-directed mutagenesis of the hAOX1 cDNA allowed the purification of protein variants bearing the amino acid changes R802C, R921H, N1135S, and H1297R, which correspond to some of the identified SNPs. The hAOX1 variants were purified and compared with the wild-type protein relative to activity, oligomerization state, and metal content. Our data show that the mutation of each amino acid residue has a variable impact on the ability of hAOX1 to metabolize selected substrates. Thus, the human population is characterized by the presence of functionally inactive hAOX1 allelic variants as well as variants encoding enzymes with different catalytic activities. Our results indicate that the presence of these allelic variants should be considered for the design of future drugs.

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“…17,27 Leimkuhler group has proposed a pioneering mechanism for the assembly and cofactor insertion of R. capsulatus (ab) 2 XDH. 28 According to the mechanism, the biosynthesis of active XDH is proposed to involve 5 processes: 1) synthesis of apoproteins consisting of the 3 domains, depicted as S, M and L; 2) formation of heteromultimer apoprotein in the case of heteromultimer multi-subunit XDH; 3) insertion of 2 [2Fe-2S] clusters and a FAD into the S and M domains respectively; 4) dimerization of apoproteins assembled with [2Fe-2S] and FAD cofactors via the L domains; 5) insertion of sulfurated Moco into the L domains with the help of chaperone protein XdhC (Fig. 3 part II).…”

Section: Biosynthesis Of Xdhs and Heterologous Productionmentioning

confidence: 99%

Xanthine dehydrogenase: An old enzyme with new knowledge and prospects

2016

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Xanthine dehydrogenase (EC 1.17.1.4, XDH) is a typical and complex molybdenum-containing flavoprotein which has been extensively studied for over 110 years. This enzyme catalyzes the oxidation of purines, pterin and aldehydes with NAD C or NADP C as electron acceptor, and sometimes can be transformed to xanthine oxidase (EC 1.17.3.2, XOD) capable of utilizing oxygen as the electron acceptor. XDHs are widely distributed in all eukarya, bacteria and archaea domains, and are proposed to play significant roles in various cellular processes, including purine catabolism and production of reactive oxygen species (ROS) and nitric oxide (NO) in both physiological and pathological contexts. The recent applications of XDHs include clinical detections of xanthine and hypoxanthine content in body fluidics, and other diagnostic biomarkers like inorganic phosphorus, 5 0 -nucleotidase and adenosine deaminase. XDHs can also find applications in environmental degradation of pollutants like aldehydes and industrial application in nucleoside drugs like ribavirin. In this commentary, we would outline the latest knowledge on occurrence, structure, biosynthesis, and recent advances of production and applications of XDH, and highlighted the need to develop XDHs with improved performances by gene prospecting and protein engineering, and protocols for efficient production of active XDHs in response to the increasing demands.

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The Mechanism of Assembly and Cofactor Insertion into Rhodobacter capsulatus Xanthine Dehydrogenase

Cited by 39 publications

References 30 publications

Characterization and Crystallization of Mouse Aldehyde Oxidase 3: From Mouse Liver toEscherichia coliHeterologous Protein Expression

Characterization and Crystallization of Mouse Aldehyde Oxidase 3: From Mouse Liver toEscherichia coliHeterologous Protein Expression

The Impact of Single Nucleotide Polymorphisms on Human Aldehyde Oxidase

Xanthine dehydrogenase: An old enzyme with new knowledge and prospects

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