Rhodobacter capsulatus xanthine dehydrogenase (XDH) is a cytoplasmic enzyme with an (␣) 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 enzymespecific 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.Xanthine oxidoreductase is a complex metalloflavoprotein that catalyzes the hydroxylation of hypoxanthine and xanthine, the last two steps in the formation of urate, using a water molecule as the ultimate source of oxygen incorporated into the product (1). The enzyme exists in two forms; the xanthine dehydrogenase form (XDH; EC1.17.1.4) 2 uses NAD ϩ as electron acceptor, whereas the xanthine oxidase (EC1.17.3.2) form uses O 2 as electron acceptor (2). Xanthine oxidoreductases are found both in eukaryotes and prokaryotes, with the enzymes isolated from bovine milk and Rhodobacter capsulatus being functionally and structurally the best characterized (3, 4). R. capsulatus XDH is a cytoplasmic enzyme with an (␣) 2 heterodimeric structure, with the two subunits encoded by the xdhA and xdhB genes, respectively (5 This report describes the detailed analysis for the requirement of XdhC to produce active XDH during heterologous expression in E. coli TP1000 cells. Analysis of XDH expressed under different aeration levels in the presence or absence of XdhC showed that, especially under aerobic conditions, XdhC is required to produce active XDH containing the terminal sulfur ligand of Moco. In addition, we purified and characterized XdhC after heterologous expression in E. coli. We could show that XdhC binds Moco/MPT in stoichiometric amounts and is able to insert bound Moco into Moco-free apo-XDH. In addition, a specific interaction between XdhC and XdhB was identified. We showed that XdhC acts as a Moco-binding protein, which protects the sulfurated form of Moco from oxidation. We propose that sulfurated Moco is inserted into apo-XDH by the aid of XdhC to produce active XDH. This is the first example of a system-specific protein involved in maturation of a molybdoenzyme for which Moco binding could be shown. Bacterial Strains, Pla...
The rapid reaction kinetics of wild-type xanthine dehydrogenase from Rhodobacter capsulatus and variants at Arg-310 in the active site have been characterized for a variety of purine substrates. With xanthine as substrate, k red (the limiting rate of enzyme reduction by substrate at high [S]) decreased ϳ20-fold in an R310K variant and 2 ؋ 10 4 -fold in an R310M variant. Although Arg-310 lies on the opposite end of the substrate from the C-8 position that becomes hydroxylated, its interaction with substrate still contributed ϳ4.5 kcal/mol toward transition state stabilization. The other purines examined fell into two distinct groups: members of the first were effectively hydroxylated by the wild-type enzyme but were strongly affected by the exchange of Arg-310 to methionine (with a reduction in k red greater than 10 3 ), whereas members of the second were much less effectively hydroxylated by wild-type enzyme but also much less significantly affected by the amino acid exchanges (with a reduction in k red less than 50-fold). The effect was such that the 4000-fold range in k red seen with wild-type enzyme was reduced to a mere 4-fold in the R310M variant. The data are consistent with a model in which "good" substrates are bound "correctly" in the active site in an orientation that allows Arg-310 to stabilize the transition state for the first step of the overall reaction via an electrostatic interaction at the C-6 position, thereby accelerating the reaction rate. On the other hand, "poor" substrates bound upside down relative to this "correct" orientation. In so doing, they are unable to avail themselves of the additional catalytic power provided by Arg-310 in wild-type enzyme but, for this reason, are significantly less affected by mutations at this position. The kinetic data thus provide a picture of the specific manner in which the physiological substrate xanthine is oriented in the active site relative to Arg-310 and how this residue is used catalytically to accelerate the reaction rate (rather than simply bind substrate) despite being remote from the position that is hydroxylated.The molybdenum-containing hydroxylases represent a unique solution to the hydroxylation of carbon centers. Other monooxygenases introduce an oxygen atom derived from O 2 and consume two reducing equivalents (along with the two removed from the substrate to be hydroxylated) in reducing O 2 to water. The molybdenum enzymes, on the other hand, utilize water itself as the ultimate source of the oxygen atom incorporated into product. In the case of enzymes such as xanthine dehydrogenase, not only are molybdenum enzyme reducing equivalents not consumed in carrying out the catalyzed reaction, but in fact physiologically useful reducing equivalents in the form of NADH are generated. As such, these enzymes represent a unique solution to the chemistry of hydroxylation, and the requisite cleavage of a carbon-hydrogen bond that accompanies it (1).The xanthine dehydrogenase from Rhodobacter capsulatus is an (␣) 2 heterotetramer comprising two cop...
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