Pterine oxidase

The aldehyde oxidoreductase from Desulfovibrio gigas shows 52% sequence identity with xanthine oxidase (199, 212) and is, so far, the single representative of the xanthine oxidase family. The 3D structure of MOP was analyzed at 1.8 A resolution in several states oxidized, reduced, desulfo and sulfo forms, and alcohol-bound (200), which has allowed more precise definition of the metal coordination site and contributed to the understanding of its role in catalysis. The overall structure, composed of a single polypeptide of 907 amino acid residues, is organized into four domains two N-terminus smaller domains, which bind the two types of [2Fe-2S] centers and two much larger domains, which harbor the molybdopterin cofactor, deeply buried in the molecule (Fig. 10). The pterin cofactor is present as a cytosine dinucleotide (MCD) and is 15 A away from the molecular surface,... 

Dioxygen reduction (oxidase activity) and activation for incorporation into organic substrates are catalysed by a number of mononuclear non-haem iron enzymes. We will first consider the intramolecular dioxygenases, in which both atoms of oxygen are introduced into the substrate, then the monoxygenases (in which we choose to include the pterin-dependent hydroxylases), the large family of a-hetoacid-dependent enzymes, and finally isopenicillin N-synthase. 

Mononuclear (pterin-bonded) I. Xanthine oxidase family Xanthine oxidase Purine or pyrinidine catabolism... 

Figure 17.2 The structure of the pterin cofactor (1) which is common to most molybdenum- and tungsten-containing enzymes and schematic active site structures for members of the xanthine oxidase (2,3), sulfite oxidase (4) and DMSO reductase (5-7) enzyme families. (From Enemark et al., 2004. Copyright (2004) American Chemical Society.)...

Xanthine oxidase, flavin, Fe S, Mo-pterin cofactors Massey (1973)... 

The similarity in the pyrimidine ring of pteridines and pterins, especially to the purines adenine and guanosine, undoubtedly makes them good templates for inhibitor design as these examples show. Another enzyme for which inhibition by pteridines has been established is xanthine oxidase <1999BBA387>. In this case, the limitation on structure for inhibitors in the pteridine series was that there should be no substituent on C-7 and that the pteridines should be fully conjugated. The best inhibitors (ICso 0.1 xM) were 6-formylpterin and 6-hydroxylumazine. 

Some compounds of this type may have a high affinity for proteins that is not due to their binding to two thiol groups (35). In particular, arsenite also reacts with the molybdenum-pterin cofactor of many enzymes (35a-d). This usually inhibits the enzyme, but in particular cases (35e) the arsenite may be oxidized indeed the enzyme arsenite oxidase contains such a center (35f). 

The evidence for a pterin-substituted 1,2-enedithiolate was first reported by Raja-gopalan, Johnson, and coworkers, who isolated pterins from the oxidative decomposition of molybdenum-bound MPT, Figure 4 [7,49,55,56], In complementary work, Taylor and coworkers confirmed the structure of several of the pterin decomposition products by direct synthesis (see Section V. A) [30,57-59], Urothi-one, first isolated in 1940 from human urine [60], was shown to be a metabolic degradation product of MPT [37], Other isolated pterin-containing decomposition and/or derivatized products from molybdenum enzymes include Form A, Form B (a urothione-like product), and camMPT (Figure 4) [7], Two other pterins, Form Z and the MPT precursor, can be obtained from molybdenum deprived organisms, N. crassa Nit-1, and oxidase-deficient children, neither of which pro-... 

Mo 0.15-0.5 mg Xanthine dehydrogenase, sulfite, aldehyde oxidases Mo seems to be always bound to a cofactor— a compound containing a pterin ring... 

Figure 6.11 Structure of the pterin cofactor, which binds molybdenum in aldehyde oxidase, xanthine oxidase, and sulfite oxidase. [Reproduced by permission from Rajago-palan, KV. Molybdenum, an essential trace element. Nutr. Rev., 45 321-328 (1987).]...

The reduction state of the pterin was a point of uncertainty throughout these studies of molybopterin derivatives. The absence of fluorescence in anaerobic molybdopterin samples suggested a reduced pterin. Redox titration of XO and SO both indicated that the pterin could undergo a two-electron oxidation reaction (73, 74). Sulfite oxidase, for example, produced the fluorescence characteristic of an oxidized pterin after addition of 2 equiv of ferricyanide. However, titrating XO was problematic due to interfering redox processes of the iron-sulfur clusters. 

The pterins include the redox cofactors biopterin and molybdopterin, as well as various insect pigments. Folic acid is a conjugated pterin, in which the pteridine ring is linked to p-aminobenzoyl-poly-y-glutamate it is this linkage that renders folate a dietary essential, because it is the ability to condense p-aminobenzoate to a pteridine, rather than to synthesize the pteridine nucleus itself, which has been lost by higher animals. Biopterin (Section 10.4) and molybdopterin (Section 10.5) are coenzymes in mixed-function oxidases they are not vitamins, but can be synthesized in the body. Rare genetic defects of biopterin synthesis render it a dietary essential for affected individuals. 

Three human redox enzymes, and a variety of bacterial enzymes, contain molybdenum chelated by two sulfur atoms in a modified pterin molybdopterin (see Figure 10.1). In sulfite oxidase, the other two chelation sites of the molybdenum are occupied by oxygen in xanthine oxidase / dehydrogenase (Section 7.3.7) and aldehyde oxidase, one site is occupied by oxygen and one by sulfur. In some bacterial enzymes, molybdopterin occurs as a guanine dinucleotide rather than free. In others, tungsten rather than molybdopterin is the chelated metal there is no evidence that any mammalian enzymes contain tungsten. 

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