Enzymes, pterin-containing

DNA cleavage by, 43 158-159 reactions, copper proteins, 39 25 Oxo-trichloroselenates(IV), 35 270-271 Oxo-type molybdenum enzyme, see Molybdenum enzymes, pterin-containing Oxovandium (IV), solvent exchange and ligand substitution, 42 47-49 Oxyanions, Groups VIB and VIIB, redox reactions, kinetics and mechanism, 40 269-274... 

Pterin, see also Tungsten, enzymes, pterin-containing... 

Bioinorganic Chemistry of Pterin-Containing Molybdenum and Tungsten Enzymes John H. Enemark and Charles G. Young... 

In the first family, the metal is coordinated by one molecule of the pterin cofactor, while in the second, it is coordinated to two pterin molecules (both in the guanine dinucleotide form, with the two dinucleotides extending from the active site in opposite directions). Some enzymes also contain FejSj clusters (one or more), which do not seem to be directly linked to the Mo centers. The molybdenum hydroxylases invariably possess redox-active sites in addition to the molybdenum center and are found with two basic types of polypeptide architecture. The enzymes metabolizing quinoline-related compounds, and derivatives of nicotinic acid form a separate groups, in which each of the redox active centers are found in separate subunits. Those enzymes possessing flavin subunits are organized as a2jS2A2, with a pair of 2Fe-2S centers in the (3 subunit, the flavin in the (3 subunit, and the molybdenum in the y subunit. 

An intriguing puzzle in NOS catalysis is the precise role of H4B. The traditional function of H4B is in aromatic amino acid metabolism where H4B directly participates in the hydroxylation reaction via a nonheme iron. However, the NOS pterin site has no similarity to the pterin site in the hydroxylases, nor does NOS have a nonheme iron to assist pterin in substrate hydroxylation as in the amino acid hydroxylases 111). NOS more closely resembles pterin-containing enz5unes that have a redox function 81). In particular, N3 and the 03 amino group form H-bonds with either GIu or Asp residues in a series of pterin enzymes 112-116) similar to NOS, except that NOS utilizes the heme propionate (Fig. 6). 

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-... 

Bioinorganic Chemistry of Pterin-Containing Molybdenum and Tungsten Enzymes... 

A range of chemical analogs of the catalytic centers of Mo and W dithiolene-containing enzymes (pterins) have been prepared. In particular, the rich chemistry of multisulfur transition metal systems allows ligand redox, internal electron transfer, and intermediate redox states. Such redox flexibility may facihtate coupled proton/electron transfer and/or 0x0-transfer mechanisms, which are employed by Mo and W enzymes. 

BIOINORGANIC CHEMISTRY OF PTERIN-CONTAINING MOLYBDENUM AND TUNGSTEN ENZYMES ... 

This chapter is restricted to the bioinorganic chemistry of pterin-containing molybdenum and tungsten enzymes. Primary emphasis is given to recent results and to the interplay of model and enzyme chemis-... 

The molybdenum-containing oxidoreductases that catalyze Eq. (1) have been variously termed molybdenum hydroxylases (6), oxotransferases (7), and oxo-type molybdenum enzymes (8). Molybdenum hydroxylase aptly describes the conversion of xanthine to uric acid, but the name seems less appropriate for the reactions catalyzed by sulfite oxidase and nitrate reductase oxotransferase implies that the function of these enzymes is to transfer oxo groups, even though relatively little is known about their actual mechanism of action and the name oxo-type molybdenum enzyme recognizes both the apparent oxo transfer chemistry of Eq. (1) and the fact that the molybdenum atom in each of these enzymes contains at least one terminal oxo group. In this chapter, we shall refer to these enzymes as pterin-containing molybdenum enzymes because a 6-substituted pterin appears to be a common chemical feature of all of the enzymes. 

The chapter consists of nine sections. Sections II through VII deal with the pterin-containing molybdenum enzymes. Biochemical and model studies of molybdopterin, Mo-co, and related species are described in Section II. In Section III, we briefly survey physical and spectroscopic techniques employed in the study of the enzymes, and consider their impact upon the current understanding of the coordination about the molybdenum atom in sulfite oxidase and xanthine oxidase. Model studies are described in Sections IV and V. Section IV concentrates on structural and spectroscopic models, whereas Section V considers aspects of the reactivity of model and enzyme systems. The xanthine oxidase cycle (Section VI) and facets of intramolecular electron transfer in molybdenum enzymes (Section VII) are then treated. Section VIII describes the pterin-containing tungsten enzymes and the evolving model chemistry thereof Future directions are addressed in Section IX. 

The postulated catalytic cycles for pterin-containing molybdenum enzymes involve a two-electron change at the molybdenum atom (Mo(VI) Mo(IV)). Microcoulometric titrations of nitrate reductase Chlorella vulgaris) (76), milk xanthine oxidase (77), and sulfite oxidase (78) show that their molybdenum centers are reduced by two electrons. The reduction potentials for the molybdenum center of chicken liver sulfite oxidase are strongly dependent upon pH and upon anion concentration (78). 

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