. Recent studies have suggested that the enzyme, which was shown nearly 50 years ago to require iron (1, 2), contains a coupled dinuclear nonheme iron cluster (5), making MIOX the most recent addition to the nonheme diiron oxygenase͞oxidase family that also includes bacterial hydrocarbon hydroxylases (e.g., soluble methane monooxygenase), plant fatty acyl desaturases (e.g., stearoyl acyl carrier protein ⌬ 9 desaturase), and protein R2 of class I ribonucleotide reductase (R2) (6-10). Mössbauer and EPR spectra showed that treatment of recombinant Mus musculus MIOX isolated in its iron-free form from Escherichia coli with Fe(II) and O 2 leads to formation of an antiferromagnetically coupled diiron cluster in either the II͞III or III͞III oxidation state, depending on the O 2 ͞MIOX ratio and the presence or absence of a reductant (ascorbate or cysteine). Binding of MI was shown to perturb the spectra of both oxidation states in a manner consistent with direct coordination of the substrate to the cluster (5).All nonheme diiron oxygenases and oxidases characterized before MIOX activate O 2 with the II͞II oxidation state of the cofactor (11,12). For several of the reactions, (peroxo)diiron(III͞III) intermediates have been demonstrated. These complexes are generally proposed to undergo O-O-bond cleavage to generate high-valent iron complexes that cleave strong C-H or O-H bonds of their oxidation targets (8,(11)(12)(13)(14). Indeed, the diiron(III͞IV) cluster, X (15, 16), and the diiron(IV͞IV) cluster, Q (8, 13, 17), have been directly characterized in the R2 and soluble methane monooxygenase reactions, respectively. In each of the previously characterized diiron-oxygenase͞oxidase reactions, a diiron(III͞III) ''product'' state of the cluster is generated at the end of the oxidation sequence. Subsequent events require reduction of the cluster back to the diiron(II͞II) state by additional proteins, with electrons provided ultimately by NAD(P)H. This redox cycling of the cofactor and provision of two electrons by the nicotinamide ''cosubstrate'' ensure that at most two electrons can be extracted from the substrate. The MIOX reaction, a four-electron oxidation, would seem to require a different mechanism.Indeed, a recent study concluded that the mixed-valent, II͞III state of the cofactor, rather than the conventional II͞II state, activates O 2 for DG production in the MIOX reaction (4). Single-turnover experiments showed that the fully reduced enzyme (MIOX II/II ) reacts with limiting O 2 in the presence of saturating MI to generate the mixed-valent enzyme as a stable product with unit stoichiometry and with only a low yield of DG. By contrast, the
