Abstract
Ammonia (NH3)-oxidizing bacteria (AOB) derive total energy for life from the multi-electron oxidation of NH3 to nitrite (NO2-). One obligate intermediate of this metabolism is hydroxylamine (NH2OH), which can be oxidized to the potent greenhouse agent nitrous oxide (N2O) by the AOB enzyme cytochrome (cyt) P460. We have now spectroscopically characterized a 6-coordinate (6c) {FeNO}7 intermediate on the NH2OH oxidation pathway of cyt P460. This species has two fates: it can either be oxidized to the {FeNO}6 that then undergoes attack by NH2OH to ultimately generate N2O, or it can lose its axial His ligand, thus generating a stable, off-pathway 5-coordinate (5c) {FeNO}7 species. We show that the wild type (WT) cyt P460 exhibits a slow nitric oxide (NO)-independent conversion (kHis-off = 2.90 × 10-3 s-1), whereas a cross-link-deficient Lys70Tyr cyt P460 mutant protein underwent His dissociation via both a NO-independent (kHis-off = 3.8 × 10-4 s-1) and a NO-dependent pathway [kHis-off(NO) = 790 M-1 s-1]. Eyring analyses of the NO-independent pathways for these two proteins revealed a significantly larger (ca. 27 cal mol-1 K-1) activation entropy (ΔS‡) in the cross-link-deficient mutant. Our results suggest that the Lys-heme cross-link confers rigidity to the positioning of the heme P460 cofactor to avoid the fast NO-dependent His dissociation pathway and subsequent formation of the off-pathway 5c {FeNO}7 species. The relevance of these findings to NO signaling proteins such as heme-nitric oxide/oxygen binding (H-NOX) is also discussed.
Highlights
Ammonia (NH3)-oxidizing bacteria (AOB) derive energy for life from nitri cation: the proton-coupled multi-electron oxidation of NH3 to nitrite (NO2À).[1,2] Nitri cation begins with the oxidation of NH3 to hydroxylamine (NH2OH) by the integral membrane enzyme ammonia monooxygenase
In our previous study,[13] we generated an off-pathway 5c {FeNO}7 species. This species was generated via the treatment of FeIII cyt P460 with the HNO donor disodium diazen-1-ium-1,2,2 triolate (Na2N2O3)
In the present work, monitoring of the UV-vis absorption spectral time course immediately a er the treatment of 15 mM FeIII cyt P460 with 100 mM HNO revealed a previously uncharacterized species
Summary
Ammonia (NH3)-oxidizing bacteria (AOB) derive energy for life from nitri cation: the proton-coupled multi-electron oxidation of NH3 to nitrite (NO2À).[1,2] Nitri cation begins with the oxidation of NH3 to hydroxylamine (NH2OH) by the integral membrane enzyme ammonia monooxygenase. NH2OH is oxidized to nitric oxide (NO) by the multi-heme enzyme hydroxylamine oxidoreductase (HAO) to establish net electron ow.[3] The physiological means through which NO is oxidized to NO2À are unknown. The remaining heme, a c-type heme, is the site of NH2OH oxidation. This heme is called the heme P460 center because it has a characteristic FeII Soret absorption maximum at 463 nm.[5] HAO heme P460
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