| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 2001275 | Nitric Oxide | 2012 | 5 Pages |
Nitrate reductases (NRs) are enzymes that catalyze reduction of nitrate to nitrite using a molybdenum cofactor. In an alternative reaction, plant NRs have also been shown to catalyze reduction of nitrite to nitric oxide, and this appears to be a major source of nitric oxide synthesis in plants, although other pathways have also been shown. Here, density functional theory (DFT) results are shown, indicating that although nitrate is thermodynamically the preferred substrate for the NR active site, both nitrite and nitrate are easily reduced to nitrite and NO, respectively. These mechanisms require a Mo(IV) state. Additionally, in the case of the nitrite, linkage isomerism is at work and controlled by the metal oxidation state, and reduction is, unlike in the nitrate case, dependent on protonation. The data may be relevant to other molybdenum enzymes with similar active sites, such as xanthine oxidase.
► DFT results are shown on nitrate and nitrite reduction in nitrite reductases. ► Nitrate is thermodynamically the preferred substrate. ► Nitrite and nitrate are both easily reduced to nitrite and NO, respectively. ► These reductions require a Mo(IV) state. ► In the case of the nitrite, linkage isomerism and proton dependence are predicted.
