The mechanism of superoxide scavenging by Archaeoglobus fulgidus neelaredoxin.

Neelaredoxin is a mononuclear iron protein widespread among prokaryotic anaerobes and facultative aerobes, including human pathogens. It has superoxide scavenging activity, but the exact mechanism by which this process occurs has been controversial. In this report, we present the study of the reaction of superoxide with the reduced form of neelaredoxin from the hyperthermophilic archaeon Archaeoglobus fulgidus by pulse radiolysis. This protein reduces superoxide very efficiently (k = 1.5 x 10(9) m(-1)s(-1)), and the dismutation activity is rate-limited, in steady-state conditions, by the much slower superoxide oxidation step. These data show unambiguously that the superfamily of neelaredoxin-like proteins (including desulfoferrodoxin) presents a novel type of reactivity toward superoxide, a result of particular relevance for the understanding of both oxygen stress response mechanisms and, in particular, how pathogens may respond to the oxidative burst produced by the defense cells in eukaryotes. The actual in vivo functioning of these enzymes will depend strongly on the cell redox status. Further insight on the catalytic mechanism was obtained by the detection of a transient intermediate ferric species upon oxidation of neelaredoxin by superoxide, detectable by visible spectroscopy with an absorption maximum at 610 nm, blue-shifted approximately 50 nm from the absorption of the resting ferric state. The role of the iron sixth ligand, glutamate-12, in the reactivity of neelaredoxin toward superoxide was assessed by studying two site-directed mutants: E12Q and E12V.

Oxygen detoxification in the strict anaerobic archaeon Archaeoglobus fulgidus: superoxide scavenging by neelaredoxin.

Archaeoglobus fulgidus is a hyperthermophilic sulphate-reducing archaeon. It has an optimum growth temperature of 83 degrees C and is described as a strict anaerobe. Its genome lacks any homologue of canonical superoxide (O2.-) dismutases. In this work, we show that neelaredoxin (Nlr) is the main O2.- scavenger in A. fulgidus, by studying both the wild-type and recombinant proteins. Nlr is a 125-amino-acid blue-coloured protein containing a single iron atom/molecule, which in the oxidized state is high spin ferric. This iron centre has a reduction potential of +230 mV at pH 7.0. Nitroblue tetrazolium-stained gel assays of cell-soluble extracts show that Nlr is the main protein from A. fulgidus which is reactive towards O2.-. Furthermore, it is shown that Nlr is able to both reduce and dismutate O2.-, thus having a bifunctional reactivity towards O2.-. Kinetic and spectroscopic studies indicate that Nlr's superoxide reductase activity may allow the cell to eliminate O2.- quickly in a NAD(P)H-dependent pathway. On the other hand, Nlr's superoxide dismutation activity will allow the cell to detoxify O2.- independently of the cell redox status. Its superoxide dismutase activity was estimated to be 59 U mg-1 by the xanthine/xanthine oxidase assay at 25 degrees C. Pulse radiolysis studies with the isolated and reduced Nlr proved unambiguously that it has superoxide dismutase activity; at pH 7.1 and 83 degrees C, the rate constant is 5 x 106 M-1 s-1. Besides the superoxide dismutase activity, soluble cell extracts of A. fulgidus also exhibit catalase and NAD(P)H/oxygen oxidoreductase activities. By putting these findings together with the entire genomic data available, a possible oxygen detoxification mechanism in A. fulgidus is discussed.

Nitrite reductase from Desulfovibrio desulfuricans (ATCC 27774)--a heterooligomer heme protein with sulfite reductase activity.

The membrane bound cytochrome c nitrite reductase from the sulfate reducer Desulfovibrio desulfuricans (ATCC 27774) was found to have a high specific activity in the reduction of sulfite, producing stoichiometric amounts of sulfide. The K(m) for sulfite in the MV+.:sulfite oxidoreductase assay is 0.75 mM, and the specific activity 2.06 mumolH2/min/mg. Visible and EPR spectroscopies studies indicate that the enzyme high-spin heme reacts with sulfite in the oxidised state, and that sulfide partially reduces the enzyme. The redoxcycled enzyme, using H2/Hydrogenase/MV+. as a reductant, is identical to the resting enzyme. This is the first time that a c-type nitrite reductase has been shown to reduce sulfite. These findings, besides revealing a new function for the nitrite reductase, raise a major question regarding the sulfur metabolism in the sulfate reducing bacteria as well as the cellular localization of the enzymatic activities involved in the dissimilatory reduction of sulfate. The purified nitrite reductase is a heterooligomer, containing two types of subunits of 62 kDa (+/- 5 kDa) and 18.8 kDa (+/- 1 kDa), and forms a complex or aggregate with a molecular mass of approximately 750 kDa.