ABSTRACTWe report the characterization of a bacterial-type oxygen reductase abundant in the cytoplasm of the anaerobic protozoan parasiteEntamoeba histolytica. Upon host infection,E. histolyticais confronted with various oxygen tensions in the host intestine, as well as increased reactive oxygen and nitrogen species at the site of local tissue inflammation. Resistance to oxygen-derived stress thus plays an important role in the pathogenic potential ofE. histolytica. The genome ofE. histolyticahas four genes that encode flavodiiron proteins, which are bacterial-type oxygen or nitric oxide reductases and were likely acquired by lateral gene transfer from prokaryotes. TheEhFdp1gene has higher expression in virulent than in nonvirulentEntamoebastrains and species, hinting that the response to oxidative stress may be one correlate of virulence potential. We demonstrate that EhFdp1 is abundantly expressed in the cytoplasm ofE. histolyticaand that the protein levels are markedly increased (up to ∼5-fold) upon oxygen exposure. Additionally, we produced fully functional recombinant EhFdp1 and demonstrated that this enzyme is a specific and robust oxygen reductase but has poor nitric oxide reductase activity. This observation represents a new mechanism of oxygen resistance in the anaerobic protozoan pathogenE. histolytica.
Superoxide reductases (SORs) are the most recently identified superoxide detoxification systems, being found in microorganisms from the three domains of life. These enzymes are characterized by a catalytic mononuclear iron site, with one cysteine and four histidine ligands of the ferrous active form. A lysine residue in the -EKHVP- motif, located close to the active site, has been considered to be essential for the enzyme function, by contributing to the positive surface patch that attracts the superoxide anion and by controlling the chemistry of the catalytic mechanism through a hydrogen bond network. However, we show here that this residue is substituted by non-equivalent amino acids in several putative SORs from Archaea and unicellular Eukarya. In this work, we focus on mechanistic and spectroscopic studies of one of these less common enzymes, the SOR from the hyperthermophilic Crenarchaeon Ignicoccus hospitalis. We employ pulse radiolysis fast kinetics and spectroscopic approaches to study the wild-type enzyme (-E23T24HVP-), and two mutants, T24K and E23A, the later mimicking enzymes lacking both the lysine and glutamate (a ferric ion ligand) of the motif. The efficiency of the wild-type protein and mutants in reducing superoxide is comparable to other SORs, revealing the robustness of these enzymes to single mutations.
Superoxide reductases (SORs) are the most recent oxygen-detoxification system to be identified in anaerobic and microaerobic bacteria and archaea. SORs are metalloproteins that are characterized by their possession of a catalytic nonhaem iron centre in the ferrous form coordinated by four histidine ligands and one cysteine ligand. Ignicoccus hospitalis, a hyperthermophilic crenarchaeon, is the only organism known to date to serve as a host for Nanoarchaeum equitans, a nanosized hyperthermophilic archaeon isolated from a submarine hot vent which completely depends on the presence of and contact with I. hospitalis cells for growth to occur. Similarly to I. hospitalis, N. equitans has a neelaredoxin (a 1Fe-type SOR) that keeps toxic oxygen species under control, catalysing the one-electron reduction of superoxide to hydrogen peroxide. Blue crystals of recombinant N. equitans SOR in the oxidized form (12.7 kDa, 109 residues) were obtained using polyethylene glycol (PEG 2000 MME) as precipitant. These crystals diffracted to 1.9 Å resolution at 100 K and belonged to the orthorhombic space group P2 1 2 1 2 1 , with unit-cell parameters a = 51.88, b = 82.01, c = 91.30 Å . Cell-content analysis suggested the presence of four monomers in the asymmetric unit. The Matthews coefficient (V M ) was determined to be 1.9 Å 3 Da
À1, corresponding to an estimated solvent content of 36%. Self-rotation function and native Patterson calculations suggested a tetramer with 222 point-group symmetry, similar to other 1Fe-SORs. The threedimensional structure will be determined by the molecular-replacement method.
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