EPR and 1H, 14,15N ENDOR spectra are described for the type 1 and type 2 Cu(II) centers of dissimilatory nitrite reductase (NiR) from Alcaligenes xylosoxidans. The study was carried out on preparations of NiR containing both type 1 and type 2 Cu sites, and also on preparations of lower activity which contained essentially only type 1 Cu centers. This has enabled ENDOR studies of type 1 and type 2 sites to be carried out largely independently of each other, by appropriate choice of the excitation field. Spectra were recorded both in the absence and presence of nitrite, allowing a clear determination of which of the two types of Cu center constitutes the substrate binding site. The EPR results show large changes in the type 2 site gparallel (which decreases by 0.065) and CuAparallel (which increases by 2.0 mT) while the type 1 site EPR is not affected. In addition, both 1H and 14N ENDOR of the type 2 Cu site undergo considerable changes on addition of nitrite whereas the type 1 Cu site ENDOR is unaffected. Our results clearly demonstrate that nitrite binds to the type 2 copper and that this process significantly perturbs the ligation of this copper by the protein histidine residues. No 15N ENDOR resonances were observed from 15N nitrite. The accessibility of the copper sites to solvent has been studied using 2H2O. The results indicate that nitrite binds to the type 2 Cu by displacing a proton, probably on a water molecule bound to the copper atom.
The intramolecular electron transfer (ET) between the type 1 Cu(I) and the type 2 Cu(II) sites of Alcaligenes xylosoxidans dissimilatory nitrite reductase (AxNiR) has been studied in order to compare it with the analogous process taking place in ascorbate oxidase (AO). This internal process is induced following reduction of the type 1 Cu(II) by radicals produced by pulse radiolysis. The reversible ET reaction proceeds with a rate constant k i = k I3P +k P3I of 450 þ 30 s 3I at pH 7.0 and 298 K. The equilibrium constant K was determined to be 0.7 at 298 K from which the individual rate constants for the forward and backward reactions were calculated to be: k I3P = 185 þ 12 s 3I and k P3I 265 þ 18 s 3I . The temperature dependence of K allowed us to determine the v vH³ value of the ET equilibrium to be 12.1 kJ mol 3I . Measurements of the temperature dependence of the ET process yielded the following activation parameters: forward reaction, v vH g = 22.7 þ 3.4 kJ mol 3I and v vS g = 3126 þ 11 J K 3I mol 3I ; backward reaction, v vH g = 10.6 þ 1.7 kJ mol 3I and v vS g = 3164 þ 15 J K 3I mol 3I . X-ray crystallographic studies of NiRs suggest that the most probable ET pathway linking the two copper sites consists of Cys IQT , which provides the thiolate ligand to the type 1 copper ion, and the adjacent His IQS residue with its imidazole being one of the ligands to the type 2 Cu ion. This pathway is essentially identical to that operating between the type 1 Cu(I) and the trinuclear copper centre in ascorbate oxidase, and the characteristics of the internal ET processes of these enzymes are compared. The data are consistent with the faster ET observed in nitrite reductase arising from a more advantageous entropy of activation when compared with ascorbate oxidase.z 1998 Federation of European Biochemical Societies.
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