Abstract
The structures of the cyanide and triiodide complexes of Arthromyces ramosus peroxidase (ARP) at different pH values were investigated by x-ray crystallography in order to examine the behavior of the invariant residues of arginine (Arg-52) and distal histidine (His-56) during the enzyme reaction as well as to provide the structural basis of the active site of peroxidase. The models of the cyanide complexes at pH 7.5, 5.0, and 4.0, respectively, were refined to the R-factors of 17.8, 17.8, and 18.5% using 7.0-1.6-A resolution data, and those of the triiodide complexes at pH 6.5 and 5.0 refined to 16.9 and 16.8% using 7.0-1.9-A resolution data. The structures of the cyanide complexes at pH 7.5, 5.0, and 4.0 are identical within experimental error. Cyanide ion bound to the heme in the bent conformation rather than in the tilt conformation. Upon cyanide ion binding, the N epsilon atom of His-56 moved toward the ion by rotation of the imidazole ring around the C beta-C gamma bond, but there was little conformational change in the remaining residues. The distance between the N epsilon atom of His-56 and the nitrogen atom of the cyanide suggests the presence of a hydrogen bond between them in the pH range investigated. In the triiodide complexes, one of the two triiodides bound to ARP was located at the distal side of the heme. When triiodide bound to ARP, unlike the rearrangement of the distal arginine of cytochrome c peroxidase that occurs on formation of the fluoride complex or compound I, the side chain of Arg-52 moved little. The conformation of the side chain of His-56, however, changed markedly. Conformational flexibility of His-56 appears to be a requisite for proton translocation from one oxygen atom to the other of HOO- by acid-base catalysis to produce compound I. The iron atom in each cyanide complex (low-spin ferric) is located in the heme plane, whereas in each triiodide complex (high-spin ferric) the iron atom is displaced from the plane about 0.2 A toward the proximal side.
Highlights
The structures of the cyanide and triiodide complexes of Arthromyces ramosus peroxidase (ARP) at different pH values were investigated by x-ray crystallography in order to examine the behavior of the invariant residues of arginine (Arg-52) and distal histidine (His-56) during the enzyme reaction as well as to provide the structural basis of the active site of peroxidase
Heme Geometries—Generally the iron of ferric heme proteins in the low-spin state lies in the heme plane, whereas in the high-spin state it deviates from the plane toward the proximal side (Perutz, 1970; Kuriyan et al, 1986; Quillin et al, 1993; Neya et al, 1993); but, in the ligand-bound forms of cytochrome c peroxidase (CCP) this correlation is lacking (Edwards and Poulos, 1993)
The present crystallographic results (Tables III and IV) show that the heme iron is located on the heme plane in the cyanide complex but is displaced from that plane (0.17 Å) toward the proximal side in the triiodide complex
Summary
Keiichi Fukuyama‡, Naoki Kunishima§, Fumiko Amada, Tomomi Kubota¶, and Hiroshi Matsubarai. When triiodide bound to ARP, unlike the rearrangement of the distal arginine of cytochrome c peroxidase that occurs on formation of the fluoride complex or compound I, the side chain of Arg-52 moved little. Peroxidases (donor: H2O2 oxidoreductase (EC 1.11.1.7)) are a class of heme proteins which oxidize a wide variety of organic and inorganic compounds by the use of hydrogen peroxide. The mechanism of compound I formation suggested is that the distal histidine and arginine concertedly stabilize charge separation and facilitate proton transfer from one oxygen to the other of the peroxide as well as heterolytic cleavage of its O-O bond (Finzel et al, 1984). The histidine and arginine residues at the distal side of the heme are conserved in ARP and LiP, structural comparison.
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