Copper,zinc-superoxide dismutase liganding

The transfer of a quadridentate N2S2-donor ligand from M2+ (M = Cr, Mn, Fe, Co or Ni) to Cu2+ (271), already mentioned in Section V.A.l, has a formal connection with an investigation of the mechanism of copper delivery to metalloproteins, such as copper zinc superoxide dismutase. Both are ligand exchange reactions of the type ML + CuL ML + CuL (300). 

The imidazole-bridge dimetallic centre in copper-zinc superoxide dismutase (EC 1.15.1.1) was a novel structural feature that had not previously been encountered in coordination chemistry [151], The Cu(II) ion is co-ordinated by four histidine side chains, His44, His46, His 118 and His61, and there is evidence for a fifth axial water ligand. 

From One Type 2 Copper Protein to Another Type 2 Copper Protein. It has been shown that a type 2 copper protein called copper-zinc superoxide dismutase (CuZnSOD) (Figure 15b) shares the same overall scaffold as its copper chaperone protein called copper chaperone for SOD (CCS). All of e zinc site ligands and three of four copper site histidine ligands in CuZnSOD are conserved in human CCS (hCCS). The zinc site in hCCS displayed the same structure as in CuZnSOD. The fourth ligand in the copper site of CuZnSOD is replaced by an aspartate residue in hCCS. Although aspartate could... 

Nalbandyan, 1982 Hodgson and Fridovich, 1975 Asada et al., 1975), whereas azide inhibits the enzymes in the following order iron > manganese > copper/zinc superoxide dismutase (Misra and Fridovich, 1978). Diethyldithiocarbamate is another well-characterized inhibitor of the copper/zinc superoxide dismutase (Heikkila et al., 1977). It forms a complex with the copper and removes the metal from all the protein ligands. The copper-diethyldithiocarbamate complex can be separated without affecting the zinc content of the protein (Cocco et al., 1981). 

Lu, Y. Roe, J. A. Gralla, E. B. Valentine, J. S. Metalloprotein ligand redesign characterization of copper-cysteinate proteins derived from yeast copper-zinc superoxide dismutase. In Bioinorganic Chemistry of Copper Karlin, K. D. Tyeklar, Z., Eds. Chapman and Hall New York, 1993 pp 64-77. 

Copper, silver and gold - The paramagnetism of Cu11 has limited the use of NMR for the direct study of copper complexes, but information is readily obtained from studies of ligand nuclei. For example, the broadening of the NMR signal by copper in copper-zinc and copper-cobalt superoxide dismutases (SODs) has been used to determine the distance between the copper and the proton on bound formate (Sette et al., 1992). Also, broadening of the formate 13C NMR resonance reveals information about the orientation of the formate. 

Cobalt has recently been used as an ESR active substitute in zinc metalloenzymes. Whilst liquid helium temperatures may be needed and theoretical aspects of the spectra are not yet as well understood, cobalt has two important advantages over copper as a metal substitute, namely that many cobalt derivatives show some enzymic activity (e.g. cobalt in carbonic anhydrase, alkaline phosphatase and superoxide dismutase) and that g values and hyperfine splitting are more sensitive to ligand environment, particularly when low spin. ESR data have been reported for cobalt substituted thermolysin, carboxypeptidase A, procarboxypeptidase A and alkaline phosphatase [51]. These are all high spin complexes. Cobalt carbonic anhydrase has been prepared and reacted with cyanide [52]. In... 

Type 2 copper centers are not uniform in ligand or ligand stereochemistries. One common feature is, however, that in the active enzyme, one coordination site is always free to bind oxygen. The most common ligand in type 2 copper centers is histidine. Tyrosine (often modified), methionine, and cysteine occur as well. There are three histidines and a modified tyrosine in amine oxidase and lysyl oxidase [28]. In diamine oxidase, two of the histidine residues have probably been replaced by cysteines [29]. In galactose oxidase, the copper ion is coordinated by two tyrosines, two histidines and an acetate ion [30]. Dopamine-/J-hydroxylase contains two differently coordinated copper ions per functional unit. One is coordinated by three histidines and a methionine and the other by two histidines and another, yet unknown, ligand [ 31 ]. Last but not least, the type 2 copper ion in Cu,Zn-superoxide dismutase is coordinated by four histidine residues, one of which connects the copper ion to the zinc ion, the second metal ion in the active site of the enzyme [32,33] (Fig. 6). 

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