Copper active sites

As a part of their efforts to model dinuclear copper active sites, Reed and co-workers reported, using alkoxo-based dinucleating ligands, a few very interesting systems from the viewpoint of magnetostructural correlations (379) (TBP Cu-Cu 3.325A 2.1 278cm ), (380) (TBP ... 

Catalytic reduction of oxygen directly to water, while not as yet possible with traditional catalyst technology at neutral pH, is achieved with some biocatalysts, particularly by enzymes with multi-copper active sites such as the laccases, ceruloplasmins, ascorbate oxidase and bilirubin oxidases. The first report on the use of a biocatalyst... 

A coupled binuclear copper active site is found in a variety of different metalloprotelns Involved in dloxygen reactions. These Include hemocyanln (reversible O- binding), tyrosinase (O2 activation and... 

SOLOMON Coupled Binuclear Copper Active Sites... 

Table 1. Proteins Containing Coupled Binuclear Copper Active Sites and Their Functions...

Our earlier research on the coupled binuclear copper proteins generated a series of protein derivatives in which the active site was systematically varied and subjected to a variety of spectroscopic probes. These studies developed a Spectroscopically Effective Model for the oxyhemocyanin active slte.(l) The coupled binuclear copper active site in tyrosinase was farther shown to be extremely similar to that of the hemocyanlns with differences in reactivity correlating to active site accessibility, and to the monophenol coordinating directly to the copper(II) of the oxytyroslnase site.(2) These studies have been presented in a number of reviews.(3) In the first part of this chapter, we summarize some of our more recent results related to the unique spectral features of oxyhemocyanin, and use... 

Figure 21. Comparison of the spectroscopically effective models for azide binding at the blnuclear copper active site in hemocyanln and the trlnuclear copper cluster site in laccase.

Many metalloproteins contain more than one metal center. Tyrosinase, for example, has a dinuclear Type 3 (T3) copper active site which, in its oxidized form, comprises two Cu(II) centers each held by three histidine groups with a p-r 2 r 2 peroxido bridging ligand (Fig. 22). 

Polyphenol oxidase (PPO) (EC 1.14.18.1 monophenol monooxygenase [tyrosinase] or EC 1.10.3.2 0-diphenol 02-oxidoreductase) is one of the more important enzymes involved in the formation of black tea polyphenols. The enzyme is a metallo-protein thought to contain a binudear copper active site. The substance PPO is an oligomeric particulate protein thought to be bound to the plant membranes. The bound form of the enzyme is latent and activation is likely to be dependent upon solubilization of the protein (35). PPO is distributed throughout the plant (35) and is localized within in the mitochondria (36), the cholorplasts (37), and the peroxisomes (38). Using antibody techniques, polyphenol oxidase activity has also been localized in the epidermis palisade cells (39). Reviews on the subject of PPO are available (40—42). 

Additional information has been obtained from single crystal, polarized optical and ESR spectroscopic studies924 on poplar plastocyanin, which have allowed a correlation of the electronic structure of the blue copper active site with its geometric structure. In summary, the three dominant absorption bands at 13 350, 16 490 and 17 870 cm-1 were assigned to CysS- Cu (d 2-,2 charge-transfer transitions. The methionine makes only a small contribution, due to the long Cu—S(Met) bond (2.9 A) and the poor overlap of the methionine sulfur orbitals with the dx y orbital of copper. Histidine-Cu charge transfer contributes to the weaker absorptions at 21 390 and... 

Other protein groups which contribute to the molecular dynamics of the entire copper active site must be complementary to inner-coordina-... 

Galactose oxidase exhibits a mononuclear copper-active site, which is flanked by a tyrosinyl radical. In a single step, a two-electron oxidation of alcohols can be performed by this enzyme, where one electron is extracted by copper and the other by the tyrosine residue [19]. 

One of the major goals of studying active sites in copper proteins has therefore been to understand the spectroscopic features associated with the active site. This has led to a classification of three general types of copper protein active sites based on their unique spectral features Blue copper, normal copper and coupled binuclear copper. An additional class of copper proteins, the multi-copper oxidases, contains a combination of these three types of copper active sites. A reasonably firm understanding of the optical and EPR spectra of a number of copper proteins has now been achieved1,2K This article presents an overview of these electronic spectral features and their relationship to geometric and electronic structure. 

Fig. 19. LEFE at 4.2 K for the Blue Copper active site in azurin (5 mM) (from Ref. 49)...

A series of hemocyanin and tyrosinase active site derivatives (Fig. 23) can be prepared61"66), allowing systematic variation of the binuclear copper active site and chemical perturbation for spectral studies. In the simplest derivative, met-apo, one copper has been removed and the remaining copper oxidized to the spectroscopically accessible Cu(II). Next in complexity is a mixed-valent binuclear copper site. The Cu(II), in this half-met derivative, exhibits open-shell d9 spectroscopic features and the Cu(I), though spectroscopically inaccessible, can still be studied by comparison to the met-apo derivative. Two derivatives have formally binuclear cupric sites met, which is EPR-non-detect-able, and dimer, which exhibits an intense broad EPR signal. Spectroscopic study of these derivatives has led to the present picture of the coupled binuclear copper protein active site shown at the bottom of Fig. 23. 

Solomon, E. I. The binuclear copper active site hemocyanin, tyrosinase and type 3 copper oxidases, ibid., chapter 2... 

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