Blue copper oxidases Ascorbate oxidase Ceruloplasmin

Multicopper Oxidases (Blue Copper Oxidases) Ascorbate Oxidase, Ceruloplasmin, and Laccase. The multicopper oxidases (MCOs) are important enzymes, which are found in many plants (lignin formation), fungi (lignin degradation and detoxification), bacteria, as well as humans (ferroxidase activity) (13). MCOs catalyze the four-electron reduction of O2 to two waters with the electrons coming firom one-electron oxidation of four substrate molecules. The latter are organic reductants for ascorbate oxidase (AO) (32) and laccase (Lc) (130), and a metal ion (ferrous ion) for ceruloplasmin (Cp) (33) (Scheme 9). 

Various spectroscopic methods have been used to probe the nature of the copper centers in the members of the blue copper oxidase family of proteins (e.g. see ref. 13). Prior to the X-ray determination of the structure of ascorbate oxidase in 1989, similarities in the EPR and UV-vis absorption spectra for the blue multi-copper oxidases including laccase and ceruloplasmin had been observed [14] and a number of general conclusions made for the copper centers in ceruloplasmin as shown in Table 1 [13,15]. It was known that six copper atoms were nondialyzable and not available to chelation directly by dithiocarbamate and these coppers were assumed to be tightly bound and/or buried in the protein. Two of the coppers have absorbance maxima around 610 nm and these were interpreted as blue type I coppers with cysteine and histidine ligands, and responsible for the pronounced color of the protein. However, they are not equivalent and one of them, thought to be involved in enzymatic activity, is reduced and reoxidized at a faster rate than the second (e.g. see ref. 16). There was general concurrence that there are two type HI... 

Ceruloplasmin is a member of the family of blue copper oxidases which also contains laccase and ascorbate oxidase. The relationship... 

Copper oxidases Blue oxidases (multicopper oxidases) Laccase Ascorbate oxidase Ceruloplasmin... 

An important family of multicopper enzymes couple the reduction of O2 to H2O with substrate oxidation. They include ascorbate oxidase, ceruloplasmin, Fet3, hephaestin, and laccase, and contain at least four copper ions. The four Cu ions are distributed between one type 1 blue copper site, one type 2 site, and one type 3 copper site. The blue Type 1 site is usually located some 12—13 A distant from a trinuclear site which has the two Type 3 coppers, linked by a bridging oxygen and one Type 2 copper. We illustrate this class of oxidases with laccase which catalyses the four-electron reduction of O2 to water, coupled with the oxidation of small organic... 

The blue copper oxidases are similar to cytochrome oxidase in their ability to catalyze reduction of Oj to HjO. Catalysis is centered upon the protein-bound copper ions that can be differentiated into three classes according to their physical, chemical, and functional properties. They are designated Types 1, 2, and 3 copper . In the blue copper proteins (tree and fungal laccases, ceruloplasmin, ascorbate oxidase) these three classes of copper appear in varying amounts the laccases contain the minimum amounts of each (one each of Types 1 and 2 and two Type 3 coppers). 

Copper oxidases are widely distributed in nature, and enzymes from plants, microbes, and mammals have been characterized (104,105). The blue copper oxidases, which include laccases, ascorbate oxidases, and ceruloplasmin, are of particular interest in alkaloid transformations. The principle differences in specificity of these copper oxidases are due to the protein structures as well as to the distribution and environment of copper(II) ions within the enzymes (106). While an in vivo role in metabolism of alkaloids has not been established for these enzymes, copper oxidases have been used in vitro for various alkaloid transformations. 

Each of these proteins is blue and appears to have a minimum of four copper atoms per molecule one type 1, one type 11, and two type III. Laccase is not known to be multimeric, nor is ceruloplasmin, but ascorbate oxidase is apparently a dimer. 

The blue oxidases contain these three types of copper together The stoichiometry is straightforward with laccase which contains one type-1 and one type-2 copper, and one type-3 dimeric copper site . One would expect two laccase-like sites in ascorbate oxidase and in ceruloplasmin, but the presence of respectively 3 and 1 and 1 and 3 type-1 and type-2 copper atoms has been deduced. Ceruloplasmin shows oxidase activities towards different substrates, like Fe (ferroxidase) and aromatic amines. It plays, moreover, an active role in the transport of copper With the proper precautions against the action of proteinases it can be isolated as a single polypeptide chain... 

In addition to its previously mentioned role in copper transport, ceruloplasmin is an amine oxidase, a superoxide dismutase, and a ferrooxidase able to catalyze the oxidation of Fe2+ to Fe3+. Ceruloplasmin contains three consecutive homologous 350-residue sequences which may have originated from an ancestral copper oxidase gene. Like ascorbate oxidase, this blue protein contains copper of the three different types. Blood clotting factors V and VIII (Fig. 12-17), and the iron uptake protein Fet3 (Section A,l) are also closely related. 

Copper has an essential role in a number of enzymes, notably those involved in the catalysis of electron transfer and in the transport of dioxygen and the catalysis of its reactions. The latter topic is discussed in Section 62.1.12. Hemocyanin, the copper-containing dioxygen carrier, is considered in Section 62.1.12.3.8, while the important role of copper in oxidases is exemplified in cytochrome oxidase, the terminal member of the mitochondrial electron-transfer chain (62.1.12.4), the multicopper blue oxidases such as laccase, ascorbate oxidase and ceruloplasmin (62.1.12.6) and the non-blue oxidases (62.12.7). Copper is also involved in the Cu/Zn-superoxide dismutases (62.1.12.8.1) and a number of hydroxylases, such as tyrosinase (62.1.12.11.2) and dopamine-jS-hydroxylase (62.1.12.11.3). Tyrosinase and hemocyanin have similar binuclear copper centres. 

In the discussion of the biochemistry of copper in Section 62.1.8 it was noted that three types of copper exist in copper enzymes. These are type 1 ( blue copper centres) type 2 ( normal copper centres) and type 3 (which occur as coupled pairs). All three classes are present in the blue copper oxidases laccase, ascorbate oxidase and ceruloplasmin. Laccase contains four copper ions per molecule, and the other two contain eight copper ions per molecule. In all cases oxidation of substrate is linked to the four-electron reduction of dioxygen to water. Unlike cytochrome oxidase, these are water-soluble enzymes, and so are convenient systems for studying the problems of multielectron redox reactions. The type 3 pair of copper centres constitutes the 02-reducing sites in these enzymes, and provides a two-electron pathway to peroxide, bypassing the formation of superoxide. Laccase also contains one type 1 and one type 2 centre. While ascorbate oxidase contains eight copper ions per molecule, so far ESR and analysis data have led to the identification of type 1 (two), type 2 (two) and type 3 (four) copper centres. 

Some proteins contain more than one copper site, and are therefore among the most complicated and least understood of all. The active site known as type 4 is usually composed of a type 2 and a type 3 active site, together forming a trinuclear cluster. In some cases, such proteins also contain at least one type 1 site and are in this case termed multicopper oxidases, or blue oxidases [3], Representatives of this class are laccase (polyphenol oxidase) [7-9], ascorbate oxidase (Figure 5.Id) [10], and ceruloplasmin [11], which catalyze a range of organic oxidation reactions. 

Copper proteins are involved in a variety of biological functions, including electron transport, copper storage and many oxidase activities. A variety of reviews on this topic are available (Sykes, 1985 Chapman, 1991). Several copper proteins are easily identified by their beautiful blue colour and have been labelled blue copper proteins. The blue copper proteins can be divided into two classes, the oxidases (laccase, ascorbate oxidase, ceruloplasmin) and the electron carriers (plastocyanin, stellacyanin, umecyanin, etc.). 

The multicopper oxidases (laccase, ascorbate oxidase, and ceruloplasmin) catalyze a four-electron reduction of dioxygen to water (285-287). Consistent with the four-electron stoichiometry, the enzymes contain four copper ions. One of the copper ions is type I, causing an intensely blue color of the proteins, thus the enzymes of this family are referred to as blue oxidases. They also contain a monomeric copper site that exhibits normal spectroscopic features, whereas the other two copper... 

The second class consists of multidomain blue copper proteins composed of exclusively two or more BCB domains and includes nitrite reductase (Section IV, E), multicopper blue oxidases such as laccase, ascorbate oxidase, ceruloplasmin, and hephaestin (Section VII), and some sequences found in extreme halophilic archaea (see Section V, E). 

Multicopper blue oxidases are synthesized as a single polypeptide chain, which is composed of three BCB domains in the case of laccases (LC) and ascorbate oxidases (AO) and six such domains in ceruloplasmin (CP) and hephaestin (HP). Structurally they are arranged in a triangular manner. These enzymes, along with heme-copper oxidases (cytochrome c oxidases and quinol-oxidases) and a cyanide-resistant alternative oxidase found in mitochondria of plants and fungi, are the only known enzymes capable of catalyzing four-electron reduction of dioxygen to water. In the... 

The number and type of copper centers, EPR parameters, and the two relevant absorption bands in the visible region for several representative members of the blue oxidases are listed in Table II. All laccases except that of the P. radiata enzyme contain four coppers per molecule with one type-1, one type-2, and one type-3 copper center. The EPR and absorption parameters resemble each other very much. Phlebia radiata laccase is supposed to contain only two coppers with one type 1, one type 2, and one PQQ per mole (70). This is quite unusual and will be discussed critically below, since it is possible that the copper content determined for this enzyme is inaccurate. Ascorbate oxidases have eight coppers per homodimer with two type-1, two type-2, and two type-3 copper centers. Ceruloplasmin typically contains six to seven copper ions per molecule with three type-1, one type-2, and one type-3 copper centers. It has also been proposed that there are only two type-1 copper ions and a new type-4 copper that is presumed to exhibit no EPR signal. In addition there is a variable content of chelatable copper. It is responsible for copper contents exceeding 6 coppers/mol but does not seem to be required for catalysis. It is now generally accepted that ceruloplasmin has three type-1 copper centers and the reason for this will be discussed below. 

The similarity matrix calculated in Messerschmidt and Huber (202) indicates clearly the six-domain structure of ceruloplasmin and three-domain structures for laccase and ascorbate oxidase. The internal triplication within the ceruloplasmin amino-acid sequence is reflected by values of about 60% difference. Comparison of both the N-terminal domains and the C-terminal domains of the blue oxidases indicates, respectively, a relationship that is closer and relevant values for percent difference that are significantly lower than those for other comparisons. This might reflect the requirements for the trinuclear copper site. The lowest values of about 70 to 73% difference are observed for both N-terminal and C-terminal domains of laccase and ascorbate oxidase, showing that the two oxidases are more closely related to ceruloplasmin than either of them. 

Redox potentials for the different copper centers in the blue oxidases have been determined for all members of the group but in each case only for a limited number of species. The available data are summarized in Table VI 120, 121). The redox potentials for the type-1 copper of tree laccase and ascorbate oxidase are in the range of 330-400 mV and comparable to the values determined for the small blue copper proteins plastocyanin, azurin, and cucumber basic protein (for redox potentials of small blue copper proteins, see the review of Sykes 122)). The high potential for the fungal Polyporus laccase is probably due to a leucine or phenylalanine residue at the fourth coordination position, which has been observed in the amino-acid sequences of fungal laccases from other species (see Table IV and Section V.B). Two different redox potentials for the type-1 copper were observed for human ceruloplasmin 105). The 490-mV potential can be assigned to the two type-1 copper sites with methionine ligand and the 580-mV potential to the type-1 center with the isosteric leucine at this position (see Section V.B). The... 

A structurally based amino-acid sequence alignment strongly suggests a three-domain structure for laccase, closely related to ascorbate oxidase, and a six-domain structure for ceruloplasmin. These domains demonstrate homology with the small blue copper proteins. The relationship suggests that laccase, like ascorbate oxidase, has a mononuclear blue copper in domain 3 and a trinuclear copper between domain 1 and domain 3, and ceruloplasmin has mononuclear copper ions in domains 2, 4, and 6 and a trinuclear copper between domain 1 and domain 6. 

---