Protein folding, azurin

The crystal structure of the pseudoazurin from Alcaligenes faecalis S-6 sometimes referred to as the blue protein (also as cupredoxin), has been reported to 2.0 A [74]. The protein folds in /3-sandwich which is described as being similar to plastocyanin and azurin. 

The salient features of A. faecalis pseudoazurin are that (1) it has a Cu-Met bond length shorter than that of either plastocyanin or azurin (see Table III) (2) it has only one NH - S bond, as does plastocyanin and (3) its overall architecture resembles plastocyanin (see Fig. 4), with an extended carboxy terminus folded into two a helices [a preliminary sequence comparison suggested that the folding would resemble plastocyanin (Adman, 1985)]. It retains the exposed hydrophobic face found in azurin and plastocyanin. Just how it interacts with nitrite reductase is still a subject of investigation. It is intriguing that the carboxy-terminal portion folds up onto the face of the molecule where the unique portions of other blue proteins are the flap in azurin, and, as we see below in the multi-copper oxidase, entire domains. 

Cucumber basic blue protein (Cbp) is a protein without known function, also known as cusacyanin or plantacyanin. Its structure (Guss et al., 1988) completes the repertoire of cupredoxins with known structures. The topology of its folding is similar (Fig. 5) to those of plastocyanin and azurin, as might have been expected from sequence similarities and... 

The subunits are arranged in the crystals as homotetramers with D2 symmetry. The structure of a subunit is shown schematically in Fig. 1 (87). Each subunit of 552 amino acid residues has a globular shape with dimensions of 49 x 53 x 65 A and is built up of three domains arranged sequentially on the polypeptide chain, tightly associated in space. The folding of all three domains is of a similar jS-barrel type. It is distantly related to the small blue copper proteins, for example, plastocyanin or azurin. Domain 1 is made up of two four-stranded jS-sheets (Fig. lb), which form a jS-sandwich structure. Domain 2 consists of a six-stranded and a five-stranded jS-sheet. Finally, domain 3 is built up of two five-stranded jS-sheets that form the jS-barrel structure and a four-stranded j8-sheet that is an extension at the N-terminal part of this domain. A topology diagram of ascorbate oxidase for all three domains and of the related structures of plastocyanin and azurin is shown in Fig. 2. Ascorbate oxidase contains seven helices. Domain 2 has a short a-helix (aj) between strands A2 and B2. Domain 3 exhibits five short a-helices that are located between strands D3 and E3 (a ), 13 and J3 (a ), and M3 and N3 (a ) as well as at the C terminus (ag and a ). Helix 2 connects domain 2 and domain 3. 

Single-crystal structural data have provided valuable information about blue copper proteins containing Type 1 Cu centres. Figure 28.10a shows a representation of the folded protein chain of spinach plastocyanin. The Cu(II) centre lies within a pocket in the chain, bound by a Cys, a Met and two His residues (Figure 28.10b) the S(Met) atom is significantly further away from the Cu(II) centre than is S(Cys). Figure 28.10c shows the backbone of the protein chain in azurin isolated from the bacterium Pseudomonas putida. The coordination environment of the Cu(II) centre resembles that in plastocyanin with Cu—S(Met) > Cu—S(Cys), but in addition, an O atom from an adjacent Gly residue is involved in a weak coordinate interaction (Figure 28.10d). Structural... 

The mutant proteins show substantial decreases of (100-1,000)-fold in NiR activity when assayed with Methyl Viologen as electron donor. Surprisingly, the D92N and D92E mutants of AxNiR had significant activity with reduced azurin." These differences could arise from an altered conformation of NiR when complexed with azurin, resulting in an increased accessibility to the active site or reorganization of the water network. 

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