Copper(2+) binding to the surface residue cysteine 111 of His46Arg human copper-zinc superoxide dismutase, a familial amyotrophic lateral sclerosis mutant.

Mutations in copper-zinc superoxide dismutase (CuZnSOD) cause 25% of familial amyotrophic lateral sclerosis (FALS) cases. This paper examines one such mutant, H46R, which has no superoxide dismutase activity yet presumably retains the gain-of-function activity that leads to disease. We demonstrate that Cu(2+) does not bind to the copper-specific catalytic site of H46R CuZnSOD and that Cu(2+) competes with other metals for the zinc binding site. Most importantly, Cu(2+) was found to bind strongly to a surface residue near the dimer interface of H46R CuZnSOD. Cysteine was identified as the new binding site on the basis of multiple criteria including UV-vis spectroscopy, RR spectroscopy, and chemical derivatization. Cysteine 111 was pinpointed as the position of the reactive ligand by tryptic digestion of the modified protein and by mutational analysis. This solvent-exposed residue may play a role in the toxicity of this and other FALS CuZnSOD mutations. Furthermore, we propose that the two cysteine 111 residues, found on opposing subunits of the same dimeric enzyme, may provide a docking location for initial metal insertion during biosynthesis of wild-type CuZnSOD in vivo.

Cobalt(2+) binding to human and tomato copper chaperone for superoxide dismutase: implications for the metal ion transfer mechanism.

The copper chaperone for superoxide dismutase (CCS) gene encodes a protein that is believed to deliver copper ions specifically to copper-zinc superoxide dismutase (CuZnSOD). CCS proteins from different organisms share high sequence homology and consist of three distinct domains; a CuZnSOD-like central domain 2 flanked by domains 1 and 3, which contain putative metal-binding motifs. We report deduced protein sequences from tomato and Arabidopsis, the first functional homologues of CCS identified in plants. We have purified recombinant human (hCCS) and tomato (tCCS) copper chaperone proteins, as well as a truncated version of tCCS containing only domains 2 and 3. Their cobalt(2+) binding properties in the presence and absence of mercury(2+) were characterized by UV-vis and circular dichroism spectroscopies and it was shown that hCCS has the ability to bind two spectroscopically distinct cobalt ions whereas tCCS binds only one. The cobalt binding site that is common to both hCCS and tCCS displayed spectroscopic characteristics of cobalt(2+) bound to four or three cysteine ligands. There are only four cysteine residues in tCCS, two in domain 1 and two in domain 3; all four are conserved in other CCS sequences including hCCS. Thus, an interaction between domain 1 and domain 3 is concluded, and it may be important in the copper chaperone mechanism of these proteins.

X-ray crystallographic and analytical ultracentrifugation analyses of truncated and full-length yeast copper chaperones for SOD (LYS7): a dimer-dimer model of LYS7-SOD association and copper delivery.

Copper-zinc superoxide dismutase (CuZnSOD) acquires its catalytic copper ion through interaction with another polypeptide termed the copper chaperone for SOD. Here, we combine X-ray crystallographic and analytical ultracentrifugation methods to characterize rigorously both truncated and full-length forms of apo-LYS7, the yeast copper chaperone for SOD. The 1.55 A crystal structure of LYS7 domain 2 alone (L7D2) was determined by multiple-isomorphous replacement (MIR) methods. The monomeric structure reveals an eight-stranded Greek key beta-barrel similar to that found in yeast CuZnSOD, but it is substantially elongated at one end where the loop regions of the beta-barrel come together to bind a calcium ion. In agreement with the crystal structure, sedimentation velocity experiments indicate that L7D2 is monomeric in solution under all conditions and concentrations that were tested. In contrast, sedimentation velocity and sedimentation equilibrium experiments show that full-length apo-LYS7 exists in a monomer-dimer equilibrium under nonreducing conditions. This equilibrium is shifted toward the dimer by approximately 1 order of magnitude in the presence of phosphate anion. Although the basis for the specificity of the LYS7-SOD interaction as well as the exact mechanism of copper insertion into SOD is unknown, it has been suggested that a monomer of LYS7 and a monomer of SOD may associate to form a heterodimer via L7D2. The data presented here, however, taken together with previously published crystallographic and analytical gel filtration data on full-length LYS7, suggest an alternative model wherein a dimer of LYS7 interacts with a dimer of yeast CuZnSOD. The advantages of the dimer-dimer model over the heterodimer model are enumerated.

A structure-based mechanism for copper-zinc superoxide dismutase.

A reaction cycle is proposed for the mechanism of copper-zinc superoxide dismutase (CuZnSOD) that involves inner sphere electron transfer from superoxide to Cu(II) in one portion of the cycle and outer sphere electron transfer from Cu(I) to superoxide in the other portion of the cycle. This mechanism is based on three yeast CuZnSOD structures determined by X-ray crystallography together with many other observations. The new structures reported here are (1) wild type under 15 atm of oxygen pressure, (2) wild type in the presence of azide, and (3) the His48Cys mutant. Final R-values for the three structures are respectively 20.0%, 17.3%, and 20.9%. Comparison of these three new structures to the wild-type yeast Cu(I)ZnSOD model, which has a broken imidazolate bridge, reveals the following: (i) The protein backbones (the "SOD rack") remain essentially unchanged. (ii) A pressure of 15 atm of oxygen causes a displacement of the copper ion 0.37 A from its Cu(I) position in the trigonal plane formed by His46, His48, and His120. The displacement is perpendicular to this plane and toward the NE2 atom of His63 and is accompanied by elongated copper electron density in the direction of the displacement suggestive of two copper positions in the crystal. The copper geometry remains three coordinate, but the His48-Cu bond distance increases by 0.18 A. (iii) Azide binding also causes a displacement of the copper toward His63 such that it moves 1.28 A from the wild-type Cu(I) position, but unlike the effect of 15 atm of oxygen, there is no two-state character. The geometry becomes five-coordinate square pyramidal, and the His63 imidazolate bridge re-forms. The His48-Cu distance increases by 0.70 A, suggesting that His48 becomes an axial ligand. (iv) The His63 imidazole ring tilts upon 15 atm of oxygen treatment and azide binding. Its NE2 atom moves toward the trigonal plane by 0.28 and 0.66 A, respectively, in these structures. (v) The replacement of His48 by Cys, which does not bind copper, results in a five-coordinate square pyramidal, bridge-intact copper geometry with a novel chloride ligand. Combining results from these and other CuZnSOD crystal structures, we offer the outlines of a structure-based cyclic mechanism.

Uclacyanins, stellacyanins, and plantacyanins are distinct subfamilies of phytocyanins: plant-specific mononuclear blue copper proteins.

The cDNAs encoding plantacyanin from spinach were isolated and characterized. In addition, four new cDNA sequences from Arabidopsis ESTs were identified that encode polypeptides resembling phytocyanins, plant-specific proteins constituting a distinct family of mononuclear blue copper proteins. One of them encodes plantacyanin from Arabidopsis, while three others, designated as uclacyanin 1, 2, and 3, encode protein precursors that are closely related to precursors of stellacyanins and a blue copper protein from pea pods. Comparative analyses with known phytocyanins allow further classification of these proteins into three distinct subfamilies designated as uclacyanins, stellacyanins, and plantacyanins. This specification is based on (1) their spectroscopic properties, (2) their glycosylation state, (3) the domain organization of their precursors, and (4) their copper-binding amino acids. The recombinant copper binding domain of Arabidopsis uclacyanin 1 was expressed, purified, and shown to bind a copper atom in a fashion known as "blue" or type 1. The mutant of cucumber stellacyanin in which the glutamine axial ligand was substituted by a methionine (Q99M) was purified and shown to possess spectroscopic properties similar to uclacyanin 1 rather than to plantacyanins. Its redox potential was determined by cyclic voltammetry to be +420 mV, a value that is significantly higher than that determined for the wild-type protein (+260 mV). The available structural data suggest that stellacyanins (and possibly other phytocyanins) might not be diffusible electron-transfer proteins participating in long-range electron-transfer processes. Conceivably, they are involved in redox reactions occurring during primary defense responses in plants and/or in lignin formation.

Subunit asymmetry in the three-dimensional structure of a human CuZnSOD mutant found in familial amyotrophic lateral sclerosis.

The X-ray crystal structure of a human copper/zinc superoxide dismutase mutant (G37R CuZnSOD) found in some patients with the inherited form of Lou Gehrig's disease (FALS) has been determined to 1.9 angstroms resolution. The two SOD subunits have distinct environments in the crystal and are different in structure at their copper binding sites. One subunit (subunit[intact]) shows a four-coordinate ligand geometry of the copper ion, whereas the other subunit (subunit[broken]) shows a three-coordinate geometry of the copper ion. Also, subunit(intact) displays higher atomic displacement parameters for backbone atoms ((B) = 30 +/- 10 angstroms2) than subunit(broken) ((B) = 24 +/- 11 angstroms2). This structure is the first CuZnSOD to show large differences between the two subunits. Factors that may contribute to these differences are discussed and a possible link of a looser structure to FALS is suggested.

A missing link in cupredoxins: crystal structure of cucumber stellacyanin at 1.6 A resolution.

Stellacyanins are blue (type I) copper glycoproteins that differ from other members of the cupredoxin family in their spectroscopic and electron transfer properties. Until now, stellacyanins have eluded structure determination. Here we report the three-dimensional crystal structure of the 109 amino acid, non-glycosylated copper binding domain of recombinant cucumber stellacyanin refined to 1.6 A resolution. The crystallographic R-value for all 18,488 reflections (sigma > 0) between 50-1.6 A is 0.195. The overall fold is organized in two beta-sheets, both with four beta-stands. Two alpha-helices are found in loop regions between beta-strands. The beta-sheets form a beta-sandwich similar to those found in other cupredoxins, but some features differ from proteins such as plastocyanin and azurin in that the beta-barrel is more flattened, there is an extra N-terminal alpha-helix, and the copper binding site is much more solvent accessible. The presence of a disulfide bond at the copper binding end of the protein confirms that cucumber stellacyanin has a phytocyanin-like fold. The ligands to copper are two histidines, one cysteine, and one glutamine, the latter replacing the methionine typically found in mononuclear blue copper proteins. The Cu-Gln bond is one of the shortest axial ligand bond distances observed to date in structurally characterized type I copper proteins. The characteristic spectroscopic properties and electron transfer reactivity of stellacyanin, which differ significantly from those of other well-characterized cupredoxins, can be explained by its more exposed copper site, its distinctive amino acid ligand composition, and its nearly tetrahedral ligand geometry. Surface features on the cucumber stellacyanin molecule that could be involved in interactions with putative redox partners are discussed.

Cloning, expression, and spectroscopic characterization of Cucumis sativus stellacyanin in its nonglycosylated form.

The cDNA encoding the 182 amino acid long precursor stellacyanin from Cucumis sativus was isolated and characterized. The protein precursor consists of four sequence domains: I, a 23 amino acid hydrophobic N-terminal signal peptide with features characteristic of secretory proteins; II, a 109 amino acid copper-binding domain; III, a 26 amino acid hydroxyproline- and serine-rich peptide characteristic of motifs found in the extension family, extracellular structural glycoproteins found in plant cell walls; and IV, a 22 amino acid hydrophobic extension. Maturation of the protein involves posttranslational processing of domains I and IV. The copper-binding domain (domain II), which shares high sequence identity with other stellacyanins, has been expressed without its carbohydrate attachment sites, refolded from the Escherichia coli inclusion bodies, purified, and characterized by electronic absorption, EPR, ESEEM, and RR spectroscopy. Its spectroscopic properties are nearly identical to those of stellacyanin from the Japanese lacquer tree Rhus vernicifera, the most extensively studied and best characterized stellacyanin, indicating that this domain folds correctly, even in the absence of its carbohydrate moiety. The presence of a hydroxyproline- and serine-rich domain III suggests that stellacyanin may have a function other than that of a diffusible electron transfer protein, conceivably participating in redox reactions localized at the plant cell wall, which are known to occur in response to wounding or infection of the plant.

Studies on plantacyanin. IV. Reconstitution with Cu-thionein, oxidation by cytochrome oxidase and autooxidation in the presence of cardiolipin.

Cu-thionein isolated from cucumber roots was used for reconstitution of plantacyanin from cucumber. The rate of the copper transfer from Cu-thionein to apoplantacyanin was found to depend on pH, ionic strength and concentrations of the proteins. The rate of reconstitution with Cu-thionein was 10-times higher than with copper ions. No intermediate was observed during reconstitution with Cu-thionein. The incubation of oxidized holoplantacyanin with Cu-thionein or apothionein brings about the reduction of plantacyanin copper. This process, however, was found to be slow as compared to the rate of copper transfer from Cu-thionein to apoplantacyanin. Cytochrome oxidase from heart mitochondria was detected to possess some plantacyanin oxidase activity with the turnover number 5 min-1. The activity of the enzyme towards plantacyanin as well as with cytochrome c as a substrate was established to be lipid and ionic strength-dependent, and it was inhibited by CN- and N3-. Lineweaver-Burk plots show that the inhibitory effect of ionic strength on plantacyanin oxidase activity is connected with changes of Michaelis constant rather than of the maximal rate. Plantacyanin which is known to be very resistant towards many cationic, anionic and nonionic detergents, becomes, as well as cytochrome c, autooxidable in the presence of cardiolipin.

Particles of photosystem 2 contain plantacyanin.

PS2 particles prepared from chloroplasts of three plant species were shown to contain the basic blue copper protein, plantacyanin, which may be extracted from the particles by concentrated saline solutions containing Triton X-100. Antibodies to plantacyanin were found to inhibit the photosynthetic oxygen evolution performed by the particles. Thus, evidences were obtained for participation of this protein in the oxygen-evolving activity of PS2 particles.

The IH-NMR-study of the copper surrounding in plantacyanin.

The 300-MHz proton NMR spectra of oxidized, reduced and apo-forms of plantacyanin were studied. The data obtained show that one of two histidines is far from copper whereas the other is a ligand of the metal. Ligands of copper are also two methionines and, possibly, tryptophan. Although the surrounding of copper in plastocyanin consists of two sulfur and two nitrogen atoms, only histidine and methionine are invariant ligand amino acids of the metal in these two copper proteins from plants.