Cu(I) binding to the Schizosaccharomyces pombe gamma-glutamyl peptides varying in chain lengths

The metal-gamma-glutamyl peptide complex of Schizosaccharomyces pombe is an oligomer of peptides of the general structure (gamma-Glu-Cys)n-Gly with n defining the number of dipeptide repeats. The complexes induced with either cadmium or copper salts are heterogeneous with respect to the number of repeat units or n. Peptides isolated from two preparations of the Cd-gamma-Glu complex by reverse-phase HPLC at low pH were of an n range of 2 to 6 with n3 and n4 peptides being predominant. In addition to peptides of the mentioned structure, peptides of n3 and n4 without the terminal Gly were isolated. These n3 and n4 desGly peptides were present in an abundance of about 10-20% of the concentration of the parent peptide. Peptides of unique n were studied in Cu(I) reconstitution experiments in an attempt to understand the significance of the peptide length heterogeneity in the oligomeric metal-thiolate cluster. Cu-gamma-Glu complexes were formed with each peptide as determined by the characteristic 260-nm shoulder in the ultraviolet absorption spectrum and luminescence indicative of Cu(I)-thiolate coordination in a solvent-inaccessible environment. Cluster formation also occurs with desGly peptides, so the carboxyl-terminal Gly is not critical for cluster formation. Maximal Cu binding stoichiometry with n3 and n4 peptides was markedly less than the maximal Cu(I) stoichiometry of a peptide mixture or the native complex. Cu ions in complexes formed with unique n peptides were more reactive with bathocuproine than Cu ions in complexes with a peptide n mixture. The results suggest that metal-peptide complexes consisting of peptides differing in n probably exist and not all metal-peptide complexes have the same n peptide constituents.     

Sulfide stabilization of the cadmium-gamma-glutamyl peptide complex of Schizosaccharomyces pombe

Addition of cadmium salts to the growth medium of Schizosaccharomyces pombe leads to synthesis of a Cd.gamma-Glu peptide complex and an enhanced generation of sulfide ions. The gamma-Glu peptide complex functions in the detoxification of heavy metal ions. Native Cd.gamma-Glu peptide complexes contain acid-labile sulfide in the metal-thiolate cluster. Two forms of the complex exist differing primarily in their sulfide content. Sulfide concentrations up to 0.2 and 1.2 mol/mol of peptide were observed in native isolates of forms I and II, respectively. Addition of sulfide to the low sulfide form I converted it to a complex similar to form II. Properties of the Cd.gamma-Glu peptide complex were altered by the incorporation of sulfide ions. Sulfide-dependent electronic transitions in the ultraviolet were evident, and the absorbance maximum of the transition was related to the sulfide content and the bound metal ion. High sulfide forms of the Cd and Zn complexes exhibited absorbance peaks at 318 nm and 255 nm, respectively. Incorporation of sulfide into the Cd.gamma-Glu peptide complex imparted greater thermodynamic stability to the complex, an increased Stokes radius, and an enhanced Cd(II) binding capacity. Sulfide generation may be a cellular response in part to enhance the effectiveness of the gamma-Glu peptide system for Cd(II) detoxification.     

Independence of the domains of metallothionein in metal binding

Mammalian metallothionein is a low molecular weight protein with two metal-binding domains. To determine if metal binding in one domain affects binding in the other, we prepared peptides corresponding to the regions that enfold the two metal-thiolate clusters. Metal reconstitution studies of these peptides revealed stoichiometries of metal binding similar to those observed within the intact molecule. Thus, the alpha domain coordinates 4 Cd(II), 6 Cu(I), or 6 Ag(I) ions regardless of whether the domain is part of the total protein or is studied as a separate peptide. Likewise, the beta domain binds 3 Cd(II), 6 Cu(I), or 6 Ag(I) ions in both the intact protein and as a separate peptide. If cluster B in intact metallothionein is preformed with Cu(I) or Ag(I), cluster A saturates with either 4 mol eq of Cd(II) or 6 mol eq of Ag(I). Similarly, preformation of the A cluster with Cd(II) does not affect the binding of 6 Cu(I) ions in the B cluster. Therefore, the metal-dependent folding of the protein to create one cluster occurs independent of constraints or influences from the other domain. Formation of the protein with a tetrahedrally coordinated metal in one cluster and a trigonally coordinated metal in the other center is possible.     

Reactivity of Cd7-metallothionein with Cu(II) ions: evidence for a cooperative formation of Cd3,Cu(I)5-metallothionein

Reaction of Cd7-metallothionein-2 (MT) with Cu(II) ions has been studied by a variety of spectroscopic techniques including UV-absorption, circular dichroism (CD) and luminescence spectroscopy. The addition of up to 5 Cu(II) equivalents to Cd7-MT resulted in a cooperative formation of the monomeric Cd3,Cu5-MT form, as revealed by the analytical data and the presence of isosbestic or isodichroic points in the respective UV and CD spectra. The presence of Cu(I) luminescence and the absence of Cu(II) EPR signal indicated that copper is bound in the Cu(I) oxidation state, i.e., Cd3,Cu(I)5-MT. Consequently, the reduction of Cu(II) ions is accompanied by the oxidation of thiolate ligands of the protein. The absorption features and the luminescence data at 77 K are consistent with the presence of an air-stable Cu(I)-cluster in Cd3,Cu(I)5-MT. The participation of other ligands, besides cysteine thiolates, in metal coordination cannot be ruled out. With more than 5 Cu(II) equivalents added a mixture of unstable MT metalloforms were formed. The concomitant reduction and binding of copper ions by metallated MT represent a new aspect of the MT structure.     

Cu(I) binding properties of a designed metalloprotein

The Cu(I) binding properties of the designed peptide C16C19-GGY are reported. This peptide was designed to form an α-helical coiled-coil but modified to incorporate a Cys-X-X-Cys metal-binding motif along its hydrophobic face. Absorption, emission, electrospray ionization mass spectrometry (ESI-MS), and circular dichroism (CD) experiments show that a 1:1 Cu-peptide complex is formed when Cu(I) is initially added to a solution of the monomeric peptide. This is consistent with our earlier study in which the emissive 1:1 complex was shown to exist as a peptide tetramer containing a tetranuclear copper cluster Kharenko et al. (2005) [11]. The presence of the tetranuclear copper center is now confirmed by ESI-MS which along with UV data show that this cluster is formed in a cooperative manner. However, spectroscopic titrations show that continued addition of Cu(I) results in the occupation of a second, lower affinity metal-binding site in the metallopeptide. This occupancy does not significantly affect the conformation of the metallopeptide but does result in a quenching of the 600 nm emission. It was further found that the exogenous reductant tris(2-carboxyethyl)phosphine (TCEP) can competitively inhibit the binding of Cu(I) to the low affinity site of the peptide, but does not interact with Cu(I) clusters.     

Functional differentiation in the mammalian metallothionein gene family: metal binding features of mouse MT4 and comparison with its paralog MT1

This paper reports on the characterization of the metal binding abilities of mammalian MT4 and their comparison with those of the well known MT1. Heterologous Escherichia coli expression in cultures supplemented with zinc, cadmium, or copper was achieved for MT4 and for its separate alphaMT4 and betaMT4 domains as well as for MT1 and its alphaMT1 domain in cadmium-enriched medium. The in vivo conformed metal complexes and the in vitro substituted zinc/cadmium and zinc/copper MT4 aggregates were characterized. Biosynthesis of MT4 and betaMT4 in Cd(II)-supplemented medium revealed that these peptides failed to form the same homometallic species as MT1, thus appearing less effective for cadmium coordination. Conversely, the entire MT4 and both of its domains showed better Cu(I) binding properties than MT1, affording Cu(10)-MT4, Cu(5)-alphaMT4 and Cu(7)-betaMT4, stoichiometries that make the domain dependence toward Cu(I) clear. Overall results allow consideration of MT4 as a novel copper-thionein, made up of two copper-thionein domains, the first of this class reported in mammals, and by extension in vertebrates. Furthermore, the in silico protein sequence analyses corroborated the copper-thionein nature of the MT4 peptides. As a consequence, there is the suggestion of a possible physiological role played by MT4 related with copper requirements in epithelial differentiating tissues, where MT4 is expressed.     

Cooperative cluster formation in metallothionein

An ion-exchange chromatography procedure was used to resolve apometallothionein from the metallo- form in a study of metal-thiolate cluster formation. Chromatography of metallothionein reconstituted with Cd(II), Zn(II), or Cu(I) at neutral pH on carboxymethyl-cellulose led to removal of apoprotein from a solution without effect on recovery of the metalloprotein. Analysis of the effluent revealed apparent cooperative binding of these metal ions to the protein. Addition of 1-4 mol eq Cd(II) ions led to the recovery of metallothionein with around 4 mol eq Cd bound. The yield of this form increased with increasing starting metal ion equivalency. These results were obtained with two different ion-exchange resins. The cooperativity of binding was not total, but was initially confined to the carboxyl-terminal alpha domain. The results of metal and protein yields are inconsistent with random, noninteractive binding. Similar data were obtained with Zn(II) and Cu(I) ions although Cu(I) exhibited initial cooperative binding within the amino-terminal beta domain with over 5 mol eq Cu(I) bound.     

Study of the biosorption of different heavy metal ions onto Kraft lignin

The ability of Kraft lignin, a waste product of paper production, for removing copper, zinc, cadmium and chromium ions from water was investigated. The studies were conducted by a batch method to determine equilibrium parameters. The adsorbed heavy metal ions followed the order: Cr(VI) ? Cd(II) > Cu(II) > Zn(II). The influence of other ions such as Ni(II), Cd(II) and Pb(II), on Cu(II) adsorption by Kraft lignin was evaluated. Obtained results support the idea that adsorption behaviour of heavy metal ions have to be perceived from the aspect of possible influence of interfering ion species.     

X-ray absorption studies of the copper-beta domain of rat liver metallothionein

Rat liver metallothionein contains two domains, each of which enfolds a separate metal-thiolate cluster. The binding stoichiometry of these clusters depends on the particular metal ion bound. In the aminoterminal beta domain the cluster can accommodate either three Cd(II) ions or six Cu(I) ions. The Cd ions are known to be coordinated in a tetrahedral geometry. In order to better understand the binding of Cu ions in this domain, the Cu-beta domain fragment of metallothionein was prepared and investigated by x-ray absorption spectroscopy. Quantitative analysis of the EXAFS data indicates copper-sulfur distances of 2.25 +/- 0.03 A. The EXAFS amplitudes and distance results are most consistent with trigonal coordination. A trigonal biprism is proposed for the Cu6Cys9 complex in which Cu occupies each vertex and cysteinyl sulfur bridges at each of the nine edges.     

Chelating ability of proctolin tetrazole analogue

The aim of the investigation was to establish the chelating ability of a new proctolin analogue of the sequence Arg-Tyr-LeuPsi[CN(4)]Ala-Thr towards copper(II) ions. The insertion of the tetrazole moiety into the peptide sequence has considerably changed the coordination ability of the ligand. Potentiometric and spectroscopic (UV-Vis, CD, EPR) results indicate that the incorporation of 1,5-disubstituted tetrazole ring favours the formation of a stable complex form of CuH(-1)L. This 4N coordination type complex is the dominant species in the physiological pH range. The tetrazole moiety provides one of these nitrogens. The data indicate that Cu(II) ions are strongly trapped inside the peptide backbone. These findings suggest that Cu(II) can hold peptide chains in a bent conformation. This bent conformation may be essential for bioactivity of the tetrazole peptides.     

X-ray absorption investigation of a unique protein domain able to bind both copper(I) and copper(II) at adjacent sites of the N-terminus of Haemophilus ducreyi Cu,Zn superoxide dismutase

The N-terminal metal binding extension of the Cu,Zn superoxide dismutase from Haemophilus ducreyi is constituted by a histidine-rich region followed by a methione-rich sequence which shows high similarity with protein motifs involved in the binding of Cu(I). X-ray absorption spectroscopy experiments selectively carried out with peptides corresponding to the two metal binding regions indicate that both sequences can bind either Cu(II) or Cu(I). However, competition experiments demonstrate that Cu(II) is preferred by histidine residues belonging to the first half of the motif, while the methionine-rich region preferentially binds Cu(I) via the interaction with three methionine sulfur atoms. Moreover, we have observed that the rate of copper transfer from the peptides to the active site of a copper-free form of the Cu,Zn superoxide dismutase mutant lacking the N-terminal extension depends on the copper oxidation state and on the residues involved in metal binding, histidine residues being critically important for the efficient transfer. Differences in the enzyme reactivation rates in the presence of mixtures of the two peptides when compared to those obtained with the single peptides suggest that the two halves of the N-terminal domain functionally interact during the process of copper transfer, possibly through subtle modifications of the copper coordination environment.     

Metal thiolate coordination in the E7 proteins of human papilloma virus 16 and cottontail rabbit papilloma virus as expressed in Escherichia coli.

The oncogenic E7 proteins of human papilloma virus (HPV 16) and of cottontail rabbit papilloma virus (CRPV) have been purified from an expression system in Escherichia coli. The proteins as purified from E. coli contain one tightly bound Zn(II) ion per molecule. The metal site shows facile exchange with either Cd(II) or Cu(I). The HPV 16 E7 maximally bound one Cd(II) or two Cu(I) ions, while the CRPV E7 bound two Cd(II) or three Cu(I) ions. The Cd(II) and Cu(I) E7 molecules exhibited optical transitions in the ultraviolet suggestive of metal:thiolate coordination. E7 proteins from HPV 16 and CRPV contain 7 and 8 cysteines/molecule, respectively. Reaction of the E7 proteins with the sulfhydryl reagent, dithiodipyridine, revealed that all the cysteinyl sulfurs are present in the reduced thiol state. Cu(I)-E7 molecules are luminescent with maximal emission at 570 nm. The observed emission at room temperature is indicative of metal coordination within a compact protein environment shielded from solvent interactions. The emission maxima occurs at the same wavelength (570 nm) as Cu(I)-cysteinyl sulfur clusters in Cu(I)-metallothioneins. The single Zn(II) atom in each protein can be removed from E7 in the presence of EDTA. The resulting apoE7 molecules remain soluble and can be partially reconstituted with Cd(II) to regain the ultraviolet charge transfer transitions.     

Yeast metallothionein. Sequence and metal-binding properties

The protein product of the CUP1 locus in Cu-resistant Saccharomyces cerevisiae has been purified and characterized. The protein was found to lack the first 8 amino acids predicted by the nucleotide sequence of the gene. The residues removed from the amino-terminal region include 5 hydrophobic residues, two of which are aromatic. The unique amino terminus starting at Gln9 of the putative DNA translation product was observed for metallothionein purified in the presence of various protease inhibitors or from a pep4 mutant yeast strain deficient in vacuolar proteases. The remainder of the primary structure of the protein is equivalent to the decoded DNA sequence, so yeast metallothionein is a 53-residue polypeptide of molecular weight 5655. The isolated protein contained 8 copper ions ligated by 12 cysteines/molecule. Reconstitution studies of the apo-molecule revealed that 8 mol eq of Cu(I) conferred maximal stability against proteolysis and depleted the zinc content of zinc-saturated metallothionein. These assays suggested that the protein has 8 binding sites for Cu(I). Ag(I) ions bound to the protein with the same stoichiometry. Yeast metallothionein was also observed to coordinate Cd(II) and Zn(II) ions in vitro. In studies of direct binding, protection against proteolysis, and metal ion exchange, these divalent ions were found to associate with the protein with a maximal stoichiometry of 4 ions/molecule. Yeast metallothionein thus exhibits two distinct binding configurations for Cu(I) and Cd(II) as does the mammalian protein.     

Cadmium accumulation and interactions with zinc, copper, and manganese, analysed by ICP-MS in a long-term Caco-2 TC7 cell model

The influence of long-term exposure to cadmium (Cd) on essential minerals was investigated using a Caco-2 TC7 cells and a multi-analytical tool: microwave digestion and inductively coupled plasma mass spectrometry. Intracellular levels, effects on cadmium accumulation, distribution, and reference concentration ranges of the following elements were determined: Na, Mg, Ca, Cr, Fe, Mn, Co, Ni, Cu, Zn, Mo, and Cd. Results showed that Caco-2 TC7 cells incubated long-term with cadmium concentrations ranging from 0 to 10 μmol Cd/l for 5 weeks exhibited a significant increase in cadmium accumulation. Furthermore, this accumulation was more marked in cells exposed long-term to cadmium compared with controls, and that this exposure resulted in a significant accumulation of copper and zinc but not of the other elements measured. Interactions of Cd with three elements: zinc, copper, and manganese were particularly studied. Exposed to 30 μmol/l of the element, manganese showed the highest inhibition and copper the lowest on cadmium intracellular accumulation but Zn, Cu, and Mn behave differently in terms of their mutual competition with Cd. Indeed, increasing cadmium in the culture medium resulted in a gradual and significant increase in the accumulation of zinc. There was a significant decrease in manganese from 5 μmol Cd/l exposure, and no variation was observed with copper.     

A solution study of the interaction of the Cu(II) ions with HisGlyGlyTrp tetrapeptide and its evaluation as superoxide dismutase mimetic complex

The superoxide anion radical is a highly reactive toxic species produced during the metabolic processes. A number of copper (II) complexes with amino acids and peptides are known to show superoxide dismutase (SOD) like activity. The design and application of synthetic low molecular weight metal complexes as SOD mimics have received considerable attention during the last decade. A variety of di- and tri-peptides containing histidyl residue in different positions have been employed to bind Cu(II) and to show the activity. But reports on Cu(II) complex with tetra-peptide having histidine amino acid in this regard are limited. As the HGGGW peptide having His at its N-terminal is reported to be a potential moiety for Cu(2+) binding, in the present work the synthesis of HisGlyGlyTrp peptide and its complexation with copper (II) ions has been reported. The interaction of synthesized peptide with Cu(II) was studied by electron spray ionization-mass spectrometer (ESI-MS) and UV-Vis spectroscopic methods. The species distribution was studied by combined spectrophotometric and potentiometric methods. The studies were performed at 25 ± 0.1 °C with constant ionic strength (μ = 0.1 M NaNO(3)) in aqueous solution using Bjerrum-Calvin's pH-titration technique as adopted by Irving and Rossotti for binary systems. The solution studies suggested that the pH of the medium play important role in the different species formation of the copper complexes. Species distribution curves indicate that Cu complexation takes place at all physiological pH values from 3-11. The resultant copper (II) peptide complex at physiological pH was tested for superoxide dismutase activity using standard NBT method. The complex has SOD activity with the IC(50) value of 1.32 μM.     

Copper(II) interaction with tetrapeptides containing proline and phenylalanine: A potentiometric and spectrophotometric study

The synthesis of four tetrapeptides, L-Phe-L-Pro-Gly-Gly, Gly-L-Pro-L-Phe-Gly, Gly-L-Pro-D-Phe-Gly, and Gly-L-Pro-Gly-L-Phe is described. The hydrogen ion and copper(II) complex formation constants have been measured at 25°C and I = 0.10 mol dm^?3 (KNO₃). Circular dichroism spectra have been recorded for copper(II)-peptide mixtures as a function of pH. The potentiometric and Spectrophotometric studies have been combined to ascertain the complex species over a broad pH range. The results obtained support the earlier suggestion on the specific role of a proline residue as a “break-point” in copper complex formation with peptides: the insertion of a proline residue into the second position of a tetrapeptide sequence leads to a novel coordination mode in Cu(II)-tetrapeptide systems.     

Ab initio modelling of the structure and redox behaviour of copper(I) bound to a His–His model peptide: relevance to the β-amyloid peptide of Alzheimer’s disease

A contributing factor to the pathology of Alzheimer's disease is the generation of reactive oxygen species, most probably a consequence of the beta-amyloid (Abeta) peptide coordinating copper ions. Experimental and theoretical results indicate that His13 and His14 are the two most firmly established ligands in the coordination sphere of Cu(II) bound to Abeta. Abeta1-42 is known to reduce Cu(II) to Cu(I). The Abeta-Cu(II) complex has been shown to catalytically generate H(2)O(2) from reducing agents and O(2). Cu(II) in the presence of Abeta has been reported to have a formal reduction potential of +0.72-0.77 V (vs. the standard hydrogen electrode). Quantum chemical calculations using the B3LYP hybrid density functional method with the 6-31G(d) basis set were performed to model the reduction of previously studied Cu(II) complexes representing the His13-His14 portion of Abeta (Raffa et al. in J. Biol. Inorg. Chem. 10:887-902, 2005). The effects of solvation were accommodated using the CPCM method. The most stable complex between Cu(I) and the model compound, 3-(5-imidazolyl)propionylhistamine (1) involves tricoordinated Cu(I) in a distorted-T geometry, with the Npi of both imidazoles as well as the oxygen of the backbone carbonyl bound to copper. This model would be the most likely representation of a Cu(I) binding site for a His-His peptide in aqueous solution. A variety of possible redox processes are discussed.     

Cadmium-Sulfide Crystallites in Cd-(gammaEC)(n)G Peptide Complexes from Tomato

Hydroponically grown tomato plants (Lycopersicon esculentum P. Mill. cv Golden Boy) exposed to 100 micromolar cadmium sulfate produced metal-(γEC)_nG peptide complexes containing acid-labile sulfur. The properties of the complexes resemble those of the cadmium-(γEC)_nG peptide complexes from Schizosaccharomyces pombe and Candida glabrata known to contain a cadmium sulfide crystallite core. The crystallite is stabilized by a sheath of peptides of general structure (γGlu-Cys)_n-Gly. The cadmium-peptide complexes of tomato contained predominantly peptides of n₃, n₄, and n₅. spectroscopic analyses indicated that the tomato cadmium-sulfide-peptide complex contained CdS crystallite core particles smaller than 2.0 nanometers in diameter.     

A Cu(I)-sensing ArsR family metal sensor protein with a relaxed metal selectivity profile

ArsR (or ArsR/SmtB) family metalloregulatory homodimeric repressors collectively respond to a wide range of metal ion inducers in regulating homeostasis and resistance of essential and nonessential metal ions in bacteria. BxmR from the cyanobacterium Osciliatoria brevis is the first characterized ArsR protein that senses both Cu (I)/Ag (I) and divalent metals Zn (II)/Cd (II) in cells by regulating the expression of a P-type ATPase efflux pump (Bxa1) and an intracellular metallothionein (BmtA). We show here that both pairs of predicted alpha3N and alpha5 sites bind metal ions, but with distinct physicochemical and functional metal specificities. Inactivation of the thiophilic alpha3N site via mutation (C77S) abolishes regulation by both Cd (II) and Cu (I), while Zn (II) remains a potent allosteric negative effector of operator/promoter binding (Delta G c >or= +3.2 kcal mol (-1)). In contrast, alpha5 site mutant retains regulation by all four metal ions, albeit with a smaller coupling free energy (Delta G c approximately +1.7 (+/-0.1) kcal mol (-1)). Unlike the other metals ions, the BxmR dimer binds 4 mol equiv of Cu (I) to form an alpha3N binuclear Cu (I) 2S 4 cluster by X-ray absorption spectroscopy. BxmR is thus distinguishable from other closely related ArsR family sensors, in having evolved a metalloregulatory alpha3N site that can adopt an expanded range of coordination chemistries while maintaining redundancy in the response to Zn (II). The evolutionary implications of these findings for the ArsR metal sensor family are discussed.