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.

Drosophila MTN: a metazoan copper-thionein related to fungal forms.

Two Drosophila metallothioneins (MT) have been reported: MTN, a 40 residue peptide including 10 Cys, and MTO, a 43 residue peptide including 12 Cys. However, neither functional nor evolutionary analyses for either of the Drosophila MT are available. Here, heterologous expression of Mtn in Escherichia coli is reported. The metal binding abilities of the Cu- and Zn-MTN complexes conformed in vivo, as well as the features of the Cd- and Cu-aggregates produced by metal replacement in vitro, have been determined by atomic emission spectrometry, circular dichroism and electrospray ionization mass spectrometry. Primary structure relationships with other MT have been examined. The results indicate a close resemblance of MTN to fungal copper-thioneins.

In vivo copper- and cadmium-binding ability of mammalian metallothionein beta domain.

The beta domain of mouse metallothionein 1 (betaMT) was synthesized in Escherichia coli cells grown in the presence of copper or cadmium. Homogenous preparations of Cu-betaMT and Cd-betaMT were used to characterize the corresponding in vivo-conformed metal-clusters, and to compare them with the species obtained in vitro by metal replacement to a canonical Zn3-betaMT structure. The copper-containing betaMT clusters formed inside the cells were very stable. In contrast, the nascent beta peptide, although it showed cadmium binding ability, produced a highly unstable species, whose stoichiometry depended upon culture conditions. The absence of betaMT protein in E. coli protease-proficient hosts grown in cadmium-supplemented medium pointed to drastic proteolysis of a poorly folded beta peptide, somehow enhanced by the presence of cadmium. Possible functional and evolutionary implications of the bioactivity of mammalian betaMT in the presence of monovalent and divalent metal ions are discussed.

Replacement of terminal cysteine with histidine in the metallothionein alpha and beta domains maintains its binding capacity.

To generate novel forms of metal-binding proteins, six mutant mouse metallothionein (MT) 1 fragments, in which a terminal cysteine residue was replaced by histidine, were expressed in Escherichia coli. The spectroscopic and analytical results showed that the alphaMT (C33H, C36H, C41H, C57H) and betaMT (C5H, C13H) mutant forms bound 4 and 3 Zn(II) atoms per molecule of protein to the nearest integer, even though in C41H and C5H, species of lower stoichiometry were also detected. In Cd(II) titrations, all the Zn(II) ions bound to the mutant proteins were displaced from the binding sites, giving rise to Cd-mutated MT forms with 4 and 3 Cd(II), respectively. However, although Cys-to-His substitutions maintained the binding capacity of the MT fragments, they caused structural changes with respect to the wild-type proteins. While C13H, C36H and C57H seem to contain Zn(II)-aggregates that are closely related to those of the wild-type proteins, only C41H and C57H gave rise to Cd(II)-aggregates similar to those of Cd4-alphaMT, where the His residue plays the role of the substituted Cys. Despite the structural implications of the Cys-to-His replacement, the dissociation constants showed no major decrease in the Cd-binding affinity in any of the mutants assayed compared with the wild-type.

Binding of excess cadmium(II) to Cd7-metallothionein from recombinant mouse Zn7-metallothionein 1. UV-VIS absorption and circular dichroism studies and theoretical location approach by surface accessibility analysis.

A mouse metallotbionein (MT) 1 expression system has been constructed that renders recombinant MT as a high purity Zn-coordinated protein. Spectral changes in absorption and circular dichroism following the addition of up to 7 mol equivalents of Cd2+ to recombinant Zn7-MT showed that it behaves like the native protein. Exposure of Cd7-MT to Cd2+ resulted in further binding of these ions to the protein, although saturation was not achieved on the addition of up to 22 mol equivalents of Cd2+ to Zn7-MT. Spectral data are compatible with a model in which the first four additional Cd2+ ions are bound to Cd7-MT via sulfur atoms, and indicate that no further thiol groups are involved in the binding of the excess Cd(II) over 11. Cd2+ ions bound in excess to Cd7-MT appear to have lower binding constants as exposure of Cdn-MT (n > 7) species to Cbelex-100 retrieved Cd7-MT. Based on the X-ray data, the accessible surface areas of sulfur atoms in Cd5,Zn2-MT 2 were calculated. This led us to propose that the coordination of the first three additional Cd(II) ions to Cd7-MT proceeds by means of S-Met1-O-Met1, S-Cys7-S-Cys13 and S-Cys5-S-Cys26 pairs. Finally, comparison of the behavior of the entire MT with that of the recombinant alpha MT and beta MT subunits indicates that mutual influences may not be negligible.

Recombinant synthesis of mouse Zn3-beta and Zn4-alpha metallothionein 1 domains and characterization of their cadmium(II) binding capacity.

Genetic engineering, coupled with spectroscopic analyses, has enabled the metal binding properties of the alpha and beta subunits of mouse metallothionein 1 (MT) to be characterized. A heterologous expression system in E.coli has led to high yields of their pure zinc-complexed forms. The cadmium(II) binding properties of recombinant Zn4-alpha MT and Zn3-beta MT have been studied by electronic absorption and circular dichroism. The former binds Cd(II) identically to alpha fragments obtained from mammalian organs, showing that the recombinant polypeptide behaves like the native protein. Titration of Zn3-beta MT with CdCl2 results in the formation of Cd3-beta MT. The addition of excess Cd(II) leads to Cd4-beta MT which, with the extra loading of Cd(II), unravels to give rise isodichroically to Cd9-beta MT. The effect of cadmium-displaced Zn(II) ions and excess Cd(II) above the full metal occupancy of three has been studied using Chelex-100. The Cd3-beta MT species is stable in the presence of this strong metal-chelating agent.