Structure-reactivity relationships among metallothionein three-metal domains: role of non-cysteine amino acid residues in lobster metallothionein and human metallothionein-3.

Metallothionein (MT) domains of different origins, exhibiting distinct, highly conserved cysteine positions, show differences in metal-cysteine coordination and reactivity. Lobster MT, which includes two Cd3S9 beta domains, was chosen as a basic model to study the structure-function relationship among the clusters. The possible influence of (1) the position of the cysteine residues and (2) the steric and electrostatic effects of neighboring amino acids on the folding and stability of MT clusters have been examined with the native lobster beta C and beta N domains, each having nine cysteines and binding three M2+ ions, and a modified domain beta C-->N, in which the cysteines of the C-terminal domain are relocated so they are spaced as in the N-terminal domain. Each has been synthesized and characterized by UV, CD, 113Cd NMR, and 1H NMR spectroscopies. The synthetic native domains (Cd3 beta C and Cd3 beta N) displayed spectroscopic properties, metal-binding affinities, and kinetic reactivity similar to those of the holo protein. In contrast, the modified Cd3 beta C-->N domain was unusually reactive and, in the presence of Chelex, a metal-ion chelating resin, was converted to a Cd5(beta C-->N)2 dimer. These differences in structure and reactivity demonstrate that the requirements for formation of a stable type-B, Cd3S9, beta cluster are more stringent than simply the sequential positions of the cysteines along the peptide chain and include specific interactions with neighboring amino acids. Molecular mechanics calculations suggest that changes of even a single amino acid in lobster Cd3 beta N toward lobster Cd3 beta C-->N or in mammalian MT1 or MT2 toward Cd3 beta-MT3 (GIF) can destabilize their structures.

The requirements for stable metallothionein clusters examined using synthetic lobster domains.

Metallothioneins (MTs) are small, cysteine-rich proteins which detoxify xenobiotic metals such as cadmium (Cd) and mercury (Hg). In crustaceans and mammals they consist of two independent domains which are folded around metal-thiolate clusters. MT clusters of different origins, exhibiting distinct, highly conserved cysteine positions on their sequences, show differences in metal-cysteine coordination and reactivity. Lobster-MT, containing two Cd3 beta domains, is an important model for structure-function relationships among the clusters. The influence of (1) the position of the cysteine residues and (2) steric and electrostatic effects of neighboring amino acids on the folding and stability of MT cluster were investigated. Thus, the native lobster beta C and beta N domains (each having nine cysteines and binding three M2+ ions) and a modified domain Cd3 beta C-->N, in which the cysteines of the C-terminal domain were relocated to match the positions of those in the N-terminal domain, were chemically prepared and characterized. The synthetic native domains (Cd3 beta C and Cd3 beta N) were found to exhibit spectroscopic properties, metal-binding affinities and kinetic reactivity similar to the holo-protein. However, the modified Cd3 beta C-->N domain was unusually reactive and in the presence of Chelex, metal chelation resin, aggregated to a Cd5(beta C-->N)2 dimer, which exhibited unusual structure as observed by its 113Cd-nuclear magnetic resonance. These differences in structure and reactivity demonstrated that the requirements for formation of a stable Cd3S9 beta-cluster are more stringent than simply the sequential positions of the cysteines along the peptide chain and must include interactions involving neighboring, noncysteine amino acids.

Characterization of calf liver Cu,Zn-metallothionein: naturally variable Cu and Zn stoichiometries.

Cu,Zn-metallothioneins were purified from bovine calf liver in order to examine the stoichiometry of metal binding to the protein. Copper and zinc analyses were carried out by atomic absorption spectrophotometry. Consistent quantitative thiolate analyses were obtained spectrophotometrically with Ellman's reagent and amperometrically with phenylmercuric acetate. These were used to define protein concentration. A complementary method to assess the sum of the thiol and Cu(I) content of metallothionein involved titration of the reducing equivalents of the protein with ferricyanide. The stoichiometry of reaction was consistent with the oxidation of all the sulphydryl groups to disulphides and all of the bound Cu from the cuprous to the cupric oxidation state. Accordingly to these methods, total numbers of zinc plus copper ions bound to metallothionein isolated from a number of calf livers centred on about 7, 10-12, or 15 g-atoms of metal per mol of protein. The reactivity of ferricyanide and 4,7-phenylsulphonyl-2,9-dimethyl-1, 10-phenanthroline (BCS) with Cu,Zn-metallothioneins of various metal ratios was assessed. Zinc metallothionein reacted almost entirely in two slow steps with ferricyanide. As the Cu content of the protein increased, the fraction of reaction occurring in the time of mixing increased in parallel. BCS was able to remove 70-80% of metallothionein-bound Cu as Cu(I). The rest was resistant to reaction.

Sequential proton resonance assignments and metal cluster topology of lobster metallothionein-1.

NMR studies of 111Cd6-MT 1 from lobster have been conducted to determine coordination structure of Cd-thiolate binding in the protein. Sequential proton resonance assignments were made using standard two-dimensional 1H NMR methods. Two-dimensional 1H-111Cd HMQC experiments were then carried out to determine the cadmium-cysteine connectivities in the protein. With this information, it was established that the six Cd ions exist in two different Cd3S9 clusters, each involving three bridging and six terminal thiolate ligands. Sequential cysteines in the sequence provide the sulfhydryl ligands for each cluster and do not overlap, as has been found in mammalian metallothionein. Comparison of the N-terminal, Cd3S9 B-type cluster of lobster MT 1 with the Cd3S9 cluster from rabbit MT 2 shows that while eight of the nine cysteine residues occupy homologous positions in their sequences, three of the 12 Cd-thiolate connectivities are different. Similarly, the C-terminal B-cluster of lobster MT 1 was compared with the Cd4S11 cluster of mammalian MT 2, excluding the two terminal cysteine sulfhydryl groups that convert this cluster from A- to B-type. As above, eight of nine cysteine positions are identical, yet five of 12 Cd-sulfhydryl connections are different. These differences are expanded when the role of each cysteine as bridging or terminal ligands in the clusters is considered.