Products of metal exchange reactions of metallothionein

Hepatic metallothionein (MT) isolated from Cd-exposed animals always contains Zn (2-3 mol/mol of protein) in addition to Cd (4-5 mol/mol of protein), and the two metals are distributed in a nonuniform, but reproducible, manner among the seven binding sites of the protein's two metal-thiolate clusters. Different methodologies of preparing rabbit liver Cd, Zn-MT in vitro were investigated to provide insight into why such a distinct mixture of mixed-metal clusters is produced in vivo and by what mechanism they form. 113Cd NMR spectra of the products of stepwise displacement of Zn2+ from Zn7-MT by 113Cd2+ show that Cd binding to the clusters is not cooperative (i.e., clusters containing exclusively Cd are not formed in preference to mixed-metal Cd, Zn clusters), there is no selective occupancy of one cluster before the other, and many clusters are produced with a nonnative metal distribution indicating that this pathway is probably not followed in vivo. In contrast, the surprising discovery was made that the native cluster compositions and their relative concentrations could be reproduced exactly by simply mixing together the appropriate amounts of Cd7-MT and Zn7-MT and allowing intermolecular metal exchange to occur. This heretofore unknown metal interchange reaction occurs readily, and the driving force appears to be the relative thermodynamic instability of three-metal clusters containing Cd. With this new insight into how Cd,Zn-MT is likely to be formed in vivo we are able for the first time to postulate rational explanations for previous observations regarding the response of hepatic Zn and metallothionein levels to Cd administration.     

113Cd NMR studies on metal-thiolate cluster formation in rabbit Cd(II)-metallothionein: evidence for a pH dependence

The formation of two metal-thiolate clusters in rabbit liver metallothionein 2 (MT) has been examined by 113Cd NMR spectroscopy at pH 7.2 and 8.6. The chemical shifts of the 113Cd resonances developing in the course of apoMT titration with 113Cd(II) ions have been compared with those of fully metal occupied 113Cd7-MT. At pH 7.2 and at low metal occupancy (less than 4), a cooperative formation of the four-metal cluster (cluster A) occurs. Further addition of 113Cd(II) ions generates all the resonances of the three-metal cluster (cluster B) in succession, suggesting cooperative metal binding to this cluster also. In contrast, similar studies at pH 8.6, at low metal occupancy (less than 4), reveal a broad NMR signal centered at 688 ppm. This observation indicates that an entirely different protein structure exists. When exactly 4 equiv of 113Cd(II) are bound to apoMT, the 113Cd NMR spectrum changes to the characteristic spectrum of cluster A. Further addition of 113Cd(II) ions again leads to the cooperative formation of cluster B. These results stress the determining role of the cluster A domain on the overall protein fold. The observed pH dependence of the cluster formation in MT can be rationalized by the different degree of deprotonation of the cysteine residues (pKa approximately 8.9), i.e., by the difference in the Gibbs free energy required to bind Cd(II) ions to the thiolate ligands at both pH values.     

Comparative 113Cd-n.m.r. studies on rabbit 113Cd7-, (Zn1,Cd6)- and partially metal-depleted 113Cd6-metallothionein-2a.

Rabbit 113Cd7-metallothionein-2a (MT) contains two metal-thiolate clusters of three (cluster B) and four (cluster A) metal ions. The 113Cd-n.m.r. spectrum of 113Cd6-MT, isolated from 113Cd7-MT upon treatment with EDTA, is similar to that of 113Cd7-MT, but the cluster B resonances are lower in intensity, suggesting its co-operative metal depletion. (Zn1,113Cd6)-MT, formed upon addition of the Zn(II) ions to 113Cd6-MT, shows 113Cd-n.m.r. features characteristic of cluster B populations containing both Cd(II) and Zn(II) ions. The overall intensity gain of the mixed cluster B resonances per Cd as to those in 113Cd6- and 113Cd7-MT suggests a stabilization effect of the bound Zn(II) ions upon the previously established intramolecular 113Cd exchange within this cluster.     

Metal selectivity of clusters in rabbit liver metallothionein.

In mammalian metallothioneins the metals are organized in two adamantane-type clusters with three and four metal ions which are tetrahedrally coordinated by thiolate ligands. The metal selectivity of the metal-thiolate clusters in rabbit liver metallothionein has been studied by offering two ions, i.e. Co(II)/Cd(II), Zn(II)/Cd(II) or Co(II)/Zn(II), to the metal-free protein. The heterogeneous metal complexes thus formed were characterized by electronic absorption, magnetic circular dichroism. 113Cd-NMR and EPR spectroscopy. In the case of Co/Cd-metallothionein, homometallic cluster occupation occurs, with the Cd(II) ions bound exclusively to the four-metal cluster. In contrast, heterometallic clusters were formed for both Zn/Cd- and Co/Zn-metallothionein. Based on evidence from corresponding inorganic structures of adamantane metal-thiolate cages, it is suggested that the major factor governing the cluster type is the protein structure perturbation due to the cluster volume variations. Thus, while metal thiolate affinities are important in the folding process, size-match selectivity is the dominant factor in the metal-loaded protein.     

Application of 113Cd NMR to metallothioneins

Metallothioneins constitute a class of ubiquitously occurring low molecular mass proteins (6–7 kDa) possessing two cysteine thiolate-based metal clusters usually formed by the preferential binding of d10 metal ions such as Zn II and Cd II. The three-dimensional solution structure of mammalian proteins has been determined by two-dimensional NMR spectroscopy of 113Cd7-metallothionein. The structure shows two protein domains encompassing the M3(CysS)9- and M4(CysS)11-cluster with each metal ion being tetrahedrally coordinated by thiolate ligands. The application of 113Cd NMR proved to be indispensable in the structural studies of metallothioneins. Thus, both homonuclear 113Cd decoupling studies and 113Cd-113Cd COSY of 113Cd7-metallothionein established the existence of two metal-thiolate clusters in this protein. The identification of sequence specific cysteine-cadmium coordinative bonds came from heteronuclear 113Cd-1H COSY experiments. Independently, the 113Cd NMR characterization of the intermediate metal-protein complexes, leading to the cluster structure in 113Cd7- metallothionein, revealed a stepwise cluster formation process with the Cd4(CysS)11-cluster being formed first. The recent demonstration of a Karplus-like dependence between the heteronuclear 3J(113 Cd,1 H) coupling constants for the cysteine C protons and the H-C: -S -Cd dihedral angles should allow to derive the geometry of the Cd-(S-Cys) centers in various metallothioneins and related metalloproteins. A possible application of 113Cd NMR to the study of metallothioneins in the environment is discussed.     

Cadmium binding and metal cluster formation in metallothionein: a differential modification study

Mammalian metallothioneins (MT) contain 20 Cys in a total of 61 amino acid residues and bind 7 Cd and/or Zn ions. The metal is localized in two clusters made up of three and four metal-thiolate complexes in the NH2- and COOH-terminal half of the chain, respectively [Otvos, J.D., & Armitage, I. M. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 7094-7098]. The formation of these oligonuclear complexes designated as Cd4 and Cd3 clusters has now been monitored in MT reconstituted with varying amounts of Cd by using differential chemical modification of Cys with [14C]iodoacetamide. At ratios below 2-3 mol of Cd/mol of MT bound, no differential protection of Cys by the metal, and hence no preferred binding, is detectable. At Cd-to-protein ratios between 3 and 5 mol of Cd/mol of MT, the modification profiles reveal preferred and cooperative binding in the COOH-terminal half of the chain, indicating formation of the Cd4 cluster. At still higher ratios, formation of the Cd3 cluster is initiated in the NH2-terminal section of the polypeptide chain. Comparison of the differential modification data of Cd6-MT and Cd7-MT suggests that the last Cd to be bound is coordinated to Cys ligands located mainly between positions 20 and 30 of the sequence. The extent of labeling of the different Cys in Cd7-MT indicates that the ligands of the Cd3 cluster are 3 times as accessible to iodoacetamide than those of the Cd4 cluster, suggesting a greater thermodynamic or kinetic stability of the latter.     

113Cd NMR studies of reconstituted seven-cadmium metallothionein: evidence for structural flexibility

A reproducible method for the reconstitution of rabbit liver metallothionein (MT) containing seven cadmium atoms per mole of protein is described. This protein was studied in detail by 113Cd NMR at 88-, 55-, and 44-MHz frequencies, including the effects of pH, temperature, and ionic strength on the spectra. Our results differ significantly from previous reports of 113Cd NMR on similar samples. Thus, the spectra of both chromatographically distinguishable isoforms MT1 and MT2 were not identical, and neither could be interpreted in terms of a unique static model with the seven Cd ions forming two independent clusters of four and three Cd ions. Large differential shifts of 113Cd resonances were observed with changes in temperature over the range 277-320 K and ionic strength (0.02-0.5 M). At low temperature a slow structural change (half-life of several minutes) was detected. The structure was more rigid at high ionic strength. The frequency dependence and two-dimensional J-resolved spectra revealed that 113Cd resonances were composed of several overlapping peaks, complicating the interpretation of fine structure in one-dimensional spectra. A new flexible model of the Cd cluster in metallothionein is proposed. This model incorporates dynamic thiolate exchange reactions and involves several configurational substates of the protein. The possible relationship of such flexibility to the function of metallothionein is discussed.     

Metal substitution of Neurospora copper metallothionein

The binding of diamagnetic Zn(II), Cd(II), and Hg(II) and paramagnetic Co(II) and Ni(II) ions to the apo form of Neurospora metallothionein (MT) was investigated by various spectroscopic techniques. In contrast to native copper MT, which was shown to bind 6 mol of Cu(I)/mol of protein (Lerch, 1980), all substituted forms reveal an overall metal to protein stoichiometry of 3. The charge-transfer (CT) transitions of the complexes containing diamagnetic metal ions as well as the d-d transitions of those with paramagnetic metal ions are indicative of a distorted Td coordination. Electron paramagnetic resonance and absorption measurements of the Co(II) derivative are in agreement with the presence of a metal-thiolate cluster in this protein. Metal titration studies of the apoprotein reveal characteristic spectral features for the derivatives containing two metal equivalents as compared to those with a full complement of three metal ions. The former features are indicative of an exclusive Td type of metal-sulfur coordination whereas the latter suggest that the third metal ion is coordinated in a different fashion. This finding is in agreement with the presence of only seven cysteine residues in Neurospora MT as opposed to nine cysteine residues in the three-metal cluster of the mammalian MT's [Winge, D.R., & Miklossy, K.-A. (1982) J. Biol. Chem. 257, 3471].     

Effect of the two conserved prolines of human growth inhibitory factor (metallothionein-3) on its biological activity and structure fluctuation: comparison with a mutant protein

Human neuronal growth inhibitory factor, a metalloprotein classified as metallothionein-3 (MT-3), impairs the survival and the neurite formation of cultured neurons. In these studies the double P7S/P9A mutant (mutMT-3) and single mutants P7S and P9A of human Zn(7)-MT-3 were generated, and their effects on the biological activity and the structure of the protein were examined. The biological results clearly established the necessity of both proline residues for the inhibitory activity, as even single mutants were found to be inactive. Using electronic absorption, circular dichroism (CD), magnetic CD (MCD), and (113)Cd NMR spectroscopy, the structural features of the metal-thiolate clusters in the double mutant Cd(7)-mutMT-3 were investigated and compared with those of wild-type Cd(7)-MT-3 [Faller, P., Hasler, D. W., Zerbe, O., Klauser, S., Winge, D. R., and Vasák, M. (1999) Biochemistry 38, 10158] and the well characterized Cd(7)-MT-2a from rabbit liver. Similarly to (113)Cd(7)-MT-3 the (113)Cd NMR spectrum of (113)Cd(7)-mutMT-3 at 298 K revealed four major and three minor resonances (approximately 20% of the major ones) between 590 and 680 ppm, originating from a Cd(4)S(11) cluster in the alpha-domain and a Cd(3)S(9) cluster in the beta-domain, respectively. Due to the presence of dynamic processes in the structure of MT-3 and mutMT-3, all resonances showed the absence of resolved homonuclear [(113)Cd-(113)Cd] couplings and large apparent line widths (between 140 and 350 Hz). However, whereas in (113)Cd(7)-mutMT-3 the temperature rise to 323 K resulted in a major recovery of the originally NMR nondetectable population of the Cd(3)S(9) cluster resonances, no such temperature effect was observed in (113)Cd(7)-MT-3. To account for the observed NMR features, a dynamic structural model for the beta-domain is proposed, which involves a folded and a partially unfolded state. It is suggested that in the partially unfolded state a slow cis/trans isomerization of Cys-Pro(7) or Cys-Pro(9) amide bonds in (113)Cd(7)-MT-3 takes place and that this process represents a rate-limiting step in a correct domain refolding. In addition, closely similar apparent stability constants of human MT-3, mutMT-3, and rabbit MT-2a with Cd(II) and Zn(II) ions were found. These results suggest that specific structural features dictated by the repetitive (Cys-Pro)(2) sequence in the beta-domain of MT-3 and not its altered metal binding affinity compared to MT-1/MT-2 isoforms are responsible for the biological activity of this protein.     

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.     

Order of metal binding in metallothionein

Purified isoforms of rat liver apometallothionein were reconstituted in vitro with Cd and Zn ions to study the order of binding of the 7 metal sites in the two separate metal clusters, one containing four metal ions (cluster A) and the other containing three (cluster B). Reconstitution with 7 Cd ions resulted in a metalloprotein similar to induced Cd,Zn-metallothionein by the criteria of electrophoretic mobility, insensitivity to proteolysis by subtilisin, and the pH-dependent release of Cd. Proteolytic digestion of metallothionein reconstituted with suboptimal quantities of Cd followed by separation of Cd-containing polypeptide fragments by electrophoresis and chromatography revealed metal ion binding initially occurs in the 4-metal center, cluster A. Upon saturation of the 4 sites in cluster A, binding occurs in the 3-metal center, cluster B. Samples reconstituted with 1 to 4 Cd ions per protein molecule, followed by digestion with subtilisin, yielded increasing amounts of a proteolytically stable polypeptide fragment identical with the alpha fragment domain that is known to encompass the 4-metal center. Samples renatured with 5 to 7 Cd ions per metallothionein molecule showed decreasing quantities of alpha fragment and increasing amounts of native-like metallothionein. Similar results were obtained in reconstitution studies with Zn ions. Samples reconstituted with 7 Cd eq followed by incubation with EDTA revealed that cluster B Cd ions were removed initially. The binding process in each domain is cooperative. Reconstitution of apometallothionein with 2 Cd ions followed by proteolysis yields a 50% recovery of saturated Cd4 alpha cluster. Likewise, when Cd5-renatured metallothionein was digested with subtilisin, 30% of the molecules were identified as Cd7 metallothionein with the remainder as Cd4 alpha fragment.     

Evidence for a dynamic structure of human neuronal growth inhibitory factor and for major rearrangements of its metal-thiolate clusters.

Human neuronal growth inhibitory factor (GIF), a metallothionein-like protein classified as metallothionein-3, impairs the survival and the neurite formation of cultured neurons. Despite its approximately 70% amino acid sequence identity with those of mammalian metallothioneins (MT-1 and MT-2 isoforms), only GIF exhibits growth inhibitory activity. In this study, structural features of the metal-thiolate clusters in recombinant Zn(7)- and Cd(7)-GIF, and in part also in synthetic GIF (68 amino acids), were investigated by using circular dichroism (CD) and (113)Cd NMR. The CD and (113)Cd NMR studies of recombinant Me(7)-GIF confirmed the existence of distinct Me(4)S(11)- and Me(3)S(9)-clusters located in the alpha- and beta-domains of the protein, respectively. Moreover, a mutual structural stabilization of both domains was demonstrated. The (113)Cd NMR studies of recombinant (113)Cd(7)-GIF were conducted at different magnetic fields (66.66 and 133.33 MHz) and temperatures (298 and 323 K). At 298 K the spectra revealed seven (113)Cd signals at 676, 664, 651, 644, 624, 622, and 595 ppm. A striking feature of all resonances is the absence of resolved homonuclear [(113)Cd-(113)Cd] couplings and large apparent line widths (between 140 and 350 Hz), which account for the absence of cross-peaks in [(113)Cd, (113)Cd] COSY. On the basis of a close correspondence in chemical shift positions of the (113)Cd signals at 676, 624, 622, and 595 ppm with those obtained in our previous studies of (113)Cd(4)-GIF(32-68) [Hasler, D. W., Faller, P., and Vasák, M. (1998) Biochemistry 37, 14966], these resonances can be assigned to a Cd(4)S(11)-cluster in the alpha-domain of (113)Cd(7)-GIF. Consequently, the remaining three (113)Cd signals at 664, 651, and 644 ppm originate from a Me(3)S(9) cluster in the beta-domain. However, the latter resonances show a markedly reduced and temperature-independent intensity (approximately 20%) when compared with those of the alpha-domain, indicating that the majority of the signal intensity remained undetected. To account for the observed NMR features of (113)Cd(7)-GIF, we suggest that dynamic processes acting on two different NMR time scales are present: (i) fast exchange processes among conformational cluster substates giving rise to broad, weight-averaged resonances and (ii) additional very slow exchange processes within the beta-domain associated with the formation of configurational cluster substates. The implications of the structure fluctuation for the biological activity of GIF are discussed.     

1H NMR studies of T4 gene 32 protein: effects of zinc removal and reconstitution

Gene 32 protein (g32P), the single-stranded DNA binding protein from bacteriophage T4, contains 1 mol of Zn(II)/mol bound in a tetrahedral ligand field. 113Cd NMR studies of Cd-substituted wild-type and mutant (Cys166----Ser166) g32Ps show Cys77, Cys87, and Cys90 to provide three sulfur donor atoms as ligands to the metal ion [Giedroc, D. P., Johnson, B. A., Armitage, I. M., & Coleman, J. E. (1989) Biochemistry 28, 2410]. Proton NMR signals from the His and Trp side chains of the protein have been followed as a function of pH and metal ion removal by biosynthesizing the protein with amino acids carrying protons at specific positions in a background of perdeuteriated aromatic amino acids. Only one of the two pairs of His resonances (from His64 and His81) titrates over the pH range 8.0-5.9. The nontitrating His side chain is most likely ligated to the metal ion. Upon Zn(II) removal, 1H NMR spectra of the fully protonated g32P-(A + B) exhibit substantial signal broadening in several regions of the spectrum, while the His 2,4-1H resonances are broadened beyond detection. The 1H NMR spectral characteristics of the original protein are restored by reconstitution with stoichiometric Zn(II). The broadening of the 1H NMR signals is not due to oligomerization of the protein, since small-angle X-ray scattering experiments show that the average radius of gyration of the apo-g32P-(A + B) is 25.0 A and that of the reconstituted Zn(II)-g32P-(A + B) is 31.2 A.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

The metal binding site of zoocin A

Direct metal analysis of the bacteriolytic exoenzyme zoocin A failed to unequivocally identify a putative metal cofactor; hence, indirect experiments utilizing NMR were undertaken to settle this question. Cd(2+) as a surrogate metal ion was reconstituted into EDTA-treated, metal-free recombinant zoocin, and (113)Cd-NMR was employed to explore binding in the protein for this ion. The Cd-substituted enzyme was found to have 80-85% of native streptococcolytic activity. A major (113)Cd resonance at 113.6 ppm was observed which with time split into resonances at 113.6 and 107.2 ppm. A minor (113)Cd resonance at 87.3 ppm was observed which increased in intensity with time. These Cd chemical shifts are indicative of two N atoms and two O atoms ligating directly to the metal site.On the basis of conserved amino acid residues in a homologous protein of known structure, LytM, the ligands in zoocin are tentatively assigned to H45, D49, H133, and some combination of water or buffer ions as the fourth oxygen donor in zoocin A. Comparison of the combined intensities for (113)Cd-substituted zoocin with a known quantity of another Cd-substituted protein gave Cd binding as approximately stoichiometric (1.2 +/- 0.2) with protein. Additional metal-removal and reconstitution experiments on the recombinant catalytic domain of zoocin implicate Zn(2+) as the metal cofactor. Therefore, the evidence supports zoocin as a single Zn(2+) ion binding metalloenzyme.     

13C and 113Cd NMR studies of the chelation of metal ions by the calcium binding protein parvalbumin

13C NMR spectra are presented for the calcium binding protein parvalbumin (pI 4.25) from carp muscle in several different metal bound forms: with Ca2+ in both the CD and EF calcium binding sites, with Cd2+ in both sites, with 113Cd2+ in both sites, and with 113Cd2+ in the CD site and Lu3+ in the EF site. The different metals differentially shift the 13C NMR resonances of the protein ligands involved in chelation of the metal ion. In addition, direct 13C-113Cd spin-spin coupling is observed which allows the assignment of protein carbonyl and carboxyl 13C NMR resonances to ligands directly interacting with the metal ions in the CD and EF binding sites. The displacement of 113Cd2+ from the EF site by Lu3+ further allows these resonances to be assigned to the CD or EF site. The occupancy of the two sites in the two cadmium species and in the mixed Cd2+/Lu3+ species is verified by 113Cd NMR. The resolution in these 113Cd NMR spectra is sufficient to demonstrate direct interaction between the two metal binding sites.     

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.     

113Cd nuclear magnetic resonance of Cd(II) alkaline phosphatases

113Cd NMR spectra of 113Cd(II)-substituted Escherichia coli alkaline phosphatase have been recorded over a range of pH values, levels of metal site occupancy, and states of phosphorylation. Under all conditions resonances attributable to cadmium specifically bound at one or more of the three pairs of metal-binding sites (A, B, and C sites) are detected. By following changes in both the 113Cd and 31P NMR spectra of 113Cd(II)2 alkaline phosphatase during and after phosphorylation, it has been possible to assign the cadmium resonance that occurs between 140 and 170 ppm to Cd(II) bound to the A or catalytic site of the enzyme and the resonance occurring between 51 and 76 ppm to Cd(II) bound to B site, which from x-ray data is located 3.9 A from the A site. The kinetics of phosphorylation show that cadmium migration from the A site of one subunit to the B site of the second subunit follows and is a consequence of phosphate binding, thus precluding the migration as a sufficient explanation for half-of-the-sites reactivity. Rather, there is evidence for subunit-subunit interaction rendering the phosphate binding sites inequivalent. Although one metal ion, at A site, is sufficient for phosphate binding and phosphorylation, the presence of a second metal ion at B site greatly enhances the rate of phosphorylation. In the absence of phosphate, occupation of the lower affinity B and C sites produces exchange broadening of the cadmium resonances. Phosphorylation abolishes this exchange modulation. Magnesium at high concentration broadens the resonances to the point of undetectability. The chemical shift of 113Cd(II) in both A and B sites (but not C site) is different depending on the state of the bound phosphate (whether covalently or noncovalently bound) and gives separate resonances for each form. Care must be taken in attributing the initial distribution of cadmium or phosphate in the reconstituted enzyme to that of the equilibrium species in samples reconstituted from apoenzyme. Both 113Cd NMR and 31P NMR show that some conformational changes consequent to metal ion or phosphate binding require several days before the final equilibrium species is formed.     

Spectroscopic studies on cadmium (II)- and cobalt(II)-substituted metallothionein from the crab Cancer pagurus. Evidence for one additional low-affinity metal-binding site

The binding of diamagnetic Cd(II) and paramagnetic Co(II) ions to the metal-free form of crab, Cancer pagurus, metallothionein (MT) was studied by various spectroscopic techniques. Both reconstituted and native Cd(II)-MT containing 6 mol Cd(II)/mol protein display electronic absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra which were indistinguishable. The stoichiometric replacement of Cd(II) ions in native Cd(II)6-MT by paramagnetic Co(II) ions enabled the geometry of the metal-binding sites to be probed. The electronic absorption and MCD spectra of Co(II)6-MT revealed features characteristic of distorted tetrahedral tetrathiolate Co(II) coordination for all six metal-binding sites. The stepwise incorporation of Cd(II) and Co(II) ions into this protein was monitored by electronic absorption and CD, and by electronic absorption and EPR spectroscopy, respectively. The results indicate that the metal-thiolate cluster structure is generated when more than four metal ions are bound. Below this titration point separate tetrahedral tetrathiolate complexes exist. This suggests that the cluster formation occurs in a two-step process. Furthermore, the spectroscopic features in both Cd(II)- and Co(II)-metal derivatives above the full metal occupancy of six suggest the existence of one additional metal-binding site. The subsequent loss of one Cd(II) ion from crab Cancer Cd(II)7-MT in the gel filtration studies demonstrate the low metal-binding affinity of the latter site. While the spectroscopic properties indicate an exclusively tetrahedral type of metal-thiolate sulfur coordination for the binding of the first six metal ions, they suggest that the seventh metal ion is coordinated in a different fashion.     

Folding pathway of apo-metallothionein induced by Zn2+, Cd2+ and Co2+.

Metal ion binding to the sulfhydryl groups of apometallothionein (apo-MT) causes both the formation of native metal-thiolate clusters and the folding of the polypeptide chain of each domain. Cd2+ and Zn2+ react with apo-MT to form metal-thiolate bonds in reactions that are complete within milliseconds and which are pH-dependent. Dual mixing experiments were conducted that involve the initial reaction of metal ion and apo-MT followed by mixing with 5,5'-N-dithio-bis(2-nitrobenzoate) or EDTA after 26 ms. They showed that structures had formed within the brief reaction period which were resistant to rapid reaction with reagents that interact with sulfhydryl groups or metal ions, respectively. It was concluded that native metallothionein domains had been constituted within this brief period. Apo-MT was also titrated with Co2+ to yield Co(n)-MT (n=1-7). Initially, Co2+ bound to independent, tetrahedral thiolate sites. Spectrophotometric analysis of the titration suggested that the independent Co(II) sites began to coalesce into clusters at n=4 (pH 7.2) or n=5 (pH 8.4). Back titration of free sulfhydryl groups (S) in Co(n)-MT (n=1-7) with iodoacetamide at pH 7.2 confirmed that clustering began at n=4. Upon conversion of these alkylated structures to the corresponding 113Cd2+ species 113Cd NMR spectroscopy established that the location of Co(II) in Co(n)-MT (n=1-3) was non-specific and that at n=4, the only observable structure was Co(II)4S11. The results suggest possible kinetic pathways of folding that are conceptually similar to those hypothesized for other small proteins.