Cadmium binding to metallothioneins. Domain specificity in reactions of alpha and beta fragments, apometallothionein, and zinc metallothionein with Cd2+

The cadmium-binding properties of rabbit liver Zn7-metallothionein (MT) 2 and apo-MT, rat liver apo-alpha MT and Zn4-alpha MT, and calf liver apo-beta MT, have been studied using circular dichroism (CD) and magnetic circular dichroism (MCD) spectroscopies. Both sets of spectra recorded during the titration of Zn7-MT 2 with Cd2+ exhibit a complicated pattern that is quite unexpected. Such behavior is not found at all in sets of spectra recorded during titrations of the apo-species (apo-MT, apo-alpha MT, and apo-beta MT), and is observed to a much lesser extent in the titration of Zn-alpha MT. Comparison between the band centers of the Cd-alpha MT and Cd-beta MT indicates that the CD spectrum of Cd7-MT is dominated by intensity from transitions that originate on Cd-S chromophores in the alpha domain, with little direct contribution from the beta domain. Analysis of the spectra recorded during titrations of Zn7-MT 2 with Cd2+ suggests: (i) that Cd2+ replaces Zn2+ in Zn7-MT isomorphously; (ii) that cadmium binds in a nonspecific, "distributed" manner across both domains; (iii) that cluster formation in the alpha domain only occurs after 4 mol eq of cadmium have been added and is indicated by the presence of a cluster-sensitive, CD spectral feature; (iv) that the characteristic derivative CD spectrum of native Cd4,Zn3-MT is only obtained from "synthetic" Cd4,Zn3-MT following a treatment cycle that allows the redistribution of cadmium into the alpha domain; warming the synthetic "native," Cd4,Zn3-MT, to 65 degrees C results in cadmium being preferentially bound in the alpha domain; and (v) Zn7-MT will bind Cd2+ quite normally at up to 65 degrees C but with greater specificity for the alpha domain compared with titrations carried out at 25 degrees C. These results suggest that the initial presence of zinc in both domains is an important factor in the lack of any domain specificity during cadmium binding to Zn-MT which contrasts the domain specific manner observed for cadmium binding to apo-MT.     

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.     

Distinct metal-binding configurations in metallothionein

In a study of the binding stoichiometry of various metals to rat liver metallothionein, the protein appears to coordinate metals in 2 distinct configurations. Ions of at least 18 different metals were shown to associate with the protein suggesting that there is little specificity in binding. Most metals exhibited saturation binding at 7 mol eq forming M7-metallothionein. These included Bi(III), Cd(II), Co(II), Hg(II), In(III), Ni(II), Pb(II), Sb(III), and Zn(II). Others metals including Os(III), Pd(II), Pt(IV), Re(V), Rh(III), and Tl(III) give a positive indication of binding, but stoichiometries were unclear. Ag(I) and Cu(I) bound in clusters as M12-metallothionein. This binding stoichiometry was determined in 3 ways: (a) by determining the equivalence point in Cu- and Ag-titrated samples where resistance to proteolysis is maximal; (b) by determining the point where Zn ions are completely displaced from Zn7-metallothionein; and (c) by direct binding studies. Ag-reconstituted protein, recovered from gel filtration, had an average Ag content of 11.5 g atoms/mol of protein. A similar stoichiometry for the Cu-protein resulted from displacement of Zn from Zn7-metallothionein by Cu(I). The M12-protein was converted to the M7-protein by displacement of Ag(I) or Cu(I) with 7 mol eq of Hg(II). Whereas the distribution of metals in the 2 domains of M7-metallothionein is M4 alpha and M3 beta, the arrangement in the M12-molecule is probably M6 alpha and M6 beta. We propose that metallothionein ligates Ag(I) and Cu(I) in a trigonal geometry by bridging thiolates. This is in contradistinction to a tetrahedral binding geometry in the M7-protein. Distinct binding configurations may result in different tertiary structures for M7- and M12-proteins which may relate to metabolic specificity of Zn-metallothionein and Cu-metallothionein, respectively.     

Structural consequences of metallothionein dimerization: solution structure of the isolated Cd4-alpha-domain and comparison with the holoprotein dimer

The NMR determination of the structure of Cd(7)-metallothionein was done previously using a relatively large protein concentration that favors dimer formation. The reactivity of the protein is also affected under this condition. To examine the influence of protein concentration on metallothionein conformation, the isolated Cd(4)-alpha-domain was prepared from rabbit metallothionein-2 (MT 2), and its three-dimensional structure was determined by heteronuclear, (1)H-(111)Cd, and homonuclear, (1)H-(1)H NMR, correlation experiments. The three-dimensional structure was refined using distance and angle constraints derived from these two-dimensional NMR data sets and a distance geometry/simulated annealing protocol. The backbone superposition of the alpha-domain from rabbit holoprotein Cd(7)-MT 2 and the isolated rabbit Cd(4)-alpha was measured at a RMSD of 2.0 A. Nevertheless, the conformations of the two Cd-thiolate clusters were distinctly different at two of the cadmium centers. In addition, solvent access to the sulfhydryl ligands of the isolated Cd(4)-alpha cluster was 130% larger due to this small change in cluster geometry. To probe whether these differences were an artifact of the structure calculation, the Cd(4)-alpha-domain structure in rabbit Cd(7)-MT 2 was redetermined, using the previously defined set of NOEs and the present calculation protocol. All calculations employed the same ionic radius for Cd(2+) and same cadmium-thiolate bond distance. The newly calculated structure matched the original with an RMSD of 1.24 A. It is hypothesized that differences in the two alpha-domain structures result from a perturbation of the holoprotein structure because of head-to-tail dimerization under the conditions of the NMR experiments.     

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.     

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.     

Refined crystal structure of Cd, Zn metallothionein at 2.0 A resolution

The crystal structure of Cd5,Zn2-metallothionein from rat liver has been refined at 2.0 A resolution of a R-value of 0.176 for all observed data. The five Cd positions in the asymmetric unit of the crystal create a pseudo-centrosymmetric constellation about a crystallographic 2-fold axis. Consequently, the distribution of anomalous differences is almost ideally centrosymmetric. Therefore, the previously reported metal positions and the protein model derived therefrom are incorrect. Direct methods were applied to the protein amplitudes to locate the Cd positions. The new positions were used to calculate a new electron density map based on the Cd anomalous scattering and partial structure to model the metal clusters and the protein. Phases calculated from this model predict the positions of three sites in a (NH4)2WS4 derivative. Single isomorphous replacement phases calculated with these tungsten sites confirm the positions of the Cd sites from the new direct methods calculations. The refined metallothionein structure has a root-mean-square deviation of 0.016 A from ideality of bonds and normal stereochemistry of phi, phi and chi torsion angles. The metallothionein crystal structure is in agreement with the structures for the alpha and beta domains in solution derived by nuclear magnetic resonance methods. The overall chain folds and all metal to cysteine bonds are the same in the two structure determinations. The handedness of a short helix in the alpha-domain (residues 41 to 45) is the same in both structures. The crystal structure provides information concerning the metal cluster geometry and cysteine solvent accessibility and side-chain stereochemistry. Short cysteine peptide sequences repeated in the structure adopt restricted conformations which favor the formation of amide to sulfur hydrogen bonds. The crystal packing reveals intimate association of molecules about the diagonal 2-fold axes and trapped ions of crystallization (modeled as phosphate and sodium). Variation in the chemical and structural environments of the metal sites is in accord with data for metal exchange reactions in metallothioneins.     

Synthesis of a nonacosapeptide (beta-fragment) corresponding to the N-terminal sequence 1-29 of human liver metallothionein II and its heavy metal-binding properties

A nonacosapeptide (beta-fragment) corresponding to the N-terminal sequence 1-29 of human liver metallothionein II was synthesized by the fragment condensation method. The Cd-binding ability of the beta-fragment was much stronger than that of cysteine as thionein and synthetic alpha-fragment corresponding to the C-terminal sequence 30-61 of human liver metallothionein II. Both the alpha- and beta-fragments bound preferentially to Cu ions rather than Cd ions.     

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.     

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.     

Detection of two Zn-finger proteins ofXenopus laevis,TFIIIA, and p43, by probing western blots of ovary cytosol with65Zn2+,63Ni2+, or109Cd2+

Two Zn-finger proteins, TFIIIA (a constituent of 7S RNP particles) and p43 (a constituent of 42S RNP particles), were detected in ovary extracts of juvenile Xenopus laevis females by in vitro binding of radiolabeled divalent metals. Proteins fractionated by SDS-PAGE (sodium dodecylsulfate-polyacrylamide gel electrophoresis) were transferred by Western blotting onto nitrocellulose membranes, probed with 65Zn2+, 63Ni2+, or 109Cd2+, and visualized by autoradiography. Detection limits for TFIIIA were approx 0.07 micrograms/well by 109Cd(2+)-probing, 0.13 micrograms/well by 65Zn(2+)-probing, and 0.26 mu/well by 63Ni(2+)-probing. Protein p43 was more clearly visualized by probing with 63Ni2+ than with 65Zn2+ or 109Cd2+. After purified TFIIIA was cleaved with cyanogen bromide, 65Zn2+, 109Cd2+, and 63Ni2+ distinctly labeled the 22 kDa middle fragment; 65Zn2+ and 109Cd2+ also labeled the 11 kDa N-terminal fragment, but did not label the 13 kDa C-terminal fragment. These results are consistent with the notion that the radioligands were bound to finger-loop domains of TFIIIA, which occur in the middle and N-terminal fragments. Based on the abilities of nonradioactive metal ions to compete with 65Zn2+ for binding to TFIIIA on Western blots, the relative affinities of the metals for TFIIIA were ranked as follows: Zn2+ = Cu2+ greater than or equal to Hg2+ greater than Cd2+ greater than Co2+ greater than or equal to Ni2+. Even at a 1000-fold molar excess, Mn2+ did not compete with 65Zn2+ for binding to TFIIIA. Probing Western blots with the radiolabeled metal ions greatly facilitates the detection, isolation, and quantitation of TFIIIA and p43.     

Accumulation and storage of Zn2+ by Candida utilis.

Starved cells of Candida utilis accumulated Zn2+ by two different processes. The first was a rapid, energy- and temperature-independent system that probably represented binding to the cell surface. The cells also possessed an energy-, pH-, and temperature-dependent system that was capable of accumulating much greater quantities of the cation than the binding process. The energy-dependent system was inhibited by KCN, Na2HAsO4, m-chlorophenyl carbonylcyanide hydrazone, N-ethylmaleimide, EDTA and diethylenetriaminepenta-acetic acid. The system was specific inasmuch as Ca2+, Cr3+, Mn2+, Co2+ or Cu2+ did not compete with, inhibit, or enhance the process, Zn2+ uptake was inhibited by Cd2+. The system exhibited saturation kinetics with a half-saturation value of 1.3 muM and a maximum rate of 0.21 (nmol Zn2+) min(-1) (mg dry wt(-1)) at 30 degrees C. Zn2+ uptake required intact membranes since only the binding process was observed in the presence of nystatin, toluene, or sodium dodecyl sulphate. Cells did not exchange recently accumulated toluene, or sodium dodecyl sulphate. Cells did not exchange recently accumulated 65Zn following the addition of a large excess of non-radioactive Zn2+. Similarly, cells pre-loaded with 65Zn did not lose the cation during starvation, and efflux did not occur when glucose and exogenous Zn2+ were supplied after the starvation period. Efflux was only observed after the addition of toluene or nystatin, or when cells were heated to 100 degrees C. Cells fed a large quantity of Zn2+ contained a protein fraction resembling animal cell metallothionein. In batch culture, cells of C. utilis accumulated Zn2+ only during the lag phase and the latter half of the exponential-growth phase.     

Raman spectroscopic study of the effects of Ca2+, Mg2+, Zn2+, and Cd2+ ions on calf thymus DNA: binding sites and conformational changes

The interaction of Mg2+, Ca2+, Zn2+, and Cd2+ with calf thymus DNA has been investigated by Raman spectroscopy. These spectra reveal that all of these ions, and particularly Zn2+, bind to phosphate groups of DNA, causing a slight structural change in the polynucleotide at very small metal: DNA (P) concentration ratio (ca. 1:30). This results in increased base-stacking interactions, with negligible change of the B conformation of DNA. Contrary to Zn2+ and Cd2+, which interact extensively with the nucleic bases (particularly at the N7 position of guanine), the alkaline-earth metal ions are bound almost exclusively to the phosphate groups. The affinity of both the Zn2+ and Cd2+ ions for G.C base pairs is comparable, but the Cd2+ ions interact more extensively with A.T pairs than Zn2+ ions. Interstrand cross-linking through the N3 atom of cytosine is suggested in the presence of Zn2+, but not Cd2+.     

Catalytic properties and inhibition of Cd2+-carbonic anhydrases

Cd2+ derivatives of human carbonic anhydrases I and II and bovine red cell carbonic anhydrase (carbonate hydro-lyase, EC 4.2.1.1) have been prepared. The metal ion in these derivatives is readily displaced by Zn2+. The Cd2+-carbonic anhydrases have appreciable 4-nitrophenyl acetate hydrolase activities. These activities increase with pH as if dependent on the basic form of a group with pKa near 10. The Cd2+-carbonic anhydrases also have significant CO2 hydration activities. The Cd2+ derivatives are strongly inhibited by monovalent anions. In particular, I- is a much more potent inhibitor of the Cd2+ enzymes than of the native enzymes. Acetazolamide (5-acetylamido-1,3,4-thiadiazole 2-sulfonamide) is also a strong inhibitor although its affinity for the Cd2+ enzyme is less than its affinity for the native enzyme.     

Spectroscopic properties of the cobalt(II)-substituted alpha-fragment of rabbit liver metallothionein

The C-terminal segment of rabbit liver metallothionein 1 (alpha-fragment) containing four paramagnetic Co(II) ions was obtained by stoichiometric replacement of the originally bound diamagnetic Cd(II) ions. The latter form was prepared by limited proteolysis with subtilisin as described previously [Winge, D. R., & Miklossy, K. A. (1982) J. Biol. Chem. 257, 3471-3476]. Electronic absorption, magnetic circular dichroism (MCD), and electron paramagnetic resonance (EPR) measurements were employed to monitor the stepwise incorporation of Co(II) ions into the metal-free fragment. Absorption and MCD spectra of the apofragment containing the first 3 Co(II) equiv show the typical features of tetrahedral tetrathiolate Co(II) coordination. However, in the d-d region only small changes in the visible and no apparent change in the near-infrared region are discernible when the fourth Co(II) is bound. This unusual spectral behavior was not seen in Co(II) substitution of native metallothionein [Vasák, M., & K?gi, J. H. R. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 6709-6713] and may indicate a different cluster geometry. In the charge-transfer region, the binding of all 4 Co(II) equiv is accompanied by characteristic increments of the thiolate S----Co(II) bands. As in the formation of Co(II)7-metallothionein, the development of the charge-transfer and EPR spectral properties upon binding of the first 2 Co(II) equiv to the apofragment is indicative of isolated, noninteracting tetrahedral tetrathiolate Co(II) complexes. The binding of the additional Co(II) ion is accompanied by a red shift in the charge-transfer region and by the dramatic loss of paramagnetism in the EPR spectra, both diagnostic of the formation of metal-thiolate cluster structures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Spectroscopic studies on metal distribution in Co(II)/Zn(II) mixed-metal clusters in rabbit liver metallothionein 2.

Metal selectivity of metal-thiolate clusters in rabbit liver metallothionein (MT) 2 has been studied by examining the metal distribution of two similarly sized divalent metal ions, cobalt and zinc, which have different thiolate affinity. The forms of mixed-metal cluster species in (Co/Zn)7-MT generated with different ratios of both metal ions offered to the metal-free protein were investigated using EPR, ultraviolet/visible absorption and MCD spectroscopy. The results demonstrated that the distribution of these metals between the two metal-thiolate clusters is not random. Thus, the EPR absorption intensities of the bound Co(II) ions in the Zn-cluster matrix increased linearly up to a ratio of Co(II)/Zn(II) equivalents of 3:4, with the final EPR intensity of three non-interacting Co(II)-binding sites. This EPR behaviour is consistent with a binding scheme in which one Co(II) ion occupies a metal-binding site within the three-metal cluster and the remaining two Co(II) ions occupy two distinctly separate sites in the four-metal cluster. With four or more Co(II) ions in the cluster matrix, magnetic coupling between adjacent, sulphur-bridged Co(II) ions was observed. In previous studies on mixed-metal clusters in MT formed with Co(II)/Cd(II), Zn(II)/Cd(II) and Cd(II)/Fe(II), changes in the respective cluster volumes were shown to be a significant factor dictating the widely differing metal distributions in these systems. Based on the results of the current study, it is suggested that both the sizes of the two metal ions and their relative affinities towards the cysteine-thiolate ligands are important in the formation of mixed-metal clusters in MT.     

Fourier transform IR and Fourier transform Raman spectroscopy studies of metallothionein-III: amide I band assignments and secondary structural comparison with metallothioneins-I and -II

The secondary structures of porcine brain Cu(4)Zn(3)-metallothionein (MT)-III and Cd(5)Zn(2)MT-I, Cd(5)Zn(2)MT-II, and Zn(7)MT-I from rabbit livers in the solid state are investigated by Fourier transform IR spectroscopy (FTIR) and Fourier transform Raman spectroscopy (FT-Raman). The Cu(4)Zn(3)MT-III contains 26-28% beta-turns and half-turns, 13-14% 3(10)-helices, 47-49% random coils, and 11-12% beta-extended chains. The structural comparison of porcine brain Cu(4)Zn(3)MT-III with rabbit liver Cd(5)Zn(2)MT-I (II) and Zn(7)MT-I shows that the contents of the random coil structure are obviously increased. The results indicate that the insert of an acidic hexapeptide in the alpha domain of Cu(4)Zn(3)MT-III possibly forms an alpha helix. However, because the bands assigned to the alpha-helix and random coil structures are overlapped in the spectra, the content of random coil structures in Cu(4)Zn(3)MT-III is therefore higher than those in Cd(5)Zn(2)MT-I, Cd(5)Zn(2)MT-II, and Zn(7)MT-I.     

Post-chemiluminescence behaviour of Ni2+, Mg2+, Cd2+ and Zn2+ in the potassium ferricyanide-luminol reaction.

A new chemiluminescence (CL) reaction was observed when Ni2+, Mg2+, Cd2+ or Zn2+ was injected into the reaction mixture after the finish of the CL reaction of alkaline luminol and potassium ferricyanide. This reaction is described as a post-chemiluminescence (PCL) reaction. The possible mechanism for the PCL was proposed based on studies of the CL kinetic characteristic and the CL spectra. The experimental conditions of the CL reactions were optimized and the feasibility of using the reaction to analyse these metal ions was evaluated. The PCL reaction method operates in the ranges: 1 x 10(-7)-8 x 10(-6) g/L Ni2+; 3 x 10(-6)-2 x 10(-4) g/L Mg2+; 8 x 10(-7)-1 x 10(-4) g/L Cd2+; and 2 x 10(-4)-2 x 10(-3) g/L Zn2+, with detection limits of 4 x 10(-8) g/mL, 1 x 10(-6) g/mL, 3 x 10(-7) g/mL, 8 x 10(-5) g/mL, respectively.     

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.