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.     

Absorption, circular dichroism, magnetic circular dichroism and emission study of rat kidney Cd,Cu-metallothionein

Absorption, circular dichroism (CD), magnetic circular dichroism (MCD) and emission spectra of rat liver and rat kidney cadmium-, zinc- and copper-containing metallothioneins (MT) are reported. The absorption, CD and MCD data of native rat kidney Cd,Cu-MT protein closely resemble data recorded for the rat liver Cd,Zn-MT. This suggests that the major features in all three spectra of the native Cd,Cu-MT are dominated by cadmium-related bands. The CD spectrum of the Cd,Cu-MT recorded at pH 2.7 has the same band envelope that is observed for a Cd,Cu-MT formed in vitro by titration of Cd,Zn-MT with Cu(I), suggesting that the copper occupies the zinc sites in Cd,Cu-MT formed both in vivo and, at low molar ratios, in vitro. Remetallalion of the metallothionein from low pH in the presence of both copper and cadmium results in considerably less cadmium bound to the protein than was present in the native sample. It is suggested that this is due to the effect of the distribution of the copper amongst all available binding sites, thus inhibiting cluster formation by the cadmium. Emission spectra are reported for the first time for a cadmium- and copper-containing metallothionein. An emission band at 610 nm is shown to be a sensitive indicator of Cu(I) binding to metallothionein. Both the native Cd,Cu-MT and a Cd,Cu-MT formed in vitro exhibit an excitation spectrum with a band in the copper-thiolate charge-transfer region.     

Circular dichroism, kinetic and mass spectrometric studies of copper(I) and mercury(II) binding to metallothionein

The metalloprotein metallothionein (MT) is remarkable in its metal binding properties: for the mammalian protein, well-characterized species exist for metal to sulfur ratios of M7S20, M12S20, and M18S20, where M = Cd(II), Zn(II), Hg(II), Ag(I), Au(I), and Cu(I). Optical spectra in general, and circular dichroism (CD) and luminescence spectra in particular, provide rich detail of a complicated metal binding chemistry when metals are added directly to the metal-free or zinc-containing protein. CD spectral data unambiguously identify key metal to protein stoichiometric ratios that result in well-defined structures. Electrospray ionization-mass spectrometry data are reported for reactions in which Hg(II) binds to apo-MT 2A as previously described from CD data. Emission spectra in the 450-750 nm region have been reported for metallothioneins containing Ag(I), Au(I), and Cu(I). The luminescence of Cu-MT can also be detected directly from mammalian and yeast cells. We report both steady-state and new dynamic data for titrations of Zn-MT with Cu(I). Analysis of kinetic data for the addition of the first two Cu(I) atoms to Zn-MT indicates a first-order mechanism over a concentration range of 5-50 microM. Three-dimensional modeling was carried out using the results of the CD and EXAFS studies, model calculations for Zn7-MT, Hg7-MT, and Cu12-MT are described.     

Silver binding to rabbit liver metallothionein. Circular dichroism and emission study of silver-thiolate cluster formation with apometallothionein and the alpha and beta fragments

We report new spectroscopic properties for a range of silver-metallothionein species. The binding reactions that take place following addition of Ag+ to rabbit liver apoMT 2, and the apo alpha and -beta fragments have been studied using the techniques of circular dichroism (CD) and emission spectroscopy. Titrations carried out at 20 degrees C and 55 degrees C reveal for the first time the formation of a sequence of clusters (Ag6-MT, Ag12-MT and, finally, Ag18-MT) as Ag+ is added to rabbit apoMT 2. (The division of mammalian metallothioneins into two major subforms, MT 1 and MT 2, is based on differences in molecular charge, which results from differences in the sequence of amino acids that do not involve the cysteines.) It is proposed that the novel Ag18-MT complex forms with a structure that involves a well defined three-dimensional structure, in the same manner as that recently reported for the Hg18-MT complex (Cai, W. and Stillman, M. J., (1988) J. Am. Chem. Soc. 110, 7872-7873). Addition of silver in excess of 20 mol equivalents leads to the collapse of this structure. At the elevated temperatures, it is suggested that the protein can exert cooperativity so that completely filled domains are formed rather than mixtures of complexes. This contrasts with the kinetic product in which metals are bound across the peptide chain forming more random "cross-linked" regions in place of the cluster structure. CD spectra were recorded as Ag+ was added to the alpha and beta fragments formed from rabbit liver MT 1. The silver-containing fragments are less stable than the Ag-MT. The alpha and beta fragments exhibit CD spectral patterns indicative of stoichiometrically defined species. The presence of Ag3- alpha MT 1 and Ag6- alpha MT 1 is suggested by the spectral data obtained at 20 and 55 degrees C. Formation of Ag3- beta MT 1 is suggested by the spectral data recorded at 20 degrees C for the beta fragment. We also report that silver-containing metallothioneins are luminescent. Both the position of the band maximum in the 460-600 nm region and the emission intensity are strongly dependent on the stoichiometry of silver to protein. In the range of molar ratios for silver:MT of 1-12, bands at 465 and 520 nm intensify to a maximum for Ag10-MT 2. A band at 575 nm reaches a maximum for Ag16-MT 2. Analysis of the emission data suggests that Ag+ binds in a domain specific mechanism to apoMT 2.     

Metal binding in metallothioneins: Competition for cadmium and zinc between chelex-100 and metal binding sites in metallothionein

A study of the use of the metal chelation properties of Chelex-100 in metal binding reactions of metallothionein (MT), is described. The stoichiometric ratios of bound metals in MT were determined at several stages during a titration in which the Zn(II) in Zn₇MT was displaced by Cd(II), by using Chelex-100 to sequester the free zinc. The stoichiometric ratios provide convincing supporting evidence that the complicated circular dichroism spectral properties observed during the titration arise because the incoming cadmium is distributed across both domains in the protein. It is shown that Chelex-100 does not sequester zinc or cadmium directly from the metallothionein binding sites. Use of Chelex-100 over the temperature range −20 to 65 °C is demonstrated. The chelation capacity of Chelex-100 (in terms of μ metal ion/mg resin) has been determined for a range of elements important in metal toxicology, including: cadmium (33 μ), zinc (22 μ), copper (19 μ), silver (38 μ), lead (40 μ) and mercury (40 μ).     

Cadmium binding studies to the earthworm Lumbricus rubellus metallothionein by electrospray mass spectrometry and circular dichroism spectroscopy

The earthworm Lumbricus rubellus has been found to inhabit cadmium-rich soils and accumulate cadmium within its tissues. Two metallothionein (MT) isoforms (1 and 2) have been identified and cloned from L. rubellus. In this study, we address the metalation status, metal coordination, and structure of recombinant MT-2 from L. rubellus using electrospray ionization mass spectrometry (ESI-MS), UV absorption, and circular dichroism (CD) spectroscopy. This is the first study to show the detailed mass and CD spectral properties for the important cadmium-containing earthworm MT. We report that the 20-cysteine L. rubellus MT-2 binds seven Cd(2+) ions. UV absorption and CD spectroscopy and ESI-MS pH titrations show a distinct biphasic demetalation reaction, which we propose results from the presence of two metal-thiolate binding domains. We propose stoichiometries of Cd(3)Cys(9) and Cd(4)Cys(11) based on the presence of 20 cysteines split into two isolated regions of the sequence with 11 cysteines in the N-terminal and 9 cysteines in the C-terminal. The CD spectrum reported is distinctly different from any other metallothionein known suggesting quite different binding site structure for the peptide.     

A spectroscopic study of rat liver and Scylla serrata crab metallothioneins

The absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of native rat liver and crab (Scylla serrata) Cd,Zn-metallothionein have been measured and the data are compared. The MCD data indicate that there are close similarities in the geometries of the cadmium-binding sites in both of these proteins; however, the CD spectra are quite different for the rat liver and crab proteins. The CD spectrum for the crab metallothionein is unlike any previously reported for a cadmium-containing metallothionein. This suggests that the CD spectrum is sensitive to the different bridging pattern used in the binding sites in the crab compared with the rat-liver metallothionein. Cadmium binding to the metal-free metallothionein is demonstrated for both proteins and it is shown that there are only minor structural differences between the native and remetallated proteins. The structural changes that occur near to the cadmium-binding sites during cadmium loading to the native proteins have been followed using absorption and CD spectroscopy. Marked changes are observed in the CD spectrum which can be associated with a two-phase reaction: initially Zn2+ is displaced by the Cd2+, then at higher concentrations of Cd2+ the tetrahedral geometry of the Cd2+-binding sites is lost as more Cd2+ is bound using the same thiolate groups. While this latter reaction results in considerable change to the CD spectrum, only minor changes are observed in the absorption spectrum. A significant red shift is observed in the S leads to Cd charge transfer transition region of the MCD spectrum (230-270 nm) following both cadmium loading of native rat liver, Cd,Zn-metallothionein and the metallation of metal-free metallothionein with cadmium. There are two contributions to this effect in Cd,Zn-metallothionein: (i) there is a S leads to Zn band underlying the S leads to Cd band; and (ii) the occupation of zinc sites by cadmium changes the energy of the S leads to Cd transition.     

锌_7与镉_7－金属硫蛋白清除羟自由基的比较

分离及纯化兔肝金属硫蛋白制备去金属金属硫蛋白、锌７与镉７金属硫蛋白．在不同ｐＨ条件下,比较后二者清除羟自由基能力;在ｐＨ６条件下,比较锌７－金属硫蛋白与有关蛋白和无机锌盐清除羟自由基效果．结论是在近生理ｐＨ条件下锌７－金属硫蛋白清除羟自由基能力远强于镉７－金属硫蛋白．金属硫蛋白清除羟自由基的能力主要来源于蛋白中处于还原态的流基．     

Formation, circular dichroism and x-ray photoelectron spectroscopy of hepatic Zn-thionein.

The formation of the powerful Zn binding protein called Zn-thionein was examined using male albino rats and [14C]cysteine, as cystein is known to be the most abundant constituent of this metal protein. 65% of the hepatic [14C]cysteine was incorporated into the protein portion of freshly prepared Zn-thionein. The protein was isolated by a combination of ethanol/chloroform treatment and various chromatographic steps, including ion exchange and gel filtration. 4.7 mol of Zn, 0.02 mol of Cd and less than 0.001 mol of either Cu or Hg were found per 12 000 g of portein. It was presumed that considerable amounts of Zn were lost during these isolation procedures, with the consequence of disulphide gridge formation. Indeed, the presence of R-S-S-R was deduced from circular dichroism and X-ray photoelectron spectroscopy. Due to the clearly detectable disulphide chromophore in the circular dichroism spectrum, it was possible to assign the shoulder at S 2p1/2,3/2 = 162.7 eV of the X-ray photoelectron spectrum of native Zn-thionein to R-S-S-R and not to strongly polarized sulphur. Upon reducing R-S-S-R-containing native Zn-thionein with dithiothreitol, all oxidised thiolate moieties of the thionein molecule could be restored. The addition of ZnCl2 with the subsequent desalting of extraneously bound Zn2 yielded a homogeneous Zn-thionein with 9.6 mol Zn2 per mol protein. A stoichiometry of ZnRS 1:3 was seen, which confirmed earlier reports of the existence of the mixed Cd,Zn-thionein. The conversion of mixed Cd,Zn-thionein into homogeneous Zn-, Cd-, Hg- and Cu-thionein by the gel filtration technique proved successful. From chiroptical measurements, the extraordinary contribution of the metal chromophores to the circular dichroism was seen. Due to the differences in the geometry of complexes formed by the respective metal ions, dramatic changes in the protein portion were expected. Polyacrylamide disc electrophoresis of purified native untreated Zn-thionein resulted in the appearance of two or more bands. This phenomenon was attributed to the different migration rates of cystine-thionein and thiolate-rich Zn-thionein, and was consistent with the spectral properties of the above Zn-protein species. By contrast, only one single band was monitored when a homogeneous metal-thionein was electrophoresed.     

Characterization of the cadmium(II) binding site in Cd,Zn-metallothionein by magnetic circular dichroism spectroscopy

Absorption and magnetic circular dichroism spectra of rat liver Cd, Zn-metallothionein, and the cadmium complexes of propanethiolate and 1,2 propanedithiolate are reported. Observation of the same derivative-like MCD signal in the 250 nm region of each of these species provides experimental evidence for the assignment of the 250 nm shoulder in the Cd, Zn-metallothionein absorption spectrum as a sulfur to cadmium charge transfer band.     

Nonoxidative cadmium-dependent dimerization of Cd7-metallothionein from rabbit liver.

The effect of free Cd(II) ions on monomeric Cd7-metallothionein-2 (MT) from rabbit liver has been studied. Slow, concentration-dependent dimerization of this protein was observed by gel filtration chromatographic studies. The dimeric MT form, isolated by gel filtration, contains approximately two additional and more weakly bound Cd(II) ions per monomer. The incubation of MT dimers with complexing agents EDTA and 2-mercaptoethanol leads to the dissociation of dimers to monomers. The results of circular dichroism (CD) and electronic absorption studies indicate that the slow dimerization process is preceded by an initial rapid Cd-induced rearrangement of the monomeric Cd7-MT structure. The 113Cd NMR spectrum of the MT dimer revealed only four 113Cd resonances at chemical shift positions similar to those observed for the Cd4 cluster of the well-characterized monomeric 113Cd7-MT. This result suggests that on dimer formation major structural changes occur in the original three-metal cluster domain of Cd7-MT.     

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.     

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.     

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.     

Cadmium binding to metallothioneins and the estimation of protein concentration using cadmium-saturation methods

The detailed spectral changes observed in the absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra upon addition of Cd²⁺ to rat liver Cd, Zn-metallothionein (MT) are reported. Results from dialysis experiments clearly demonstrate that up to 8.6 mole equivalents of Cd²⁺ can be bound to this protein. The excess Cd²⁺ ions bound appear to have lower binding constants than those of the first seven Cd²⁺ ions bound. Red blood cell hemolysate (RBC) can compete with the metallothionein for all Cd²⁺ bound in excess of seven mole equivalents. Thus the RBC hemolysate method of estimating protein concentrations is shown to be correct when based upon complete loading of all binding sites in MT with Cd²⁺.     

Displacement of zinc and copper from copper-induced metallothionein by cadmium and by mercury: in vivo and ex vivo studies

The in vitro affinity of metals for metallothionein (MT) is Zn less than Cd less than Cu less than Hg. In a previous study Cd(II) and Hg(II) displaced Zn(II) from rat hepatic Zn7-MT in vivo and ex vivo (Day et al., 1984, Chem. Biol. Interact. 50, 159-174). The ability of Cd(II) or Hg(II) to displace Zn(II) and/or Cu(II) from metallothionein in copper-preinduced rat liver (Zn, Cu-MT) was assessed. Cd(II) and Hg(II) can displace zinc from (Zn, Cu)-MT both in vivo and ex vivo. The in vitro displacement of copper from MT by Hg(II) was not confirmed in vivo and ex vivo. Cd(II) treatment did not alter copper levels in (Zn, Cu)-MT, as expected. Hg(II) treatment, however, did not decrease copper levels in MT, but rather increased them. The sum of the copper increase and mercury incorporation into MT matched the zinc decrease under in vivo conditions and actually exceeded the zinc decrease under ex vivo conditions. Short-term exposure of rat liver to exogenous metals can result in incorporation of these metals into MT by displacement of zinc from pre-existing MT. Displacement of copper from pre-existing MT by mercury, as predicted by in vitro experiments, was not confirmed under the conditions of our in vivo and ex vivo experiments. This result is explainable based on the differing affinities and/or preferences of the two metal clusters in MT.     

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.     

Circular dichroism studies of the HIV-1 Rev protein and its specific RNA binding site

The circular dichroism (CD) spectrum of the Rev protein from HIV-1 indicates that Rev contains about 50% alpha helix and 25% beta sheet at 5 degrees C in potassium phosphate buffer, pH 3, and 300 mM KF. The spectrum is independent of protein concentration over a 20-fold range. At neutral pH, Rev is relatively insoluble but can be brought into solution by binding to its specific RNA binding site, the Rev-responsive element (RRE), at a Rev:RNA ratio of about 3:1. Nonspecific binding to tRNA does not solubilize Rev. As judged by difference CD spectra, the conformation of Rev when bound to the RRE at neutral pH is similar to the conformation of unbound Rev at pH 3, although changes in the RNA may also contribute to the difference spectrum. Indeed, some difference is observed near 260 nm, consistent with a conformational change of the RRE upon Rev binding. Rev alone at pH 3 shows irreversible aggregation as the temperature is raised, while Rev bound to the RRE at neutral pH shows a reversible transition with a Tm of 68 degrees C.     

Molecular biology of copper. A circular dichroism study on copper complexes of thionein and penicillamine.

Chicken liver Cd, Zn-thionein (metallothionein) was isolated from Cd-pretreated chickens weighing 1 500 g. The native Cd, Zn-thionein contained 9 g-atoms of metals per 12 000 g of protein. Upon the addition of Cu(CH3CN)4ClO4, all Cd2 and Zn2 were successfully replaced. 15 g-atoms of Cu from the acetonitrile perchlorate complex were bound to the protein. Due to the absence of aromatic amino acid residues, thionein has unique ultraviolet and circular dichroism properties. The shoulder of the ultraviolet spectrum at 250 nm (A250 X A280(-1) = 23.9) was shifted to 275 nm (A250 X A280(-1) = 1.6). No significant absorption was detected in the visible region. Th conformational changes of the protein moiety were much more visible in the circular dichroism spectra. The titration with Cu(CH3CH)2 caused the appearence of three new Cotton effects: 257.5 nm (+), 350 nm (+) and 301 nm (-). The negative Cotton effect at 239 nm of the original metallothionein was completely levelled off. The binding strength of copper with thionein is extraordinarily high: it survives proton treatment up to pH 1.9. Displacement of the Cd2 by Cu employing Cd-thionein which was formed at pH 2.2 resulted in the same circular dichroism properties as observed for Cu-thionein. D-Penicillamine proved a suitable model for the metal-free thionein, since redox reactions and polymerization of the sterically hindered thiol residue are known to be slow. The correlation of the circular dichroism properties of either copper complex using thionein or D-penicillamine was surprisingly high. Circular dichroism measurements of Cu(I)-D-penicillamine revealed Cotton effects at 255 nm (+), 280 nm (+) and 355 nm (-). Upon examining the red-violet mixed Cu(-i)-cu(II)-D-penicillamine complex, Cotton bands in the visible region at 425 nm (-) and 495 nm (+) were seen. In many blue copper enzymes, the copper is assumed to be in the neighborhood of both cysteine and aromatic amino acid residues, which are known to play an important role in the electron transfer. This is not the case in the Cu-thionein, which would explain many different properties of this copper protein. It is very attractive to conclude that the sterically hindered SH-group of D-penicillamine reacts with excess copper in a specific way, similar to the Cu-thionein. This phenomenon could explain the considerable success of D-penicillamine in the treatment of Wilson's disease.     

Effects of heating at neutral and acid pH on the structure of beta-lactoglobulin A revealed by differential scanning calorimetry and circular dichroism spectroscopy

The structural change of beta-lactoglobulin A (betaLG A) on heating was measured at pH 3.0 and 7.5 with UV absorption difference spectra, differential scanning calorimetry (DSC), and circular dichroism (CD). At pH 3.0, betaLG A showed a reversible structural change by heating at 80 degrees C, while an irreversible change was observed and molecular aggregates of betaLG were formed by heating at 95 degrees C. DSC analysis of betaLG A gave endothermic peaks at 75 degrees C and 90 degrees C at pH 7.5, and 90 degrees C at pH 3.0. At pH 7.5, betaLG A modified with N-ethylmaleimide (NEM-betaLG A) gave two endothermic peaks: at 72 degrees C and 90 degrees C. CD spectra of betaLG A heated at various temperatures and pHs were measured and the spectra at pH 3.0 and 7.5 were not changed by heating to 95 degrees C and 80 degrees C, respectively. Unheated NEM-betaLG A gave a spectrum similar to that of heated betaLG A, suggesting that the secondary structure was changed by NEM treatment.