Simultaneous induction of Pb-metallothionein-like protein and Zn-thionein in the liver of rats given lead acetate.

Administration of a sublethal dose of lead acetate to rats induced the simultaneous synthesis of a Pb-metallothionein (Pb-MT)-like protein (Pb-BP) and Zn-thionein (Zn-BP) in the liver. The Pb-BP had an apparent molecule mass of 6900 Da and seemed to bind preferentially to lead in the liver cytosol. The Zn-BP was identified by comparison of the Mr, elution profiles from Sephadex G-75 and DEAE-Sephadex A-25 columns, and polyacrylamide-gel-electrophoretic mobility, with those of rat liver Zn-MT-II. The Pb-BP accumulated in the liver to a maximum 6 h after the intraperitoneal injection of lead acetate and accounted for about 60% of the lead in the liver cytosol at this stage. However, after that, it gradually decreased in the liver, until it was close to the basal amount 24 h after the induction. In contrast, the amount of Zn-MT increased gradually, reached a maximum 12 h after the administration of lead acetate and maintained a constant value until at least 24 h after the induction. Amino acid analysis of the Pb-BP indicated that it contained about 28% half-cysteine. These results strongly suggest that lead acetate induces the synthesis of Pb-MT as well as Zn-MT in rat liver.     

Isolation of copper thionein from rat liver

The inducible Cu-binding protein from adult rat liver previously referred to as Cu-chelatin has been purified and shown to be Cu-thionein. The Cu-protein was purified to homogeneity by gel filtration and thiopropyl-Sepharose chromatography. The Cu-thionein exhibited an amino acid composition similar but not identical to that of the two forms of rat liver Cd,Zn-thionein. The polypeptide-chain molecular weight of Cu-thionein was indistinguishable from that of Cd,Zn-thionein. The identification of the Cu-protein as metallothionein was substantiated by the complete immunological cross-reactivity with antisera prepared against purified rat liver Cd,Zn-thionein. Purified Cu-thionein bound 9–11 g atoms of Cu per mole of protein in an electron paramagnetic resonance nondetectable form. The $\text{Cu}\text{Zn}$ ratio of the protein is about 100. Ion-exchange chromatography resolved the Cu-protein into three polymorphic forms which differed from the polymorphism of Cd,Zn-thionein.     

Metal constitution of metallothionein influences inhibition of delta-aminolaevulinic acid dehydratase (porphobilinogen synthase) by lead.

This study was undertaken to evaluate the effect of Zn and Cd pretreatment on the inhibition of delta-aminolaevulinic acid dehydratase (ALAD; porphobilinogen synthase, EC 4.2.1.24) by Pb. Male CD rats were pretreated with 200 mumol of Zn/kg s.c. (subcutaneously) or 18 mumol of Cd/kg s.c., 48 and 24 h before assay of ALAD. Pretreatment with Zn resulted in activation of hepatic and renal ALAD and attenuated the inhibition of this enzyme by Pb in vitro. Pretreatment with Cd increased hepatic ALAD activity, and the inhibitory effect of Pb on the hepatic enzyme was attenuated in this group. In contrast with the situation in liver, pretreatment with Cd did not affect the activity of renal ALAD and did not alter the inhibitory effect of Pb on the renal enzyme. The Pb IC50 (concentration causing half-maximal inhibition) values for hepatic and renal ALAD in Zn-pretreated rats and for hepatic ALAD in Cd-pretreated rats were increased above control, whereas the IC50 for renal ALAD in Cd-pretreated rats was unchanged. Cytosolic binding patterns for the three metals were assessed by gel-filtration chromatography and disclosed that 203Pb was co-eluted with Zn and Cd bound to liver and kidney Zn-thioneins and liver Cd,Zn-thionein, although minimal binding of 203Pb to kidney Cd,Zn-thionein was observed. Estimation of the molar ratio of metals bound revealed Cd/Zn ratios of 2 and 5 for Cd,Zn-thioneins from liver and kidney respectively. The inhibition of purified ALAD by Pb was also attenuated by addition of purified Zn-thioneins and Cd,Zn-thioneins from liver and kidney in the following order: liver Zn-thionein = kidney Zn-thionein greater than liver Cd,Zn-thionein much greater than kidney Cd,Zn-thionein. Thus liver and kidney Zn-thioneins and liver Cd,Zn-thionein with a low Cd/Zn ratio readily decrease the free pool of Pb available to interact with ALAD. These data also demonstrate that the capacity of metallothionein to alter the intracellular distribution of Pb and mediate the inhibition of ALAD by Pb is dependent on the tissue source and relative metal constitution of the metallothionein.     

Induction and degradation of Zn-, Cu- and Cd-thionein in Chang liver cells

Human liver cells (Chang liver) were exposed to 5 micrograms Zn, 2.5 micrograms Cu or 1 microgram Cd/ml in cultured medium. These exogeneous heavy metals were accumulated by the cells and induced de novo synthesis of metallothionein after a 3-h incubation period. The production of Zn-, Cu- or Cd-thionein started in the cells with accumulation of 1 nmol Zn, 0.3 nmol Cu and 0.1 nmol Cd/mg cytosol protein and subsequently the amounts of metal-binding thioneins increased in agreement with the relative amount of metal accumulated in the cytosol over a 24-h period. When cells containing Zn- or Cu-thionein were placed in metal free medium, 70% or 25% of the zinc or copper bound to each original metallothionein was released after 3 h; bound metals decreased to 85% and 65% respectively after 24 h. The disappearance of metal from metallothionein correlated with increases of metal in the medium. On the other hand, 35S-counts incorporated into Zn- and Cu-thionein decreased only to 40% and 15% of the levels in the original metallothionein after 3 h; 35S-counts decreased to 65% and 45%, respectively, after 24 h, indicating that metals bound to metallothionein decreased more quickly than 35S-counts. These results suggest that metals were released from metallothionein and were excreted into the medium. However, 35S- and 109Cd-counts in Cd-thionein changed very little, if at all, in the cells even after a 24-h incubation period. Our data strongly suggest that Zn- and Cu-thionein are degraded in the cells, but that Cd-thionein remains longer than either Zn- or Cu-thionein. When cells containing Zn-thionein were incubated in metal-free medium, Zn-thionein was digested in the cells and peptide fragments ranging about 200-400 daltons were excreted from the cells.     

Differences in the polymorphic forms of metallothionein

Metallothionein induced in rat liver by metal ions can be resolved into two forms, referred to as isoforms I and II. These polymorphic forms differ in several properties. Sequence analysis of the CNBr-digested thionein isoforms revealed seven differences in the first 25 amino acids between isoforms I and II of Cd-induced thionein. The sequence of the first 25 amino acids in isoform II of Cu-induced thionein was identical to that of isoform II of Cd-induced thionein, suggesting that the same polymorphic forms are induced with different metal ions. Isoform II of Cd,Zn-thionein exhibited a reproducibly greater Stokes radius (17 Å) by gel filtration compared to isoform I (16.2 Å), whereas isoform II of Cu-thionein eluted with a Stokes radius of 16.2 Å. The isoforms also differ in Zn-binding affinity. Isoform I of several preparations of Cd,Zn-thionein and Zn-thionein invariably reconstituted greater esterase activity in apo-carbonic anhydrase than did isoform II. In Cd,Zn-thionein samples, only the Zn²⁺ ions were transferred to apo-carbonic anhydrase. Similarity, the Zn²⁺ ions in isoform I were more reactive with EDTA compared to isoform II. The greater reactivity of isoform I with EDTA was evident kinetically from spectrophotometric assays as well as thermodynamically from equilibrium dialysis experiments. The significance of these differences is unclear, but it is conceivable that the dissimilarities in the conformational and Zn-binding affinity of rat liver metallothionein may correlate with a functional distinction.     

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.     

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.     

Activation of pyridoxal kinase by metallothionein

Brain pyridoxal kinase, which uses ATP complexed to either Zn(II) or Co(II) as substrates, displays high catalytic activity in the presence of Zn-thionein and Co-thionein. Several steps intervene in the process of pyridoxal kinase activation, i.e., binding of Zn ions to ATP and interaction between Zn-ATP and the enzyme. Equilibrium binding studies show that ATP mediates the release of Zn ions from the metal-thiolate clusters of the thioneins, whereas spectroscopic measurements conducted on Co-thionein reveal that the absorption transitions corresponding to the metal-thiolate of the protein are perturbed by ATP. The binding Zn-ATP to the kinase proceeds with a delta G = -6.3 kcal/mol as demonstrated by fluorometric titrations. Direct interaction between the kinase and derivatized-metallothionein could not be detected by emission anisotropy measurements, indicating that juxtaposition of the proteins does not influence the exchange of metal ions. Since the concentration of free Zn in several mammalian tissues is lower than 1 nM, it is postulated that under in vivo conditions the concentration of metallothionein regulates the catalytic activity of pyridoxal kinase.     

Circular dichroism of metallothioneins. A structural approach.

A comprehensive study on circular dichroism of metallothioneins containing Zn, Cd and Cu was carried out. The contributions of the metals, the sulphur and the polypeptide chain to the observed Cotton effects was shown. From the pH dependency of the extrinsic Cotton effects which are due to the metal-thiolate chromophore the stability of the metal clusters was found to decrease in the order Cu greater than Cd greater than Zn. The pH values corresponding to the dissociation of half of the bound metal ions are 0.44 for Cu-thionein, 3.05 for Cd-thionein and 4.6 for Zn-thionein. The extrinsic Cotton effects of Cd, Zn-thioneins of varying Cd to Zn ratio could be simulated using the difference circular dichroic spectra of Cd-thionein (bands at 227, 242.5 and 262 nm), Zn-thionein (bands at 225 and 244 nm) and the circular dichroic spectrum of cysteine-thionein (band at 200 nm, shoulder at 225 nm). Since during the dissociation of the metals the circular dichroic spectra exhibited changes only in amplitude and not in shape we can conclude that the dissociation of the metal ions involves the complete sequential degradation of metal clusters. In the near-ultraviolet region the metal-free proteins show only Cotton effects attributable to a disulphide chromophore. Thus Cotton bands are observed for cystine-thionein at 282.5 and 260 nm. From the intrinsic circular dichroism of Cd- and Zn-thionein (negative Cotton effect at 200 nm, shoulder at 225 nm) it follows that the protein conformation consists of less than 5% helical or pleated sheet structure and therefore has to be classified as unordered structure or "fixed" random coil     

Effect of 2-mercaptoethanol on the electrophoretic behavior of rat and dogfish metallothionein and chromatographic evidence of a naturally occurring metallothionein polymerization

1. Metallothionein behavior in SDS-PAGE has been characterized. 2. It has been found that metallothionein behavior in this electrophoretic system depends upon the reducing environment. Migration as a well-defined protein band is only achieved in the presence of 2-100 mM 2-mercaptoethanol. 3. Within those 2-mercaptoethanol levels, both rat and dogfish metallothionein migrate as a protein with a molecular weight several times higher than that expected by amino acid analyses. This is not due to molecule oxidations, since this effect is promoted by the presence of 2-mercaptoethanol. 4. No effect of 2-mercaptoethanol on metallothionein behavior is found in conventional PAGE. 5. The present results suggest that to study the effect of 2-mercaptoethanol in SDS-PAGE is a simple and accurate way to identify a protein as metallothionein. 6. It has also been found that metallothionein aggregates naturally in the absence of ionic strength.     

Regulation of metallothionein gene expression and secretion in rat adipocytes differentiated from preadipocytes in primary culture.

The gene encoding metallothionein, a low mol. wt. metal binding and stress response protein, is expressed in white adipose tissue. In the present study, metallothionein (MT-1) gene expression and factors regulating metallothionein production have been examined in adipocytes induced to differentiate from fibroblastic preadipocytes in primary cell culture. On the induction of differentiation, the metallothionein-1 gene was strongly expressed in the cells and metallothionein released into the medium. A peak in metallothionein-1 mRNA level and metallothionein secretion occurred at 2 and 10 days post-differentiation, respectively, with a decrease in protein release after this time. The metallothionein-1 gene was expressed in the adipocytes prior to the adipsin and lipoprotein lipase genes, suggesting that it is an early marker of adipocyte differentiation. The addition of the glucocorticoid, dexamethasone, led to a substantial increase in metallothionein-1 mRNA in the cells and metallothionein secretion. Insulin and leptin also stimulated metallothionein production, although the effect was small. Neither noradrenaline nor the beta3-adrenoceptor agonist, BRL 37 344, altered metallothionein release but forskolin and bromo-cAMP were stimulatory, markedly increasing both metallothionein-1 level and metallothionein secretion. It is suggested that metallothionein is a novel secretory product of the differentiated white adipocyte and that its production is regulated particularly by glucocorticoids and through a cAMP-dependent pathway.     

Ubiquitin-metallothionein fusion protein expression in yeast. A genetic approach for analysis of ubiquitin functions

We have established a Saccharomyces cerevisiae genetic system that expresses the fusion protein ubiquitin-metallothionein. We have evaluated the effects of amino-terminal ubiquitination of metallothionein on the stability and function of metallothionein. The fusion protein of wild type ubiquitin and metallothionein was rapidly processed in vivo to release free ubiquitin and metallothionein. Site-directed mutants of ubiquitin-metallothionein expressed in yeast were used to study the specificity of the (alpha-NH2-ubiquitin) protein endopeptidases. The data suggest that amino-terminal ubiquitination is not a signal for the proteolysis of yeast metallothionein in yeast. We have also discovered that expression of selected ubiquitin mutants blocked the growth of yeast. The data suggest that in addition to its function as a proteolytic signal, ubiquitination of proteins plays multiple roles in the cell.     

Metal-binding proteins of the Syrian hamster ovaries: apparent deficiency of metallothionein

A deficiency of metallothionein, a high-affinity metal-binding protein thought to detoxify cadmium, has been observed in rat and mouse testes, tissues that are highly susceptible to the necrotizing and carcinogenic effects of cadmium. Like the testes, the ovaries undergo a hemorrhagic necrosis when exposed to cadmium, and female Syrian hamsters have recently been shown to be highly susceptible to cadmium. However, the nature of cadmium-binding proteins in the ovary is unknown; thus, this study was undertaken to define the nature of any such proteins in the Syrian hamster ovary. A low molecular weight (Mr) zinc- and cadmium-binding protein was detected in cytosol derived from the ovaries after gel filtration that eluted with a relative elution volume similar to authentic metallothionein. This protein was extractable by heat-treatment and sequential acetone precipitation. When such extracts were further purified with a reverse phase high performance liquid chromatography (HPLC) technique developed for the isolation of metallothionein isoforms, two forms were separated. However, neither of these could be classified as metallothionein on the basis of amino acid composition, since both were particularly low in cysteine, a very common amino acid in metallothionein. The ovarian protein also contained significant amounts of aromatic amino acids, unlike metallothionein--which is devoid of aromatics, and contained much more glutamate than metallothionein. Hamsters were also made resistant to cadmium-induced ovarian necrosis by zinc treatment. Such zinc treatment, however, did not alter levels of this protein, yet caused a marked induction of hepatic metallothionein. Likewise, cadmium treatment did not increase the levels of the ovarian metal-binding protein yet markedly induced hepatic metallothionein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dogfish metallothionein--II. Electrophoretic studies and comparison with rat metallothionein

A low-molecular weight metal-binding protein has been isolated and characterized as metallothionein in the liver of the dogfish (Scyliorhinus canicula). This protein is present in both male and female animals and both control and cadmium-treated (both water and i.p. administration) animals as revealed by SDS-PAGE studies. Dogfish metallothionein shows the same metal-dependent anomalous behaviour as rat metallothionein in SDS-PAGE. SDS-PAGE is a good method to identify a protein as metallothionein.     

Yeast metallothionein. Sequence and metal-binding properties

The protein product of the CUP1 locus in Cu-resistant Saccharomyces cerevisiae has been purified and characterized. The protein was found to lack the first 8 amino acids predicted by the nucleotide sequence of the gene. The residues removed from the amino-terminal region include 5 hydrophobic residues, two of which are aromatic. The unique amino terminus starting at Gln9 of the putative DNA translation product was observed for metallothionein purified in the presence of various protease inhibitors or from a pep4 mutant yeast strain deficient in vacuolar proteases. The remainder of the primary structure of the protein is equivalent to the decoded DNA sequence, so yeast metallothionein is a 53-residue polypeptide of molecular weight 5655. The isolated protein contained 8 copper ions ligated by 12 cysteines/molecule. Reconstitution studies of the apo-molecule revealed that 8 mol eq of Cu(I) conferred maximal stability against proteolysis and depleted the zinc content of zinc-saturated metallothionein. These assays suggested that the protein has 8 binding sites for Cu(I). Ag(I) ions bound to the protein with the same stoichiometry. Yeast metallothionein was also observed to coordinate Cd(II) and Zn(II) ions in vitro. In studies of direct binding, protection against proteolysis, and metal ion exchange, these divalent ions were found to associate with the protein with a maximal stoichiometry of 4 ions/molecule. Yeast metallothionein thus exhibits two distinct binding configurations for Cu(I) and Cd(II) as does the mammalian protein.     

Dynamic structure of metallothionein

Molecular sieve chromatography of rabbit liver metallothionein at different electrolyte concentrations revealed that this protein undergoes an increase in Stokes radius from 1.50 to 1.78 nm when the ionic strength is lowered from 0.5 to 0.015 indicating a change in molecular shape and/or hydration. The variation in ionic strength also affects the far-UV circular dichroism of metallothionein reflecting a conformational transition in the protein. The effects are attributed to changes in intramolecular repulsion between the strongly negatively charged metal-thiolate clusters of the protein. It is suggested that metallothionein exists in at least two interchangeable conformational states which differ in hydrodynamic properties and whose equilibrium concentrations are determined by the electrostatic free energy of the system.     

Fish and mammalian metallothioneins: a comparative study

Structural studies show that fish and mammalian metallothioneins are endowed of distinctive features. In particular, the ninth cysteine residue present in the alpha domain of fish metallothionein is shifted of two positions with respect to the mammalian metallothionein, introducing a conformational modification in the protein structure. In addition, the fish metallothionein is less hydrophobic and more flexible than its mammalian counterpart. Our previous studies showed that the hydropathy of piscine and mammalian metallothioneins is significantly correlated with organismal temperature. In the present paper we have performed phylogenetic comparative analysis on metallothioneins of 24 species of fish and mammals. The results of such analysis failed to indicate that metallothionein hydropathy is an adaptive response to the thermal regime of the species. We concluded that metallothionein hydropathy is a trait that did not evolve in association with environmental changes.     

Spectroscopic studies on Neurospora copper metallothionein

The spectral properties of Neurospora copper metallothionein were investigated and compared with those of the Cu(I)-2-mercaptoethanesulfonic acid complex. In both cases, the absorption spectra are rather similar, showing a characteristic shoulder at approximately 250 nm. However, marked differences were observed in their emissive properties. Thus, only metallothionein emits detectable luminescence in solution, but both the copper protein and the Cu(I) complex are luminescent at 77 K. The circular dichroism spectrum of Neurospora copper metallothionein shows several Cotton extrema attributable to asymmetry in metal coordination. The influence of HgCl2 and p-(chloromercuri)benzoate on the spectral properties of metallothionein was also investigated. The two mercurials exerted a pronounced effect on the electronic absorption, chiroptical, and emissive properties of the protein. Spectroscopic titrations followed by gel filtration experiments indicate that two mercurials can be bound per metallothionein molecule without loss of copper. This binding is responsible for the disappearance of the emissive properties of metallothionein and for the distinct changes in its electronic absorption and circular dichroism spectra. From these data, it is suggested that the Cu(I) ions are coordinated to the cysteinyl residues in the form of a single metal cluster.