The role of Cu(I)-thiolate clusters during the proteolysis of Cu-thionein

Rat liver Cu,Zn-[35S]thionein and yeast Cu-thionein were subjected to proteolysis in vitro using equilibrium dialysis. The partially copper-loaded vertebrate thionein (2-7 Cu/mol) was affected by different proteases including thermolysin, proteinase K, protease from Streptomyces griseus and lysosomal enzymes. Unlike the 2Cu-thionein the respective 7Cu-thiolate-centred metallothionein was hardly proteolytically digested. In contrast to fully copper-loaded native yeast Cu-thionein both the H2O2-oxidized and the metal-free protein were effectively cleaved in the presence of proteinase K. It is important to realize that the native Cu(I)-thiolate chromophore survives the proteolytic attack. When the copper-sulphur bonding is broken and the same amount of copper is unspecifically bound to the thionein portion, proteolysis proceeds identically with respect to the rate observed in the presence of the apoprotein. The unsuccessful proteolysis of native Cu-thionein is not attributable to a simple copper-dependent inhibition of the proteinases. It is suggested that prior to proteolysis the copper-sulphur clusters must be destroyed.     

Copper-thionein in leucocytes

Summary Upon incubation of peripheral leucocytes with copper sulphate a dramatic cellular copper uptake reaching levels of 25–50-fold compared to that of the natural copper content was measured. The orange-red fluorescence of the copper-treated white blood cells was assigned to the formation of Cu(I)-thiolate clusters in Cu(I)-thionein. A protein of 6–8 kDa was isolated from homogenized bovine leucocytes and characterized by its electronic absorption and amino acid composition to be identical to the above Cu(I)-thionein. More than 70% of the intracellular copper was attributed to this protein in its monomeric and polymeric form. Cu-thionein formation was more pronounced in monocytes than in granulocytes. As most intriguing phenomenon, the release of this Cu-thionein from leucocytes, was also noticed. The occurrence of Cu-thionein in leucocytes and the excretion of the intact Cu(I)-thiolate protein is of considerable interest with respect to the observed elevated copper levels in white blood cells and plasma during tumor malignancies and inflammatory processes.     

Copper-release from yeast Cu(I)-thionein by hypothiocyanite (OSCN−)

In the course of an oxidative burst oxygen free radicals and hypothiocyanite (OSCN^–), a transiently abundant derivative of thiocyanate (SCN^–), are formed in the presence of activated polymorphonuclear leukocytes (PMNs). At the same time Cu(I)-thionein is present and the question arose whether or not thiocyanate and its oxidized form may transiently release highly Fenton active copper to improve the efficacy of the above mentioned oxidative burst. Thus, the reaction of yeast Cu-thionein with OSCN^– was examined. Indeed, a release of copper from the Cu(I)-thiolate clusters of the protein was observed ex vivo. Both the chiroptic and luminescence emission signals of Cu-thionein essentially levelled off in the presence of a 15-fold molar excess of OSCN^– expressed per equivalent of thionein-copper. The effective copper-releasing activity of this reagent was confirmed by equilibrium dialysis. The demetallized protein could be reconstituted under reductive conditions. SCN^– did not affect the copper-thiolate bonding. It rather acts as a potent metabolic source for the transient copper release from Cu-thionein in the presence of activated PMNs.     

Reconstitution of stellacyanin as a case of direct Cu(I) transfer between yeast copper thionein and 'blue' copper apoprotein

It was of interest to examine whether yeast Cu-thionein could be used to transfer the thiolate bound copper directly into the copper binding site of 'blue' apoproteins which contain free thiol groups. In particular apo-stellacyanin was used in the present study and it was found to be able to accept Cu(I) from yeast Cu-thionein, without any detectable unspecific Cu(II) intermediate, both aerobically and anaerobically.     

Cu(II) transfer into apo-Cu2Zn2-superoxide dismutase from Cu-thionein oxidized by activated leukocytes

The leukocyte-induced oxidative cleavage of yeast Cu(I)-thionein was examined. Oxidation was followed by the progressive decline of the specific Cotton bands attributed to the Cu(I)-thiolate chromophores between 400 and 270 nm. Despite many potent and competitive copper binding sites certainly present in leukocytes, the reconstitution of apo-Cu₂Zn₂-superoxide dismutase was expected due to its higher thermodynamic stability. Both enzymic activity measurements and characteristic Cu(II) EPR properties of Cu₂Zn₂-superoxide dismutase supported a successful reconstitution. The most favoured pathway for releasing Cu(II) from Cu-thionein was suggested to be an enzyme- controlled oxidation.     

Oxidation-reduction reactions of copper-thiolate centres in Cu-thionein.

Cu-thionein from yeast was investigated by EPR spectroscopy to probe the oxidation state of copper, and the effects on it of oxidizing and reducing agents. At pH 0.2 the copper was released, but no EPR signal from Cu(II) was observed, unless air was present. Optical experiments did not detect any disulphide groups which might have been formed during anaerobic release of copper. The mercurial, p-hydroxymercuribenzoate caused the release of EPR-detectable copper only under aerobic conditions, and EDTA caused release of Cu(II) on heating. No reduction of the copper-thiolate units in Cu-thionein by ascorbate was detected. Potentiometric titrations with hexachloroiridate(IV) or hexacyanoferrate(III) produced several different Cu(II) EPR signals at various stages of oxidation. The former oxidizing agent required a lower oxidation-reduction potential (+350 mV) to oxidize the copper, than the latter (+410 mV) and neither titration was fully reversible. The EPR signal from Cu(II) oxidized by hexachloroiridate(IV) resembled that produced by p-hydroxy-mercuribenzoate in air, suggesting that the copper was released from its thiolate ligands. It is concluded that the EPR non-detectable copper in the native protein is Cu(I). Oxidation-reduction of the copper-thiolate clusters of Cu-thionein is proposed to be decisive for controlling storage and transport of cellular copper.     

Copper transport from Cu(I)-thionein into apo-caeruloplasmin mediated by activated leucocytes.

A study on the transfer of copper from Cu-thionein into apo-caeruloplasmin, using Cu-thionein that was previously oxidised by activated leucocytes, was performed. Cu(I)-thiolate oxidation was conveniently monitored by the progressive decline of the specific Cotton bands between 400 and 300 nm. The characteristic e.p.r. properties and NN-dimethyl-p-phenylenediamine oxidase activity indicated a successful formation of caeruloplasmin. Taking into account the simultaneous occurrence of leucocytes, apo-caeruloplasmin and Cu-thionein in blood plasma, such an interaction would favour a possible metabolic link between either copper protein.     

Differently bound copper(I) in yeast Cu8-thionein

The reactivity of yeast Cu-thionein in the presence of the Cu(I)-chelators, bathocuproinesulphonate and cuproine, was examined to distinguish between possible differently coordinated Cu(I). Electronic absorption measurements revealed that two out of eight coppers of the protein reacted within seconds with the chelator. At the same time, the shape and magnitude of the characteristic Cotton bands attributable to the Cu(I)-thiolate chromophores remained constant. Due to the successful removal of circular dichroic silent copper, all specific theta Cu values rose by 53% of the original value. Thus, it is strongly suggested that two or more distinct types of Cu(I) ought to be present in Cu8-thionein. In the light of the many different Cu/cysteine ratios of Cu-thioneins from vertebrate and microbial origin, possible interconversion reactions of the Cu(I)-thiolate centres seem to be likely.     

Copper transfer through the intestinal wall Serosal release of metallothionein

Summary The elucidation of the molecular side of copper transport in biological systems is a promising task. In this context the transfer of ingested copper into the portal blood plasma was examined. Intralumenal addition of 200 M copper caused the release of Cu-thionein into the venous effluent. This Cu-thionein became detectable after prior perfusion of the porcine small bowel using a modified isotonic phosphate-buffered saline (P_i/NaCl) medium. The protein was characterized by gel chromatography, luminescence, electronic absorption and immunological identification. ELISA and immunoblotting employing a murine monoclonal antibody to rat liver metallothionein-I proved to be most convenient. Using buffer-loaded sacs of porcine jejunum into which Cu²⁺, Zn²⁺ and Cd²⁺ were added, the release of metallothionein into the serosal fluid was successfully seen by ELISA. The observed excretion of metallothionein into the portal compartment may be a genuine metal transport system for many biochemically active metals.     

Copper reduction by yeast cell wall materials and its role on copper uptake in Debaryomyces hansenii

Copper binding reducing activities of cell wall materials (CWM) prepared from cells of the yeast Debaryomyces hamsenii were examined. When CWM was treated with copper sulfate (0.1 mM CuSO₄), the copper was partially reduced from Cu (II) to Cu (I) and bound to CWM (below 10 nmol per mg dry wt.). The bound copper was mostly in the fraction of mannan-protein. Both copper-binding ability and protein content decreased with protease treatments. Mannan-protein prepared from CWM bound more copper than mannan did. This suggests that Cu (II) bound to the protein portion in CWM and was reduced to Cu (I). The optimum pH of copper reduction by CWM was about 5.0. The amount of copper bound to CWM increased with reducing agents and decreased with oxidizing agents. On the other hand, the copper uptake by yeast whole cells and spheroplasts was also stimulated by reducing agents, but inhibited by oxidizing agents. Furthermore, copper uptake by spheroplasts was stimulated in the presence of CWM. The optimum pH of copper uptake coincided with that of copper reducing activity. These results suggest that yeast cell wall not only supplies copper binding but also reduces copper, and the reduced copper is transported into yeast cells. The yeast cells may have copper-reducing proteins in the cell wall.     

Overexpression, Purification, and Characterization of Human and Bovine Mitochondrial ATPase Inhibitors: Comparison of the Properties of Mammalian and Yeast ATPase Inhibitors

Mitochondrial ATP synthase (F₁F₀-ATPase) is regulated by an intrinsic ATPase inhibitor protein. In this study, we overexpressed and purified human and bovine ATPase inhibitors and their properties were compared with those of a yeast inhibitor. The human and bovine inhibitors inhibited bovine ATPase in a similar way. The yeast inhibitor also inhibited bovine F₁F₀-ATPase, although the activity was about three times lower than the mammalian inhibitors. All three inhibitors inhibited yeast F₁F₀-ATPase in a similar way. The activities of all inhibitors decreased at higher pH, but the magnitude of the decrease was different for each combination of inhibitor and ATPase. The results obtained in this study show that the inhibitory mechanism of the inhibitors was basically shared in yeast and mammals, but that mammalian inhibitors require unique residues, which are lacking in the yeast inhibitor, for their maximum inhibitory activity. Common inhibitory sites of mammalian and yeast inhibitors are suggested.     

Release of copper from yeast copper-thionein after S-alkylation of copper-thiolate clusters.

Our knowledge on the release of copper from Cu-thionein in biological systems is limited. Other than oxidative cleavage or direct transfer, the possibility of an alkylation mechanism seemed attractive. Iodoacetamide and methyl methanesulphonate were successfully employed to alkylate the Cu-thiolate sulphur atom of homogeneous Cu(I)-thionein from yeast. The alkylation caused a weakening of the Cu-S bonding, which led to the release of copper. After equilibrium dialysis a proportion of the released copper was found in the dialysis buffer. When iodoacetamide was used carboxymethylcysteine was detected in the protein hydrolysate. A 10-fold molar excess over cysteine was sufficient for complete alkylation, which could be conveniently monitored by c.d. at 328 and 359 nm. The reaction proceeded under both aerobic and anaerobic conditions. E.p.r. measurements of Cu2+ revealed unequivocally the complete cleavage of the Cu-thiolate bonding in less than 5 h. It is possible that this mode of copper release might be of relevance to the molecular transport of this biochemically important transition metal.     

Metal binding sites of rat liver Cu-thionein

Cu-thionein purified from rat liver contains 10 g atoms Cu per mole protein. EPR and NMR bulk susceptibility studies indicate that the copper ions are bound in a diamagnetic state. Purification of the metalloprotein anaerobically results in a sample in which 18 cysteines can be titrated by 2,2-dithiodipyridine. Only 10–12 cysteines could be titrated in aerobically prepared samples. The copper ions in aerobically prepared Cu-thionein are more easily removed by ethylenediaminetetraacetic acid and diethylenetriaminepentaacetic acid than are the ions in the anaerobically purified protein. Likewise, the Cu ions in aerobically prepared Cu-thionein molecules have the ability to reactivate aposuperoxide dismutase and to bind to apocarbonic anhydrase whereas the metal ions in anaerobically prepared Cu-thionein molecules do not. A qualitative correlation was found between the extent of sulfhydryl oxidation in Cu-thionein and the reactivity of thionein-bound Cu ions with chelators such as the apometalloenzymes. The reconstitution assay system represents a sensitive indicator of the reactivity of Cu-thionein. The results suggest that rat liver Cu-thionein is very susceptible to oxidation and the Cu-binding affinity varies accordingly.     

Purification and characterization of a methanol-induced cobamide-containing protein from Sporomusa ovata

The major cobamide-containing protein from methanol-utilizing Sporomusa ovata was 8-fold enriched to apparent homogeneity. The protein exhibited a molecular mass of 40 kDa and of 38 kDa determined by gel filtration and by SDS-polyacrylamide gel electrophoresis, respectively. This finding indicates a monomeric protein structure. Monospecific polyclonal antisera raised against the protein did not cross react with another cobamide-containing protein from Sporomusa cells. Only the 40 kDa cobamide-containing protein was induced by methanol, since proteins from cells grown on 3,4-dimethoxybenzoate, betaine H₂/CO₂, or fructose showed faint or no cross reaction. Hence, the 40 kDa cobamide-containing protein is presumably involved in the methyltransfer reaction of the methanol metabolism. The purified enzyme revealed 1.1 mol of p-cresolyl cobamide per mol of protein, but it lacked of iron-sulfur centers. Remarkably, the cofactor was firmly bound to its protein.     

Cobalt-(cysteinyl)4 tetrahedra in yeast cobalt(II)-thionein

The conversion of yeast Cu(I)-thionein into the Co(II) derivative was successful. 2.6 Co atoms were incorporated per mole of protein yielding a Co : S ratio of 1 : 3. The electronic absorption of this highly air sensitive Co(II)-thionein is virtually identical to those of the Co(II) derivatives of other metallothioneins originating from vertebrates and N. crassa. Weaker Cotton extrema are noticed and the two doublet splittings of Cu-thionein disappeared. Throughout the molar ellipticities of the cobalt protein were markedly lower compared to those of the Cu-thionein. Owing to the characteristic charge transfer bands and d-d transitions a tetrahedral Co-thiolate coordination was deduced. The best fit proposal maintaining the above Co : S ratio of 1 : 3 was a six-membered ring with three bridging cysteine sulphurs.     

Prostaglandin I2 as a potentiator of acute inflammation in rats

Prostaglandin I₂ potentiated the paw swelling induced by carrageenin in rats. Prostaglandin I₂ (0.1 μg) showed similar activity to PGE₁ (0.01 μg). This potentiating property disappeared in 60 minutes and was completely abolished by diphenhydramine (25 mg kg⁻¹, i.p.). In vascular permeability tests, PGI₂ itself (2.5 × 10⁻¹⁰ mol, 88 ng) caused no dye leakage reaction, but PGE₁ (2.5 × 10⁻¹⁰ mol, 88.5 ng) caused a significant dye leakage. This effect of PGE₁ was statistically significant compared with vehicle- or PGI₂-treated group (p<0.05). Prostaglandin I₂ potentiated the increased vascular permeability induced by 5-hydroxytriptamine (2.5 × 10⁻¹⁰ mol), bradykinin (5 × 10⁻¹⁰ mol) and histamine (2 × 10⁻¹⁰ to 2 × 10⁻⁸ mol). The potentiation was the most evidence in the case of histamine.     

Does 13C-or 15N-labeling affect Cu(I)-thiolate cluster arrangement in yeast copper-metallothionein?

It was attempted to examine whether or not isotope labeling may possibly affect an oligonuclear metal-thiolate cluster. Cu-metallothioneins are known to contain strongly distorted Cu-thiolate clusters and seemed appropriate for this study. Thus, yeast ¹³C-and ¹⁵N-Cu-metallothioneins were isolated from Saccharomyces cerevisiae cells grown in a minimal synthetic medium and some physicochemical parameters were compared with those of the unlabeled Cu-thionein. Surprisingly, the ¹³C- and ¹⁵N- labeled Cu₇-thioneins are distinctly different in their characteristic spectroscopic properties. The electronic absorption was blue-shifted while both luminescence emission and chiroptic features display a distinct red shift with markedly diminished intensities, respectively. Contrary to common knowledge that isotope labeling does not affect the molecular architecture of a protein the present results support such a phenomenon. Attributable to the fortunate happenstance that there is a strongly distorted structural situation in the oligonuclear Cu-thiolate cluster this isotope effect came to light.     

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.     

Chemiluminescence Assays of Cu2Zn2 Superoxide Dismutase Mimicking Cu-Complexes

The aqueous decay of K₃CrO₈ was used to compare the reactivity of Cu₂Zn₂ superoxide dismutase and two active centre analogues where the first shell atoms around the copper are four unsaturated nitrogens. Unlike the acetate or biuret type Cu(II) chelates these di-Schiff-base complexes had an identical reactivity compared to that of the intact enzyme. Nanomolar concentrations of copper coordinated in these complexes were sufficient to inhibit the K₃CrO₈ induced chemiluminescence by 50%.

Furthermore, a lucigenin amplified chemiluminescence assay based on isolated polymorph nuclear leucocytes in the absence and presence of whole, unseparated blood was developed and successfully employed. CuPu(Im), and CuPu(Py), equivalent to 0.5 and 0.8 SOD units. only, were required to inhibit the photon emission by 50% in the absence of bovine serum albumin. Even in the presence of 600 μM albumin mimicking the competitive copper chelation in biological fluids Cu-Pu(Py)₂ and CuPu(lm)₂ remained active, whereas the carboxylate-and biuret type chelates Cu(Sal)₂ and Cu(Ser)₂ reacted like CuSO₄ The same reactivity of these low M, SOD mimics was seen in human blood.     

A comparative structural and functional analysis of cyanobacterial plastocyanin and cytochrome c 6 as alternative electron donors to Photosystem I

Plastocyanin and cytochrome c ₆ are two soluble metalloproteins that act as alternative electron carriers between the membrane-embedded complexes cytochromes b ₆ f and Photosystem I. Despite plastocyanin and cytochrome c ₆ differing in the nature of their redox center (one is a copper protein, the other is a heme protein) and folding pattern (one is a β-barrel, the other consists of α-helices), they are exchangeable in green algae and cyanobacteria. In fact, the two proteins share a number of structural similarities that allow them to interact with the same membrane complexes in a similar way. The kinetic and thermodynamic analysis of Photosystem I reduction by plastocyanin and cytochrome c ₆ reveals that the same factors govern the reaction mechanism within the same organism, but differ from one another. In cyanobacteria, in particular, the electrostatic and hydrophobic interactions between Photosystem I and its electron donors have been analyzed using the wild-type protein species and site-directed mutants. A number of residues similarly conserved in the two proteins have been shown to be critical for the electron transfer reaction. Cytochrome c ₆ does contain two functional areas that are equivalent to those previously described in plastocyanin: one is a hydrophobic patch for electron transfer (site 1), and the other is an electrically charged area for complex formation (site 2). Each cyanobacterial protein contains just one arginyl residue, similarly located between sites 1 and 2, that is essential for the redox interaction with Photosystem I. This revised version was published online in June 2006 with corrections to the Cover Date.