Cadmium-copper interaction in intestinal mucosal cell cytosol of mice

In vivo as well as in vitro protein-metal interaction was studied in cytosolic fractions from intestinal mucosal cells. Female Swiss-Webster mice wre pretreated with cadmium (25 ppm) or copper (100 ppm) in drinking water for 3 weeks. Treatment groups were divided into subgroups receiving Cd or Cd+Cu for an additional 6 weeks. In the in vitro study, mucosal cytosol obtained from pretreated animals was incubated with Cd-109 or Cd-109+Cu. Proteins were separated by gel filtration chromatography and metals determined by furnace AAS or gamma-spectrometry. Cadmium-induced synthesis of metallothionein-like proteins (MTP) in cytosol was indicated by increased Cd in those eluted fractions corresponding to the molecular weight of purified equine renal metallothionein. This cadmium level reached a plateau after 3 weeks of cadmium treatment. In addition, an increased amount of cadmium bound to MTP was noted when copper was added to cadmium in drinking water of mice pretreated with copper. This was not the case for Cd-pretreated animals. The in vitro experiments produced similar results, in that MTP fractions retained a greater percentage of Cd when animals were pretreated with copper compared to controls. Cadmium pretreatment resulted in even higher amounts of cadmium bound to MTP. The existence of a Cd as well as a separate Cu MTP, each with specific metal-binding properties, is suggested.     

Relative cadmium-binding capacity of metallothionein and other cytosolic fractions in various tissues of the rat.

The Cd-binding capacity of soluble proteins in 10 tissues of normal rats not excessively exposed to heavy metals was measured by saturation of freshly isolated cytosol with 109CdCl2 in vitro followed by Sephadex G-75 chromatography. The Cd-binding capacity of a 10,000 molecular weight Cd-binding peak (10,000 MW Cd-BP), which had a high affinity for Cd and was probably metallothionein, was the highest in kidney (78nmol Cd/g fresh tissue), followed by testis (63 nmol/g), liver (38 nmol/g) and then by brain (14 nmol/g). The amount of the Cd-BP in these tissues (assuming that it was metallothionein and bound 9 mol Cd/10,000g) was calculated to be 87, 70, 42 and 16 mg/kg fresh tissue in kidney, testis, liver and brain, respectively, or in the order of 10(-5) to 10(-6) mol/kg tissue. A significant amount of the 10,000 MW Cd-BP was also found in small intestine. It was present in rather small amounts in heart and lung, and possibly in spleen and skeletal muscle as well. In contrast, the protein was not detectable by this technique in plasma. The results suggest that metallothionein is a rather ubiquitous, intracellular protein in tissues of normal animals and may have other biological functions, besides its possible fortuitous role in heavy metal detoxification. A 30,000 molecular weight Cd-binding peak (30,000 MW Cd-BP) having a very high affinity Cd, apparently higher than that of the 10,000 MW Cd-BP, was found only in testes, among the 10 tissues examined. Its estimated Cd-binding capacity was 51 nmol Cd/g of testis, slightly less than that of metallothionein in testis. These findings support the hypothesis that the 30,000 MW Cd-BP is a plausible target of Cd in Cd-induced testicular injury, and suggest a basis for the peculiar sensitivity of the rat testis to Cd.     

Low-molecular weight metalloproteins in tissues of the narwhal (Monodon monoceros)

Narwhal (Monodon monoceros) liver and kidney cytosol were fractionated by gel chromatography, anion-exchange chromatography and electrophoresis. Cadmium was associated largely with low molecular weight proteins, while mercury was associated also with high molecular weight proteins, but apparently not because of saturation of the metallothionein mechanism. Eight different electrophoretic bands, four of which were metalloproteins, were found under the "metallothionein" peak. Anion-exchange chromatography yielded five metal peaks while further fractionation on G-50 gave two peaks, one containing almost pure metallothionein (Mt-1) and the other a metalloprotein having twice the molecular weight of metallothionein. Mt-2 was observed, at a much lower concentration than Mt-1, in liver but not kidney.     

Cadmium-2-acetylaminofluorene interaction in isolated rat hepatocytes

Cadmium (Cd) is a non-essential, highly toxic heavy metal and a ubiquitous environmental contaminant. Evidence exists that Cd can affect parameters which are of great importance in the response towards xenobiotics. However, there is a lack of information about the mechanisms that take place at the cellular and molecular levels upon dual exposure to Cd and other toxins. The purpose of the present work was therefore to examine the biochemical interactions between Cd and a well-known genotoxic hepatocarcinogen, 2-acetylaminofluorene (AAF) in isolated rat hepatocytes. The cells were incubated for 10 hr with a sub-cytotoxic concentration (0.22 M) of ¹⁰⁹Cd. This was followed by a 10 hr exposure to 1 M [³H]AAF. Cellular distribution of Cd and ³H was determined. Sephadex G-75 elution profiles of the cytosol showed that Cd was almost entirely associated with the intermediate molecular weight (IMW) fractions containing metallothionein (MT) (>80%), and with high molecular weight proteins. In parallel, the highest proportion of ³H was found in the low molecular weight components. Further analysis of IMW fractions by DEAE A-25 anion-exchange chromatography revealed that, in addition to Cd, there was some ³H which coeluted along with MT-I and MT-II isoforms, but preferentially with MT-I. Moreover, Cd pretreatment caused a 1.6-fold increase in MT level, as measured by the silver-saturation assay. Under these conditions, there was a 17% lower binding of ³H to the DNA. This reduced binding was neither accompanied by diminished AAF uptake nor by inhibition of cytochrome P-450 activity. Taken together, these results suggest that Cd exposure has a protective effect against the genotoxicity of AAF. MT, whose synthesis is induced, could play a role in the Cd-AAF interaction through scavenging of reactive metabolites.Abbreviations AAF 2-acetylaminofluorene - Cd cadmium - DMSO dimethyl sulfoxide - HBSS Hank's balanced salt solution - LDH lactate dehydrogenase - MT metallothionein - UDS unscheduled DNA synthesis     

Some properties of a unique cadmium-binding moiety in the soluble fraction of rat testes.

A 30,000 molecular weight testicular Cd-binding peak (30,000 MW Cd-BP) previously implicated in Cd-induced testicular injury was unstable during storage with respect to apparent molecular weight determined by Sephadex G-75 chromatography. Storage of testicular cytosol labeled with 109Cd in vivo or in vitro for several days at 4 degrees C under nitrogen resulted in disappearance of the 30,000 MW Cd-BP and increased 109Cd uptake in other protein fractions. Rechromatography of the previously isolated 30,000 MW Cd-BP after storage gave rise to a 109Cd peak eluting in the higher molecular weight region. The latter effect was prevented by 1 mM dithiothreitol, suggesting that sulfhydryl groups were involved in the apparent aggregation. The 30,000 MW Cd-BP found in testes of rats was not present in testes of roosters, nor in liver and kidney of either species, providing further evidence of a correlation between the occurrence of 30,000 MW Cd-BP protein in the tissue and susceptibility to Cd-injury. The inability of parenterally administered HgCl2 to induce testicular injury compared to the same dose of CdCl2(0.011 mmol/kg) is apparently related to the poor uptake of Hg in the testes (one-eighteenth that of Cd) rather than to an inability of Hg to bind to the 30,000 MW Cd-BP. Our studies indicate that binding of Cd to this unique 30,000 MW testicular component, as yet unidentified, is a possible basis for the unique sensitivity of the testis to Cd injury.     

Effects of chelating agents on the cadmium burden of cells in culture

The effects of some new chelating agents on the cadmium burden of CHO cells in culture were investigated. The chelators were sodium-N-(4-methoxybenzyl)-D-glucamine-dithiocarbamate (MeOBG-DTC), sodium-N-benzyl-D-glucaminedithiocarbamate (BG-DTC) and di-isopropylmeso-2,3-dimercapto succinate (DiP-DMSA). The results were compared with the effect of the well known dimercaptopropanol (BAL).The derivates of dithiocarbamate are much less toxic than DiP-DMSA and BAL. All chelators effectively prevent Cd uptake into the cells. Mobilization of intracellular Cd, however, is more effective by the DTC-derivatives than by DiP-DMSA or BAL. Within the cell the major fraction of Cd after 48 hours incubation is found in the nuclei and cytosol and very little in the peroxisomes. The chelating agents remove the metal mostly from nuclei and cytosol. Incubation of the cells with cadmium leads to the induction of a Cd binding protein of an apparent molecular weight of 12500 Da, presumably metallothionein. MeOBG-DTC is more effective in removing the metal from this protein than BG-DTC.Abbreviations MeOBG-DTC Na-N(4-methoxybenzyl)-D-glucaminedithiocarbamate - BG-DTC Na-N-benzyl-D-glucaminedithiocarbamate - DiP-DMSA di-isopropyl-2,3-dimercaptosuccinate - BAL 2,3-dimercaptopropane-1-o1 - Da dalton - MEM minimum essential medium - IU international units - FBS fetal bovine serum - CD unbroken cells and debris - N nuclei - ML mitochondria, and lysosomes - P peroxisomes - HMW high molecular weight - MT metallothionein     

Partial purification and biological activity of liver metallothionein

The hepatic metallothionein was isolated and partially purified from rats treated previously with stable Cl2Cd and Cl2Cd109. The livers were subjected to the extraction of proteins of low relative molecular weight by heat, ammonium sulphate, Sephadex G-25 and Sephadex G-75. The partially purified extracts were subjected to the pharmacological activity test on isolated mouse vas deferens. A specific effect on the norepinephrine synapsis was obtained through an increment of the answer to the electric stimulus. The mechanism of action could be explained by the increase of the calcium permeability through the membrane or by the increment of the norepinephrine presynaptic release.     

Interaction of platinum with metallothionein-like ligands in the rat kidney after administration of cis-dichlorodiammine platinum II

After the administration of the anticancer drug cis-dichlorodiammine platinum II (cisplatin) to male rats, the Pt in the soluble fraction of the kidney is isolated, by gel filtration, in association with a high molecular weight component and a low molecular weight fraction. At 24 h, Pt is also recovered in a metallothionein-like fraction which elutes from Sephadex G-50 with a lower apparent molecular weight than endogenous (Cu, Zn)-thionein or Cd-thionein isolated from the kidneys of Cd2+-treated rats. None of these low molecular weight metal-binding fractions binds to Octyl Sepharose CL-4B. On DE-52 ion exchange chromatography, Cd-thionein is resolved into two isometallothioneins whereas the low molecular weight Pt-binding fraction is only partially purified and contains at least six components which elute at higher gradient concentrations than metallothionein. Pretreatment with Cd2+ which stimulates the synthesis of renal and hepatic metallothionein has no effect on the uptake and subcellular distribution of Pt in the liver and kidneys. Cisplatin treatment reduces the concentration of Cu and Zn in the renal metallothionein and other soluble protein fractions in the kidney. When administered to Cd2+-pretreated rats, cisplatin promotes the loss of Zn from the soluble protein fractions but causes the redistribution of Cd from the metallothionein to the high molecular weight fraction and fails to inhibit the Cd2+-induced accumulation of Cu in the kidneys and the binding of Cu to the soluble protein fractions. It is suggested that metallothionein probably does not have a significant role in the renal metabolism of Pt following the administration of cisplatin to rats.     

Detection of metallothionein on nitrocellulose membrane using Western blotting technique and its application to identification of cadmium-binding proteins

A convenient method for detecting metallothionein (MT) and other cadmium-binding proteins (Cd-BPs) in tissue cytosol was established. A sample that contains MT was separated on a sodium dodecyl sulfate-polyacrylamide gel and then electrophoretically transferred to a nitrocellulose membrane after reduction with 2-mercaptoethanol (2-ME) on the gel. The membrane was incubated in a buffer containing 109Cd and then subjected to autoradiography. MT-I and -II in rat liver cytosol were detected as radioactive bands together with a Cd-BP of 60,000 Da. On the other hand, three Cd-BPs of 40,000, 29,000, and 24,000 Da were detected in the cytosol when the reduction with 2-ME was omitted.     

Isolation of a novel rat testicular metalloprotein binding cadmium and zinc

Various testicular metal-binding proteins having apparent mol wt in the range of 10–30 kD have been demonstrated by gel filtration of¹⁰⁹Cd- or⁶⁵Zn-labeled cytosol, but in no case has a purified metalloprotein been isolated that contains stoichiometric amounts of the metal. The purpose of this work was to purify from rat testes a testes-specific 30 kD Cd-binding protein (Cd-testin) following in vitro addition of¹⁰⁹Cd to testis cytosol. Conventional purification methods similar to those used for purification of metallothionein could not be used because Cd was not retained in stoichiometric amounts by the 30 kD species when these methods were employed. However, using ammonium sulfate fractionation, hydrophobic interaction and gel filtration chromatography, a 30 kD protein containing 2.6 mol of Cd/ mol of protein was isolated. Two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis demonstrated that the isolated protein contained one major polypeptide with a mol mass of 22 kD and a pI of 4.6 (22 kD/pI 4.6) and two minor polypeptides (16 kD/pI 4.6 and 10±4 kD/pI 6.3) Two-dimensional gel electrophoresis demonstrated that the 22 kD species is a major low mol mass (<60 kD) protein in rat testic cytosol. The 22 kD protein was not detectable in cytosol of rooster testis, a tissue that is insensitive to Cd-induced damage and devoid of the 30 kD Cd-binding protein. Gel filtration and hydrophobic interaction chromatography of¹⁰⁹Cd- and⁶⁵Zn-labeled cytosol demonstrated that¹⁰⁹Cd and⁶⁵Zn cochromatography with the 30 kD protein. The function of this novel 30 kD testicular metal-binding protein is not known, but our work and other studies suggest that its occurrence in testes is linked to the production of a unique 22 kD polypeptide.     

Hepatic metallothioneins in two neotenic salamanders,Proteus anguinus and Necturus maculosus (Amphibia,Caudata)

The presence of metallothionein (MT) and the subcellular distribution of copper, zinc and cadmium were investigated in livers of two neotenic salamanders, Proteus anguinus and Necturus maculosus. In P. anguinus, caught in the wild, hepatic MTs were present as a single isoform of (Zn, Cu, Cd)-thioneins, whose molecular weight was estimated to be approximately 12000 by size exclusion chromatography. The percentage of zinc and cadmium was higher in the cytosol and of copper in the pellet. Cytosolic cadmium was almost exclusively associated with MTs (80%), while zinc and copper were also present in the regions of higher-molecular weight proteins. In laboratory bred N. maculosus, MTs were isolated from the liver cytosol and extract of the pellet as (Cu, Zn)- and (Zn, Cu)-thioneins, respectively. According to the low amount of copper extracting from liver pellets of N. maculosus, the presence of water insoluble aggregated forms of Cu-thioneins should be checked in further investigations.     

The binding of gold(I) to metallothionein

The binding of gold(I) to metallothionein, MT, has been unambiguously established by the reaction of Na₂AuTM with purified horse kidney MT. Zinc was displaced more readily than cadmium although the latter could be displaced using large Au/Cd ratios. The metal exchange reactions were complete within 2 hr of mixing. Further evidence that such reactions might be physiologically significant were obtained by studying in vitro metal displacements in the liver cytosol of in vivo metal treated rats: When Na₂AuTM was added to the cytosol of rats administered CdCl₂ in vivo, zinc, copper and cadmium were displaced in 2/1/1 ratios from the metallothionein fraction. The zinc and cadmium displacement provide direct evidence that the gold was binding to MT. Addition of Cd⁺² to liver cytosol of gold-treated rats resulted in displacement of copper and zinc, but not gold, from the MT fractions. When liver MT is prepared from rats exposed to Au or Cd, the Cd/protein ratio increased during the preparation, but the Au/protein ratio decreased. The Mt-bound metals account for 95% of the cytosolic Cd but only 15%–30% of the cytosolic gold in these studies. Thus, the nonspecific binding of gold to MT in vivo should be considered as one aspect in its equilibration among protein binding sites, which include, inter alia, metallothionein. Gold was found to coelute with zinc and cadmium in the MT fraction of rat kidney cytosol, when both Cd and Na₂AuTM were administered to the rats. The possible significance of gold binding to MT in the treatment of rheumatoid arthritis-chrysotherapy-is briefly discussed.     

Maleate induced change in the kidney binding of mercury in rats pretreated with cadmium

The kidney uptake of Hg2+ was increased by Cd2+-pretreatment when Hg2+ was given intraperitoneally but not subcutaneously. Subsequent s.c. administration of maleate increased Hg2+ release from the kidneys only if Hg2+ was given subcutaneously. Neither the effect of Cd2+, nor that of maleate, on the distribution of Hg2+ among the renal soluble protein fractions was affected by the route of Hg2+ administration. The protective effect of Cd2+-pretreatment against the nephrotoxic effect of Hg2+ was also independent of the route of Hg2+ administration. Maleate given in nephrotoxic doses removed Hg2+ and copper, but not Cd2+ from the renal metallothionein fraction. Mercury in the urine, however, was not complexed by proteins with the molecular weight of thionein, but was bound to high molecular weight proteins and diffusible molecules. These findings are discussed in relation to the role of metallothionein in the interaction between Cd2+ and Hg2+.     

Isolation of a novel metal-binding protein from rat testes. Characterization and distinction from metallothionein

This study was undertaken to further establish the nature of the low molecular weight metal-binding proteins in rat testes. In all cases, control testes were compared to livers of zinc-treated rats, which are known to contain high concentrations of metallothionein. Gel filtration of testicular and hepatic cytosol revealed a major zinc- and/or cadmium-binding protein in the low molecular weight range in both tissues. This protein could be partially purified from either source by a combination of heat treatment and sequential acetone precipitation. When such partially purified preparations were further fractionated by high performance liquid chromatography using a linear gradient of 25%-40% acetonitrile in 0.1% trifluoroacetic acid, two major forms with similar retention times were seen in each tissue. The utility of this high performance liquid chromatography system for separating isoforms of metallothionein was verified by separation of commercially available purified rabbit hepatic metallothionein into a total of five separate forms. Amino acid analysis of the two proteins derived from rat liver was consistent with the known amino acid composition of metallothionein. However, the two testicular forms separated by high performance liquid chromatography were notably different in amino acid composition from metallothionein, with a distinctly lower content of cysteine. These results indicate that the major low molecular weight cadmium/zinc-binding proteins in rat testes are not metallothioneins.     

The influence of dietary and waterborne zinc on heat-stable metal ligands in rainbow trout, Salmo gairdneri Richardson: quantification by 109Cd radioassay and evaluation of the assay

The ¹⁰⁹Cd binding assay of Eaton & Toal was critically evaluated and then used to assess the induction of cytosolic metal-binding ligands in rainbow trout exposed to Zn in the diet and/or in the water for 16 weeks. With purified rabbit Cd-Zn metallothionein (MT), ¹⁰⁹Cd binding and total Cd recovery in the assay were linear up to 5 μg of protein; gel chromatography revealed a single peak. With heat-denatured extracts of gill, liver and intestine from control and Cd- and Zn-injected trout, ¹⁰⁹Cd binding was generally linear with sample size. Gel chromatography demonstrated that ¹⁰⁹Cd was bound by a protein with the same apparent weight as MT (∼ 11000 daltons), but significant binding occurred also at three other regions [molecular weight (mol wt) >70 000, 30000 and <3000]. In the dietary/waterborne Zn exposure, induced ¹⁰⁹Cd-binding activity occurred not in the MT peak but in the low mol wt peak (< 3000). Activity in the gill rose in response to both dietary and waterborne Zn, but the liver did not respond. The maximum five-fold elevation in the gill was primarily a waterborne effect. In the intestine, the maximum rise was 25-fold due to both factors. The thresholds for induction were > 39 μg Zn^| in water, and > 90 mg kg ^| in the diet, but only when waterborne Zn was also high. There was no correlation between ¹⁰⁹Cd binding and acid soluble thiol levels, which tended to decline at higher Zn exposures.     

Effects of feeding on zinc and cadmium accumulation by the polychaete Neanthes arenaceodentata

Abstract

The effects of feeding on the kinetics of accumulation and depuration of ⁶⁵Zn and ¹⁰⁹Cd and on the subcellular distribution of these metals has been studied in the polychaete Neanthes arenaceodentata (Moore). Feeding increases the rate of accumulation of Zn and Cd and decreases the length of time for the metals to reach a steady state concentration in the animals. These effects can be attributed to the adsorption of metals from the medium by the algal food. Feeding does not have a marked effect on the depuration of either of the metals. Both metals are lost in a biphasic manner. The initial phase probably represents the elimination of unassimilated metals from the gut lumen.

Feeding does not dramatically alter the subcellular distribution of the metals. Zinc is found primarily in the 200 g pellet while Cd is primarily found in the cytosol associated with two Cd- binding ligand pools with apparent molecular weights of 9.7 and 5.0 kDa. The former co-elutes with purified metallothionein. The latter contains the majority of the Cd in the cytosol and is prominent in fed organisms. The use of these ligands as subcellular indicators of metal induced stress is discussed.     

Growth and Heavy Metal Binding Properties of Transgenic Chlamydomonas Expressing a Foreign Metallothionein Gene

We have compared the growth rates and cadmium binding capacity of wild-type and transgenic Chlamydomonas reinhardtii cells expressing a foreign class-II metallothionein. We observed that cells expressing metallothionein grew to significantly higher cell densities than wild-type cells in the presence of a toxic cadmium concentration (40 μM). When grown at a low (5 μM) cadmium concentration, cells expressing metallothionein bound twofold more cadmium (0.43 μg Cd)mg Ch1) than wild-type. At cadmium concentrations (40 μM), which induce phytochelatin synthesis in wild-type cells the cadmium binding capacity of both wild-type (79.6 μg Cd)mg Ch1) and transformed cells (86.4 μg Cd)mg Ch1) was similar; however, the transformed cells grew to higher densities than the wild type. These results suggest that under conditions that apparently induce phytochelatin expression, the presence of metallothionein in the cytoplasm reduces heavy metal toxicity. Furthermore, because cells expressing metallothionein grow to higher densities than wild-type cells at a toxic cadmium concentration (40 μM), the transgenic cells sequester more total cadmium (9% of total Cd) from the medium than the wild type (5.5% of total Cd). These results indicate that the trace-metal binding properties of Chlamydomonas can be enhanced through the expression of trace-metal-specific binding proteins.     

Expression of the Neurospora crassa metallothionein gene in Escherichia coli and its effect on heavy-metal uptake

The gene coding for the Neurospora crassa metallothionein protein was chemically synthesized and cloned into the fusion expression vectors pMal-c and pMal-p. Cell-fractionation experiments demonstrated the proper localization of the pMal-c- and pMal-p- expressed proteins to the cytosol and periplasm of the bacteria respectively. Control bacteria as well as the recombinant bacteria producing the metallothionein protein were incubated with solutions of ¹⁰⁹Cd at concentrations of 0.2 M, 1 M, and 10 M. The recombinant bacteria were able to accumulate significantly more ¹⁰⁹Cd than control bacteria at all concentrations tested. Cadmium accumulation was rapid and highly selective. Maximum uptake was achieved at a pH of 7.0, with lower accumulation at lower or higher pH values. The pH-dependent uptake of cadmium by the recombinant bacteria was exploited to strip off the bound cadmium from the recombinant bacteria and to regenerate most of the cadmium-binding sites. These observations suggest the potential for using a metallothionein-based biosorbent for certain heavy-metal removal applications.     

Prevention by copper of cadmium sequestration by metallothionein in liver.

Following chronic CdCl2 administration to rats, more than 98% of the metal in liver supernatant is bound to the low molecular weight binding protein, metallothionein. Simultaneous administration of high doses of Cd and copper salts result in an increase in toxicity which is accompanied by a failure of Cd sequestration by metallothionein in vivo. This may be due to an aggregation of metallothionein which has been observed in the presence of copper in vitro.