The interaction of cadmium and certain other metal ions with proteins and nucleic acids

Quantitative aspects of metal ion content and toxicity in Drosophila

As a basis for both a genetic and a biochemical approach to a study of metal ion effects, a method for quantitating the toxic response of Drosophila to metal ions was developed. The response to 13 metal ions has been examined, including several chemical groups from the periodic table: the IIb ions Zn2+, Cd2+, and Hg2+; the IIa ions, Be2+, Mg2+, Sr2+, and Ba2+; the transition elements, Ni2+, Cu2+, Co2+, and Mn2+: and trivalent ions, Y3+ and Cr3+. The standard test procedure provides estimates of the median lethal concentration (LC50) and the range of the tolerance distribution both of which are obtained by the method of probit transformation. Range is defined as the change in concentration between the LC2.5 and the LC97.5. Estimation of range as the measure of the limits of the tolerance distribution was utilized to measure variation in the response to metals with time. Genetic characterization of strains will require strains of flies without overlapping tolerance ranges. Although there was a general trend of increasing values of range with increasing LC50 values, the exceptions (e.g., Cr3+ and Be2+) indicated that several factors may be involved in determining the range of lethal responses. Elemental analyses have been performed on flies before and after metal ion treatments to establish the amount of metal ion taken up and baselines for comparison. This study provides additional evidence that Drosophila is an appropriate organism for the study of specific biochemical alterations induced by metals, e.g., the cadmium-induced increase in Q(+)tRNAs.

Reduced Cd2+ accumulation and elevated metallothionein levels in a Cd2+ and Zn2+-resistant clonal CHO-K1 cell line

A clonal cell line, R40F, was selected from a heterogenous population of Cd2+ and Zn2+-resistant CHO-K1 cells. These R40F cells demonstrated resistance to 120- and 4-fold higher concentrations of Cd2+ and Zn2+, respectively, than did wild type CHO-K1 cells. When cultured in the presence of low concentrations of Cd2+ (0.5-1.0 microM), the accumulation of intracellular Cd2+ in R40F cells appears to be significantly less than in wild type cells. Since R40F cells maintained in medium containing high concentrations of Cd2+ (200 microM) retain levels of Cd2+ equivalent to the intracellular concentration observed in wild type cells exhibiting cytotoxicity, it is assumed that reduced Cd2+ transport alone is unlikely to account for the resistance to Cd2+ toxicity. Exposure of R40F cells to non-toxic (2 microM or 100 microM) or toxic (200 microM) Zn2+ levels resulted in an accumulation of Zn2+ equal to, or greater than, that observed in the wild type cell. When compared to the basal level in uninduced wild type cells, metallothionein levels were elevated 14- and 23-fold, respectively, in R40F cells cultured in the presence of 0.5 microM Cd2+ and 100 microM Zn2+. These results are consistent with the hypothesis that R40F cells express Cd2+ and Zn2+ resistance as a consequence of a reduction in unbound intracellular Cd2+ levels and an elevation of metallothionein synthesis.

In vitro assessment of the toxicity of metal compounds : III. Effects of metals on DNA structure and function in intact cells

A review has been compiled illustrating the directions taken in examining the genotoxic effects of metals and their compounds centering only on those studies pertaining to effects of metals and their compounds on DNA structure and function, such as the induction of DNA strand breaks, production of DNA-protein crosslinks, induction of chromosomal aberrations, and sister chromatid exchanges. Although it is premature to declare a cause and effect relationship between the carcinogenic activity of metals and their ability to induce one or more lesions in DNA, strong evidence is emerging to suggest such a relationship. Low concentrations of metals induce the appearance of DNA lesions, such as strand breaks and crosslinks, or induce sister chromatid exchanges or DNA repair synthesis. Assays based upon these events constitute extremely sensitive probes for genotoxic effects of metals and their compounds. These effects of metals on DNA are consistent with the currently accepted mechanism of chemical carcinogenesis, allowing the acquisition and propagation of altered DNA function. The lack of complete information on the activity of metals in producing DNA lesions allow only preliminary conclusions to be drawn. Certain compounds containing potentially or actually carcinogenic elements, such as Ni, Be, As, Cr, Cd, and to a minor extent Pb, have yielded positive responses in one or more DNA lesion assays. At relatively nontoxic levels of Ni and Cr, considerable evidence suggests that multiple types of DNA lesions are induced.

Uptake and binding of cadmium and mercury to metallothionein in rat hepatocyte primary cultures

The administration of inorganic Cd and Hg in vivo has been shown to result in markedly different metal concentrations in rat liver. Primary cultures of rat hepatocytes were utilized to gain insight into the dispositional differences between these chemically similar metals. Hepatocyte monolayer cultures were exposed to several concentrations of Cd or Hg (3, 10 and 30mum) in serum-containing medium for 30min. The cells were then washed and incubated in fresh medium for the remainder of the experiment. Hepatocytes exposed to Cd accumulated significantly more metal than hepatocytes exposed to equimolar concentrations of Hg. In cells exposed to 3mum-Cd there was an initial loss of Cd from the hepatocytes when placed in fresh medium, followed by a gradual re-uptake of metal, concomitant with increased binding to metallothionein. In hepatocytes exposed to 3 and 10mum-Cd, 87 and 77% of the intracellular Cd was bound to metallothionein within 24h. Loss of Hg from hepatocytes pulsed with 30mum-Hg was also observed upon the addition of fresh medium and continued for the duration of the experiment. No time-dependent increase in Hg binding to metallothionein was observed. A maximum of about 10% of the intracellular Hg was found associated with metallothionein in hepatocytes exposed to 30mum-Hg. Studies utilizing [(35)S]cysteine incorporation indicated significant increases in the amount of metallothionein synthesized in hepatocytes exposed to 3 and 10mum-Cd (300% of control value) and 30mum-Hg (150% of control value) 24h after metal pulsing. Time-course studies revealed a 6-12h lag in metallothionein synthesis, followed by a significant elevation in [(35)S]cysteine incorporation into metallothionein between 12 and 24h. These studies suggest that (a) isolated hepatocytes differentiate between Cd and Hg and preferentially accumulate the former, and (b) Cd strongly stimulates the induction of, and preferentially binds to, metallothionein, whereas Hg induces weakly, and does not preferentially bind to, metallothionein.

Queuine-containing isoacceptor of tyrosine tRNA in Drosophila melanogaster. Alteration of levels by divalent cations

Dietary cadmium causes the queuine-containing, Q(+), isoacceptors to increase relative to the guanine-containing, Q(-), ones of tRNATyr, tRNAHis and tRNAAsp of Drosophila melanogaster. Of the other divalent cations examined, Sr2+, Ni2+, Cu2+, Zn2+ and Hg2+, only Hg2+ failed to cause an increase in Q(+)tRNATyr. For these results, all pre-adult stages of the organism were spent on media containing the divalent ions. Adult flies that had developed on a normal diet also responded to divalent ions; Hg2+ as well as Cd2+, Sr2+ and Zn2+ caused an increase in Q(+)tRNATyr in 4 days. Using adult flies, the rate of the response was measured; when placed on a Cd2+-containing diet, they formed significantly more Q(+)tRNATyr within 24 h as compared to adults on a normal diet. Whether the queuine is derived from the diet or from de novo synthesis is yet to be determined. Since the metal ions represent a range of values in the 'hard-soft' classification, different sites of reaction are expected, yet for Drosophila a common result is an alteration in the ratio of Q(+) and Q(-) isoacceptors of these tRNAs. The transition to Q(+)tRNA may be an early indication of the metabolic imbalances resulting from the presence of the divalent cation.

Tissue concentrations and interaction of zinc with lead toxicity in rabbits

Adult male rabbits were exposed to lead (0.2%), zinc (0.5%) or to both lead and zinc (0.2% and 0.5%) which were given in the drinking water as acetates for 2 weeks or 4 weeks. Blood lead levels in lead exposed rabbits were about 15-fold in comparison with the controls after 2 weeks exposure and remained at this level after further exposure, but when zinc was given with lead the blood lead level doubled from 2 weeks to 4 weeks. In rabbits having both lead and zinc, the cerebral lead concentration was much lower than in rabbits exposed only to the respective amount of lead. No such effect was found in the cerebellum or sciatic nerve. Zinc did not prevent lead accumulation in the parenchymal tissues. Only a rather low induction of drug metabolizing enzyme activities was found in the liver of lead-exposed rabbits and zinc did not modify this induction. The results suggest that, although zinc might delay the lead accumulation in the cerebrum, it has little value in preventing peripheral neuropathy or metabolic alterations caused by lead.

The induction of DNA strand breakage by nickel compounds in cultured Chinese hamster ovary cells

Both NiCl2 and crystalline alphaNiS induced DNA strand breaks in cultured Chinese hamster ovary (CHO) cells. Alkaline sucrose gradient analysis of [3H]thymidine radiolabelled DNA isolated from cells exposed to NiCl2 at 1 microgram/ml for only 2 h indicated a high degree of DNA strand breakage. Similarly crystalline alphaNiS caused substantial strand breakage at 1 microgram/ml following a 24-h treatment interval. These nickel compounds caused DNA strand breaks at concentrations which did not significantly impair normal cellular division. A concentration-dependent effect upon the number and average size of DNA fragments was obtained with both NiCl2 and crystalline alphaNiS. Since DNA strand breakage occurred at such low concentrations, these results suggest that nickel compounds which cause cellular transformation have highly selective and specific effects upon DNA structure.

Fetal zinc deficiency as a mechanism for cadmium induced toxicity to the developing rat lung and pulmonary surfactant

Maternal exposure to cadmium alters lung and pulmonary surfactant development in the rat fetus. A toxic property of cadmium is its biological interaction with the essential trace metal zinc. The present study was undertaken to determine the role of zinc in the induction of fetal anomalies by cadmium. Pregnant rats were injected with 8 mg/kg cadmium chloride alone or with 12 mg/kg zinc chloride on gestation days 12-15 and sacrificed on gestation day 21. Controls received injections of saline and zinc chloride. Pulmonary surfactant phospholipids were isolated from fetal lungs and quantified. Concentrations of cadmium and zinc in maternal and fetal tissues and placenta were measured. Cadmium treatment caused embryonic death, lung hypoplasia and diminished quantity of the major pulmonary surfactant phospholipid, phosphatidylcholine. Zinc treatment alone did not alter normal fetal development. Coadministration of zinc with cadmium prevented all of the previously observed cadmium-induced fetotoxicity. The placenta appeared to act as a barrier to cadmium movement, as cadmium was found in the placenta but not in fetal tissues. However, cadmium treatment decreased fetal zinc content. Simultaneous injection of zinc with cadmium maintained the fetal zinc concentration at the control level. Thus cadmium appears to exert its fetotoxic effects indirectly, through a fetal zinc deficiency.

Medium for the accumulation of extracellular hemolysin and protease by Aeromonas hydrophila

A medium for the accumulation of extracellular hemolysin (300 to 1,600 hemolytic units per ml) and protease (2 to 3 proteolytic units per ml) was developed for an anaerogenic strain of Aeromonas hydrophila. In this medium, growth yields were less but levels of accumulated toxin were greater or equivalent when compared with the same responses in brain heart infusion and nutrient broths. The medium was considered to be partially defined since the conditions for maximum observed hemolysin accumulation (1,600 hemolysin units per ml) were not identified. The results showed that iron and zinc contributed to the control of the extracellular accumulation of both toxins. Whereas iron exerted an inhibitory effect, zinc stimulated the accumulation of both toxins.

Carcinogenicity, mutagenicity and teratogenicity of nickel

Nickel is widely used in the metallurgical industry, and although not released extensively into the environment, may represent a hazard to human health. Owing to their low absorption from the gastrointestinal tract, nickel compounds, except nickel carbonyl, are essentially non-toxic after ingestion. Epidemiological investigations and experimental studies have demonstrated that certain nickel compounds are extremely potent carcinogens after inhalation, but also that the carcinogenic risk is limited to conditions of occupational exposure. The relatively small number of mutagenicity studies performed up to now do not yet allow definite conclusions as to whether nickel is mutagenic. Nickel can cross the placenta and has embryotoxic and teratogenic properties. The principal hazard of nickel to man, beside its carcinogenicity, however, is its ability to provoke reactions of sensitization.

Effect of several metal ions on misincorporation during transcription

By use of poly(dA-dT) as template and Escherichia coli RNA polymerase, several metal ions were tested for their effect on the efficiency of transcription and on the misincorporation of CMP into the poly(rA-rU) product. In the presence of 10 mM MgCl2, Mn2+ has a stimulatory effect on the transcription, Co2+ has very little effect on the reaction, Cu2+ and Zn2+ are strongly inhibitory, and Cd2+ and Ni2+ are less inhibitory. The background misincorporation of CMP in the presence of MgCl2 is about 1 nucleotide per 2000 correct nucleotides incorporated and is independent of Mg2+ concentration. Zn2+, Ca2+, Sr2+, Li+, Na+, and K+--all nonmutagenic and noncarcinogenic--do not increase misincorporation. Mn2+ causes a concentration-dependent threefold increase in the misincorporation that can be slightly reversed at higher MgCl2 concentrations. Cd2+ causes a dramatic increase in the misincorporation with increasing CdCl2 concentration that can be substantially overcome by higher concentrations of Mg2+. Cu2+ also increases the misincorporation, Ni2+ slightly increases it, and Co2+ does not increase it at all. Several control experiments indicate that the misincorporation of CMP is dependent on the template-directed synthesis of poly(rA-rU). Nearest-neighbor analysis indicates that CMP is incorporated in place of UMP into the poly(rA-rU) product. The increase in misincorporation appears to be related both to the "hard-soft" character of the metal ions and to their carcinogenic potential.

Cadmium inhibition of RNA metabolism in murine lymphocytes

Cadmium, as Cd2+, has become an environmental pollutant of significant proportions. We and others have reported that cadmium in in vitro culture can alter several metabolic parameters including the synthesis of RNA. In the present study, a detailed examination of the mechanism of inhibition was undertaken. Cadmium, at 30 microM, decreased cellular uptake of uridine as well as incorporation into RNA up to 60 microM. Above this concentration, uridine incorporation fell to zero while that associated with the lymphocytes remained at a significantly higher value. LPS caused an increase in the fraction of the precursor incorporated into RNA. In the presence of cadmium, the fraction incorporated by non-stimulated cells fell continually while in the stimulated cells, the fraction had increased at 10 microM above which it dropped until at the highest concentration it was as for the unstimulated lymphocytes. It was found that up to 30 microM the ability of LPS to stimulate the lymphocytes in the presence of cadmium was enhanced while above that concentration it decreased so that at 70 microM no stimulation occurred. Cadmium also inhibited the formation of phosphorylated intermediates from uridine with UTP the most affected and the unstimulated lymphocytes the more sensitive. From the study of the intermediate steps it was found that RNA synthesis was directly inhibited and the most sensitive of the several inhibitory points.