The modulation by metallothionein of cadmium-induced cytotoxicity in primary hepatocyte cultures

Cadmium uptake in rat hepatocytes in relation to speciation and to complexation with metallothionein and albumin

Cadmium (Cd) uptake has been studied in primary cultures of rat hepatocytes focusing on the impact of inorganic and organic speciation. Uptake time-course studies over a 60-min exposure to 0.3 microM (109)Cd revealed a zero-time uptake and a slower process of accumulation which proceeds within minutes. (109)Cd uptake showed saturation kinetics (K(m) = 3.5 +/- 0.8 microM), and was highly sensitive to inhibition by Zn and Hg. There was no evidence for sensitivity to the external pH nor for any preferential transport of the free cation Cd(2+) over CdCl(n) (2-n) chloro-complexes. According to the assumption that only inorganic metal species are available, metal uptake decreased upon albumin (BSA) addition to the exposure media. In contrast, higher levels of (109)Cd accumulation were obtained under optimal conditions for Cd complexation by MT. Comparison among uptake data obtained under inorganic and organic conditions revealed that Cd-MT would be taken up 0.4 times as rapidly as Cd(inorg). We conclude that uptake of Cd in rat hepatocytes involves specific transport mechanism(s) subjected to Zn or Hg interactions. Uptake of inorganic Cd is not proportional to the levels of free Cd(2+) and does not involve the divalent cation transporter DCT1 nor the co-transporter Fe(2+)-H(+) NRAMP2. We found Cd-MT but not Cd-BSA to be available for the liver cells, and have estimated a binding affinity four orders of magnitude higher for Cd complexation with MT compared to BSA; MT may have a significant role in Cd delivery to the liver.

Metallothionein in physiological and physiopathological processes

The multipurpose nature of MT that we have presented in this review has drawn attention from many different fields of research: biochemistry, molecular biology, toxicology, pharmacology, etc. In recent years, considerable advances have been made concerning the regulation of MT genes by metals. Little, however, is known at the molecular level about the mechanisms of MT induction by nonmetallic inducers such as growth factors. This is of particular interest since MT is highly expressed during liver regeneration, an event orchestrated by a series of growth stimulators and inhibitors. The significance of the nuclear distribution of MT in growing cells and what controls its translocation are questions that remain unanswered at the present time. The possibility that MT could participate in a DNA synthesis-related process through donation or abstraction of Zn to and from transcription factors has been inferred from in vitro studies. Such transfer mechanisms, however, have yet to be confirmed in vivo. Overexpression of MT is often accompanied by increased resistance towards a variety of alkylating agents and chemotherapeutic drugs. The mechanisms by which MT protects cells against these agents may depend on their distinct mode of toxic action. For some, MT cysteines can be the target of the direct attack from the parent compound. For others such as N-methyl-N-nitroso compounds, MT cysteines may serve as a sink for the reactive oxygen species now known to be derived from their metabolism. In either case, a primary consequence of such interactions is the release of the metals initially bound to MT. Therefore, the metal composition of MT appears to be an important factor to consider in determining the overall effect of MT in the resistance process.

Recovery potential of hepatocytes from inhibition of albumin secretion by cadmium

The aim of this study was to examine albumin production, a typical liver-specific function, in hepatocytes treated with Cd and to examine the reversibility of the perturbations induced by the toxic metal. Cultures of freshly isolated rat hepatocytes were exposed to increasing amounts of Cd in modified Leibowitz L-15 medium for 20 h; the cells were then allowed to recover by further incubation in Cd-free medium for an additional period of 20 h. The levels of albumin secreted into the extracellular medium were determined by enzyme-linked immunosorbent assay and were found to be reduced by Cd in a concentration-dependent fashion over the first 20 h. Inhibition was seen at Cd concentrations that did not cause any loss of cellular viability (up to 0.5 microM Cd), as judged from the release of lactate dehydrogenase by the cells. After replacement of the exposure medium by Cd-free medium, the same pattern of diminished albumin secretion was obtained, revealing the persistence of the cytotoxic effects when recovery conditions were applied. Moreover, hepatocytes exposed to 0.5 microM Cd for 20 h and processed for visualization of albumin immunoreactive sites using protein A-gold and electron microscopy exhibited very low albumin-specific labeling as compared to the controls (0.6 +/- 0.05 vs. 20.0 +/- 2.6 gold particles/micron2). Intracellular glutathione levels were not significantly changed by Cd either after the initial exposure or after the incubation that followed in control medium. The accumulation of Cd by the cells, as measured by graphite furnace atomic absorption spectrophotometry, was concentration dependent. It remained stable after medium change, indicating that Cd efflux was negligible upon reestablishment of normal conditions. The present data show that the perturbations in albumin metabolism caused by Cd are not readily alleviated after the cells are returned to Cd-free medium, suggesting a limited short-term recovery potential against cytotoxic damage. The data also demonstrate that hepatocyte-specific functions can be used as sensitive indicators for the detection of cellular disturbances by hepatotoxins.

Distribution of cadmium chloride and cadmium-metallothionein to liver parenchymal, Kupffer, and endothelial cells: their relative ability to express metallothionein

Acute exposure to cadmium (Cd) salts results in liver toxicity, while administration of cadmium-metallothionein (CdMT) iv, causes renal damage. When CdMT is administered iv there is a rapid accumulation of Cd in the proximal tubule cells of the kidney. In comparison, only small amounts of Cd accumulate in the liver following administration of CdMT. Thus, in order to better understand the regulation of MT as well as the toxicity of Cd, the present study has examined the ability of each of the three primary liver cells, parenchymal (PC), Kupffer (KC), and endothelial (EC), to accrue Cd after administration of either inorganic or organic forms of Cd. In addition, the relative ability of each cell type to express metallothionein (MT) mRNA and protein was examined. Following CdCl2 (3.5 mg Cd/kg) treatment, Cd concentrations increased to about the same degree in PC and KC, but EC had about 2-fold more than PC. After administration of CdCl2 (1.0 mg Cd/kg) each cell responded to the presence of Cd by increasing intracellular MT mRNA and protein. However, PC showed the greatest response, with a 30-fold increase in mRNA and a 21-fold increase in protein. Interestingly, KC and EC possessed intracellular Cd concentrations equal to or greater than that of PC, but contained less MT than would have been expected on the basis of their intracellular Cd concentrations. Thus, KC had a 7-fold increase in MT mRNA and a 2-fold increase in protein, while EC increased mRNA 3-fold and protein 2-fold over control values. In contrast, following CdMT (0.5 mg Cd/kg) administration, only low levels of Cd were detected, with similar concentrations in each cell type. After administration of CdMT (0.4 mg Cd/kg), PC again showed the greatest response, with a 3-fold increase in mRNA and a 6-fold increase in MT protein. Only slight changes were observed in KC and EC. In conclusion, the present study has shown the following: (1) Endogenous levels of MT in KC and EC are higher than those in PC. (2) Cd is readily accumulated by all three cell types, when administered as CdCl2, but not when given as CdMT. (3) PC, KC, and EC are capable of responding to intracellular Cd by increasing MT.

Binding and detoxification of heavy metals in lower vertebrates with reference to metallothionein

1. The metabolism of Cu, Zn, Cd and Hg in lower vertebrates is described, using fish as a model. 2. The main part of this review deals with metallothionein and the role of this protein for the storage and detoxification of these metals. 3. Factors influencing the bioavailability and probable uptake routes are identified. 4. The distribution of the metals within the organism is outlined. The distribution between tissues is described and the subcellular distribution discussed with reference to metallothionein.

Comparison of the toxicity of inorganic and liver-incorporated cadmium: a 4-wk feeding study in rats

The toxicity of cadmium was examined in rats fed diets containing either tissue-incorporated cadmium or cadmium salt for 4 wk. The test diets contained 30 mg cadmium/kg either as cadmium chloride, or as cadmium incorporated in pigs' livers; the control group was fed a diet containing liver from a pig not treated with cadmium. Over 90% of the cadmium present in the pigs' livers was bound to metallothionein. Analysis of the diet and determination of the food consumption revealed that both cadmium-fed groups were exposed to similar dietary cadmium levels. There was no adverse effect on general health or survival. Feeding cadmium resulted in growth retardation and slightly decreased water intake. Moreover, both cadmium-treated groups showed clear signs of anaemia and increased plasma aspartate and alanine aminotransferase activities. For the group fed cadmium chloride, all of these effects were more pronounced than for the group fed cadmium incorporated in liver. Microscopic examination of the liver and kidneys, however, did not reveal any lesion that could be attributed to the cadmium treatment. After exposure to cadmium the spleen showed decreased extramedullary haematopoiesis, an effect that was also more pronounced after feeding of the cadmium chloride than after feeding liver-incorporated cadmium. The differences in the extent of the toxic effects between the inorganic and the tissue-incorporated cadmium were accompanied by differences in the cadmium concentrations in liver and kidneys: the feeding of cadmium incorporated in pigs' livers resulted in about half the accumulation of cadmium in the rats' livers that took place after intake of a diet containing cadmium chloride. In contrast a much less marked difference in cadmium accumulation was observed in the kidneys. Since humans are usually exposed to tissue-incorporated cadmium these findings deserve further investigation, with special attention to the observed difference in tissue accumulation.

The cytotoxic effects of cadmium chloride and mercuric chloride mixtures in rat primary hepatocyte cultures

The toxic effects of Cd and Hg mixtures were studied using primary monolayer cultures of rat hepatocytes. Cytotoxicity was assessed by measuring the release of lactic dehydrogenase from the cells. Cytotoxic and non-cytotoxic metal levels were used. At the higher exposure concentrations (0.2 micrograms Cd.ml-1 and 2.0 micrograms Hg.ml-1), Cd was very toxic to hepatocytes whereas Hg was only marginally toxic. The combination of Cd and Hg was more toxic than predicted by summation of the individual metal toxicities. The incorporation of [35S]cysteine into protein of the cytosol and insoluble cell fraction was increased in response to Cd or Hg exposure and was directly related to cell 35S accumulation. Combinations of Cd and Hg significantly increased the proportion of total 35S which was incorporated in cell protein, an effect that was attributed to the accumulation of protein in the insoluble cell fraction. Cd uptake by hepatocytes was related to exposure concentration but was lower when Hg was also present in the incubation medium. Gel chromatography of the cytosol from Cd-exposed cells showed 3 Cd containing fractions which corresponded to the elution positions of high Mr proteins, metallothionein (MT) and low Mr molecules. When hepatocytes were exposed to Hg in combination with Cd, the MT-like fraction was no longer evident and Cd in the low Mr fraction was greatly reduced. Regardless of the presence or absence of Cd in the exposure medium, 98% of cytosol Hg in Hg-exposed cells was found to elute after the low Mr fraction, at a position equivalent to inorganic salts. This indicates that the enhanced cytotoxicity of Cd and Hg may be related to a decrease in the MT-like protein in the cytosol and not due to a direct competitive binding interaction in relation to the protein.

Selective protein arylation by acetaminophen and 2,6-dimethylacetaminophen in cultured hepatocytes from phenobarbital-induced and uninduced mice. Relationship to cytotoxicity

To evaluate the mechanistic importance of covalent binding in acetaminophen (APAP)-induced hepatotoxicity, we compared the effects of 2,6-dimethylacetaminophen (2,6-DMA) to those of APAP in primary cultures of mouse hepatocytes. Immunochemical analysis of electrophoretically separated proteins has shown that the majority of covalent binding after a cytotoxic dose of APAP occurs on two major bands of 44 and 58 kD (Bartolone et al., Biochem Pharmacol 36: 1193-1196, 1987). At equimolar concentrations, 2,6-DMA bound proteins only 15% as extensively as did APAP and was not cytotoxic in hepatocytes from uninduced mice. However, when the hepatocytes were obtained from phenobarbital-induced mice, APAP administration resulted in increased protein arylation and a more rapid onset of cytotoxicity. Furthermore, in the cells from phenobarbital-induced mice, 2,6-DMA not only resulted in increased binding but also in overt cytotoxicity. Since our affinity-purified anti-APAP antibody did not cross-react with 2,6-DMA, a new antibody specific for 2,6-DMA was prepared and, after affinity purification, was used to detect 2,6-DMA protein adducts by Western blotting. Results indicated that, in hepatocytes from both phenobarbital-induced and non-induced mice, the binding of 2,6-DMA was also highly selective with the most prominent target being the 58 kD cytosolic protein. However, by contrast to APAP, only minimal binding to the 44 kD protein was detected after 2,6-DMA treatment. Although several additional protein adducts were increased in treated cells from phenobarbital-induced mice, the 58 kD protein was clearly the most prominently arylated target associated with both APAP and 2,6-DMA cytotoxicity. These data suggest that both the specificity of covalent binding as well as the extent of binding to the major targets may play an important role in the ensuing toxicity.

Cadmium-induced alterations of chlorpropham metabolism in isolated rat hepatocytes

In order to investigate the various steps of chlorpropham (CIPC) metabolism which could be influenced by cadmium, isolated rat hepatocytes were incubated in the presence of CIPC (0.1 mM) and of increasing Cd concentrations (0-180 microM). The results showed that Cd accumulation in hepatocytes was in good correlation to its concentration in the incubation medium. At 90 microM Cd, hydroxylation of CIPC was only slightly decreased by 30%, while CIPC hydrolysis into 3-chloraniline was unaffected by the presence of Cd. Accordingly, unchanged CIPC increased in hepatocytes. At 27 microM Cd, free 4-hydroxychlorpropham (4-OHCIPC) increased in the intracellular medium as a consequence of a strong suppression of both sulfation and glucuronidation which was related to the strong depletion of the intracellular ATP level under the combined influences of both cadmium and free 4-OHCIPC. Acetylation of 3-chloroaniline, which represents a minor pathway of CIPC metabolism, was already markedly suppressed (43%) with the lowest Cd concentration (27 microM). These in vitro results suggest that Phase II reactions are more sensitive to Cd than Phase I processes and that Cd enhanced the CIPC cytotoxicity as shown by alterations of the membrane integrity.

Response of rat hepatocyte cultures to cadmium chloride and cadmium-diethyldithiocarbamate

Cellular effects of cadmium (Cd) were studied in primary cultures of rat hepatocytes incubated with cadmium chloride (CdCl2) or cadmium-diethyldithiocarbamate (Cd(DTC)2), labelled with 109Cd. The lipid-soluble complex Cd(DTC)2 was rapidly taken up into the cells and a maximal concentration was reached after 4 h incubation. On the other hand, incubation with CdCl2 resulted in a slow, continuous accumulation of Cd for up to 20 h. Cd was found to be associated with proteins to a higher extent when added to the incubation medium as CdCl2 than when added as Cd(DTC)2, which in addition to differences in lipophilicity of the Cd compounds partly explains the differences in Cd uptake. Subcellular distribution studies showed that a significantly higher proportion of Cd was associated with the total particulates fraction in cells after incubation with Cd(DTC)2 compared to CdCl2 (32 and 19%, respectively). The activities of glutathione reductase and succinic dehydrogenase were inhibited to a similar extent by the 2 Cd compounds. Alcohol dehydrogenase was more strongly affected by CdCl2 than by Cd(DTC)2, although the uptake of Cd was 3-4 times higher in cells incubated with Cd(DTC)2 than in those incubated with CdCl2. The results from the present study show that DTC can increase the transport of Cd into the cell by complex formation with Cd. Compared to CdCl2 the Cd(DTC)2 complex was less toxic as indicated by the biochemical parameters used.