The Influence of Selenium on Methyl Mercury Toxicity in Rat Hepatoma Cells,Human Embryonic Fibroblasts and Human Lymphocytes in Culture

Abstract The effect of methyl mercury and two selenium compounds have been studied in cell cultures. Methyl mercury in concentrations above 1 μM had a pronounced inhibiting effect on the growth of rat Morris hepatoma cells. Glucose and lactate uptake in relation to cell protein was appreciably stimulated by the organic mercury compound. Selenite in low concentrations (0.5 μM) and seleno-di-N-acetyl glycine in thousandfold higher concentrations offered considerable protection against these effects of methyl mercury. The same selenite concentration (0.5 μM), which did not affect cell growth, caused an appreciable protection against methyl mercury (6 μM), even if it was added 3 days after methyl mercury. The methyl mercury inhibited the growth of human embryonic fibroblasts and the DNA-synthesis in the human lymphocytes. However, no protective effect of selenite were observed in these cell types. These results suggest that selenium compounds exert their protective effects through cell specific processes rather than by a direct chemical reaction between selenite and methyl mercury.     

Hemolytic effects of sodium selenite and mercuric chloride in human blood

Many works have reported the interaction between selenium and mercury in the mammalian body and that chalcogen seems to have a protective effect against mercury toxicity. The aim of this study was to investigate the hemolytic effects of sodium selenite and/or mercuric chloride in human blood under in vitro conditions. For this, total venous blood from healthy subjects (males and females) was heparinized and incubated at 37 degrees C for 90 min with different concentrations of sodium selenite and/or mercuric chloride. The hemolytic effects of compounds were evaluated by measuring plasma hemoglobin concentration after centrifugation. In addition, 2-thiobarbituric acid reactive substances (TBARS) from plasma and erythrocytes, as well as erythrocyte nonprotein thiols (NPSH), were also evaluated in order to investigate molecular mechanisms related to selenite- or mercury-induced hemolysis. Mercuric chloride and sodium selenite, alone (400 microM), promoted a small in vitro hemolytic effect in human erythrocytes. However, when blood was exposed to both compounds (200 microM of each), there was an extremely high synergistic hemolytic effect. The exposure of blood to sodium selenite (400 microM), mercuric chloride (400 microM), and both compounds (200 microM each) did not alter erythrocyte TBARS levels. Sodium selenite presented a high oxidant effect toward erythrocyte NPSH; however, this effect was inhibited by mercuric chloride. The current results point to a synergistic hemolytic effect of sodium selenite and mercuric chloride in human blood, suggesting new understanding on the selenium-mercury antagonism. Moreover, this observed hemolysis seems to be not related to lipoperoxidation or thiol depletion.     

Hemolytic Effects of Sodium Selenite and Mercuric Chloride in Human Blood

Many works have reported the interaction between selenium and mercury in the mammalian body and that chalcogen seems to have a protective effect against mercury toxicity. The aim of this study was to investigate the hemolytic effects of sodium selenite and/or mercuric chloride in human blood under in vitro conditions. For this, total venous blood from healthy subjects (males and females) was heparinized and incubated at 37°C for 90 min with different concentrations of sodium selenite and/or mercuric chloride. The hemolytic effects of compounds were evaluated by measuring plasma hemoglobin concentration after centrifugation. In addition, 2-thiobarbituric acid reactive substances (TBARS) from plasma and erythrocytes, as well as erythrocyte nonprotein thiols (NPSH), were also evaluated in order to investigate molecular mechanisms related to selenite- or mercury-induced hemolysis. Mercuric chloride and sodium selenite, alone (400 µM), promoted a small in vitro hemolytic effect in human erythrocytes. However, when blood was exposed to both compounds (200 µM of each), there was an extremely high synergistic hemolytic effect. The exposure of blood to sodium selenite (400 µM), mercuric chloride (400 µM), and both compounds (200 µM each) did not alter erythrocyte TBARS levels. Sodium selenite presented a high oxidant effect toward erythrocyte NPSH; however, this effect was inhibited by mercuric chloride. The current results point to a synergistic hemolytic effect of sodium selenite and mercuric chloride in human blood, suggesting new understanding on the selenium–mercury antagonism. Moreover, this observed hemolysis seems to be not related to lipoperoxidation or thiol depletion.     

The Effect of Selenium on the Biliary Excretion and Organ Distribution of Mercury in the Rat after Exposure to Methyl Mercuric Chloride

Abstract The influence of selenium compounds on the biliary excretion and the organ distribution of mercury after injection of methyl mercuric chloride (4 μmol/kg) have been tested. Selenite, seleno-di-N-acetylglycine and seleno-methionine strongly inhibited the biliary excretion of mercury. Selenite even in a molar dose of 1/40 of the methyl mercury dose inhibited the biliary excretion of mercury. The less toxic seleno-di-N-acetylglycine was needed in larger molar doses and did not act as rapidly as selenite. Biliary excreted methyl mercury is known to be partly reabsorbed in the gut. Subsequently a part of it is deposited in the kidneys since drainage of the bile lowered the kidney content of mercury. Rats given selenium compounds in combination with bile drainage showed further reduction of the kidney mercury content than bile duct drainage alone. Thus the demonstrated lowering effect of selenium compounds on the kidney mercury content cannot be completely explained by an inhibition of biliary excretion of mercury. The mercury concentration in the brain was increased by the selenium compounds; the effect being dependent of the selenium dose reaching a maximum at an equimolar selenite - to methyl mercury dose ratio. The mechanisms by which selenium influences the methyl mercury kinetics are discussed.     

Effect of methylated forms of selenium on cell viability and the induction of DNA strand breakage.

Selenobetaine (SB) and selenobetaine methyl ester (SBME) are methylated selenonium derivatives that undergo metabolism to release methyl selenide and dimethylselenide, respectively, as primary metabolites. Since methylation of selenium is considered to be detoxifying, the toxicologic activity of SB or SBME may differ from that of inorganic forms of selenium, such as selenite, that undergo reduction and can induce cell damage. In this study, the effects of SB, SBME and selenite on the viability and long-term growth potential of a mouse leukemia cell line (L1210) were compared. Treatment with 20 microM selenite reduced the rate of cell doubling and the long-term growth potential of cells as measured by colony-forming ability. These effects of selenite were accompanied by a reduction in DNA integrity, assessed by alkaline elution analysis for single-strand breaks. Exposure to 500 microM SB or SBME for 24 hr reduced the colony-forming ability of cells in the absence of any effect on dye exclusion or induction of single-strand breaks in DNA. Exposure of cells to 500 microM SB or SBME resulted in levels of intracellular selenium similar to those after exposure to 20 microM selenite. These observations indicate that it is possible to maintain high intracellular levels of selenium, by exposure to methylated selenocompounds, without affecting DNA integrity. These findings also suggest that DNA fragmentation resulting from exposure to selenite occurs during its reductive metabolism and not from the accumulation of a methylated metabolite of selenium. The fact that SB or SBME reduced the ability of L1210 cells to form colonies in agar in the absence of either DNA fragmentation or any effect on the ability of treated cells to exclude a vital dye suggests that both methylated compounds alter the long-term proliferative potential of cells via a mechanism(s) distinct from that associated with cell injury and death by necrosis. Efforts are underway to determine the origin of these effects.     

The effect of selenium on the biliary excretion and organ distribution of mercury in the rat after exposure to methyl mercuric chloride.

The influence of selenium compounds on the biliary excretion and the organ distribution of mercury after injection of methyl mercuric chloride (4 mumol/kg) have been tested. Selenite, seleno-di-N-acetylglycine and seleno-methionine strongly inhibited the biliary excretion of mercury. Selenite even in a molar dose of 1/40 of the methyl mercury dose inhibited the biliary excretion of mercury. The less toxic seleno-di-N-acetylglycine was needed in larger molar doses and did not act as rapidly as selenite. Biliary excreted methyl mercury is known to be partly reabsorbed in the gut. Subsequently a part of it is deposited in the kidneys since drainage of the bile lowered the kidney content of mercury. Rats given selenium compounds in combination with bile drainage showed further reduction of the kidney mercury content than bile duct drainage alone. Thus the demonstrated lowering effect of selenium compounds on the kidney mercury content cannot be completely explained by an inhibition of biliary excretion of mercury. The mercury concentration in the brain was increased by the selenium compounds; the effect being dependent of the selenium dose reaching a maximum at an equimolar selenite--to methyl mercury dose ratio. The mechanisms by which selenium influences the methyl mercury kinetics are discussed.     

A cell aggregation model for the protective effect of selenium and vitamin E on methylmercury toxicity

Histotypic aggregation of embryonic neural retinal cells was chosen as a test model to evaluate mercury toxicity. After 24 h rotational culture with methylmercury (CH3HgCl) at 4 microM, aggregation was completely inhibited. A dose-response relationship between concentrations of methylmercury and final sizes of aggregates was found. Selenium (Na2SeO3) at concentrations of 1, 3 and 5 microM provided a protective effect for methylmercury (1 microM) toxicity. Vitamin E (DL-alpha-Tocopherol acetate) at concentrations 5, 7 and 10 microM also provided protection against the same concentration of methylmercury; however, it was less effective than selenium. Histotypic embryonal retinal cell aggregation may be a useful assay system for in vitro neurotoxic studies in morphogenesis.     

Effects of selenium on toxicity and ultrastructural localization of mercury in cultured murine macrophages

The effects of selenium on cellular toxicity and histochemical distribution of mercury were examined in a cell culture system of mouse peritoneal macrophages. Selenium protected against the toxicity of mercury in cultures exposed to 4 microM of mercuric chloride. Selenomethionine caused a significant increase in cell survival throughout the experiments, while sodium selenite delayed the toxicity of mercury for a while, after which selenite itself had a toxic effect. The amount of mercury visualized by autometallography was increased in macrophage cultures pre-exposed to sodium selenite or selenomethionine. The additional mercury made visible by this histochemical demonstration was located in the cytoplasm as well as in the lysosomes.     

Maternal selenium deficiency enhances the fetolethal toxicity of methyl mercury

The effect of maternal selenium deficiency on methyl mercury fetotoxicity was examined in the ICR strain of mice. Pregnant mice were fed either selenium-deficient diets based on torula yeast or selenium-supplemented diets which were identical to the former except that 0.1, 0.2, or 0.4 mg of selenium per kilogram of diet was added as sodium selenite. Fetolethality of methyl mercury was exacerbated by maternal selenium deficiency when mothers were administered sc 15, 25, or 35 mumol/kg/day of methylmercuric chloride (MMC) on the 13, 14, and 15th days of pregnancy. One-tenth part per million of selenium in the diet was sufficient to protect the fetuses against MMC fetolethality when dams were administered 25 mumol/kg/day of MMC. Mercury concentrations in maternal and fetal tissues were independent of the dietary selenium level. Selenium concentration and glutathione peroxidase (GSH-Px) activity in maternal tissues were unaffected by MMC administration. In fetal liver, on the other hand, selenium concentration was increased and GSH-Px activity was decreased concurrently by maternal MMC administration in the selenium-supplemented groups. Therefore, as far as GSH-Px activity was concerned, the bioavailability of selenium was markedly decreased in fetal liver by maternal injection of MMC. The increase in selenium content in fetal liver, which was observed only in the selenium-supplemented groups, may play an important role in protection against fetolethal toxicity of MMC.     

The role of thioredoxin reductase activity in selenium-induced cytotoxicity

The selenoprotein thioredoxin reductase is a key enzyme in selenium metabolism, reducing selenium compounds and thereby providing selenide to synthesis of all selenoproteins. We evaluated the importance of active TrxR1 in selenium-induced cytotoxicity using transfected TrxR1 over-expressing stable Human Embryo Kidney (HEK-293) cells and modulation of activity by pretreatment with low concentration of selenite. Treatment with sodium selenite induced cytotoxity in a dose-dependent manner in both TrxR1 over-expressing and control cells. However, TrxR1 over-expressing cells, which were preincubated for 72h with 0.1 microM selenite, were significantly more resistant to selenite cytotoxicity than control cells. To demonstrate the early effects of selenite on behaviour of HEK-293 cells, we also investigated the influence of this compound on cell motility. We observed inhibition of cell motility by 50 microM selenite immediately after administration. Moreover, TrxR1 over-expressing cells preincubated with a low concentration of selenite were more resistant to the inhibitory effect of 50 microM selenite than those not preincubated. It was also observed that the TrxR over-expressing cells showed higher TrxR1 activity than control cells and the preincubation of over-expressing cells with 0.1 microM selenite induced further significant increase in the activity of TrxR1. On the other hand, we demonstrated that TrxR1 over-expressing cells showed decreased glutathione peroxidase activity compared to control cells. These data strongly suggest that TrxR1 may be a crucial enzyme responsible for cell resistance against selenium cytotoxicity.     

Selenium compounds modulate the activity of recombinant rat AsIII-methyltransferase and the methylation of arsenite by rat and human hepatocytes

Formation of methylated metabolites is a critical step in the metabolism of inorganic arsenic or selenium. We have previously shown that under conditions of a concurrent exposure sodium selenite inhibits methylation of arsenite by cultured rat hepatocytes. Here, we compare the effects of sodium selenite and mono-, di-, and trimethylated selenium compounds on the methylation of arsenite by purified recombinant rat As(III)-methyltransferase (Cyt19) and by primary rat and human hepatocytes. Among these compounds, sodium selenite was the most potent inhibitor of the methylation of arsenite by the recombinant enzyme (K(i) = 1.4 microM) and by cultured cells. In both systems, methylseleninic acid was an order of magnitude less potent an inhibitor (K(i) = 19.4 microM) than was sodium selenite. Dimethylselenoxide and trimethylselenonium iodide were weak activators of recombinant As(III)-methyltransferase activity but were weak inhibitors of arsenite methylation in hepatocytes. These data suggest that selenite, rather than its methylated metabolites, is responsible for inhibition of arsenite methylation in cultured hepatocytes and that inhibition may involve direct interactions between selenite and As(III)-methyltransferase.     

Effect of selenium on the uptake of methyl mercury across perfused gills of rainbow trout Oncorhynchus mykiss

The uptake of methyl mercury was measured across the perfused gills of rainbow trout Oncorhynchus mykiss. The effect of selenium, either in the blood (perfusion medium), or in the water was investigated. Methyl mercury was effectively taken up from the water across the gills into the perfusate. The uptake rate reached a stable level after 30 min perfusion. When the gills were placed in mercury free water after exposure to mercury in the water for 1 h, they continued to liberate significant amounts of accumulated mercury into the perfusate. Exposure to selenite (SeIV) or selenate (VI) (0.075–0.75 μM) in the external medium did not affect the uptake of methyl mercury across the gills or the liberation of the metal from the gills. Internal selenite or selenate (7.5 μM) augmented the uptake of methyl mercury across the gills and internal selenite also increased the amounts of liberated methyl mercury from the gills in the unload period. Internal selenium, increased the mercury accumulation in the gills, whereas, external selenium did not alter the mercury accumulation in the gills. Uptake of selenium from the water across the gills occurred very slowly.     

Interactions between mercuric chloride and sodium selenite on cultured rat cerebrum

Explants of rat cerebrum in culture were treated with toxic concentration of HgCl₂ of 1.10^?4 M and with varying concentrations of sodium selenite. Treatment with sodium selenite resulted in a reduced neurotoxicity of HgCl₂, a maximal effect being attained at a selenite concentration of 1.10^?5 M. However, 1.10^?5 M sodium selenite was itself toxic. In in vitro cell systems, the toxicity of either mercury or selenium is decreased in the presence of the other element.     

Selenium compounds prevent the effects of methylmercury on the in vitro phosphorylation of cytoskeletal proteins in cerebral cortex of young rats.

In this study we investigated the protective ability of the selenium compounds ebselen and diphenyldiselenide against the effect of methylmercury on the in vitro incorporation of 32P into intermediate filament (IF) proteins from the cerebral cortex of 17-day-old rats. We observed that methylmercury in the concentrations of 1 and 5 microM was able to inhibit the phosphorylating system associated with IF proteins without altering the immunocontent of these proteins. Concerning the selenium compounds, diselenide (1, 15, and 50 microM) did not induce alteration of the in vitro phosphorylation of IF proteins. Conversely, 15 microM diselenide was effective in preventing the toxic effects induced by methylmercury. Otherwise, ebselen induced an altered in vitro phosphorylation of the cytoskeletal proteins in a dose-dependent manner. Ebselen at intermediate concentrations (15 and 30 microM) increased the in vitro phosphorylation. However, at low (5 microM) or high (50 and 100 microM) concentrations it was ineffective in altering the cytoskeletal-associated phosphorylating system. Furthermore, 5 microM ebselen presented a protective effect against the action of methylmercury on the phosphorylating system. In conclusion, our results indicate that the selenium compounds ebselen and diselenide present protective actions toward the alterations of the phosphorylating system associated with the IF proteins induced by methylmercury in slices of the cerebral cortex of rats.     

Toxicity of selenite in the unicellular green alga Chlamydomonas reinhardtii: comparison between effects at the population and sub-cellular level

The toxicity of selenium in aquatic ecosystems is mainly linked to its uptake and biotransformation by micro-organisms, and its subsequent transfer upwards into the food chain. Thus, organisms at low trophic level, such as algae, play a crucial role. The aim of our study was to investigate the biological effects of selenite on Chlamydomonas reinhardtii, both at the sub-cellular level (effect on ultrastructure) and at the population level (effect on growth). The cells were grown under batch culture conditions in well-defined media and exposed to waterborne selenite at concentrations up to 500 microM; i.e. up to lethal conditions. Based on the relationship between Se concentration and cell density achieved after a 96 h exposure period, an EC(50) of 80 microM with a 95% confidence interval ranging between 64 and 98 microM was derived. No adaptation mechanisms were observed: the same toxicity was quantified for algae pre-contaminated with Se. The inhibition of growth was linked to impairments observed at the sub-cellular level. The intensity of the ultrastructural damages caused by selenite exposure depended on the level and duration of exposure. Observations by TEM suggested chloroplasts as the first target of selenite cytotoxicity, with effects on the stroma, thylakoids and pyrenoids. At higher concentrations, we could observe an increase in the number and volume of starch grains. For cells collected at 96 h, electron-dense granules were observed. Energy-dispersive X-ray microanalysis revealed that these granules contained selenium and were also rich in calcium and phosphorus. This study confirms that the direct toxicity of selenite on the phytoplankton biomass is not likely to take place at concentrations found in the environment. At higher concentrations, the link between effects at the sub-cellular and population levels, the over-accumulation of starch, and the formation of dense granules containing selenium are reported for the first time in the literature for a phytoplankton species after exposure to selenite.     

Inhibition by selenium compounds of catecholamine secretion due to inhibition of Ca2+ influx in cultured bovine adrenal chromaffin cells

Selenium is an essential trace metal element, whereas large doses of selenium exert adverse effects to the human body. We examined the effects of selenium compounds, sodium selenite (Na2SeO3) and sodium selenate (Na2SeO4), on catecholamine secretion from cultured bovine adrenal chromaffin cells. Treatment of chromaffin cells with sodium selenite for 72, 48, and 24 h caused decreases in protein and catecholamine contents, in association with cell damage, at concentrations over 30, 300, and 300 microM, respectively. The cells treated with subtoxic conditions (<100 microM, 48 h) of sodium selenite were used for further experiments. Sodium selenite treatment for 48 h inhibited carbachol (CCh)-induced catecholamine secretion in a concentration-dependent and non-competitive manner, while it did not affect high K+- and veratridine-induced catecholamine secretion. Sodium selenite (100 microM) did not affect CCh- and veratridine-induced 22Na+ influx, while the compound inhibited 45Ca2+ influx induced only by CCh, but not high K+ and veratridine. Sodium selenate even at higher concentrations (1000 microM) did not affect any stimulus-induced catecholamine secretion and 45Ca2+ influx. Thus, sodium selenite may specifically exert adverse effects, such as inhibition of physiological stimulus-induced catecholamine secretion from adrenal chromaffin cells due to inhibition of Ca2+ influx.     

Toxicity of nutritionally available selenium compounds in primary and transformed hepatocytes

The essential trace element selenium is also toxic at low doses. Since supplementation of selenium is discussed as cancer prophylaxis, we investigated whether or not bioavailable selenium compounds are selectively toxic on malignant cells by comparing primary and transformed liver cells as to the extent and mode of cell death. Sodium selenite and selenate exclusively induced necrosis in a concentration-dependent manner in all cell types investigated. In primary murine hepatocytes, the EC50 was 20 microM for selenite, 270 microM for selenate, and 30 microM for Se-methionine. In the human carcinoma cell line HepG2, the EC50 for selenite was 40 microM, and for selenate 1.1 mM, whereas Se-methionine was essentially non-toxic up to 10 mM. Similar results were found in murine Hepa1-6 cells. Exposure of primary murine cells to selenate or selenite resulted in increased lipid peroxidation. Toxicity was inhibited by superoxide dismutase plus catalase, indicating an important role for reactive oxygen intermediates. In primary hepatocytes, metabolical depletion of intracellular ATP by the ketohexose tagatose, significantly decreased the cytotoxicity of Se-methionine, while the one of selenite was increased. These data do not provide any in vitro evidence that bioavailable selenium compounds induce preferentially apoptotic cell death or selectively kill transformed hepatocytes.     

Effect of interaction between 65Zn,mercury and selenium in rats (retention,metallothionein, endogenous copper)

Interaction of zinc with mercuric chloride and sodium selenite was studied in the rat at the organ and subcellular levels (liver and kidneys). Zinc chloride was administered subcutaneously at dose of 5 mg Zn/kg, mercury chloride into the tail vein at a dose of 0.5 mg Hg/kg (both metals every other day during 2 weeks) and sodium selenite intragastrically, at doses of 0.1 mg Se/kg, every day. Zinc retention in the rat did not exceed 20% and was unchanged in the presence of mercury. An interaction effect was reflected by an increased whole-body retention of zinc by selenium, mercury, and selenium. In the presence of selenium no peak of metallothionein-like proteins stimulated by zinc or mercury was found in the soluble fraction of the kidneys. The metallothionein level did not differ from that typical for control group animals, too. A significant increase in the level of endogenous copper was found only in the kidneys of rats exposed to zinc in the presence of mercury and selenium.     

In vitro enhancement of erythrocyte merucry uptake by spironolactone.

Four groups of male Wistar rats were fed the following regimen for 40 days: (1) 20 ppm methylmercury chloride (MMC); (2) 20 ppm MMC + 3 ppm sodium selenite; (3) 3 ppm sodium selenite; (4) basal diet. The basal diet which contained 0.4 ppm “organic selenium” originating mainly from fish meal and wheat was resumed on day 41. Protective effect of selenite over toxicity of methylmercury was observed in terms of both growth rate and morbidity.Concentrations of total mercury, methylmercury and selenium were determined on Days 0, 20, 41, 47, 54, and 61 in the brain, liver, kidney, and blood. It was noted that methylmercury increased accumulation of selenium in all the organs analyzed while selenium retention varied according to the type of selenium and the organs. Modification by selenite, despite its protective effect, remained equivocal in regard to the organ accumulation of mercury and its retention therein.     

A norbergenin derivative inhibits neuronal cell damage induced by tunicamycin

Several chemically synthesized compounds were examined for protective effects against the cell damage in tunicamycin-treated human neuroblastoma IMR-32 cells. Among the compounds tested, an antioxidant, Norbergenin-11-caproate (10 microM), exhibited complete protection against the cell growth inhibitory effect of tunicamycin but did not inhibit the induction of Bip/GRP78 mRNA by tunicamycin. Both norbergenin-11-caproate and alpha-tocopherol completely inhibited the production of reactive oxygen species induced by tunicamycin, however, alpha-tocopherol inhibited tunicamycin-induced cell damage only partially, even at 100 microM. These findings suggest the potential of Norbergenin-11-caproate for therapeutic application in endoplasmic reticulum (ER) stress-dependent diseases implicating a specific mechanism other than anti-oxidative one.