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.     

Selenium and lead: Mutual detoxifying effects

Antagonistic toxic effects of selenium and lead were studied in growing rats. Chronic lead intoxication was produced by cutaneous application of lead naphthenate solution (80–200 mg Pb/kg body weight) for a period of 8 weeks and chronic selenium intoxication was induced by giving 5 ppm, 10 ppm and 15 ppm selenium in drinking water. The growth rate and food consumption of rats receiving selenium in addition to lead approached normal rate while animals treated with only one of them showed hampered growth rate and lower food consumption. The enzymatic activity of δ-aminolevulinic acid dehydrase (ALA-D) in whole blood, liver and kidney and liver P-450 enzyme activity were normal in rats receiving both selenium and lead. The enzymic activities assayed were, however, depressed in the animals receiving either lead or selenium.Assay of lead and selenium in liver, brain, kidney and blood was carried out. Rats receiving both metals and higher concentrations of these metals in the organs studied, as compared to those only receiving one component. The data seem to indicate that the effect of selenium on the toxic effects of lead is similar to its protective role against methylmercury intoxication.     

Selenium and high dose vitamin E administration protects cisplatin-induced oxidative damage to renal, liver and lens tissues in rats

Cisplatin is one of the most active cytotoxic agents in the treatment of cancer but its clinical use is associated with nephrotoxicity. Several studies suggest that supplementation with antioxidant can influence cisplatin induced nephrotoxicity. In the present study, we investigated the effect of selenium with high dose vitamin E administration on lipid peroxidation (MDA) and scavenging enzyme activity in kidneys, liver and lens of cisplatin-induced toxicity in rats. Forty female Wistar rats were used. They were randomly divided into five groups. The first and second groups were used as control and cisplatin (6 mg/kg BW) intraperitoneally administrated groups. Groups III, IV and V received intraperitoneally five doses of selenium (1.5 mg/kg BW) and a high dose of vitamin E (1000 mg/kg BW) combination before, simultaneously and after with cisplatin, respectively. Glutathione peroxidase (GSH-Px), vitamin E and beta-carotene levels in the kidney, lens and liver, vitamin A and reduced glutathione (GSH) levels in the kidney were significantly (P<0.05 to <0.001) lower in the cisplatin group than in the control whereas there was a significant increase in kidney, liver and lens MDA levels in rats treated with cisplatin. The decreased antioxidant enzymes and vitamins and increased MDA levels in the kidney, lens and liver of animals administered with cisplatin were significantly (P<0.05 to <0.001) improved with selenium and a high dose vitamin E injection. In conclusion, this data demonstrates that there is an increase in lipid peroxidation in the kidney, liver and lens of animals administered with cisplatin whereas there is a decrease in antioxidant vitamins and enzymes. However, intraperitoneally injected selenium combined with a high dose of vitamin E seem to produce a significant improvement on antioxidants concentrations in rats treated before, simultaneously and after with cisplatin. The selenium with high dose vitamin E injection may play a role in preventing cisplatin-induced nephropathy and cataract formation in cancer patient.     

Formation and possible role of bis(methylmercuric) selenide in rats treated with methylmercury and selenite

The metabolic fate of methylmercury after administration of [²⁰³Hg]-methylmercuric chloride in combination with sodium selenite was investigated in rats. Whole body autoradiography and radioassay showed that administration of selenite decreased the mercury concentration in the liver and kidney, and increased that in the brain. The rapid changes of methylmercury concentration in the tissues after selenite injection were accompanied by increases in mercury extractable with benzene at neutral pH. The maximum levels of benzene-extractable mercury in the blood, kidney and liver were attained 30 min after selenite injection and were 30, 23 and 8 percent, respectively, of the total mercury. Thin-layer chromatography showed that the benzene-extractable mercury was a complex of methylmercury with selenium, bis(methylmercuric) selenide. These findings indicate that selenite alters the distribution of methylmercury in the tissues by formation of a diffusible complex with methylmercury, bis(methylmercuric) selenide.     

Gestational exposure to chlorpyrifos: dose response profiles for cholinesterase and carboxylesterase activity

This study investigates the in vivo dose response profiles of the target enzyme cholinesterase (ChE) and the detoxifying enzymes carboxylesterase (CaE) in the fetal and maternal compartments of pregnant rats dosed with chlorpyrifos [(O,O'-diethyl O-3,5,6-trichloro- 2-pyridyl) phosphorothionate], a commonly used organophosphorus insecticide. Pregnant rats were dosed daily (po) with chlorpyrifos in corn oil (0, 3, 5, 7, or 10 mg/kg) on gestational days (GD) 14-18. Animals were sacrificed 5 h after the last chlorpyrifos dose (time of maximum brain cholinesterase inhibition) for analysis of ChE and CaE activity in maternal blood, liver, brain, placenta, and fetal liver and brain. The in vitro sensitivity (i.e., IC50, 30 min, 26 degrees C) of CaE also was determined by assaying the activity remaining after incubation with a range of chlorpyrifos-oxon concentrations. In vivo exposure to 10 mg/kg chlorpyrifos from GD14-18 caused overt maternal toxicity, with dose-related decreases in ChE activity more notable in maternal brain than fetal brain. Dose-related effects were also seen with chlorpyrifos-induced inhibition of fetal liver ChE and maternal brain CaE activities. Gestational exposure caused no inhibition of placental ChE or CaE, fetal brain CaE, or maternal blood CaE. ChE activities in the maternal blood and liver, as well as fetal and maternal liver CaE, however, were maximally inhibited by even the lowest dosage of chlorpyrifos. The in vitro sensitivity profiles of CaE to chlorpyrifos-oxon inhibition were valuable in predicting and verifying the in vivo CaE response profiles. Both the in vivo and in vitro findings indicated that fetal liver CaE inhibition was an extremely sensitive indicator of fetal chlorpyrifos exposure.      

Chronic kidney disease in pregnant mothers affects maternal and fetal disposition of mercury

Chronic kidney disease (CKD) affects over 15 % of the adults in the United States. Pregnant women with CKD present an additional challenge in that they are at increased risk for adverse events such as preterm birth. Exposure to environmental toxicants, such as methylmercury, may exacerbate maternal disease and increase the risk of adverse fetal outcomes. We hypothesized that fetuses of mothers with CKD are more susceptible to accumulation of methylmercury than fetuses of healthy mothers. The current data show that when mothers are in a state of renal insufficiency, uptake of mercury in fetal kidneys is enhanced significantly. Accumulation of Hg in fetal kidneys may be related to the flow of amniotic fluid, maternal handling of Hg, and/or underdeveloped mechanisms for cellular export and urinary excretion. The results of this study indicate that renal insufficiency in mothers leads to significant alterations in the way toxicants such as mercury are handled by maternal and fetal organs.     

Ontogeny of the activity of alcohol dehydrogenase and aldehyde dehydrogenases in the liver and placenta of the guinea pig

The objectives of this study were to elucidate the ontogeny of the activity of alcohol dehydrogenase (ADH), low Km aldehyde dehydrogenase (ALDH) and high Km ALDH in the liver and placenta of the guinea pig, and to determine the relationship between the relative activity of each enzyme in the guinea pig maternal-placental-fetal unit and the disposition of ethanol and its proximate metabolite, acetaldehyde. The enzyme activities were determined in maternal liver, fetal liver, and placenta of the guinea pig at 34, 50, 60 and 65 days of gestation (term, about 66 days), in the liver of the 2-day-old neonate, and in adult liver. There was low ADH activity in fetal liver and placenta throughout gestation and in neonatal liver. The fetal liver low Km ALDH activity increased progressively and, at 60 days of gestation, was similar to adult liver activity, as was also the case for neonatal liver enzyme activity. Placental low Km ALDH activity was less than adult liver activity throughout gestation. Fetal hepatic high Km ALDH activity increased during gestation, but was less than adult liver activity, as was also the case for neonatal liver enzyme activity. Placental high Km ALDH activity was low throughout gestation. For oral administration of 0.5 g ethanol/kg maternal body weight to pregnant guinea pigs at mid-gestation (34 days), the maternal blood and fetal body ethanol concentration-time curves were similar. Acetaldehyde was measurable in maternal blood and fetal body at similar concentrations, which were 100- to 1000-fold less than the respective ethanol concentrations. The major difference in the disposition of ethanol and acetaldehyde at near-term pregnancy, compared with mid-gestation, was the lack of measurable acetaldehyde in fetal blood. These results indicate that the guinea pig fetus throughout gestation has virtually no capacity to oxidize ethanol, and its duration of exposure to ethanol is regulated by maternal hepatic ADH-catalyzed biotransformation of ethanol. The fetus, however, appears to have increasing low Km ALDH-dependent capacity to oxidize ethanol-derived acetaldehyde during development, and would appear to be increasingly protected from exposure to acetaldehyde as gestation progresses.     

Selenium and drug metabolism--I. Multiple modulations of mouse liver enzymes

Male albino mice were raised on diets containing less than 10 ppb selenium (Se-) or supplemented with 0.5 ppm selenium (Se+) for 6 months. In the (Se-) group total liver selenium was less than 10% of the control, liver selenium-dependent glutathione peroxidase (GSH-Px) less than 2%. The specific activities of catalase and superoxide dismutase showed essentially no differences between the dietary groups. Several phase I-related specific enzyme activities were measured in liver microsomes. No significant differences between the two animal groups were found for cytochrome P-450 and b 5 content, NADH-cytochrome b 5 reductase, as well as for aniline hydroxylation and aminopyrine dealkylation rates. In (Se-) microsomes, NADPH-cytochrome P-450 reductase activity was about half that found in (Se+) microsomes. An increase in microsomes from (Se-) mice was found for 7-ethoxycoumarine deethylation rate (460%), cytochrome P-450 hydroperoxidase activity (170%), and heme oxygenase (276%). The N-oxidation rate of the flavin-containing monooxygenase decreased by 35%, the N-demethylation rate by 50% in (Se-) animals. Stopped-flow measurements of the reduction rates of microsomal pigments did not support evidence for limitations in microsomal electron supply during selenium deficiency. Among the phase II reactions examined, sulfotransferase activity towards 4-nitrophenol was 47% of the controls in Se-deficient liver cytosols while UDP-glucuronyl transferase activity towards this substrate increased to 215%. Glutathione-S-transferase activity was much higher in (Se-) livers than in (Se+): 310% with 1,2-dichloro-4-nitrobenzene, 255% with 1-chloro-2,4-dinitrobenzene and 120% with ethacrynic acid as substrate. The data indicate that in addition to GSH-Px many other enzyme activities in mouse liver are affected by prolonged dietary selenium deficiency. These effects might be useful in assessing the severity of selenium deficiency. A microsomal selenium-dependent metabolic modulator is discussed as a possible mechanism.     

Gestational exposure to chlorpyrifos: comparative distribution of trichloropyridinol in the fetus and dam.

Chlorpyrifos (O,O'-diethyl O-[3,5,6-trichloro-2-pyridyl] phosphorothionate) is a commonly used anticholinesterase insecticide, and therefore the potential for human exposure is high. The present time course and dose response studies were conducted to delineate the toxicokinetics of chlorpyrifos and its metabolites in the pregnant rat and fetus. Time-pregnant, Long-Evans rats were treated orally with chlorpyrifos during late gestation (Gestational Days 14-18). Following euthanasia the level of chlorpyrifos and its metabolites, chlorpyrifos-oxon and 3,5,6-trichloro-2-pyridinol (TCP), were measured in both fetal and maternal brain and liver (limits of quantitation: 59.2, 28.8, and 14.0 ng/g tissue, respectively). In addition, cholinesterase inhibition was also measured in the same tissues for comparison. TCP was the only component detected. The highest level of TCP and the lowest level of cholinesterase activity showed the same time of peak effect: 5 h after the last dose. The concentration of TCP in the maternal liver was approximately fivefold higher than the TCP concentration in fetal liver, but, paradoxically, the concentration of TCP in the fetal brain was two- to fourfold higher than the TCP concentration in the maternal brain. The half-life of the TCP was identical in all tissues examined (12-15 h). These toxicokinetic results suggest that the fetal nervous system may be exposed to a higher concentration of chlorpyrifos than the maternal nervous system when the dam is orally exposed to chlorpyrifos during late gestation.     

Comparison of hepatic drug-metabolizing enzymes induced by 3-methylcholanthrene and phenobarbital between pre- and postnatal rats

Effects of 3-methylcholanthrene (3MC) and phenobarbital (PB) on the hepatic drug-metabolizing enzyme system in fetal liver of rats were investigated. Intraperitoneal administration of 3MC (25 mg/kg, 72 and 48 hr before death) to pregnant rats significantly increased hexobarbital (HB) and aminopyrine (AM)-metabolizing activities in fetuses on the 21st day of gestation to 148.0 and 150.6% of control fetuses, respectively. In contrast, HB and AM-metabolizing activities in 4-day-old neonates and mothers were decreased by administration of 3MC on the 21st day of gestation. Benzo[a]pyrene (BP)-metabolizing activity, NADPH-cytochrome c reductase activity, and cytochrome P-450 content in 3MC-treated fetuses were significantly increased to 2143.6, 137.6, and 323.8% of the control, respectively. Following 3MC administration, the maximum absorption of the cytochrome P-450-CO difference spectra in liver microsomes of fetuses was observed at 449-450 nm. The induction profile following 3MC administration in the fetal livers was different from that in the neonatal and the maternal livers. On the other hand, intraperitoneal administration of PB (60 mg/kg, 72, 48, and 24 hr before death) significantly increased HB, AM, and BP-metabolizing activities in fetal livers to 263.7, 231.0, and 151.2% of the respective controls. The profile induced by PB in the fetal livers was similar to that in maternal livers. These results suggest that HB and AM-metabolizing enzymes in fetal livers treated with 3MC or PB possess the capacity to be induced, and the responsiveness of the drug-metabolizing enzyme system to 3MC during the prenatal stage may differ from the postnatal stage.     

Influence of cadmium and copper on tissue element levels of pregnant rats

In the current study, we examined the effects of Cd on Cd, Cu, Zn and Fe levels in placenta and maternal and fetal plasma and tissues, the placental weight, total fetal and maternal body weights, and fetal and maternal tissue weights during pregnancy. A total of 21 adult female rats were treated during gestation with drinking water containing one of the following: 70 mg/L of CdCl₂, a combination of 70 mg/L of CdCl₂ and 70 mg/L of CuSO₄, or no addition (control). Placenta Cu and Fe levels, fetal liver and kidney Cu levels, and fetal liver tissue weights were lower in the group administered Cd than in the control group. Also, Cd levels in the placenta, maternal and fetal liver, and maternal kidney were higher in the group treated with Cd than in controls. In the group administered both Cd and Cu, fetal body and tissue weights did not change, but Cd levels in the placenta, maternal and fetal liver, and maternal kidneys were higher than in controls. Zn and Fe levels in the maternal kidney and fetal liver were also lower in this group. Cd exposure during pregnancy resulted in Cd accumulation in maternal and fetal tissues during pregnancy and a decrease in the total weight of fetuses, and the combination of Cd and Cu caused some changes in the both maternal and fetal levels of Cu, Zn, and Fe, but it did not cause changes in the total fetal body weight or the weights of individual tissues.     

Mechanisms of selenium methylation and toxicity in mice treated with selenocystine

 Mechanisms of selenium methylation and toxicity were investigated in the liver of ICR male mice treated with selenocystine. To elucidate the selenium methylation mechanism, animals received a single oral administration of selenocystine (Se-Cys; 5, 10, 20, 30, 40, or 50 mg/kg). In the liver, both accumulation of total selenium and production of trimethylselenonium (TMSe) as the end-product of methylation were increased by the dose of Se-Cys. A negative correlation was found between production of TMSe and level of S-adenosylmethionine (SAM) as methyl donor. The relationship between Se-Cys toxicity and selenium methylation was determined by giving mice repeated oral administration of Se-Cys (10 or 20 mg/kg) for 10 days. The animals exposed only to the high dose showed a significant rise of aspartate aminotransferase (AST) and alanine aminotransferase (ALT) activities in plasma. Urinary total selenium increased with Se-Cys dose. TMSe content in urine represented 85% of total selenium at the low dose and 25% at the high dose. The potential of Se-methylation and activity of methionine adenosyltransferase, the enzyme responsible for SAM synthesis, and the level of SAM in the liver were determined. The high dose resulted in inactivation of Se-methylation and decrease in SAM level due to the inhibition of methionine adenosyltransferase activity. To learn whether hepatic toxicity is induced by depressing selenium methylation ability, mice were injected intraperitoneally with periodate-oxidized adenosine (100 μmol/kg), a known potent inhibitor of the SAM-dependent methyltransferase, at 30 min before oral treatment of Se-Cys (10, 20, or 50 mg/kg). Liver toxicity induced by selenocystine was enhanced by inhibition of selenium methylation. These results suggest that TMSe was produced by SAM-dependent methyltransferases, which are identical with those involved in the methylation of inorganic selenium compounds such as selenite, in the liver of mice orally administered Se-Cys. Depression of selenium methylation ability resulting from inactivation of methionine adenosyltransferase and Se-methylation via enzymic reaction was also found in mice following repeated oral administration of a toxic dose of Se-Cys. The excess selenides accumulating during the depression of selenium methylation ability may be involved in the liver toxicity caused by Se-Cys. Received: 27 March 1996/Accepted: 19 June 1996     

Selenium and drug metabolism--II. Independence of glutathione peroxidase and reversibility of hepatic enzyme modulations in deficient mice

Male mice were fed a diet containing less than 0.01 ppm selenium (Se-) for 6 months. A control group received the same diet containing 0.5 ppm selenium (Se+). In the livers of the Se- animals a drastic decrease in glutathione peroxidase (GSH-Px) activity was observed. It reached undetectable levels after 17 days of the Se- diet. At that time, GSH-transferase activity began to increase significantly, followed by changes in many other enzyme activities. After the 60th day, these enzyme modulations had reached a plateau with the following percentage changes compared to controls: GSH-transferases: 320% (1,2-dichloro-4-nitrobenzene), 218% (1-chloro-2,4-dinitrobenzene); glutathione reductase: 160%; ethoxycoumarin deethylase: 330%; cytochrome P-450-hydroperoxidase: 230%; heme oxygenase: 240%; UDP-glucuronyltransferase: 200%; GSH-thioltransferase: 64%; sulphotransferase: 62%; NADPH-cytochrome-P-450-reductase: 65%; flavin-containing mono-oxygenase: 57%. No significant changes were observed for GSH-transferase activity assayed with ethacrynic acid or for microsomal H2O2 formation and aniline hydroxylase activity. In single-pulse repletion experiments by injection of 250 micrograms selenium/kg body wt, different individual time constants for the recovery process of the enzymatic perturbations were observed. The half-times for the recovery ranged from 5.7 hr for the microsomal NADPH-cytochrome-P-450 reductase to over 29 hr for GSH-Px up to 44 hr for part of the GSH-transferase activity. 250 micrograms selenium/kg body wt were needed to restore 50% of GSH-Px activity in the long-term Se- mice compared to Se+ controls. All other enzymatic changes in the Se- mice needed a dose of 7 micrograms selenium/kg body wt for 50% restorage . The results demonstrate that processes other than those related to GSH-Px take place in a later phase of selenium deficiency in mouse liver with a chronologically common beginning. The different repletion and depletion kinetics as well as the different need of these processes for the trace element are discussed with respect to the existence of two separate selenium pools.     

Effect of acute ethanol administration on diamine oxidase activity in maternal, embryonal and fetal tissues

Pregnant rats were acutely treated with ethanol to study the influence of this drug on diamine oxidase activity of maternal, embryonal, and fetal tissues. When ethanol was given on day 12 of gestation, enzyme activity was unmodified in placenta and embryo, whereas it was reduced by 38 and 31%, respectively, in maternal liver and plasma at 3 h. When ethanol was given on day 18 of gestation, diamine oxidase activity diminished in maternal liver, plasma and placenta by about 35-40% at 6 h. Moreover, in the fetus ethanol caused a 35% diminution of enzyme activity in liver at 6 h and a 45% stimulation in brain at 3 h, and of about 65% at 6-12 h. These data may be of interest in view of the physiological role of diamine oxidase in the oxidation of the large amounts of amines produced during pregnancy.     

Interaction of methylmercury and selenium on the bioaccumulation and histopathology in medaka (Oryzias latipes)

Interaction of methylmercury and selenium in medaka (Oryzias latipes) on bioaccumulation of pollutants and histopathological changes in liver and gill were studied. Juvenile medaka fish were submitted to a series of waterborne methylmercury chloride (MMC), sodium selenite (Na(2)SeO(3)) and their mixture for 210 days, respectively. The methylmercury (MeHg) and selenium contents in the whole body of medaka were determined. The dose- and time-dependent increase of MeHg and selenium contents in medaka were observed. Histopathological changes, such as edema, vacuoles, pyknotic nucleus, and telangiectasis, could clearly be observed in the slices from the exposed medaka's liver and gill. Concurrent exposure to MMC and Na(2)SeO(3) showed the increased selenium accumulation. When the exposure molar ratio of MeHg:Se was about 1, the interaction between MeHg and selenium offered a limited protection against the serious intoxication of both MMC and Na(2)SeO(3) to medaka.     

Differential effects of chronic ethanol exposure on cytochrome P450 2E1 and the hypothalamic–pituitary–adrenal axis in the maternal–fetal unit of the guinea pig

BackgroundEthanol neurobehavioural teratogenicity is a leading cause of developmental mental deficiency, in which the hippocampus is a target site of injury. The multi-faceted mechanism of ethanol teratogenicity is not completely understood. This study tested the hypothesis that chronic ethanol exposure (CEE), via chronic maternal ethanol administration, increases cytochrome P450 2E1 (CYP2E1) expression and alters hypothalamic–pituitary–adrenal (HPA) axis activity in the maternal–fetal unit during the third-trimester-equivalent of gestation.MethodsPregnant Dunkin–Hartley-strain guinea pigs received daily oral administration of ethanol (4 g ethanol/kg maternal body weight) or isocaloric-sucrose/pair-feeding (control) throughout gestation (term, about gestational day (GD) 68). On GD 45, 55 and 65, pregnant animals were euthanized 2 h after the last daily dose. Maternal and fetal body weights and fetal hippocampal brain weight were determined. Maternal and fetal samples were collected for the determination of liver CYP2E1 enzymatic activity and plasma free cortisol and ACTH concentrations.ResultsCEE, with maternal blood ethanol concentration of 108–124 mg/dl at 2 h after the last dose, decreased fetal hippocampal weight only at GD 65 and had no effect on fetal body weight compared with control. CYP2E1 activity increased with gestational age in the fetal liver microsomal and mitochondrial fractions. CEE increased CYP2E1 activity in the microsomal and mitochondrial fractions of maternal liver at the three gestational ages and in both hepatic subcellular fractions of the GD 65 fetus compared with control. There was a gestational-age-dependent increase in maternal and fetal plasma free cortisol concentrations, but no effect of CEE compared with control. Maternal and fetal plasma ACTH concentrations were unaffected by CEE compared with control, and were virtually unchanged during the third-trimester-equivalent that was studied.ConclusionThese data demonstrate that, in the pregnant guinea pig, this CEE regimen increases liver CYP2E1 activity, without affecting HPA axis function, in the maternal–fetal unit during near-term gestation. The CEE-induced increase in liver CYP2E1 activity and potential oxidative stress in the maternal–fetal unit may play a role in the pathogenesis of ethanol teratogenicity.     

河蚬提取物对小鼠酒精性肝损伤的保护作用

目的探讨河蚬提取物对酒精性肝损伤的保护作用及其机制.方法选用普通级雄性小鼠40只,按体重随机分为4组,分别为正常对照组,乙醇组,河蚬提取物低剂量组及高剂量组,每组10只.各组小鼠均以每次0.1mL/10g体重灌胃,正常对照组和乙醇组上午灌胃蒸馏水,河蚬提取物低剂量组和高剂量组分别灌胃河蚬提取物1g·(kg·d)-1和2g·(kg·d)-1.下午除正常对照组蒸馏水灌胃外,其他各组以乙醇灌胃,浓度为450mL·L-1,连续8周.末次灌胃后禁食12h,颈椎脱臼处死小鼠后迅速取出肝脏,用冷匀浆介质制成10%肝匀浆.检测肝组织中三酰甘油,丙二醛,硒含量及超氧化物歧化酶,谷胱甘肽过氧化物酶活性.结果实验共纳入小鼠40只,全部进入结果分析.乙醇组三酰甘油,丙二醛含量明显高于正常对照组(P<0.05),河蚬提取物低剂量组和高剂量组三酰甘油,丙二醛含量明显低于乙醇组(P<0.05),与正常对照组比较差异不明显(P>0.05).河蚬提取物低剂量组和高剂量组的超氧化物歧化酶,谷胱甘肽过氧化物酶活性及硒含量均明显高于乙醇组(P<0.05).结论河蚬提取物可能通过抑制脂质过氧化反应对酒精性肝损伤有保护作用.     

Inhibition of cholinesterase enzymes following a single dermal dose of chlorpyrifos and methyl parathion, alone and in combination, in pregnant rats

Pregnant Sprague-Dawley rats (14-18 d of gestation) were treated with either a single dermal subclinical dose of 30 mg/kg (15% of dermal LD50) chlorpyrifos (O,O-diethyl-O-[3,5,6-trichloro-2-pyridinyl] phosphorothioate) or a single dermal subclinical dose of 10 mg/kg (15% of dermal LD50) methyl parathion (O,O-dimethyl O-4-nitrophenyl phosphorothioate) or the two in combination. Chlorpyrifos inhibited maternal and fetal brain acetylcholinesterase (AChE) activity within 24 h of dosing, (48% and 67% of control activity, respectively). Following application of methyl parathion, peak inhibition of maternal and fetal brain AChE activity occurred at 48 h and 24 h after dosing (17% and 48% of control activity, respectively). A combination of chlorpyrifos and methyl parathion produced peak inhibition of maternal and fetal brain AChE activity at 24 h postdosing (35% and 73% of control activity, respectively). Maternal and fetal brain AChE activity recovered to various degrees of percentage of control 96 h after dosing. Application of methyl parathion or chlorpyrifos alone or in combination significantly inhibited maternal plasma butyrylcholinesterase (BuChE) activity. No significant inhibition of fetal plasma BuChE activity was detected. Peak inhibition of maternal liver BuChE occurred 24 h after application of methyl parathion or chlorpyrifos alone or in combination (64%, 80%, and 61% of control activity, respectively). Significant inhibition of placental AChE occurred within 24 h after application of methyl parathion or chlorpyrifos alone or in combination. The results suggest that methyl parathion and chlorpyrifos, alone or in combination, were rapidly distributed in maternal and fetal tissues, resulting in rapid inhibition of cholinesterase enzyme activities. The lower inhibitory effect of the combination could be due to competition between chlorpyrifos and methyl parathion for cytochrome P-450 enzymes, resulting in inhibition of the formation of the potent cholinesterase inhibitor oxon forms. The faster recovery of fetal plasma BuChE is attributed to the de novo synthesis of cholinesterase by fetal tissues compared to maternal tissues.     

Induction of lipid peroxidation in tissues of thallous malonate-treated hamster

Thallous malonate was administered orally to hamsters in a single dose of 10 mg Tl/kg or 50 mg Tl/kg body weight. After 1 day and 3 days the levels of lipid peroxidation and non-protein sulfhydryls (NPSH) and glutathione peroxidase (GSH-Px) activity in tissues were measured. At a thallium dose of 10 mg/kg, increases in lipid peroxidation were already apparent in the kidney after 1 day. On the other hand, a marked increase in lipid peroxidation with decrease in NPSH content and GSH-Px activity in the kidney and liver were found 3 days after administration of the 50 mg Tl/kg dose, and renal and liver damage also developed. These results suggested that thallous malonate-induced tissue damage may be associated with the development of peroxidative processes caused by depression of GSH and inhibition of the GSH-Px activity-linked defensive system.     

Involvement of tissue sulfhydryls in the formation of a complex of methylmercury with selenium

Albumin-bound methylmercury was converted to a benzene-extractable form by the soluble fraction of rat liver, kidney or brain in the presence of selenite, but not in its absence. The factors in the soluble fraction causing this conversion were investigated by column chromatography. Sephadex G-25 chromatography showed that effective factors were present in non-protein and protein fractions. It was concluded from ion exchange and Sephadex G-200 chromatography that these factors in the non-protein and protein fractions were reduced glutathione (GSH) and protein sulfhydryl groups respectively. Because GSH and the soluble protein could be replaced by sulfhydryl compounds, such as cysteine and 2-mercaptoethanol, as well as by a purified protein with sulfhydryl groups, reduced ribonuclease (RNase), respectively, it was concluded that sulfhydryl groups of GSH and/or proteins in the soluble fraction were needed for selenite-induced conversion of methylmercury to a benzene-soluble form. Among the various selenium compounds tested, only H₂Se (the reduced metabolite of selenite) was found to react directly with methylmercury to form a benzene extractable mercury compound in the absence of the soluble fraction. These findings suggest that the conversion of methylmercury to a benzene-soluble form occurs by reaction of methylmercury with selenium (possibly H₂Se) reduced by GSH and/or protein sulfhydryl groups in the soluble fraction. Thin-layer chromatography showed that benzene-extractable mercury consists mainly of bis(methylmercuric) selenide (BMS). A minor component, trismethylmercuric selenonium, was also detected by mass spectrography.