Study of aconitine toxicity in rat embryos in vitro

BACKGROUND: Aconitum is widely used in traditional medicine for its anti-inflammatory, analgesic, and cardiotonic properties. Knowledge is limited, however, on its effects on embryonic development. METHODS: Whole embryo culture was applied to explore the effects of aconitine on rat embryos during their critical period of organogenesis. All embryos isolated on gestational day 9.5 were exposed to 0, 1, 2.5, 5, and 10 microg/ml of aconitine with and without S9 mix, and scored for their growth and differentiation at the end of the 48-hr culture period. RESULTS: The embryonic growth and development were adversely affected at the concentration of 2.5 microg/ml aconitine without S9 mix, represented as reduced crown-rump length and head length, decreased number of somites, and lower morphologic score. When the concentration of aconitine was increased to 5 microg/ml, it induced severe dysmorphogenesis effects, including cardiac defect (undivided cardiac tube and inflated pericardial cavity), irregular somites, and brain malformation (e.g., narrow brain vesicles). In the presence of S9 mix, Aconitine toxicity to rat embryos was reduced to a certain extent. CONCLUSIONS: Our study showed that Aconitine had direct embryotoxic effects during the rat organogenetic period. NOAEL was about 1 microg/ml and metabolism in S9 mix could induce the attenuation of Aconitine toxicity. Until more is known about the effects of Aconitine in pregnant women, we suggest its use should be treated with caution.     

Embryotoxicity induced by diethylstilbestrol in vitro1

The embryotoxic potential of diethylstilbestrol (DES) was examined in a whole embryo culture system containing a P-450–dependent bioactivating system. Sprague-Dawley rat embryos were explanted on day 10 and cultured for 24 hours. Concentration-dependent effects of DES on embryonic growth parameters, viability, and embryotoxicity were observed. Concentrations of DES greater than 0.26 mM (final concentration) produced 100% embryolethality, while those below 0.15 mM were without significant effects. At a final concentration of 0.19 mM, DES produced only a slight increase in embryolethality. The same concentration elicited a marked increase in observed embryotoxicity, including prosencephalic hypoplasia, incomplete axial rotation, and open neural tubes. In addition, reductions in embryonic length, somite number, and protein and DNA content were observed. An exogenous P-450–dependent hepatic biotransforming (catechol-generating) system failed to alter either the incidence of observed toxic effects or measured growth parameters. Likewise, exposure of cultured embryos to 20% carbon monoxide (CO) failed to reduce DES-induced embryotoxicity, indicating a lack of participation of an endogenous P-450-dependent embryonic bioactivating system. Arachidonic acid (0.20 mM) and/or indomethacin (0.50 mM) also had no observable effect on DES-induced embryotoxicity, suggesting that prostaglandin synthase was not involved in the embryotoxic activity of DES, as has been proposed to explain its carcinogenic effect. The antioxidants N-acetylcysteine (1.14 mM) and α-tocopherol (0.08 mM) failed to protect against DES-induced embryotoxicity, while the antiestrogen tamoxifen (up to 0.85 mM) actually enhanced this effect of DES in culture. The DES analogs Z,Z-dienestrol (DIES, 0.10 mM) and hexestrol (HES, 0.48 mM) were both embryotoxic in vitro. The presence of an exogenous P-450-dependent hepatic biotransforming system appeared to protect against HES-induced embryolethality but had little effect upon DIES-induced embryotoxicity. The results were consistent with a direct effect of DES independent of either estrogenicity or exogenously generated metabolites.     

Difference in teratogenic potency of ethylenethiourea in rats and mice: relative contribution of embryonic and maternal factors

Ethylenethiourea (ETU) is a potent teratogen in the rat but not in the mouse or any other species tested. Embryotoxic and teratogenic effects are produced in mice only after exposure to 10-40 times the teratogenic dose of ETU in rats. This study was undertaken to determine whether the difference in sensitivity between rats and mice is due to differences within the embryo, to maternal metabolic differences, or both. Comparably staged rat and mouse embryos (gestation day 10.5 and 8.5, respectively) with intact extra-embryonic membranes were maintained under identical conditions in whole embryo culture and exposed to static concentrations of ETU for 48 hours. The teratogenic effects of ETU were qualitatively similar in both species, characterized by excessive fluid accumulations in embryonic structures. The most common abnormalities were distended neural tube, especially in the hindbrain, and clear blisters on the caudal region. At least two times as much ETU was required to produce a similar incidence of abnormalities in mice as in rats. Thus, there is some intrinsic difference in the quantitative response of rat and mouse embryos to ETU, but it is insufficient to account for the in vivo discrepancy. The role of maternal metabolism in modifying the teratogenicity of ETU was assessed by adding hepatic S-9 fractions from Aroclor 1254-induced rats and mice to whole embryo culture. Rat S-9 had no effect on ETU teratogenicity. Mouse S-9 virtually eliminated the formation of abnormalities typical of ETU in both rat and mouse embryos. Decreased exocoelomic fluid osmolality, a physiological effect produced by ETU, also was not observed in embryos exposed to ETU and mouse S-9. ETU-typical defects were observed in embryos exposed to ETU and mouse S-9 which had been treated with carbon monoxide to inactivate its monooxygenase system, indicating that the mouse S-9 was metabolizing ETU. A surprising result was that adding mouse S-9 to embryo cultures containing ETU resulted in the formation of abnormalities (principally open neural tube) that were not observed in in vitro rat or mouse embryos exposed to ETU alone, or in mouse embryos in vivo. We believe that the most likely cause of these abnormalities is a putative ETU metabolite, which is rapidly excreted by the dam in vivo, but accumulates to teratogenic concentrations in vitro.     

Embryonal disposition of salicylate: in vivo-in vitro comparisons

The distribution of salicylate to embryonal compartments for in situ and in vitro rat embryos under equivalent exposure conditions, and salicylate disposition in the in vivo mid-gestation embryo and late gestation fetus, were compared. Pregnant Sprague-Dawley CD rats were exposed to steady-state blood levels of salicylate by infusing 14C-salicylic acid iv for a 24 hour period from gestation day 11.5 to 12.5. Cultured Sprague-Dawley rat embryos (in medium consisting of 100% male rat serum) were exposed to the steady-state 14C-salicylate concentration achieved in maternal serum in vivo for the same 24 hour developmental period. At the end of the exposure period radioactivity in visceral yolk sac, extra-embryonic fluid and embryos, and in maternal tissues, was measured. The distribution of salicylate to embryonal tissues was statistically comparable in vivo and in vitro, although the embryos in vitro accumulated slightly (but not significantly) less of the chemical. There was considerable binding of salicylate by maternal serum and culture medium proteins: less than 20% of the chemical was free at the 40 micrograms/ml concentration used in this experiment. Consequently, the salicylate concentration in embryonal compartments appeared to be quite low when compared to the surrounding serum/medium, but was actually equal to or greater than the concentration of unbound salicylate in serum or culture medium. The proportion of free salicylate in serum increased at concentrations higher than 40 micrograms/ml, resulting in somewhat higher concentrations of salicylate in in vitro embryos and extraembryonic fluid (as compared to medium) when cultured in the presence of 200 or 400 micrograms/ml salicylate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Induction of sister-chromatid exchanges in human lymphocytes and Chinese hamster cells exposed to aflatoxin B1 and N-methyl-N-nitrosourea.

The effect of a 1-h exposure to aflatoxin B1 (AFB1) in inducing sister-chromatid exchange in Chinese hamster ovary (CHO) cells and human lymphocytes in the presence or absence of mixed function oxidase ("S9 mix") was compared. CHO cells were also exposed to a graded series of doses of N-methyl-N-nitrosourea, a powerful inducer of SCE whose action was independent of the presence or absence of S9 mix. CHO and human cells showed a close correlation in response to SCE induction by AFB1 and in both cell systems the additon of mixed function oxidases in the S9 mix resulted in a marked enhancement of action of AFB1.     

The requirement for glutathione S-transferase in the conjugation of activated aflatoxin B1 during aflatoxin hepatocarcinogenesis in the rat

The formation of an aflatoxin B1-reduced glutathione (AFB1-GSH) conjugate in in vitro systems has been examined. AFB1 was activated by a chicken liver microsomal system and factors affecting the subsequent conversion to the AFB1-dihydrodiol or conjugation with GSH were investigated by HPLC. A requirement for glutathione S-transferase in the formation of the AFB1-GSH conjugate was observed. Studies using CM-cellulose columns showed the fractions containing glutathione S-transferase B activity were the most effective in catalysing the formation of the AFB1-GSH conjugate. The possibility of changes in the level of AFB1-GSH conjugate production in the liver during carcinogenesis by AFB1 has been examined. It has been found, using freshly isolated rat hepatocytes, that low level feeding with AFB1 in vivo increases the production of the conjugate in vitro. Further increases in the production of the conjugate by hepatocytes in vitro, accompanying increases in the preneoplastic lesions, are achieved by partially hepatectomising the AFB1-fed animals. Partial hepatectomy of control-fed animals yielded no similar changes. The AFB1/partial hepatectomy treatment resulted in increased levels of all the glutathione S-transferase activities fractionated on CM-cellulose. Macromolecular binding of AFB1 and/or of its metabolites was detected in the fractions containing glutathione S-transferase activity, but there was no evidence for a greater binding in the glutathione S-transferase B/ligandin containing fractions. Furthermore fractionation on Sephadex G-75 indicated a predominance of binding of AFB1 to proteins of a higher molecular weight than the glutathione S-transferases, although some binding in the molecular weight range of the latter was observed.     

2(3)-tert-butyl-4-hydroxyanisole inhibits oxidative metabolism of aflatoxin B1 in isolated rat hepatocytes

Previous studies indicate that dietary administration of phenolic antioxidants, 2(3)-tert-butyl-4-hydroxyanisole (BHA) and 3,5-di-tert-butyl-4-hydroxytoluene, inhibits the carcinogenic effect of a number of chemical carcinogens including aflatoxin B1 (AFB1). Induction of hepatic enzymes, such as glutathione S-transferase, UDP-glucuronyltransferase, and epoxide hydrolase, has been shown to be responsible for the reduction of AFB1 cytotoxic and carcinogenic effects. The effect of BHA on AFB1 activation was examined in vitro utilizing isolated rat hepatocytes and liver microsomes. In hepatocytes, the total AFB1 content and bound form of AFB1 were 3.4 and 1.4 pmol/10(6) cells, respectively. In the cell-free microsomal activating system, 2.2 pmol were activated per mg of microsomal protein during 60 min of incubation. BHA (0.1-0.5 mM) inhibited AFB1 activation and binding in both systems in a dose-dependent manner; in hepatocytes, 90% inhibition was observed at 0.5 mM. Analyzing various AFB1 adducts, BHA (0.25 mM)-treated hepatocytes contained a significantly reduced amount of AFB1 macromolecular adducts. The antioxidant neither stimulated nor inhibited the cytosolic glutathione S-transferase and microsomal UDP-glucuronyltransferase activities. Analysis of various hydroxylated (aflatoxins M1 and Q1 (AFM1 and AFQ1] and demethylated (aflatoxin P1 (AFP1] metabolites of AFB1 in both the conjugated and unconjugated form indicated that there was a 30-50% reduction of unconjugated AFP1, AFQ1, and AFM1, whereas AFB1 was increased 3-fold. There was no significant change of conjugated metabolites. The effect of BHA on AFB1 activation in hepatocytes was compared with that of other cytochrome P-450 inhibitors; the ED50 values of SKF 525A, BHA, and metyrapone were 9 microM, 40 microM, and 280 microM, respectively. In the cell-free microsomal system, biotransformation of AFB1 to AFP1, AFM1, and AFQ1 was also inhibited. Kinetic analysis of p-nitroanisole O-demethylase activity of rat liver microsomes demonstrated that BHA inhibited noncompetitively with an apparent Ki of 90 microM. In the absence of enzyme induction, the phenolic antioxidant, BHA, blocks the oxidative biotransformation of AFB1 in isolated hepatocytes.     

The embryolethality and teratogenicity of acrolein in cultured rat embryos

Acrolein, a three-carbon unsaturated aldehyde, is teratogenic to rats in vivo following intraamniotic administration but has been reported not to be teratogenic in vitro in the rat whole embryo culture system. In this study the effects of acrolein on rat embryos cultured in the standard medium consisting of rat serum were assessed over a narrow-concentration range. Additionally, a comparison was done of the effects of culture in a serum medium vs. a serum-free medium. In the serum medium acrolein caused 100% embryolethality at 140 microM and was found to be teratogenic in the concentration range of 80-120 microM. In the serum-free medium acrolein was 100% embryolethal at 20 microM and was teratogenic in the range of 5-15 microM. The EC50 for malformations in the serum medium was 137 microM, whereas that for embryolethality was 115 microM; the EC50s for malformations and embryolethality in the serum-free medium were 2.8 microM and 8.3 microM, respectively. Malformations were observed in the brain, facial area, and heart in addition to blebs and twisted or kinked bodies. Decreases in yolk sac diameter, crown-rump length, head length, number of somites, morphological score, and protein content were observed within the teratogenic ranges in each type of medium. Thus acrolein is teratogenic and embryolethal in vitro as well as in vivo. Dissociation between embryolethality and teratogenicity was seen in the serum-free medium. The slope of the acrolein log concentration-response curve in the serum-free medium was twice that in the serum medium, indicating that acrolein may have a different mechanism of action in this medium.     

The effects of pretreatment with cytochrome P-450 inducers and preincubation with a cytochrome P-450 effector on the mutagenicity of genotoxic carcinogens mediated by hepatic and renal S9 from two species of marine fish

A series of experiments was designed to characterize the cytochrome P-450-dependent activation of 7 genotoxic carcinogens in the Salmonella preincubation assay by hepatic postmitochondrial fractions (S9) from the oyster toadfish and the Americal eel and by renal S9 from the toadfish. Significant S9-dependent mutagenicity was observed for benzo[a]pyrene (BAP), 2-aminoanthracene (2AA), aflatoxin B1 (AFB1), 7,12-dimethylbenz[a]anthracene (DMBA) and cyclophosphamide (CP) with hepatic S9 from untreated fish (UI S9) of both species and with renal S9 from untreated toadfish, although renal UI S9 was only marginally effective for activating AFB1. Neither UI S9 from toadfish liver or kidney nor that from eel liver consistently affected the direct mutagenicity of ethylene dibromide (EDB) or substantially activated dimethylnitrosamine (DMN). Pretreatment of toadfish with 3-methylcholanthrene (MC) decreased the mutagenicity of 2AA and increased the mutagenicities of BAP, AFB1 and DMBA, whereas, pretreatment of eels with MC increased the mutagenicities of BAP, 2AA and AFB1. Pretreatment of toadfish with Aroclor 1254 (AC) decreased the mutagenicity of AFB1 and increased the mutagenicity of 2AA, whereas, pretreatment of eels with AC increased the mutagenicities of BAP and DMBA. Pretreatment of toadfish with beta-napthoflavone (BNF) effected changes similar to those by pretreatment with MC except that the mutagenicity of AFB1 was not increased. Coincubation with 10(-4) M alpha-napthoflavone (ANF) decreased the mutagenicity of BAP mediated by toadfish MC and BNF S9 and eel AC S9 and decreased the mutagenicity of AFB1 mediated by toadfish MC and BNF S9 and by eel MC S9. Coincubation with ANF increased the mutagenicity of AFB1 mediated by toadfish and eel AC S9 and increased the mutagenicity of 2AA mediated by eel AC S9. Pretreatment of toadfish with MC, BNF and AC decreased the mutagenicity of 2AA mediated by renal S9 and ANF decreased the mutagenicity of 2AA mediated by renal UI and BNF S9. MC pretreatment of toadfish and eels and BNF pretreatment of toadfish induced BAP monooxygenase activity in hepatic microsomes. ANF (10(-4) M) inhibited the BAP monooxygenase activity of MC microsomes from toadfish and eels and of BNF microsomes from toadfish. The conjugation effectors diethyl maleate and salicylamide alone or combined had little or no effect on the mutagenicities of BAP and 2AA mediated by toadfish and eel UI and MC S9.(ABSTRACT TRUNCATED AT 400 WORDS)     

Embryotoxicity of phenyl ketone analogs of cyclophosphamide

Phenylketophosphamide and phenylketoisophosphamide are preactivated acyclic ketone analogs of cyclophosphamide and isophosphamide with antitumor activity. These compounds undergo an elimination reaction to yield phosphoramide or isophosphoramide mustard and phenyl vinyl ketone. In this study, the embryotoxicity of phenylketophosphamide, phenylketoisophosphamide, and phenyl vinyl ketone were determined. Embryotoxicity was assessed in vitro in whole rat embryos cultured on day 10.5 of gestation in the absence and presence of an activating system derived from maternal liver. Both phenylketophosphamide and phenylketoisophosphamide were embryotoxic in the absence of metabolic activation. Moreover, there was no enhancement of this embryotoxicity in the presence of an activating system. A 10-microM concentration of phenylketophosphamide produced 100% malformed embryos, while this concentration of phenylketoisophosphamide was not teratogenic. At 25 microM phenylketoisophosphamide, all the surviving exposed embryos were malformed. Phenylketophosphamide was embryolethal to more than 50% of the exposed embryos at a concentration of 50 microM. In contrast, a concentration of phenylketoisophosphamide of 100 microM was required to produce significant embryolethality. Phenyl vinyl ketone was not embryotoxic at any of the concentrations tested. The major malformation observed, a hypoplastic prosencephalon, and the growth retardation effects were not only similar for phenylketophosphamide and phenylketoisophosphamide, but also similar to those previously reported for "activated" cyclophosphamide. Unlike the results with cyclophosphamide, where both phosphoramide mustard and the aldehydic metabolite of cyclophosphamide, acrolein, are toxic, the embryotoxic effects of phenylketophosphamide and phenylketoisophosphamide are mediated only by the mustard metabolite.     

Lipid mediator production by post-implantation rat embryos in vitro

The production of inflammatory lipid mediators by post-implantation rodent embryos was examined in this study. Explanted day 10 rat embryos, either intact or after homogenization, were cultured for 3 hr in vitro and the resulting culture medium and embryonic tissue were assessed for eicosanoids and platelet-activating factor (PAF). The rank order of cyclooxygenase arachidonate products produced by intact embryos was as follows: 6-keto-PGF1 alpha much greater than congruent to PGF2 alpha congruent to TXB2. No lipoxygenase products of arachidonic acid metabolism were detected by either high performance liquid chromatography or radioimmunoassay. PAF production was detectable in embryonic cultures. Homogenization of rat embryos prior to in vitro culture enhanced eicosanoid and PAF production from 2.1-6.9 fold over intact embryos. These findings demonstrate the extent of lipid metabolism by early post-implantation rat embryos and support the concept that potent lipid mediators of inflammation generated by the conceptus may play a role in both the initiation and maintenance of pregnancy.     

Aflatoxin B1-induced toxicity in HepG2 cells inhibited by carotenoids: morphology, apoptosis and DNA damage

Aflatoxin B1 (AFB1) is a fungal toxin that has been associated with primary hepatocellular carcinoma (HCC) in humans. This study was undertaken to determine the cellular and molecular mechanisms by which the antioxidants beta-carotene and lycopene inhibit AFB1-induced toxic changes in human hepatocytes (HepG2 cells). An in vitro system was optimized to test the chemoprotective effects of lycopene and beta-carotene on HepG2 cells exposed to different concentrations of AFB1. Ultrastructurally, HepG2 cells cultured in the presence of AFB1 showed mitochondrial damage, nuclear condensation and a loss of cell-to-cell contact; the latter was reflected in the observation of dysfunctional gap junctions, resulting in a loss of cell-to-cell communication. At the genomic level, AFB1 formed AFB1-N7-guanine adducts, caused apoptotic cell death and suppressed p53 protein expression. In the presence of the carotenoids, survival of cells exposed to AFB1 was increased, and there was also a significant increase in cellular mitochondrial activity. Our results demonstrate that HepG2 cells pretreated with lycopene and beta-carotene are protected from the toxic effects of AFB1 at both the cellular and molecular levels.     

A staging scheme for assessing development in vitro of organogenesis stage embryos of the stripe-faced dunnart, Sminthopsis macroura (Marsupialia: dasyuridae)

The inaccessibility of mammalian organogenesis stage embryos has precluded their widespread use in embryological and teratological studies. As organogenesis occurs during the last 1.5 days of the 10. 7 days of gestation in the stripe-faced dunnart (Sminthopsis macroura), the aim of the present study was to investigate whether day 9 and day 10 embryos and fetuses could be grown to term in vitro. High glucose Dulbecco's modified Eagle's medium with 10% fetal calf serum (FCS) supported embryonic growth for various periods of time, some to within 5 h of the predicted time of parturition. A roller culture system maintained at 35 degrees C was used to incubate organogenesis stage embryos (n = 43). Nine unincubated (control) embryos were either fixed for microscopic analysis or frozen for microprotein determination. The results of the present study indicate that with some optimization of the culture conditions (increasing oxygen in the gas phase in the culture tubes, replacing FCS with rat serum), it might be possible for organogenesis stage S. macroura embryos to be grown to term. A scoring scheme for assessing morphological development was devised for use as a standard in staging organogenesis stage embryos. This scheme reflects the highly compressed schedule of developmental events that occurs mainly during day 9 of gestation in S. macroura embryos. In comparison, during embryogenesis in Didelphis virginiana these developmental events occur from day 8 to day 10.5 of gestation, and birth occurs on day 13.     

Potent and stage-specific action of glutathione on the development of goat early embryos in vitro

The effect of glutathione (GSH) addition on the development of 1- or 2-cell goat early embryos in vitro was examined. Embryos were collected from superovulated Korean black goat (Capra hircus aegagrus) and cultured for 6 days in synthetic oviduct fluid medium supplemented with either bovine serum albumin (BSA) or serum. Without GSH addition, almost all embryos could not develop beyond 8- to 16-cell block. However, GSH addition greatly improved in vitro development of early embryos to blastocyst stage, and its action was highly dependent on the presence and source of proteins supplemented into the culture medium. Among the protein-supplemented cultures, GSH effect was most prominent in 10% FBS-supplemented culture, in which the proportion (91%) of blastocysts developed from early embryos was much higher than that of BSA- (42-64% depending on its content) or goat serum (GS)-supplemented cultures (21%), or even than that of somatic cell-supported co-culture (60%). As well as in terms of the morphological development, mean cell number of blastocysts (185 +/- 12) developed from FBS condition was significantly higher than that of blastocysts developed from any other culture conditions and moreover comparable to that of blastocysts developed in vivo (190 +/- 9). The viability of these blastocysts was finally confirmed by their term development (6/12) from embryo transfer. To delineate action time of GSH during embryo development, GSH was treated at 1-day intervals through 6-days culture periods excepting the last day. In the GSH-treated embryos at day 3 of culture, which corresponds to the time of in vitro 8- to 16-cell block stage, the proportion of blastocyst was markedly increased up to 77% of cultured embryos and conversely that of the arrested embryos was decreased to 7%. In the embryos treated later, however, their developmental potency decreased abruptly. Therefore, these results clearly demonstrated that GSH could greatly improve the in vitro development of goat early embryos by specifically acting on the 8- to 16-cell block stage during in vitro development, suggesting that GSH may be one of the important regulators on the development of goat embryos in vivo.     

The direct toxicity of alpha-naphthylisothiocyanate in cell culture

α-naphthylisothiocyanate (ANIT) kills rat liver cells in culture. Testing of a variety of related compounds revealed that toxicity depended upon the isothiocyanate group. The toxicity of ANIT was similar on several lines of cultured cells and in the presence of inhibitors and inducers of microsomal enzyme systems. The addition of a microsomal metabolizing system from rat liver to the cell cultures greatly enhanced the toxicity of 2 hepatotoxins requiring metabolism, but did not affect the toxicity of ANIT. It is concluded therefore that ANIT is toxic without biotransformation.     

Further study of the genetic toxicity of gentian violet

The genetic toxicity of gentian violet was studied with the Ames and the Rosenkranz bacterial assays as well as the cytogenetic assays (Chinese hamster ovary cells in vitro in the presence of rat-liver S-9 fractions, the chicken-embryo and mouse-bone-marrow cells in vivo).Gentian violet was found to be toxic but not mutagenic in the Ames assay. however, it was active in the Rosenkranz assay causing reparable DNA damage. The presence of S-9 in the in vitro cytogenetic assay and in the bacterial assays showed that the activity of gentian violet could be reduced or eliminated. In the in vivo assays, gentian violet was not clastogenic and failed to induce sister-chromatid exchanges. However, gentian violet proved to be highly toxic to growing chick embryos at high dosage and depressed mitotic activities in mouse bone marrow after prolonged treatment.Our study suggested that gentian violet can be inactivated by the liver detoxification system. However, it is potentially hazardous to cells that are exposed to the dye directly (e.g. skin epithelium and cell lining of the gastro-intestinal tract).     

The toxicity of niridazole in rat embryos in vitro

The antischistosomal drug niridazole (NDZ) was found to be teratogenic in a concentration-dependent manner from 10 to 50 micrograms/ml (47-233 microM) in rat embryos cultured from day 10 to day 11. A striking malformation consisting of axial asymmetry in which the right side of the embryo showed severe necrosis was the predominant malformation. The drug showed significantly greater dysmorphogenic activity at low (5%) compared to high (20%) oxygen tensions in cultures. Coincubation of embryos and NDZ with an exogenous source of metabolic enzymes and cofactors (NADPH) failed to modify teratogenicity. Inclusion of CO in the culture atmosphere significantly reduced the malformation incidence as did preincubation of the drug with S-9 and cofactors in medium with low O2 tension. Treatment of gravida with NDZ up to and including the maternal-lethal dose failed to result in observable malformations despite the use of several routes of exposure. These data lead us to hypothesize that rat embryos are capable of performing the reductive activation of NDZ in a fashion analogous to the schistosome but that reductive extraembryonic metabolism may result in teratogenic bioinactivation.     

Effect of vitamin A dietary intake on in vitro and in vivo activation of aflatoxin B1.

The mechanism by which vitamin A prevents or delays in chemical carcinogenesis remains unclear. In the present study, we assess the suggestive role of vitamin A in the initiation phase of carcinogenesis. We have conducted a dose-effect relationship between vitamin A dietary intake and aflatoxin B1 (AFB1) genotoxicity measured both in vitro and in vivo. Thus AFB1-induced mutagenesis in Salmonella typhimurium TA98 was investigated and compared to AFB1-induced single-strand breaks (SSBs) in DNA of rat hepatocytes. Rats were fed ad libitum with diet containing 0, 5, 50 or 500 IU of retinyl palmitate for 8 weeks. The AFB1-treated rats were injected i.p. with 1 mg/kg body weight. In the Ames test conditions TA98 back-reversion was negatively correlated with the log of vitamin A concentration in liver S9 fractions from experimental groups. However, the activities of metabolizing enzymes which specifically activate or deactivate AFB1 were found to be significantly decreased in vitamin A-deficient animals and weakly modified in vitamin A-supplemented animals. For in vivo experiments, the DNA elution rate of both AFB1-treated and untreated rats was increased in vitamin A deficiency condition (+79% and +17% respectively) and was reduced with the higher vitamin A dietary level (-44% and -53% respectively). DNA damage measured in vivo showed a significant positive correlation with mutagenic activity measured in the Ames test. These results confirm that the vitamin A status of animals can influence AFB1 genotoxic activity in vitro and indicate that this phenomenon also occurs in vivo. Thus a similar mechanism may be considered for the protective action of vitamin A both in vitro and in vivo. However, this mechanism is unlikely to involve modulation of the microsomal enzyme system responsible for AFB1 metabolism. Therefore a protective mechanism at the cytosolic or nuclear levels may be suggested.     

Further study of the genetic toxicity of gentian violet.

The genetic toxicity of gentian violet was studied with the Ames and the Rosenkranz bacterial assays as well as the cytogenetic assays (Chinese hamster ovary cells in vitro in the presence of rat-liver S-9 fractions, the chicken-embryo and mouse-bone-marrow cells in vivo). Gentian violet was found to be toxic but not mutagenic in the Ames assay. However, it was active in the Rosenkranz assay causing reparable DNA damage. The presence of S-9 in the in vitro cytogenetic assay and in the bacterial assays showed that the activity of gentian violet could be reduced or eliminated. In the in vivo assays, gentian violet was not clastogenic and failed to induce sister-chromatid exchanges. However, gentian violet proved to be highly toxic to growing chick embryos at high dosage and depressed mitotic activities in mouse bone marrow after prolonged treatment. Our study suggested that gentian violet can be inactivated by the liver detoxification system. However, it is potentially hazardous to cells that are exposed to the dye directly (e.g. skin epithelium and cell lining of the gastrointestinal tract).     

Somatomedin inhibitors from human serum produce abnormalities in mouse embryos in culture

Two human serum fractions, one from normal individuals (Mr 1,150-1,310 daltons) and the other (Mr 800-1,100 daltons) from patients suffering with uremia (renal failure, azotemia), were added to the medium used to grow embryos in whole-embryo culture (WEC) beginning at the 3-5 (day 9) or 18-21 (day 10) somite stage. Both of these fractions possessed somatomedin (insulin-like growth factor) inhibitory activity. Day 9 embryos exposed to either of the serum fractions for 24 hr exhibited incomplete rotation and neural tube closure defects and were smaller than control embryos (decreased total protein content). Developmental abnormalities induced in day 10 embryos following 24 hr in culture included a marked decrease in expansion of the brain regions, hypoplasia of the first two branchial arches, and decreased amounts of total protein compared to controls. The visceral yolk sacs (VYSs) of somatomedin inhibitor (SI)-exposed conceptuses were opaque, and those from day 10 conceptuses contained significantly more protein than controls. Morphologically, the VYS endoderm cells from SI-exposed embryos contained a much higher density of "vacuoles" than controls. These results mimic those produced by exposure of conceptuses to an SI of Mr800-1,100 obtained from the serum of diabetic rats and suggest that similar substances and mechanisms are involved.