Relationship of DNA damage and embryotoxicity induced by 4-hydroperoxydechlorocyclophosphamide in postimplantation rat embryos

4-Hydroperoxydechlorocyclophosphamide (4-OOHdeCl-CP) is a preactivated analogue of cyclophosphamide (CP) that undergoes an elimination reaction to yield acrolein and the nonalkylating derivative of phosphoramide mustard (PM), i.e., dechlorophosphoramide mustard. We used this analogue to assess the role of acrolein in CP-induced embryotoxicity. Embryotoxicity was assessed using day 10 rat embryos cultured in vitro. 4-OOHdeC1-CP was embryotoxic over a concentration range of approximately 75-150 microM and produced complete embryolethality at concentrations of 175 microM and above. This analogue induced abnormal development characterized by tail defects at low drug concentrations and microencephaly or prosencephalic hypoplasia at high concentrations. Using the technique of alkaline elution, we also assessed DNA damage induced by embryotoxic concentrations of drug. When embryos were cultured in serum-containing medium during drug exposure, no DNA damage was detected, even at embryolethal drug concentrations. However, if cellular glutathione (GSH) was depleted with buthionine sulfoximine (BSO) before drug exposure and embryos were cultured in serum-free medium during drug exposure, DNA damage, primarily DNA single-strand breaks, was detected, but only at embryolethal concentrations. Using radiolabeled CP, we showed that acrolein does reach the embryo; however, more acrolein is incorporated into the yolk sac. Binding studies revealed that acrolein binds preferentially to cellular protein, whereas PM binds preferentially to DNA. These results suggest that, unlike the case with PM, the embryotoxic target for acrolein is protein and not DNA. Furthermore, our results indicate that acrolein may mediate its effects on the embryo via the yolk sac.     

Effects of phosphoramide mustard and acrolein, cytotoxic metabolites of cyclophosphamide, on mouse limb development in vitro

Phosphoramide mustard and acrolein are toxic and reactive metabolites of the widely used anticancer drug and known teratogen cyclophosphamide. To study the mechanism(s) involved and to determine which of the active metabolites of cyclophosphamide is responsible for the production of limb malformations, the effects of exposure of cultured limb buds to phosphoramide mustard and acrolein were investigated. Fore- and hindlimbs were excised from ICR mice on day 12 of gestation and cultured in roller bottles for 6 days. Limbs were exposed to either phosphoramide mustard or acrolein (10 or 50 micrograms/ml) for the first 20 hours of the culture period. Exposure to phosphoramide mustard produced limb reduction malformations in both the fore- and hindlimbs; total limb bone area was greatly reduced, while the relative contribution of the paw to this area in forelimbs was increased. There was a fourfold reduction in both DNA and RNA; protein content was reduced only by one-half. Alkaline phosphatase activity was significantly decreased in fore- and hindlimbs exposed to phosphoramide mustard, whereas creatine phosphokinase activity was only reduced in hindlimbs in the limbs exposed to the higher concentration of phosphoramide mustard. Exposure to acrolein also produced malformed limbs with a mangled appearance; however, total limb bone area and the relative contribution of the long bones versus paw structures were not altered. Acrolein exposure had little effect on growth parameters such as DNA (decreased only in hindlimbs exposed to 50 micrograms/ml), RNA (increased in hindlimbs exposed to 50 micrograms/ml), or protein content. Alkaline phosphatase and creatine phosphokinase activities were not altered in acrolein-exposed fore- or hindlimbs. Thus, phosphoramide mustard and acrolein have dramatically different effects on developing limbs in vitro; this observation may indicate that they have different targets and/or mechanisms of action as teratogens in the limb. The effects of phosphoramide mustard are very similar to those of "activated" cyclophosphamide (4-hydroperoxycyclophosphamide).     

Embryotoxicity of the intercalating agents m-AMSA and o-AMSA and the epipodophyllotoxin VP-16 in postimplantation rat embryos in vitro

The intercalating agent, m-AMSA, and the epipodophyllotoxin, VP-16, both topoisomerase II-reactive anticancer agents, are also embryotoxic agents in rat embryos cultured in vitro. Quantifying the embryotoxic effects of these drugs revealed that the no observed adverse effect level (NOAEL) for m-AMSA is 10 nM, the embryotoxic concentration range is 50-500 nM, and complete lethality is observed at 1 microM. In contrast, the NOAEL for o-AMSA, an inactive isomer of m-AMSA, is 1.0 microM, the embryotoxic concentration range is 10-100 microM, and complete lethality occurs at 200 microM. Based upon the concentrations of drugs required to produce 50% embryotoxicity or 50% malformed embryos, m-AMSA exhibits a 200-500-fold-higher embryotoxicity compared to o-AMSA. VP-16 exhibits a NOAEL of 1.0 microM, an embryotoxic concentration range of 2-5 microM, and complete lethality at 10 microM. Compared to m-AMSA, VP-16 is approximately 10-fold less embryotoxic. At appropriate concentrations, all three drugs were dysmorphogenic resulting in embryos that were characterized by hypoplasia of the prosencephalon with associated microopthalmia and dilation of the rhombencephalon. and dilation of the rhombencephalon. As a prelude to future studies focusing on the mechanism of drug-induced embryotoxicity, we have used established biochemical and immunologic methods to identify and quantify topoisomerase II in rat embryos. In addition, we have demonstrated that the embryo topoisomerase II can be inhibited by both m-AMSA and VP-16. Finally, we have used a human cDNA probe to detect topoisomerase II mRNA in the rat embryo. Thus, the combination of the in vitro whole embryo culture and these biochemical/molecular assays should allow us to explore the role of a specific nuclear target, i.e., topoisomerase II, in the teratogenic effects of some commonly employed chemotherapeutic agents.     

Morphological and biochemical aspects of monofunctional phosphoramide mustard teratogenicity in rat embryos cultured in vitro

Day 10 rat embryos were exposed in vitro to a monofunctional analog of phosphoramide mustard (MPM) at concentrations of 25 to 200 micrograms/ml (144 to 1,156 X 10(-6) M). After a 24-hour exposure, embryos exhibited a dose-dependent decrease in growth parameters (crown-rump length, number of somites, and protein content) as well as incidence of malformations. Abnormal embryos were characterized by hypoplasia of the prosencephalon as well as hypoplasia of the mandibular arches, tail, and limb buds. Histological analysis revealed abnormal levels of necrotic cells, particularly in the neuroepithelium and surrounding mesenchyme. In all respects embryos exposed to MPM could not be distinguished from embryos exposed to phosphoramide mustard. We also determined using mouse L1210 cells that at the maximum nonlethal concentration used in our embryo exposure experiments, MPM did not cause DNA cross-linking but did cause single-strand DNA breaks. Phosphoramide mustard, at concentrations teratogenic to embryos in vitro, did produce DNA cross-linking. Taken together, our results indicate that although cyclophosphamide (CP)-induced DNA cross-linking may play a role in CP teratogenesis, DNA cross-linking is not an absolute requirement.     

Effects of 4-hydroperoxycyclophosphamide (4-OOH-CP) and 4-hydroperoxydechlorocyclophosphamide (4-OOH-deCICP) on the cell cycle of post implantation rat embryos.

In this study, we used preactivated forms of cyclophosphamide (CP) and dechlorocyclophosphamide (deClCP) to examine the effects of phosphoramide mustard (PM) and acrolein, respectively, on the cell cycle of postimplantation rat embryos. The percentage distribution of cells in the G1/G0, S, and G2/M phases of the cell cycle was determined by flow-cytometric analysis. At embryotoxic concentrations, 4-OOH-CP (PM) induced major cell cycle perturbations whereas 4-OOH-deClCP (acrolein) caused no major perturbation of the cell cycle. These data support the hypothesis that the mechanism of the embryotoxic action of PM involves alkylation of DNA, whereas the mechanism of action of acrolein does not. The primary effect of PM on the cell cycle was an initial delay in the S phase followed by a G2/M arrest. At low embryotoxic concentrations of 4-OOH-CP, there was apparent reversal of the G2/M arrest; at higher embryotoxic concentrations there was little recovery from the G2/M arrest. The high level of cell death found at higher drug concentrations suggests that prolonged G2/M arrest leads to cell death. Using radiolabeled CP and cell sorting, it was determined that PM predominantly alkylated DNA in the S phase of the cell cycle. Overall, the data from this study support the hypothesis that DNA cross-links, induced by the alkylation of DNA by PM, induce cell cycle perturbations. Furthermore, these cell cycle alterations may be one of the early steps in the mechanism leading to the embryotoxicity of PM.     

A comparison of sodium arsenite- and hyperthermia-induced stress responses and abnormal development in cultured postimplantation rat embryos.

Acute exposures to sodium arsenite (50 microM) were embryotoxic in day 10 rat embryos exposed in vitro. Sodium arsenite-induced embryotoxicity was characterized by decreased growth (crown-rump length, somite number, and embryo protein content) and abnormal development (hypoplastic prosencephalon, abnormal somites, and abnormal flexion of the tail). At embryotoxic exposures, sodium arsenite also induced the synthesis of three heat shock proteins (hsps), one of which is recognized by a monoclonal antibody specific for the heat-inducible hsp 72. In addition, sodium arsenite induced the accumulation of heat-inducible hsp 70 mRNA. Although the abnormal morphologies induced by sodium arsenite and hyperthermia appear to be different, the stress response as measured by the synthesis of hsps, the accumulation of hsp 72 protein, and the accumulation of hsp 70 mRNA is similar in embryos exposed to these two embryotoxic agents. Thus, sodium arsenite and hyperthermia both induce a stress response; however, the relationship between the induction of a stress response and the subsequent abnormal development that ensues is unclear.     

Influence of dietary carrot on cytostatic drug activity of cyclophosphamide and its main directly acting metabolite: induction of sister-chromatid exchanges in normal human lymphocytes, Chinese hamster ovary cells, and their DNA repair-deficient cell lines

We have utilized an in vivo drug metabolism technique (i.e. injecting the chemical into rat and isolating plasma with metabolites from blood) for detecting the genotoxicity of indirectly acting cyclophosphamide and its directly acting metabolite phosphoramide mustard in cultures of human peripheral blood lymphocytes of normal individuals, Fanconi's anaemia (FA) and aplastic anaemia (AA) patients, wild-type Chinese hamster ovary cells (CHO) and its DNA repair-deficient mutant 43-3B cells. In addition, the influence of dietary carrot on the clastogenic activity of these 2 chemicals in all the different cell types was studied. The genotoxicity was assessed by the ability of the metabolites of these agents to induce sister-chromatid exchanges in the treated cells. A dose-dependent increase in the frequencies of sister-chromatid exchanges was observed in all cell strains following treatment with activated metabolites of cyclophosphamide or phosphoramide mustard. The sensitivity of lymphocytes from normal donors, FA and AA patients to these 2 chemicals was similar. In CHO cell lines the induced frequency of sister-chromatid exchanges was slightly higher after treatment with the metabolites of cyclophosphamide than with phosphoramide mustard. The mutant 43-3B cells responded with higher frequencies of SCEs when compared to the wild-type CHO cells, about 1.5-2-fold, at low doses. Pretreating of rats with fresh carrot juice effectively inhibited the increase in the frequencies of sister-chromatid exchanges induced by cyclophosphamide in wild-type and mutant CHO cells (P less than 0.01), and to a lesser extent in human lymphocytes (p less than 0.05). In contrast, no inhibitory effect was observed in any of these cell types in combination of dietary carrot for direct acting phosphoramide mustard on the frequency of induced sister-chromatid exchanges. The possibility that dietary carrot exerts its antimutagenic effect by affecting the processes of enzymatic activation of cyclophosphamide is discussed.     

Evaluation of aflatoxin B1 embryotoxicity using the frog embryo teratogenesis assay-Xenopus and bio-activation with microsome activation systems

BACKGROUND: Aflatoxins are a group of mycotoxins produced by Aspergillus, A. flavus, and A. parasiticus. Aflatoxin B1 (AFB1) should be a strong teratogen in hamsters, but its effect in rats is equivocal and extremely limited in mice. Therefore, the AFB1 embryotoxic potential in mammals remains unclear. METHODS: Little is known about the AFB1 effects on amphibians, therefore its embryotoxic potential was evaluated using the frog embryo teratogenesis assay-Xenopus (FETAX). X. laevis blastulae were exposed to: 1) positive controls for bio-activation (4 g/L cyclophosphamide monohydrate, Cy, and 4 g/L Cy+30 mg/L MAS-rat; 4 g/L Cy+30 mg/L MAS-human); 2) positive controls for MAS (30 mg/L MAS-rat and 30 mg/L MAS-human); 3) exposed groups to AFB1 (1 mg/L AFB1); and 4) AFB1 bio-activation (1 mg/L AFB1+30 mg/L MAS-rat and 1 mg/L AFB1 +30 mg/L MAS-human). RESULTS: In MAS-rat and human, Cy did not induce a statistically significant increase of mortality and malformed larvae percentage, but when bio-activated Cy increased the percentage of mortality. Instead, MAS-rat and human alone did not show any increase of mortality and malformed larvae percentages. When bio-activated by MAS-rat and human, AFB1 increased significantly both the mortality and malformed larvae percentages. The malformed larvae were mainly plurimalformed, i.e., affected by generalized edema, abnormal gut coiling, and microphthalmia. CONCLUSIONS: This research shows that AFB1 alone is not embryotoxic but, when bio-activated with MAS-rat or MAS-human the percentage of mortality and malformed larvae increased significantly. These results also show that AFB1 must be bio-activated to exert its embryotoxic effects.     

The effect of oxygen concentration on the teratogenicity of salicylate, niridazole, cyclophosphamide, and phosphoramide mustard in rat embryos in vitro

Comparisons were made of rat embryos cultured at 5% or 20% oxygen in the presence of salicylate (SAL), cyclophosphamide (CP), niridazole (NDZ), or phosphoramide mustard (PM). Multiple regression analyses were used to compare the effects of drug concentration, oxygen concentration, and the product of drug times oxygen concentration on malformation incidence, viability, and protein content of embryos cultured for 24 hours. Drug concentration significantly affected malformation incidence or severity and protein content (P less than 0.001) for the four drugs tested. Oxygen concentration significantly affected protein content for the four compounds (P less than 0.001) but affected malformation incidence only with NDZ. Furthermore, the interaction of oxygen concentration and drug concentration significantly affected the malformation incidence in the presence of NDZ (P less than 0.001), and protein content (P less than 0.001) and viability (P less than 0.001) in the presence of CP. The pattern of significant effects of the independent variables (drug concentration, oxygen concentration, and drug times oxygen concentration) is consistent with the hypotheses of oxygen-dependent metabolism (or lack of metabolism) of the drugs in question. NDZ, which is thought to be converted to reactive intermediates by an oxygen-inhibited nitroreductase, was more toxic at reduced oxygen tension. CP, which is activated by an oxygen-dependent P-450 system, was more toxic with increased oxygen tension. Significant effects of the independent variables on embryos exposed to SAL or PM were consistent with the effects on control embryos, notably, increased protein content with increased oxygen.     

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.     

Synthesis and structure-activity relationships of nitrobenzyl phosphoramide mustards as nitroreductase-activated prodrugs

A series of nitrobenzyl phosphoramide mustards and their analogs was designed and synthesized to explore their structure-activity relationships as substrates of nitroreductases from Escherichia coli and trypanosomes and as potential antiproliferative and antiparasitic agents. The position of the nitro group on the phenyl ring was important with the 4-nitrobenzyl phosphoramide mustard (1) offering the best combination of enzyme activity and antiproliferative effect against both mammalian and trypanosomatid cells. A preference was observed for halogen substitutions ortho to benzyl phosphoramide mustard but distinct differences were found in their SAR of substituted 4-nitrobenzyl phosphoramide mustards in E. coli nitroreductase-expressing cells and in trypanosomatids expressing endogenous nitroreductases.     

Lack of chick embryotoxicity after 20 kHz, 1.1 mT magnetic field exposure

This investigation was undertaken because biological studies to evaluate the effects of intermediate frequency magnetic fields are insufficient. White Leghorn fertile eggs (60/group) were either exposed to a 20 kHz, 1.1 mT(rms) sinusoidal magnetic field or sham‐exposed during the first 2, 7, or 11 days of embryogenesis. Lower dose exposures at 0.011 and 0.11 mT(rms) for 2 days were also conducted to elucidate possible dose–response relationships. Additional eggs given all‐trans‐retinoic acid, a teratogen, were exposed to the 1.1 mT(rms) magnetic field for the same periods to investigate the modification of embryotoxicity. After exposure, embryos were examined for mortality and developmental abnormalities. Developmental stage, number of somite pairs, and other developmental endpoints were also evaluated. Experiments were triplicated and conducted in a blind fashion. No exposure‐related changes were found in any of the endpoints in intact embryos exposed to1.1 mT(rms) or to the lower doses of 0.11 and 0.011 mT(rms) magnetic fields. Retinoic acid administration produced embryotoxic responses, which were embryonic death and developmental abnormalities, in 40–60% of embryos in the sham‐exposed groups. The magnitude of these responses was not changed significantly by the magnetic field exposures. Under the present experimental conditions, exposure to 20 kHz magnetic field up to 1.1 mT(rms) was not embryotoxic in the chick and did not potentiate the embryotoxic action of retinoic acid. Bioelectromagnetics 30:573–582, 2009. © 2009 Wiley‐Liss, Inc.     

Embryotoxicity of 1,2-dibromoethane in chick embryos in ovo: early and late effects.

Embryotoxic effects of 1,2-dibromoethane (DBE), a compound still widely used in industry, have been analyzed using chick embryos in ovo. Administration on embryonic days (ED) 3,4 or 5 induced dose-dependent embryotoxicity, manifested namely as the early embryonic death. A serious disturbance of the vascular system represented probably the main cause of strong embryolethality and growth retardation in the group of survivors. Amniotic bands in the parietal region and defects of brain and aorta prevailed in the malformation spectrum registered on ED 10. The local character of early induced changes suggests a direct effect of DBE itself in the embryotoxic action. This process is probably accomplished through interaction with lipids in cell membranes owing to the hydrophobic character of DBE molecules. The results, however, did not exclude an involvement of reactive metabolites in final embryotoxicity via the formation of DNA-adducts. In any case, a decreasing embryotoxicity of DBE with the age of treated embryos documented that the onset of liver function, assumed to occur on ED 5, did not increase the efficacy of DBE bioactivation. Our results confirmed the short-term embryotoxic properties of DBE reported in rat embryonic cultures. In addition, the in ovo system enabled us to reveal also long-term consequences represented namely by the formation of amniotic bands, not detectable in studies in vitro. The results obtained with the chick embryo in ovo confirmed the suitability of this system for embryotoxicity testing.     

A comparative study of the toxicity of mercury dichloride and methylmercury, assayed by the Frog Embryo Teratogenesis Assay--Xenopus (FETAX)

The Frog Embryo Teratogenesis Assay-Xenopus (FETAX) is a powerful and flexible bioassay that makes use of the embryos of the anuran amphibian Xenopus laevis. The FETAX can detect xenobiotics that affect embryonic development, when mortality, teratogenicity and growth inhibition are used as endpoints. The FETAX was used to compare the embryotoxic and teratogenic potentials of two chemical species of mercury, inorganic mercury(II) chloride (HgCl2) and organic methylmercury chloride (MeHgCl). A higher toxicity of MeHgCl (the estimated median lethal concentration [LC50] and median teratogenic concentration [TC50] were 0.313microM and 0.236microM, respectively) over HgCl2, with estimated LC50 and TC50 values of 0.601microM and 0.513microM, respectively). On the basis of these results, HgCl2 and MeHgCl can be classified as "slightly teratogenic compounds", as the ratio of LC50/TC50 is less than 1.5. There was a significant deviation from the commonly described monotonic behaviour of the concentration-response curves, suggesting a hormetic effect of both species of mercury. Uptake experiments, followed by neutron activation analysis, showed a higher incorporation of mercury in embryos exposed to MeHgCl compared with those exposed to HgCl2. Interestingly, Hg- exposed embryos showed a higher content of selenium and zinc than did control embryos.     

Progesterone inhibits embryotoxic effect of the complement system

The complement system of normal human serum (NHS) manifests a strong, dose dependent embryotoxic potential when administered to chick embryos inducing, among others, also malformations of the brain. We have demonstrated, however, that the degree of complement-induced embryotoxicity varied remarkably in the course of the menstrual cycle of fertile healthy women, although the complement serum activity (CH100) exhibited no significant fluctuation. On the other hand, the variation of embryotoxicity appeared negatively associated with progesterone levels. Following our results high progesterone levels occurring physiologically in luteal phase of the menstrual cycle suppress the embryotoxic action of the complement system.     

Sister-chromatid exchange analyses in rodent maternal, embryonic and extra-embryonic tissues: Transplacental and direct mutagen exposures

Sister-chromatid exchange (SCE) analyses were conducted in maternal, embryonic and extraembryonic tissues of pregnant rats and mice. The various tissues were substituted in vivo with 5-bromodeoxyuridine (BrdU) by implantation of a BrdU tablet in pregnant animals at mid-gestation. Following maternal exposure to 5–20 mg/kg cyclophosphamide, embryonic liver cells demonstrated dose-dependent SCE increases up to 10-fold that of control. Rat embryos revealed little intralitter variability for this transplacental effect. Maternal marrow and yolk sac cells examined in the rat also underwent significant increases in SCE, although to different extents. While marrow SCE frequencies were similar to those of embryo liver, yolk sac SCE frequencies were generally much lower.

SCE analyses were also conducted in rat yold sac cells substituted in vivo with BrdU and subsequently explanted to whole-embryo culture. In vitro exposure to cyclophosphamide at concentrations up to 100 μg/ml had no SCE-inducing effect. However, similar exposures to phosphoramide mustard, a presumed metabolite of cyclophosphamide, caused dose-dependent increases in SCE up to 8-fold higher than control at 2 μg/ml. Thus, cyclophosphamide appears to require maternal metabolic activation in order to cause an increased SCE frequency in yolk sac cells. The system described permits versatile SCE analyses which can help to define relative maternal and embryo tissue-specific sensitivities to chemical-induced genetic damage.     

Effects of pulsing electromagnetic fields on the prenatal and postnatal development in mice and rats: in vivo and in vitro studies

Electromagnetic fields (EMF) might have various biological effects on the developing embryo. We studied the effects of pulsing electromagnetic fields (PEMF) on the in vitro development of preimplantation mouse embryos and of early somite rat embryos as well as on the in vivo development of rat embryos. We used PEMF at frequencies of 1, 20, 50, 70, and 100 Hz with a tension of 0.6 V/m. The embryos were exposed to PEMF throughout the experimental period. PEMF at frequencies of 20 and 50 Hz were embryotoxic, inhibiting over 50% of blastocysts from hatching and further development, all within 72 h of culture. PEMF at frequencies of 50 and 70 Hz induced 22% and 30% incidence of malformations in 10.5 day old rat embryos after 48 h in culture. The main malformations were absence of telencephalic, optic, and otic vesicles and of forelimb buds. In addition, retarded growth and development manifested by fewer somites, reduction in crown-rump length, and retarded closure of the neural tube were found in many embryos. No significant pathological changes were found by TEM in PEMF-exposed embryos. Disappearance of microvilli and collapse of apical parts of endodermal cells were observed by SEM in many yolk sacs of embryos exposed to 50 and 70 Hz PEMF. A slightly reduced litter average, a reduction or increase of weight, and a delay in eye opening was observed among offspring of pregnant rats exposed throughout pregnancy to PEMF at frequencies of 20, 50, and 100 Hz. No malformations were observed among these offspring. The mechanism of PEMF-induced embryotoxicity and teratogeneity is unknown, as is the mechanism of the "protective effects" of the mother on the rat embryos exposed to PEMF in vivo.     

Toxicity of uterine fluids to rabbit embryos at the stage of eight cells or fewer

A total of 1018 rabbit embryos at different developmental stages were incubated in uterine fluids from rabbits or rats or in fractions obtained by ultrafiltration of these fluids. Rabbit and rat uterine fluids inhibited the development of rabbit embryo pronuclei but supported the development of morulae. The embryotoxicity of uterine fluid is not restricted to unicellular embryos. Embryos at the 2-, 4- and 8-cell stages do not develop correctly in rabbit uterine fluid. The embryotoxic factor seems to be of low molecular weight (< 500 daltons).     

Tea epigallocatechin-3-gallate increases 8-isoprostane level and induces caudal regression in developing rat embryos

Tea is the most common beverage after water. Concerns have been raised about the safety of tea during pregnancy, especially for embryo development. We aimed at studying the effects of active tea components on developing embryos by in vitro rat embryo culture. Rat embryos during early organogenesis were cultivated in serum supplemented with one of the tea catechins. Developmental hallmarks and malformations (Mal) in the developing embryos were compared and evaluated by a standard morphological scoring system. The embryotoxicity of each tea catechin was classified according to the European Center for the Validation of Alternative Methods. Cell viability was assessed by supervital dye staining, apoptosis by TUNEL assay, and peroxidation by the 8-isoprostane EIA method. We found that (+)-catechin had the least effect on developing embryos (Mal(50)=715.1 mg/L; IC50(Mal)=435 mg/L), whereas (-)-epigallocatechin gallate had the most adverse effect (Mal(50)=54.2 mg/L; IC50(Mal)=45.8 mg/L). The major malformation in affected embryos included caudal retardation with abnormal axial flexion and delayed hind-limb formation. All catechins were classified as nonembryotoxic except (-)-epigallocatechin gallate, which was classified as weakly embryotoxic. With (-)-epigallocatechin gallate, increased numbers of nonviable and apoptotic cells in the malformed embryos were associated with increased embryo 8-isoprostane.     

H2O2 induces abnormal tail flexure in Xenopus embryos: similarities with Paraquat teratogenic effects

BACKGROUND: As previously shown, Paraquat (PQ) treatments of Xenopus developing embryos mainly induce a characteristic developmental alteration we named "abnormal tail flexure." PQ oxidative activity has been indicated as the cause of this malformation. Since PQ evokes reactive oxygen species (ROS), among which hydroxyl radicals (OH(*)), and H(2)O(2) can be converted to (OH(*)) via Fenton reaction, we compared here the lethal and teratogenic potentials of both oxidants by using the Frog Embryo Teratogenesis Assay-Xenopus (FETAX), in order to grasp eventual similarities in their teratogenic activity. METHODS: Xenopus embryos were exposed, from stage 8 to stage 47, at 368, 491, 612, and 735 microM H(2)O(2) and 0.388 microM PQ. The probit analysis of H(2)O(2) mortality and malformed larva percents gave a 598.82 microM Lethal Concentration 50% (LC(50)) and 536.04 microM Teratogenic Concentration 50% (TC(50)) from which a 1.11 Teratogenic Index (T.I.) has been calculated. This T.I. value should allow the classification of H(2)O(2) as a non-teratogenic compound. RESULTS: A comparison of H(2)O(2) mortality and malformed larva percents with those obtained from PQ exposure showed the higher embryotoxicity of PQ, but, markedly, both compounds mainly induced the "abnormal tail flexure." Histological analysis of both H(2)O(2) and PQ malformed embryo tails showed a similar distorted morphology of both somites and myocytes. Some of muscle cells were necrotic and affected by an apical enlargement as well as a detachment from the connective tissue of intersomitic boundaries. CONCLUSIONS: In our opinion, both of the tested chemicals likely weaken the mechanical bridge connecting the myocyte contractile apparatus to the extracellular matrix, therefore causing the detachment of some of tail myocytes from their connectival septum as well as their apical enlargement. This could lead to the unbalance of tail tensional forces and, in turn, to the appearance of the "abnormal tail flexure."