A study of diclofenac-induced teratogenicity during organogenesis using a whole rat embryo culture model.

BACKGROUND: Diclofenac is a non-steroidal anti-inflammatory drug, commonly used by reproductive age women for the treatment of a variety of conditions. However, there is limited information regarding the teratogenic effects of this drug. METHODS: The effect of diclofenac on the developing embryo during the critical period of organogenesis was investigated by using a whole rat embryo culture model. Embryos were exposed to various concentrations of diclofenac and scored for growth and differentiation at the end of the culture period. RESULTS: Total developmental score and score for caudal neural tube, flexion and hindlimb were significantly lower in embryos exposed to high concentrations of diclofenac (7.5 and 15.0 microg/ml), but no difference in these parameters was observed when embryos were exposed to low concentration of diclofenac (1.5, 2.5 and 5.0 microg/ml). No significant differences in yolk sac diameter, crown-rump length and number of somites was found between embryos in the experimental and the control group. CONCLUSIONS: Our study has demonstrated that diclofenac exerts direct teratogenic effects on rat embryos. Until more is known about the effects of diclofenac (especially in moderate to high doses) in women of reproductive age, we suggest its use should be treated with caution.     

酒精致金黄地鼠神经管和眼畸形的实验研究

目的 观察酒精致金黄地鼠胚胎神经管和眼畸形发生过程的形态学改变，并定量观察致畸过程中的细胞凋亡。方法 实验组孕金黄地鼠分别用腹腔注射酒精致畸处理后4、8、16、24、48和72h剖腹取胚或胎，在光镜、体视显微镜和扫描电镜下观察胚胎神经管和眼的畸形发生中的形态变化；借助TUNEL法和透射电镜，定量研究神经管和眼畸形发生过程中的细胞凋亡。结果 1．酒精可使金黄地鼠神经管和视杯的发生明显延迟。2．酒精处理后8h，神经上皮细胞凋亡显著增加，尤以前脑和神经嵴处明显；16h和24h，凋亡仍大量存在，主要位于神经嵴和延迟发生的视沟部位；48h后神经上皮细胞凋亡逐渐减少。结论 酒精可使金黄地鼠神经管和视杯的发生明显延迟，神经上皮和视泡、视杯上皮细胞过度凋亡，这可能是酒精致神经管和眼畸形的机理之一。     

Inhibition of cephalic neural tube closure by 5-azacytidine in neurulating rat embryos in vitro

Summary Head-fold stage rat embryos (9.5 days of gestation) were cultured for 48 h in rat serum with or without 0.8 M 5-azacytidine. Incomplete closure of the cephalic neural tube was observed in 5-azacytidine-treated embryos cultured for 48 h (25-somite stage). Control embryos showed complete fusion of cephalic neural folds at 33 h (16-somite stage) in culture. Drug administration or removal experiments revealed that embryos were sensitive to 5-azacytidine during 6–12 h of culture (three to five somite stages). Electron microscopical studies indicated that the arrangement and fine structure of cephalic neuroepithelial cells were almost the same in control and treated embryos. There was no significant difference in DNA and protein contents between control and treated embryos cultured for 36 h. Immunocytochemical observations using 5-methylcytosine-specific antibody revealed that the staining of neuroepithelial cells in the median part of the transversely sectioned cephalic neural plate, and of mesenchymal cells near the apices of the plate, was suppressed by 5-azacytidine. These results suggest that DNA methylation of these cells plays an important role in closure of the cephalic neural tube.     

Teratogenic effects of N-nitrosodiethylamine in embryos of the hermaphroditic fish Rivulus marmoratus.

Exposure of N-nitrosodiethylamine (NDEA) to hermaphroditic fish (Rivulus marmoratus) embryos induced specific congenital malformations when the chemical was applied to embryos on days 0-6 post morula stage. This sensitive period generally coincided with the known period of organogenesis in this species, and the incidence of anomalies was clearly dose related. These results indicate that NDEA is teratogenic to fish embryos.     

Deceleration and acceleration in the rate of posterior neuropore closure during neurulation in the curly tail (ct) mouse embryo

Summary Curly tail (ct) is a mouse mutant producing spinal neural tube defects as a result of delayed closure of the posterior neuropore (PNP). The purpose of the present study was to determine in ct/ct embryos the time of onset of the delay in PNP closure, and the pattern of this closure, as well as to study the possibility that reopening of the neural tube occurs. Normal spinal neurulation was studied in non-mutant Swiss (Sw) embryos. In the latter, the average PNP length diminished steadily between the 7- and 25-somite stages, and then decreased more rapidly, indicating an acceleration of closure rate, until the 30- to 32-somite stage, when all PNPs closed. PNP width decreased steadily between the stages of 7 and 30 somites. In ct/ct embryos the average PNP length showed a slight increase between the stage of 23 to 28 somites, indicating a temporary deceleration of closure rate, and the range of PNP sizes increased markedly. This was followed by a decrease in PNP length until the 37-somite stage, indicating an acceleration of closure rate. From the stage of 32 somites onwards, the proportion of embryos with closed PNPs gradually increased to 90%. The population of ct/ct embryos was subdivided. Embryos with large PNPs showed a marked deceleration of closure rate during a period of 11 somite stages, followed by a brief but very high acceleration of closure rate. This resulted in closure of the PNP in a proportion of these embryos, while in the remainder of the embryos the deceleration phase had been too enhanced to allow complete catch up of closure during the acceleration phase; these embryos would develop spina bifida. Embryos with relative small PNPs also showed a deceleration of closure rate, but only during a period of four somite stages. This was followed by an acceleration, resulting in closure of all PNPs at the stage of 32 to 33 somites. The enlargement of the PNP in ct/ct embryos was not due to re-opening of a closed neural tube, but resulted from a sharp decline in the rate of PNP closure combined with a normal rate of caudal elongation of the embryo. It is concluded that the ct strain forms a homogeneous population, with a large variation of its specific phenotype: deceleration of PNP closure during a restricted period. The disturbance of spinal neurulation in ct/ct embryos takes the form of a deceleration/acceleration pattern, resulting in a net delay of closure. It is suggested that, due to the ct mutation, forces are generated in the embryonic axis which oppose a normal neurulation process at a specific stage of development.     

Culture of whole rodent embryos in teratogen screening

Rodent embryos can be grown in vitro during a period of rapid organogenesis. During a 24-48 hour culture period, growth and development closely approximate the values of embryos in utero at the same gestational stage. Embryos can be exposed to carefully controlled concentrations of test substances in a system which is free of maternal variables such as nutritional status or stress effects. Developmental abnormalities are limited to those systems developing during the culture period, but those available may show heightened sensitivity relative to the embryo in utero. Recently several systems have been developed which permit incorporation of either metabolites or metabolic enzymes in embryo culture. These materials can be obtained from species other than that of the test embryos. Because studies have shown the importance of maternal metabolism in the activation and inactivation of teratogens, it is hoped that these systems will enable us to understand the biochemical basis of species variability in teratogenic sensitivity and construct a teratogen screen which can reliably identify compounds which pose teratogenic hazards to humans.     

Slit2/Robo1信号对鸡胚早期神经管及体节发育的影响

目的: 探讨Slit2/Robo1对鸡胚早期神经管和体节发育的影响。 方法: 显微注射法将质粒注射入HH10期胚胎神经管内,活体胚胎细胞电穿孔方法转染胚胎半侧神经管,以另一侧神经管为对照侧,原位杂交及免疫荧光方法观察转染10 h后神经管的发育和神经嵴细胞迁移至体节的情况。结果: 下调Robo1侧神经管发育较正常对照侧异常,同时发现Slug表达和神经嵴细胞迁移至体节路线发生改变。结论: Slit2/Robo1信号可能通过影响Slug基因表达,对胚胎早期神经管闭合、神经嵴细胞正常产生及迁移方向以及体节分化有重要作用。     

Glucose-regulated protein 78 (GRP78) is elevated in embryonic mouse heart and induced following hypoglycemic stress

This study investigates the distribution and heart levels of glucose regulated protein (GRP) 78 during normal development and in response to hypoglycemia in the mouse. Results demonstrate that GRP78 is strongly expressed with in the heart, neural tube, gut endoderm, somites, and surface ectoderm of mouse embryos during early organogenesis, and GRP78 staining remains prominent in the heart from gestational days 9.5 through 13.5. Cardiac myocytes are the primary site of GRP78 expression within the heart. GRP78 levels are highest in the heart during early organogenesis and levels decrease significantly by the fetal period. GRP78 expression is increased after 24 h of hypoglycemia in the early organogenesis-stage heart. Considering the tissue specific pattern of GRP expression and changes during development of the heart, GRPs may play significant roles in the normal differentiation and development of cardiac tissue. GRP induction may also be involved in hypoglycemia-induced cardiac dysmorphogenesis. Accepted: 25 January 2000     

The influence of excess vitamin A on neural tube closure in the mouse embryo

Summary The effect of excess vitamin A on the closure of the neural tube in mouse embryos was examined with light microscopy, transmission and scanning electronmicroscopy. The embryos were treated with the vitamin just before closure of the brain vesicles and examined during the following 24 h, a period during which under normal conditions the brain completely closes.At 18–24 h after treatment the external features of the treated specimens began to differ from those of the controls. In the treated embryos the neural walls folded laterally and became widely separated, whereas those of the controls folded dorsomedially and fused in the midline. Histologically, the first difference between treated and control embryos was noted at two hours after treatment, when large intercellular spaces appeared between the neuroepithelial cells of the treated embryos. These spaces were mainly present between the apical ends of the wedge-shaped neuroepithelial cells. This accumulation of intercellular spaces interfered with the normal morphogenetic movement of the neural walls, which remained convex instead of becoming concave. This convex bending resulted in non-closure of the neural tube.In addition to the appearance of large intercellular spaces some neuroepithelial cells as well as some mesenchymal, endothelial, and surface ectoderm cells showed swelling and degeneration as a result of the vitamin A treatment. This cell degeneration probably contributes to failure of the neural tube to close due to loss of cohesion at the luminal surface and the lack of mesenchymal support needed for the elevation of the neural walls. However, the increase of intercellular spaces at the apical side of the neuroepithelium is in all probability the major cause for the failure of the neural tube to close.     

Homocysteine is embryotoxic but does not cause neural tube defects in mouse embryos

The observation of elevated maternal plasma homocysteine concentration in pregnancies affected by neural tube defects (NTD) suggests that folate metabolism may be disturbed in NTD cases. In addition, studies on the chick embryo suggest that hyperhomocysteinaemia may contribute directly to the development of NTD. In order to test the hypothesis that homocysteine may cause NTD, we cultured mouse embryos in the presence of homocysteine thiolactone during the period of cranial neural tube closure. At doses of 0.5 mM or above, exposure to homocysteine thiolactone caused growth retardation, blisters and abnormalities of somite development. Despite the teratogenic effects of homocysteine we did not detect any increase in the incidence of neural tube defects. Neither was there an effect on the incorporation of thymidine into DNA, a potential marker of alterations in the folate or homocysteine/methionine cycles. These observations suggest that homocysteine is unlikely to be a direct cause of NTD in humans. Rather, the elevated levels of homocysteine in human NTD pregnancies may reflect a disturbance in folate-related metabolism.     

Mitochondrial alterations in embryos exposed to B-hydroxybutyrate in whole embryo culture

The ketone body B-hydroxybutyrate (B-OHB) produces malformations and ultrastructural alterations in mitochondria of mouse embryos exposed for 24 hours to the compound in whole embryo culture. The present study was conducted to establish the time-course of the mitochondrial changes to determine whether the changes are reversible, and to relate these changes to the malformations produced by the compound. Since mitochondria also play a key role in the metabolism of ketone bodies, the capacity of the early somite embryo to metabolize B-OHB was investigated in an effort to link the morphological alterations in the mitochondria to a biochemical process. Early somite embryos were cultured 4, 8, or 24 hours in the presence of 32 mM DL-B-OHB and then cultured for an additional 24 hours in control serum. Finally, embryonic tissue during the teratogenic period was assessed for its capability to oxidize B-OHB using D-(3-14C)-B-OHB. The treated embryos showed progressive alterations in the mitochondria, beginning at 4 hours with a loss of matrix density and culminating at 24 hours with high-amplitude swelling, complete loss of matrix density, and disappearance of cristae. These alterations were reversible following removal of the embryos after 24 hours of exposure to B-OHB and culturing for an additional 24 hours in control serum. Metabolism studies demonstrated that the early somite embryo possesses a limited capacity to oxidatively metabolize B-OHB. The biochemical implications of these findings are discussed with respect to the possible role of ketone bodies in the mechanism of diabetes-induced congenital malformations.     

Effects of cytochalasin B on the morphogenesis of explanted early chick embryos.

Effects of cytochalasin B (CB) on chick embryos explanted at stages 4-5 and cultured for 24 hours were studied. CB (2-4 mug/ml) inhibited blastodermal expansion and neural tube closure in over 90% of the embryos. Somite formation was inhibited only where neural tissue was very degenerate. The development of other structures was usually unaffected. Cellular degeneration occurred in severely affected neuroepithelium, but cells at various phases of mitosis were found throughout its thickness, suggesting that interkinetic nuclear migration had been inhibited. Electron microscopic studies of the flattened neural tube showed that CB disrupted microfilaments and reduced the number of cytoplasmic extensions, but had no apparent effect on microtubules and other organelles. These effects were reversible. Futhermore, dimethyl sulfoxide, at 0.2-0.4% (concentrations present in 2-4 mug/ml CB medium), had no adverse effect, indicating that the observed abnormalities were direct consequences of CB treatment.     

Relationship between altered axial curvature and neural tube closure in normal and mutant (curly tail) mouse embryos

Neural tube defects, including spina bifida, develop in the curly tail mutant mouse as a result of delayed closure of the posterior neuropore at 10.5 days of gestation. Affected embryos are characterized by increased ventral curvature of the caudal region. To determine whether closure of the neuropore could be affected by this angle of curvature, we experimentally enhanced the curvature of non-mutant embryos. The amnion was opened in 9.5 day embryos; after 20 h of culture, a proportion of the embryos exhibited a tightly wrapped amnion with enhanced curvature of the caudal region compared with the control embryos in which the opened amnion remained inflated. Enhanced curvature correlated with a higher frequency of embryos with an open posterior neuropore, irrespective of developmental stage within the range, 27–32 somites. Thus, within this somite range, caudal curvature is a more accurate determinant for normal spinal neurulation than the exact somite stage. Enhanced ventral curvature of the curly tail embryo correlates with an abnormal growth difference between the neuroepithelium and ventral structures (the notochord and hindgut). We experimentally corrected this imbalance by culturing under conditions of mild hyperthermia and subsequently determined whether the angle of curvature would also be corrected. The mean angle of curvature and length of the posterior neuropore were both reduced in embryos cultured at 40.5°C by comparison with control embryos cultured at 38°C. We conclude that the sequence of morphogenetic events leading to spinal neural tube defects in curly tail embryos involves an imbalance of growth rates, which leads to enhanced ventral curvature that, in turn, leads to delayed closure of the posterior neuropore.     

Relationship between altered axial curvature and neural tube closure in normal and mutant (curly tail) mouse embryos

Neural tube defects, including spina bifida, develop in the curly tail mutant mouse as a result of delayed closure of the posterior neuropore at 10.5 days of gestation. Affected embryos are characterized by increased ventral curvature of the caudal region. To determine whether closure of the neuropore could be affected by this angle of curvature, we experimentally enhanced the curvature of non-mutant embryos. The amnion was opened in 9.5 day embryos; after 20 h of culture, a proportion of the embryos exhibited a tightly wrapped amnion with enhanced curvature of the caudal region compared with the control embryos in which the opened amnion remained inflated. Enhanced curvature correlated with a higher frequency of embryos with an open posterior neuropore, irrespective of developmental stage within the range, 27–32 somites. Thus, within this somite range, caudal curvature is a more accurate determinant for normal spinal neurulation than the exact somite stage. Enhanced ventral curvature of the curly tail embryo correlates with an abnormal growth difference between the neuroepithelium and ventral structures (the notochord and hindgut). We experimentally corrected this imbalance by culturing under conditions of mild hyperthermia and subsequently determined whether the angle of curvature would also be corrected. The mean angle of curvature and length of the posterior neuropore were both reduced in embryos cultured at 40.5°C by comparison with control embryos cultured at 38°C. We conclude that the sequence of morphogenetic events leading to spinal neural tube defects in curly tail embryos involves an imbalance of growth rates, which leads to enhanced ventral curvature that, in turn, leads to delayed closure of the posterior neuropore.     

The honeybee syndrome - implications of the teratogenicity of mannose in rat-embryo culture

Lethal effects of D-mannose in the honeybee have been recognized for more than a half a century. We observed another toxic effect of D- mannose during culture of rat embryos from the early head-fold stage to the 26-to-29-somite stage (Days 9-1/2 through 11-1 of gestation). The addition to culture mediums of 1.5 mg of D-mannose per milliliter caused growth retardation and faulty neural-tube closure in approximately two thirds of the embryos. Mannose effects occurred during the first 24 hours of culture and were attended by modes inhibition of the glycolysis that constitutes the principal energy pathway at this stage of development. Adding more glucose to preserve glycolytic flux or increasing atmospheric oxygen to promote oxidative metabolism offset the mannose teratogenesis. Our findings highlight the metabolic vulnerabilities that exist during early organogenesis, before oxidative flexibility is established. They may serve as a model to explain the teratogenicity of many other seemingly unrelated agents that could act by perturbing glycolysis at this vulnerable stage.     

In vitro embryotoxic effects of ethylene glycol in rats

Rat embryos of the CD strain were treated in a whole embryo culture system with either 30 or 40 microliters of ethylene glycol (EG) per milliliter of culture medium for the first 8 (0-8 hr) or second 8 (8-16 hr) hr of a 48-hr culture period. The compound was not embryolethal under these conditions but did alter growth and development. EG at 40 microliters/ml of culture medium at 8-16 hr decreased morphological score, somite number, crown-rump and head lengths, as well as DNA and protein contents. The most frequent abnormality induced by the compound was absence of yolk sac circulation; absent hindlimb bud, hypoplastic telencephalon, and lack of development of the otic and optic systems were also seen in EG-exposed embryos. Since it has been reported that rodent embryos cultured in vitro lack alcohol and aldehyde dehydrogenases that metabolize EG, present results suggest that the parent compound is capable of altering normal embryonic development when administered during a brief period or organogenesis.     

Somitogenesis in cultured embryos of the Japanese quail,Coturnix coturnix japonica

The ability of unsegmented paraxial mesoderm from Japanese quail embryos to form somites was studied by culturing pieces of embryos, containing the segmental plates, on an agar medium. In the first experiments, two explants were prepared from each donor embryo. Both explants contained a segmental plate and neural tube, but only one contained notochord. The explants containing notochord formed 11.4 ± 2.1 somites, while the explants without notochord formed 11.1 ± 1.3 somites. It was concluded that explants containing Japanese quail segmental plates readily form somites in culture and that the continued presence of the notochord is not required for these somites to form. In a second series of experiments, one explant from each donor embryo contained neural tube and notochord along with the segmental plate, while the corresponding explant did not contain axial structures. The results, which were similar to those obtained in the first experiments, indicated that neither neural tube nor notochord is required for somitogenesis in vitro. Additional experiments demonstrated that bilateral symmetry extends to the unsegmented somite mesoderm, where there was a strong tendency for each segmental plate of a given embryo to form the same number of somites. It was also shown that over a three-fold range of segmental plate length, there was only a slight tendency for shorter segmental plates to make fewer somites. It was estimated that Japanese quail embryos having five to 21 pairs of somites have segmental plates that represent 11.3 ± 2.9 prospective somites each.     

The effect of ethanol on fat storage in healthy subjects.

BACKGROUND. Ethanol can account for up to 10 percent of the energy intake of persons who consume moderate amounts of ethanol. Its effect on energy metabolism, however, is not known. METHODS. We studied the effect of ethanol on 24-hour substrate-oxidation rates in eight normal men during two 48-hour sessions in an indirect-calorimetry chamber. In each session, the first 24 hours served as the control period. On the second day of one session, an additional 25 percent of the total energy requirement was added as ethanol (mean [+/- SD], 96 +/- 4 g per day); during the other session, 25 percent of the total energy requirement was replaced by ethanol, which was isocalorically substituted for lipids and carbohydrates. RESULTS. Both the addition of ethanol and the isocaloric substitution of ethanol for other foods reduced 24-hour lipid oxidation. The respective mean (+/- SE) decreases were 49.4 +/- 6.7 and 44.1 +/- 9.3 g per day (i.e., reductions of 36 +/- 3 percent and 31 +/- 7 percent from the oxidation rate during the control day; P less than 0.001 and P less than 0.0025). This effect occurred only during the daytime period (8:30 a.m. to 11:30 p.m.), when ethanol was consumed and metabolized. Neither the addition of ethanol to the diet nor the isocaloric substitution of ethanol for other foods significantly altered the oxidation of carbohydrate or protein. Both regimens including ethanol produced an increase in 24-hour energy expenditure (7 +/- 1 percent with the addition of ethanol, P less than 0.001; 4 +/- 1 percent with the substitution of ethanol for other energy sources, P less than 0.025). CONCLUSIONS. Ethanol, either added to the diet or substituted for other foods, increases 24-hour energy expenditure and decreases lipid oxidation. Habitual consumption of ethanol in excess of energy needs probably favors lipid storage and weight gain.