Time-dependent differences in the development of somites of four different mouse strains

Histology Atlas of the Developing Mouse Respiratory System From Prenatal Day 9.0 Through Postnatal Day 30

Respiratory diseases are one of the leading causes of death and disability around the world. Mice are commonly used as models of human respiratory disease. Phenotypic analysis of mice with spontaneous, congenital, inherited, or treatment-related respiratory tract abnormalities requires investigators to discriminate normal anatomic features of the respiratory system from those that have been altered by disease. Many publications describe individual aspects of normal respiratory tract development, primarily focusing on morphogenesis of the trachea and lung. However, a single reference providing detailed low- and high-magnification, high-resolution images of routine hematoxylin and eosin (H&E)-stained sections depicting all major structures of the entire developing murine respiratory system does not exist. The purpose of this atlas is to correct this deficiency by establishing one concise reference of high-resolution color photomicrographs from whole-slide scans of H&E-stained tissue sections. The atlas has detailed descriptions and well-annotated images of the developing mouse upper and lower respiratory tracts emphasizing embryonic days (E) 9.0 to 18.5 and major early postnatal events. The selected images illustrate the main structures and events at key developmental stages and thus should help investigators both confirm the chronological age of mouse embryos and distinguish normal morphology as well as structural (cellular and organ) abnormalities.

BRCA1 protein dose-dependent risk for embryonic oxidative DNA damage, embryopathies and neurodevelopmental disorders with and without ethanol exposure

Although widely known as a tumor suppressor, the breast cancer 1 susceptibility protein (BRCA1) is also important in development, where it regulates fetal DNA repair pathways that protect against DNA damage caused by physiological and drug-enhanced levels of reactive oxygen species (ROS). We previously showed that conditional heterozygous (+/-) knockout (cKO) mouse embryos with a minor 28% BRCA1 deficiency developed normally in culture, but when exposed to the ROS-initiating drug, alcohol (ethanol, EtOH), exhibited embryopathies not evident in wild-type (+/+) littermates. Herein, we characterized a directBrca1 +/- knockout (KO) model with a 2-fold greater (58%) reduction in BRCA1 protein vs. the cKO model. We also characterized and compared learning & memory deficits in both the cKO and KO models. Even saline-exposed Brca1 +/- vs. +/+ KO progeny exhibited enhanced oxidative DNA damage and embryopathies in embryo culture and learning & memory deficits in females in vivo, which were not observed in the cKO model, revealing the potential pathogenicity of physiological ROS levels. The embryopathic EtOH concentration for cultured direct KO embryos was half that for cKO embryos, and EtOH affected Brca1 +/+ embryos only in the direct KO model. The spectrum and severity of EtOH embryopathies in culture were greater in both Brca1 +/- vs. +/+ embryos, and direct KO vs. cKO +/- embryos. Motor coordination deficits were evident in both male and female Brca1 +/- KO progeny exposed in utero to EtOH. The results in our direct KO model with a greater BRCA1 deficiency vs. cKO mice provide the first evidence for BRCA1 protein dose-dependent susceptibility to developmental disorders caused by physiological and drug-enhanced oxidative stress.

Histology Atlas of the Developing Mouse Placenta

The use of the mouse as a model organism is common in translational research. This mouse-human similarity holds true for placental development as well. Proper formation of the placenta is vital for development and survival of the maturing embryo. Placentation involves sequential steps with both embryonic and maternal cell lineages playing important roles. The first step in placental development is formation of the blastocyst wall (approximate embryonic days [E] 3.0-3.5). After implantation (∼E4.5), extraembryonic endoderm progressively lines the inner surface of the blastocyst wall (∼E4.5-5.0), forming the yolk sac that provides histiotrophic support to the embryo; subsequently, formation of the umbilical vessels (∼E8.5) supports transition to the chorioallantoic placenta and hemotrophic nutrition. The fully mature ("definitive") placenta is established by ∼E12.5. Abnormal placental development often leads to embryonic mortality, with the timing of death depending on when placental insufficiency takes place and which cells are involved. This comprehensive macroscopic and microscopic atlas highlights the key features of normal and abnormal mouse placental development from E4.5 to E18.5. This in-depth overview of a transient (and thus seldom-analyzed) developmental tissue should serve as a useful reference to aid researchers in identifying and describing mouse placental changes in engineered, induced, and spontaneous disease models.

Distinct Nuclear Architecture of Photoreceptors and Light-Induced Behaviors in Different Strains of Mice

Purpose

The mouse retina is considered a remarkable model for studying gene functions. However, variations in genetic background influence phenotypes in the mammalian retina. Therefore this study aimed to investigate the effects of the genetic background on the nuclear architecture of photoreceptor cells and the light-induced behavior in C57BL/6, 129 × 1/svj, and ICR mice.

Methods

The nuclear architecture of photoreceptor cells was investigated using various staining methods on postnatal day 21 (P21). Murine behavior was observed using a light-dark compartment test.

Results

The outer nuclear layer and retina were significantly thicker in C57BL/6 mice than in 129 × 1/svj mice. The percentage of photoreceptors with one chromocenter was significantly higher in C57BL/6 mice than in 129 × 1/svj and ICR mice on P21. The numbers of photoreceptor cells in C57BL/6 and ICR mice were significantly higher than those in 129 × 1/svj mice. The behavior test revealed that the walking distance and velocity in the light compartment were increased in C57BL/6 and ICR mice compared to 129 × 1/svj mice.

Conclusions

Different mouse strains had a distinct nuclear architecture of photoreceptors on P21, and C57BL/6 and ICR mice were more active than 129 × 1/svj mice in response to light-induced stress.

Translational Relevance

This study demonstrates a technique for assessing retinal structures and nuclear architecture in various strains of mice, which are often used to model human retinal disease. Hence, this study may help to elucidate the effect of genetic or disease-induced variance in retinal architecture and the organization of photoreceptor nuclear content on visual function in humans.

Histology Atlas of the Developing Prenatal and Postnatal Mouse Central Nervous System, with Emphasis on Prenatal Days E7.5 to E18.5

Evaluation of the central nervous system (CNS) in the developing mouse presents unique challenges, given the complexity of ontogenesis, marked structural reorganization over very short distances in 3 dimensions each hour, and numerous developmental events susceptible to genetic and environmental influences. Developmental defects affecting the brain and spinal cord arise frequently both in utero and perinatally as spontaneous events, following teratogen exposure, and as sequelae to induced mutations and thus are a common factor in embryonic and perinatal lethality in many mouse models. Knowledge of normal organ and cellular architecture and differentiation throughout the mouse's life span is crucial to identify and characterize neurodevelopmental lesions. By providing a well-illustrated overview summarizing major events of normal in utero and perinatal mouse CNS development with examples of common developmental abnormalities, this annotated, color atlas can be used to identify normal structure and histology when phenotyping genetically engineered mice and will enhance efforts to describe and interpret brain and spinal cord malformations as causes of mouse embryonic and perinatal lethal phenotypes. The schematics and images in this atlas illustrate major developmental events during gestation from embryonic day (E)7.5 to E18.5 and after birth from postnatal day (P)1 to P21.

Differences between NMRI and DBA/2J mice in the development of somites and susceptibility to methylnitrosourea-induced skeleton anomalies

The development of DBA/2J mouse strain embryos is nearly 12 h - or 6 somite pairs - delayed as compared to the outbred NMRI mouse embryos of the same age on gestation days (GD) 8-12. To evaluate inter-strain differences in susceptibility to teratogens, dams were treated with methylnitrosourea (MNU, 5 mg/kg body weight i.p.) on defined gestation days (NMRI: GD 9, 91/2 or 10; DBA/2J: GD 10 or 101/2). Skeletal anomalies produced by MNU on both mouse strains varied with the GD of treatment. The pattern of anomalies produced by MNU on a given GD markedly differed between the two mouse strains, yet they were similar -with a few exceptions- when exposures at equivalent embryonic stages are compared. Findings from this study indicated that strain-dependent differences in the developmental stage of mouse embryos of the same gestational age occur, a possibility that has been often neglected when inter-strain differences in susceptibility to developmental toxicants are interpreted.

Early detection and staging of spontaneous embryo resorption by ultrasound biomicroscopy in murine pregnancy

BACKGROUND

Embryo resorption is a major problem in human medicine, agricultural animal production and in conservation breeding programs. Underlying mechanisms have been investigated in the well characterised mouse model. However, post mortem studies are limited by the rapid disintegration of embryonic structures. A method to reliably identify embryo resorption in alive animals has not been established yet. In our study we aim to detect embryos undergoing resorption in vivo at the earliest possible stage by ultra-high frequency ultrasound.

METHODS

In a longitudinal study, we monitored 30 pregnancies of wild type C57BI/6 mice using ultra-high frequency ultrasound (30-70 MHz), so called ultrasound biomicroscopy (UBM). We compared the sonoembryology of mouse conceptuses under spontaneous resorption and neighbouring healthy conceptuses and correlated the live ultrasound data with the respective histology.

RESULTS

The process of embryo resorption comprised of four stages: first, the conceptus exhibited growth retardation, second, bradycardia and pericardial edema were observed, third, further development ceased and the embryo died, and finally embryo remnants were resorbed by maternal immune cells. In early gestation (day 7 and 8), growth retardation was characterized by a small embryonic cavity. The embryo and its membranes were ill defined or did not develop at all. The echodensity of the embryonic fluid increased and within one to two days, the embryo and its cavity disappeared and was transformed into echodense tissue surrounded by fluid filled caverns. In corresponding histologic preparations, fibrinoid material interspersed with maternal granulocytes and lacunae filled with maternal blood were observed. In later stages (day 9-11) resorption prone embryos were one day behind in their development compared to their normal siblings. The space between Reichert's membrane and inner yolk sac membrane was enlarged The growth retarded embryos exhibited bradycardia and ultimately cessation of heart beat. Corresponding histology showed apoptotic cells in the embryo while the placenta was still intact. In the subsequent resorption process first the embryo and then its membranes disappeared.

CONCLUSIONS

Our results provide a temporal time course of embryo resorption. With this method, animals exhibiting embryo resorption can be targeted, enabling the investigation of underlying mechanisms before the onset of total embryo disintegration.

Gene expression changes in C57BL/6J and DBA/2J mice following prenatal alcohol exposure

BACKGROUND

Prenatal alcohol exposure can result in fetal alcohol spectrum disorders (FASD). Not all women who consume alcohol during pregnancy have children with FASD and studies have shown that genetic factors can play a role in ethanol teratogenesis. We examined gene expression in embryos and placentae from C57BL/6J (B6) and DBA/2J (D2) mice following prenatal alcohol exposure. B6 fetuses are susceptible to morphological malformations following prenatal alcohol exposure while D2 are relatively resistant.

METHODS

Male and female B6 and D2 mice were mated for 2 hours in the morning, producing 4 embryonic genotypes: true-bred B6B6 and D2D2, and reciprocal B6D2 and D2B6. On gestational day 9, dams were intubated with 5.8 g/kg ethanol, an isocaloric amount of maltose dextrin, or nothing. Four hours later, dams were sacrificed and embryos and placentae were harvested. RNA was extracted, labeled and hybridized to Affymetrix Mouse Genome 430 v2 microarray chips. Data were normalized, subjected to analysis of variance and tested for enrichment of gene ontology molecular function and biological process using the Database for Annotation, Visualization and Integrated Discovery (DAVID).

RESULTS

Several gene classes were differentially expressed in B6 and D2 regardless of treatment, including genes involved in polysaccharide binding and mitosis. Prenatal alcohol exposure altered expression of a subset of genes, including genes involved in methylation, chromatin remodeling, protein synthesis, and mRNA splicing. Very few genes were differentially expressed between maltose-exposed tissues and tissues that received nothing, so we combined these groups for comparisons with ethanol. While we observed many expression changes specific to B6 following prenatal alcohol exposure, none were specific for D2. Gene classes up- or down-regulated in B6 following prenatal alcohol exposure included genes involved in mRNA splicing, transcription, and translation.

CONCLUSIONS

Our study identified several classes of genes with altered expression following prenatal alcohol exposure, including many specific for B6, a strain susceptible to ethanol teratogenesis. Lack of strain specific effects in D2 suggests there are few gene expression changes that confer resistance. Future studies will begin to analyze functional significance of the expression changes.

Quantitative trait locus mapping for ethanol teratogenesis in BXD recombinant inbred mice

BACKGROUND

Individual differences in susceptibility to the detrimental effects of prenatal ethanol (EtOH) exposure have been demonstrated. Many factors, including genetics, play a role in susceptibility and resistance. We have previously shown that C57BL/6J (B6) mice display a number of morphological malformations following an acute dose of EtOH in utero, while DBA/2J (D2) mice are relatively resistant. Here, we present the results of quantitative trait locus (QTL) mapping for EtOH teratogenesis in recombinant inbred strains derived from a cross between B6 and D2 (BXD RIs).

METHODS

Pregnant dams were intubated with either maltose-dextrin or 5.8 g/kg EtOH on day 9 of gestation (GD9). On GD 18, dams were sacrificed and fetuses and placentae were removed. Placentae and fetuses were weighed; fetuses were sexed and examined for gross morphological malformations. Fetuses were then either placed in Bouin's fixative for subsequent soft-tissue analyses or eviscerated and placed in EtOH for subsequent skeletal examinations. QTL mapping for maternal weight gain (MWG), prenatal mortality, fetal weight (FW) at c-section, placental weight (PW), and several morphological malformations was performed using WebQTL.

RESULTS

Heritability for our traits ranged from 0.06 for PW to 0.39 for MWG. We found suggestive QTLs mediating all phenotypes and significant QTLs for FW and digit and rib malformations. While most QTL regions are large, several intriguing candidate genes emerged based on polymorphisms between B6 and D2 and gene function.

CONCLUSIONS

In this first mapping study for EtOH teratogenesis, several QTLs were identified. Future studies will further characterize these regions. Identification of genes and epigenetic modifications mediating susceptibility to the teratogenic effects of alcohol in mice will provide targets to examine in human populations.

Maternal effects on ethanol teratogenesis in a cross between A/J and C57BL/6J mice

Genetic factors influence adverse pregnancy outcome in both humans and animal models. Animal research reveals that both the maternal and fetal genetic profiles are important for determining the risk of physical birth defects and prenatal mortality. Using a reciprocal-cross breeding design, we investigated whether the mother's genes may be more important than fetal genes in determining risk for ethanol teratogenesis. Examination of possible synergistic genetic effects on ethanol teratogenesis was made possible by using two mouse strains known to be susceptible to specific malformations. Inbred A/J (A) and C57BL/6J (B6) mice were mated to produce four fetal genotype groups: the true-bred AċA and B6ċB6 genotypes and the genetically identical AċB6 and B6ċA genotypes (the F(1) genotype). Dams were administered either 5.8 g/kg ethanol or an isocaloric amount of maltose-dextrin on day 9 of pregnancy. Fetuses were removed by laparotomy on gestation day 18, weighed, and assessed for digit, vertebral, and kidney malformations. Digit malformations in the genetically identical F(1) ethanol-exposed litters showed a pattern consistent with a maternal genetic effect (AċB6 [2%] and B6ċA [30%]). In contrast, vertebral malformations were similar in all ethanol-exposed litters (AċA [26%], AċB6 [18%], B6ċA [22%], and B6ċB6 [33%]). The percentage of malformations did not differ between male and female fetuses, indicating sex-linked factors are not responsible for the maternal effect. Ethanol exposure decreased litter weights but did not affect litter mortality compared with maltose-exposed controls. This study supports the idea that genes influence malformation risk following in utero alcohol exposure. Specifically, maternal genes influence risk more than fetal genes for some teratogenic outcomes. No evidence supported synergistic genetic effects on ethanol teratogenesis. This research supports the conclusion that uterine environment contributes to determining risk of Fetal Alcohol Spectrum Disorder.

Ethanol teratogenesis in five inbred strains of mice

BACKGROUND

Previous studies have demonstrated individual differences in susceptibility to the detrimental effects of prenatal ethanol exposure. Many factors, including genetic differences, have been shown to play a role in susceptibility and resistance, but few studies have investigated the range of genetic variation in rodent models.

METHODS

We examined ethanol teratogenesis in 5 inbred strains of mice: C57BL/6J (B6), Inbred Short-Sleep, C3H/Ibg, A/Ibg, and 129S6/SvEvTac (129). Pregnant dams were intubated with either 5.8 g/kg ethanol (E) or an isocaloric amount of maltose-dextrin (MD) on day 9 of pregnancy. Dams were sacrificed on day 18 and fetuses were weighed, sexed, and examined for gross morphological malformations. Every other fetus within a litter was then either placed in Bouin's fixative for subsequent soft-tissue analyses or eviscerated and placed in ethanol for subsequent skeletal analyses.

RESULTS

B6 mice exposed to ethanol in utero had fetal weight deficits and digit, kidney, brain ventricle, and vertebral malformations. In contrast, 129 mice showed no teratogenesis. The remaining strains showed varying degrees of teratogenesis.

CONCLUSIONS

Differences among inbred strains demonstrate genetic variation in the teratogenic effects of ethanol. Identifying susceptible and resistant strains allows future studies to elucidate the genetic architecture underlying prenatal alcohol phenotypes.

Embryonic and Neonatal Phenotyping of Genetically Engineered Mice

Considerable progress has been made in adapting existing and developing new technologies to enable increasingly detailed phenotypic information to be obtained in embryonic and newborn mice. Sophisticated methods for imaging mouse embryos and newborns are available and include ultrasound and magnetic resonance imaging (MRI) for in vivo imaging, and MRI, vascular corrosion casts, micro-computed tomography, and optical projection tomography (OPT) for postmortem imaging. In addition, Doppler and M-mode ultrasound are useful noninvasive tools to monitor cardiac and vascular hemodynamics in vivo in embryos and newborns. The developmental stage of the animals being phenotyped is an important consideration when selecting the appropriate technique for anesthesia or euthanasia and for labeling animals in longitudinal studies. Study design also needs to control for possible differences between inter- and intralitter variability, and for possible long-term developmental effects caused by anesthesia and/or procedures. Noninvasive or minimally invasive intravenous or intracardiac injections or blood sampling, and arterial pressure and electrocardiography (ECG) measurements are feasible in newborns. Whereas microinjection techniques are available for embryos as young as 6.5 days of gestation, further advances are required to enable minimally invasive fluid or tissue samples, or blood pressure or ECG measurements, to be obtained from mouse embryos in utero. The growing repertoire of techniques available for phenotyping mouse embryos and newborns promises to accelerate knowledge gained from studies using genetically engineered mice to understand molecular regulation of morphogenesis and the etiology of congenital diseases.

Intrauterine bisphenol A exposure leads to stimulatory effects on Sertoli cell number in rats

Using the optical disector for quantifying cell numbers, we investigated whether oral treatment of rats on days 6-21 of gestation with the weakly estrogenic bisphenol A (BPA, 0.1 or 50 mg/kg) or the highly estrogenic ethinyl estradiol (EE, 0.02 mg/kg) alters testicular histology, in those offspring 9-12 month of age. Since production of male germ cells depends on Sertoli cell number, possible changes in that parameter were investigated using unbiased stereology. Spermatogenesis was qualitatively normal in all groups. BPA increases Sertoli cell number per organ but not when expressed as per gram testis. EE did not affect cell number per organ but did affect numbers on a per gram testis basis due to a lowered testis weight. In contrast to the lowering of Sertoli cell numbers that might have been expected according to the estrogen hypothesis, intrauterine administration of these xenoestrogens in fact resulted in minor increases in Sertoli cell numbers and had no qualitative effect on spermatogenesis.

Stage-specific homeotic vertebral transformations in mouse fetuses induced by maternal hyperthermia during somitogenesis

To investigate the heat shock effects upon somitogenesis and specification of the vertebral identity, pregnant ICR mice were briefly exposed to 42 degrees C or 43 degrees C at E7.5, E8.5, or E9.5 (noon of the plug day = E0.5). Heat treatment induced embryonic day-specific vertebral transformations whose frequency and severity were dependent on the temperature elevation. Following a heat treatment at E8.5, the vertebral identity of T6 through S1 was shifted anteriorly by one or two segments (posterior transformations). Such shifts were found in more than one-third of the fetuses heat-stressed at 42 degrees C, and in over 90% of those exposed to 43 degrees C. When heated at E7.5, the anterior boundary of vertebral transformations was shifted cranially to cervical levels (C1-C7), and when heated at E9.5, it was shifted caudally to the lower thoracic and lumbar levels (T13-L4). Examination of Hox gene expression domains by in situ hybridization showed that the anterior boundaries of Hoxa-5, Hoxa-7, Hoxc-8, and Hoxc-9 expression domains in the paraxial mesoderm were shifted cranially by one somite segment in embryos heated at E7.5, as compared with the corresponding levels of their expression in control embryos. Such cranial shifts were found for Hoxa-7, Hoxc-8 and Hoxc-9, but not for Hoxa-5, in embryos heated at E8.0. In embryos heated at E8.5, only the expression domains for Hoxc-8 and Hoxc-9 were found to be shifted. The observed stage-specific vertebral transformations and shifts of the Hox gene expression domains were consistent with the temporal colinearity and posterior predominance of Hox gene expression during development. Further histological and cytochemical analyses revealed that heat-induced vertebral transformations may not be a result of induced cell death, but heat-induced transient arrest of cell proliferation and somitogenesis could result in altered expression of Hox genes and subsequently produce vertebral transformations.

Contributions of dam and conceptus to differences in sensitivity to valproic acid among C57 black and SWV mice

To ascertain the relative contributions of genotypes of conceptus and dam to developmental toxicity occasioned by valproic acid (VPA), crosses were established between resistant C57BL/6JBk (C, C57) and susceptible SWV/Bk (S, SWV) strains of mice. These included matings of pure lines, reciprocal outcrosses, and reciprocal backcrosses with F1 hybrids. At 8 d:12 h +/- 5 h, for each mating, 0, 500, or 600 mg/kg aqueous VPA was injected ip. Fetuses were examined on gestation day (gd) 18 for exencephaly (the paradigmatic anomaly), other abnormalities, mortality, litter size, and fetal weight. At 600 mg/kg, sensitivity to exencephaly induction in all cases was that of the dam, regardless of sire. Thus exencephaly here seems to be largely a function of the uterine environment produced by the maternal genotype. This inference is confirmed in backcrosses where F1-dams x S-sires and F1-dams x C-sires produced-identical outcomes, and S-dams x F1-sires produced much higher frequencies of exencephaly than C-dams x F1-sires. For prenatal mortality, the genotypes of both dam and conceptus appear to be important determinants. Fetal contribution is inferred from the observations that S-dam x S-sire matings produced a much higher frequency of mortality than S-dams x C-sires, and C-dams x C-sires produced higher mortality than C-dams x S-sires. Therefore, heterozygosity of the conceptus was protective. Among backcrosses, fetal determination of sensitivity to mortality is also seen by the observation that F1-dams x C-sires produces the same fetal mortality as C-dams x F1-sires. The contribution of uterine environment is seen in the observation that matings of S-dams x C-sires resulted in higher fetal mortality than did those with C-dams x S-sires. Therefore, identical conceptuses in different dams showed different levels of fetal loss. Thus exencephaly response appears to be largely controlled by genes active in the dam, and mortality as a result of a multigenic outcome with contributing genes active in both conceptus and dam. The data also suggest that SWV pure-line dams make a contribution to prenatal mortality not seen in C57 or F1 dams. Mean litter size among VPA-exposed litters showed high variability in pure lines and outcrosses. In backcrosses, F1 dams produced larger litters than pure line dams, arguing for heterosis as a contributor to this parameter. Reduction in litter size occasioned by VPA exposure was great in pure line dams and nonexistent in F1 dams. The SWV dams crossed with F1 sires were the only group among the backcrosses to show reduction of litter size, providing further confirmation of the increased sensitivity of pure-line (i.e., homozygous) SWV dams to VPA exposure. Fetal weight seems to be a function of uterine environment because female SWV produced conceptuses with lower fetal weight in all crosses, and produced a greater reduction in fetal weight attributable to VPA exposure than C57 or F1 dams. Fetal weight did not correlate closely with litter size, suggesting that a lower fetal weight may be a strain characteristic, as are exencephaly induction and prenatal mortality in response to VPA. Differences in sensitivity to VPA insult are seen for all parameters investigated with SWV dams being the most sensitive, but mechanisms seem to differ for a number of the endpoints.

Effects of 2-methoxyethanol on mouse neurulation

The potent developmental toxicant, 2-methoxyethanol (2-ME), elicits exencephaly in near-term mouse fetuses following a single maternal treatment early on gestation day (gd) 8. Deleterious morphological consequences to the neurulating embryo shortly after exposure have not been reported. The present study was designed to fill this gap and to investigate the impact of 2-ME treatment on cell death patterns in the embryonic neural folds. Dams were injected subcutaneously with saline, 250 or 325 mg 2-ME/kg 2 hr prior to the beginning of gd 8. The effect of 2-ME on gross and microscopic neural development was examined in conceptuses on gd 9, 6 hr (9:6), 10:6, and 18:0. Compared to saline, 2-ME treatment increased the percentage of embryos with open neural tubes (ONTs) at all gestation days. Although few statistically significant differences (P < 0.05) existed among the ONT rates on the 3 observation days, an interesting biological response occurred. Both high and low 2-ME doses appeared to elicit the greatest incidence of neural tube patency on gd 9:6 (affecting approximately 27% of embryos). During the subsequent 24 hr, recovery occurred and many neural folds apparently closed. Consequently, the ONT incidences on gd 10:6 (approximately 11%) were quite similar to the gd 18 exencephaly rates elicited by both chemical treatments (approximately 15%). A dose response was not seen due to a substantial increase in resorption rates following the 325 mg/kg dose. Compared to the other treatment groups, the low 2-ME dose significantly inhibited embryonic growth as indicated by reduced crown-rump and head lengths and increased incidence of developmentally delayed brain maturation. To evaluate chemically induced changes in cell death, neurulating embryos were collected on gd 8:6 and either immersed in the vital dye, Nile blue sulfate (NBS), or processed for histopathology. In 2-ME-exposed embryos, excessive NBS uptake occurred in neural fold neuroepithelium at sites of nonclosure. Using histopathology, the extent of cell death in the cephalic neural folds was dependent on the 2-ME dose, and the neuroepithelium was more severely affected than the mesenchyme. These observations suggest 1) a trend toward repair and catch-up growth later in gestation which may ameliorate the overt early effects of 2-ME, and 2) an association between enhanced cell death and regions of the neural tube particularly vulnerable to nonclosure.