Ultrastructure and function of the rat yolk sac: damage caused by teratogenic anti-VYS serum and recovery

It was hypothesized that heterologous anti-rat visceral yolk sac serum (AVYS) exerts its teratogenic effect by reducing the endocytosis of serum proteins by the visceral yolk sac (VYS), thus reducing the supply of amino acids to the embryo and VYS. To evaluate this hypothesis, we studied the effect of teratogenic AVYS on the endocytic function of the VYS and the ultrastructure of the VYS and parietal yolk sac (PYS). Rat conceptuses were exposed to a teratogenic dose of AVYS on the 10th day of gestation in vivo or in vitro. Control and AVYS-exposed specimens were collected 24-192 hr later and prepared for scanning and transmission electron microscopy (SEM and TEM, respectively) utilizing standard procedures. The Endocytic Index was calculated for the VYS utilizing standard procedures. Approximately 97% of the in vivo exposed and 94% of the in vitro exposed embryos were morphologically abnormal. Ultrastructural observations showed that exposure to AVYS in vivo or in vitro caused severe damage to the VYS endodermal epithelial cells with loss of cellular borders, reduction in the number and length of microvilli, and increased cellular inclusions; and some damage to PYS endodermal cells with increased blebbling and decreased cell number. Recovery was evident at 72 hr and complete by 96 hr. The Endocytic Index was significantly reduced in the VYS 24 and 48 hr after injecting AVYS into the pregnant rat but was not significantly different at 96 and 192 hr. Our results show that the AVYS antiserum damaged visceral endodermal epithelium experienced ultrastructural recovery with parallel functional recovery. These studies suggest that transient yolk sac placental ultrastructural damage and dysfunction was probably sufficient to cause irreversible damage to the developing embryo during early organogenesis. We conclude that the proximate effect of the AVYS was on the plasma membrane of the visceral endoderm and that decreased pinocytosis is a consequence of this effect.     

Lipid droplets in the visceral yolk sac endodermal cells of the postimplantation rat embryo: Application of malachite green-glutaraldehyde fixative

Summary The ultrastructure of the visceral yolk sac (VYS) of the rat embryo at day 9.5 of gestation was examined after fixation with either Karnovsky's glutaraldehyde-paraformaldehyde solution or malachite green-containing glutaraldehyde (MGA) solution. Fixation with MGA retained homogeneously electron-dense droplets in the cytoplasm and the nucleus of endodermal cells, both of which were lost in the specimens prepared by Karnovsky's fixation method. The cytoplasmic MGA-positive droplets were frequently associated with other cytoplasmic organelles such as rough endoplasmic reticulum, mitochondria and membrane-delineated inclusion bodies, but these cytoplasmic organelles never incorporated MGA-positive materials, whereas Golgi apparatus contained intracisternal MGA-positive droplets. Extracellular MGA-positive droplets were also encountered at the apical surface of endodermal cells and in the intercellular space between endodermal cells and the underlying mesodermal cells. These MGA-positive droplets were considered to be lipid in nature, and their origin in the endodermal cells of VYS is discussed.     

Cell physiology of the rat visceral yolk sac: a study of pinocytosis and lysosome function

The rat visceral yolk sac is active in pinocytosis. Macromolecules accumulated by the tissue are, in general, routed to the lysosomes, where they either accumulate (if non-digestible by the lysosomal enzymes) or are degraded to their monomeric components. The yolk sac cells engage in adsorptive pinocytosis, which leads to the preferential uptake of macromolecules bearing certain surface features, such as a hydrophobic or a cationic domain. Substrates that enter the yolk sac by adsorptive pinocytosis can in some cases act as bivalent ligands, carrying in a second substance by "piggy-back" pinocytosis. Pinocytosis and intralysosomal digestion of plasma proteins by the organogenesis-stage rat embryo play an important nutritional role, supplying a high proportion of the embryo's amino acid requirement. Teratogenic effects can be induced by substances that inhibit either pinocytosis or intralysosomal proteolysis at this sensitive stage of gestation.     

Immunocytochemical localization of oncodevelopmental proteins in human germ cell and hepatic tumors.

In a combined tissue and serum study alpha-1-antitrypsin (AAT) and alpha-fetoprotein are demonstrated in parallel within tumor tissue inclusions in both endodermal sinus (yolk sac) tumors and malignant hepatomas, and AAT is demonstrated as a marker in both neoplastic and preneoplastic liver lesions occurring in oral contraceptive users, all in association with normal serum AAT phenotype. The tumor inclusions in the first two instances differ immunocytochemically from AAT liver cell globules found in inherited AAT deficiency, which are unreactive for alpha-fetoprotein. It is concluded that unlike the molecular basis of storage associated with AAT phenotypic variation, the tumor inclusions reflect a separate, nongenetic mechanism of AAT storage, which may be epigenetic in nature. AAT and alpha-fetoprotein both are synthesized normally in yolk sac and fetal liver, a parallelism which disappears soon after birth. The reexpression of both proteins in two distinct tumor types arising from endodermal origins (yolk sac and liver), suggests that these markers may represent reemerging fetal gene products, a phenomenon previously proposed only for alpha-fetoprotein, a prototypic "oncofetal antigen."     

Altered visceral yolk sac function produced by a low-molecular-weight somatomedin inhibitor

A fraction from diabetic rat serum containing a low-molecular-weight (800-1000) somatomedin inhibitor (SI) alters growth and development in both neurulation and early limb bud staged mouse embryos in vitro. Previous studies suggested that an accumulation of serum proteins and morphological changes of the visceral yolk sac (VYS) were produced following exposure to the SI in early limb bud staged conceptuses. The morphological changes, characterized by the presence of large endosomes in the endodermal cells, suggested that the SI altered histiotrophic nutrition, whereby proteins are pinocytosed by the endodermal VYS cells and degraded to constituent amino acids. Therefore, the effects of the SI on pinocytosis and protein degradation by the VYS were evaluated using the whole embryo culture system. Results showed that the SI reduced fluid phase pinocytosis as determined by the uptake of [U-14C]sucrose, but that accumulation of [3H]leucine-labeled hemoglobin ([3H]Hb) by the VYS was greater following exposure to the SI than in controls. In contrast, the accumulation of 3H-labeled amino acids in the embryo (produced from the degradation of [3H]Hb by the VYS) was reduced by the SI. The extent of amino acid reduction in embryonic accumulation is dependent upon the concentration of SI in the culture medium and correlates with the incidence of malformations produced by the SI, i.e., high rates of malformations occur with large reductions in embryonic 3H-labeled amino acid accumulation. The apparent paradox of high [3H]Hb accumulation in the presence of decreased pinocytosis appears to be the result of altered processing of the [3H]Hb in the endodermal cells. The altered processing decreases the "elimination" of the proteins from the VYS and results in the decrease in 3H-labeled amino acid present in the embryo proper. Therefore, the SI appears to alter two processes of VYS histiotrophic function. (1) decreased pinocytosis and (2) altered protein processing, ultimately resulting in a decreased availability of substrates for the embryo. During the early stages of embryogenesis in the human, the trophoblast cells of the placenta are responsible for the transport of nutrients from the maternal to embryonic systems. Since these cells show high phagocytic and pinocytotic activities, the SI may also disrupt these processes in the chorioallantoic placenta and contribute to diabetes-induced embryopathies.     

Expression of v-src induces aberrant development and twinning in chimaeric mice

The role of the proto-oncogene c-src in mouse development has been investigated by studying the consequences of expressing its viral homologue, v-src. Embryonic stem (ES) cell lines with differing levels of v-src tyrosine kinase activity have been used to generate chimaeric mice. Whereas a low level of v-src expression is compatible with embryogenesis, chimaeras derived from ES clones with high levels of v-src activity develop abnormally and die on the 8th-9th day of gestation. These abnormalities are characterized by the formation of twin or multiple embryos within the same Reichert's membrane, and by the arrest of embryonic development at the late egg cylinder stage, accompanied by relative expansion of the visceral yolk sac (VYS) and hyperplasia of the VYS endoderm. These results demonstrate for the first time that deregulated expression of the src protooncogene product can induce developmental abnormalities during early embryogenesis.     

Experimental yolk sac dysfunction as a model for studying nutritional disturbances in the embryo during early organogenesis

Our investigations concerning the importance of cell surface macromolecules during embryonic development led us to the discovery in 1961 that heterologous anti-rat kidney serum produced teratogenesis, growth retardation and embryonic death when injected into the pregnant rat during early organogenesis. It was established that IgG was the teratogenic agent, primarily directed against the visceral yolk sac (VYS) but not the embryo. Heterologous anti-rat VYS serum was prepared which was teratogenic localized in the VYS and served as a model for producing VYS dysfunction and embryonic malnutrition. The role of the yolk sac placenta in histiotrophic nutrition is now recognized to be critical for normal embryonic development during early organogenesis in the rodent. VYS antiserum affects embryonic development primarily by inhibiting endocytosis of proteins by the VYS endoderm, resulting in a reduction in the amino acids supplied to the embryo. Our laboratory has recently developed teratogenic monoclonal yolk sac antibodies (MCA) which can be utilized; to study VYS plasma membrane synthesis and recycling, to compare yolk sac function among different species, and to identify components of the plasma membrane involved in pinocytosis. MCA prepared against certain VYS antigens provide an opportunity to study embryonic nutrition with minimal interference with the nutritional state of the mother. Recent developments in the study of the human yolk sac along with our laboratory's ability to isolate a spectrum of yolk sac antigens, prepare monoclonal antibodies, and perform functional studies, should provide information that will increase our understanding of yolk sac function and dysfunction in the human and determine the relative importance of various amino acids to normal development during mammalian organogenesis.     

Proteolytic activity in the yolk sac membrane of quail eggs.

Extraembryonal degradation of yolk protein is necessary to provide the avian embryo with required free amino acids during early embryogenesis. Screening of proteolytic activity in different compartments of quail eggs revealed an increasing activity in the yolk sac membrane during the first week of embryogenesis. In this tissue, the occurrence of cathepsin B, a lysosomal cysteine proteinase, and cathepsin D, a lysosomal aspartic proteinase, has been described recently (Gerhartz et al., Comp Biochem Physiol, 118B:159-166, 1997). Determination of cathepsin B-like and cathepsin D-like proteolytic activity in the yolk sac membrane indicated a significant correlation between growth of the yolk sac membrane and proteolytic activity, shown by an almost constant specific activity. Both proteinases could be localized in the endodermal cells, which are in direct contact to the yolk. The concentration of proteinases in the endodermal cells appears to be almost unaltered in the investigated early stage of quail development, whereas the amount of endodermal cells increases rapidly, seen by a complicated folding of the yolk sac membrane. In the same cells quail cystatin, a potent inhibitor of quail cathepsin B (Ki 0.6 nM), has been localized at day 8 of embryonic development. Approximately at this stage of development, the quail embryo stops metabolizing yolk. In conclusion, it is strongly indicated that the amount of available free amino acids, produced by proteolytic degradation and supporting embryonic growth, is regulated by the growth of the yolk sac membrane.     

Studies on the mechanism of trypan blue teratogenicity in the rat developing in vivo and in vitro

Trypan blue is a potent teratogen in vivo and in vitro in the rat. Many of the abnormalities produced by trypan blue--including swollen neural tube and pericardium, subectodermal blisters, hematomas, and generalized edema--may result from altered fluid balance in and around the embryo. The present study demonstrates relationships between changes in the fluid environment around the embryo and appearance of anomalies. Rat embryos were exposed in utero or in vitro to trypan blue during the early period of organogenesis. Both exposures resulted in defects that are typical of trypan blue treatment. Osmolality of exocoelomic fluid (ECF) was measured on gestation day 10 in vivo and day 12 in vitro, both after 48 hr of exposure to trypan blue. In both cases ECF osmolality was significantly lower than controls. This was correlated with the presence of edema-related anomalies in the embryo. On gestation day 11 in vivo, three days after maternal injection of trypan blue, ECF osmolalities were significantly higher than controls; however, there was tremendous variability in this parameter in day 11 treated embryos, and some had ECF osmolalities below the control range. Increased frequency of abnormalities was correlated with abnormal ECF osmolality, below and above the control range. Trypan blue probably exerts its teratogenic effects by disturbing the function of the visceral yolk sac. The movements of an amino acid and a monosaccharide across the visceral yolk sac were measured on gestation day 12 embryos in vitro. This aspect of yolk sac function was not altered by trypan blue exposure. Ultrastructure of the visceral yolk sac was observed after trypan blue exposure in vivo and in vitro. Endodermal cells in trypan blue-treated yolk sacs contained fewer large, electron dense lysosomes than controls. These were replaced by numerous small vacuoles, which may contain trypan blue. Trypan blue causes osmotic changes in the rat embryo in vivo and in vitro. These changes are correlated with embryonic malformations. Alterations in yolk sac ultrastructure indicate that trypan blue affects the function of this membrane.     

The pig yolk sac I

Summary Yolk sacs from pig embryos ranging between 18 mm and 55 mm in length were investigated by scanning electron microscopy (SEM), transmission electron microscopy (TEM), and histochemistry. The organ was no longer present in embryos of 70 mm length. The endoderm proliferates in embryos of about 20 mm length with gland-like endodermal cell columns and finally becomes stratified, representing over 90% of the yolk sac mass. The endodermal cells show a high activity of oxidoreductases and lysosomal enzymes; their luminal surface bears few absorptive specializations. The mesothelium is inert, as judged from its surface ultrastructure, organelle composition and enzyme content. TEM reveals the endodermal cells to be polarized even in stratified areas. They resemble liver parenchymal cells with respect to their basal villi, which are exposed to capillaries with discontinuous or fenestrated endothelium. Giant mitochondria with crystalline inclusions in the mature endodermal cytoplasm are outnumbered by large stacks of the rough ER, which can amount to 60% of the cytoplasm. This conspicuous RER is suspected to be the production site of serum proteins which are discharged into the vascular bed. Close to the time of the organ's regression, an unusual storage of material in terminal buds of the ER was found. Intercellular canaliculi and the endocytic apparatus of the endoderm are thought to serve regression.     

Effects of lysosomal proteinase inhibition on the development of the rat embryo in vitro

Altered lysosomal function in the visceral yolk sac can result in abnormal development. As proteolysis is an important function of the rodent visceral yolk sac during early and mid-gestation, we characterized the lysosomal proteolytic enzyme activity of this extraembryonic membrane and determined the effects of inhibitors of protein degradation on embryonic development. Constituent activities of cysteine and aspartic acid proteinases were measured in rat visceral yolk sac on gestation day 12, and the effects of the cysteine proteinase inhibitors leupeptin, E-64 [trans-epoxysuccinyl-l-leucylamido(4-guanido)butane] and N-ethylmaleimide and the aspartic acid proteinase inhibitor pepstatin were determined in Sprague-Dawley rat embryos cultured in vitro from gestation days 10-12. It was determined that only cysteine proteinases, primarily cathepsins B and L, are active in the mid-gestation visceral yolk sac. The cysteine proteinase inhibitors leupeptin and E-64 both produced a concentration-related decrease in embryonic growth, as measured by crown-rump length, somite number, and embryonic protein content, and a concentration-related increase in incidence of abnormalities. A characteristic pattern of abnormalities was produced which involved a decrease in neural tube volume and the formation of a subectodermal blister opposite the point of attachment of the vitelline vessels. At high concentrations, anophthalmia was also observed. The decreased neural tube volume was associated with increased osmolality of the exocoelomic fluid, the major extraembryonic fluid compartment. It is possible that the osmotic change decreased neural tube volume by causing water to move to the compartment with a higher solute concentration, out of the embryo.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biochemical characterization of lysosomes in unfertilized eggs of Xenopus laevis.

Relations between lysosomes and yolk platelets of amphibian eggs have been suggested. This work demonstrates the presence of acid hydrolases in oocytes induced to ovulate in vitro. About 40% of the acid hydrolases are found in a sedimentable fraction, and, in accordance with the lysosomal concept, they display structural latency. Biochemical data did not indicate any association between lysosomal enzymes and yolk platelets. The mechanism of yolk resorption is discussed and it is suggested that the fusion of lysosomes and yolk platelets might be one of the mechanisms involved in yolk digestion.     

Biochemical characterization of lysosomes in unfertilized eggs of xenopus laevis

Relations between lysosomes and yolk platelets of amphibian eggs have been suggested. This work demonstrates the presence of acid hydrolases in oocytes induced to ovulate in vitro. About 40% of the acid hydrolases are found in a sedimentable fraction, and, in accordance with the lysosomal concept, they display structural latency. Biochemical data did not indicate any association between lysosomal enzymes and yolk platelets. The mechanism of yolk resorption is discussed and it is suggested that the fusion of lysosomes and yolk platelets might be one of the mechanisms involved in yolk digestion.     

Spatial and temporal ontogenies of glutathione peroxidase and glutathione disulfide reductase during development of the prenatal rat.

Spatial and temporal expression and regulation of the antioxidant enzymes, glutathione peroxidase (GSH-Px), glutathione disulfide reductase (GSSG-Rd) may be important in determining cell-specific susceptibility to embryotoxicants. Creation of tissue-specific ontogenies for antioxidant enzyme activities during development is an important first step in understanding regulatory relationships. Early organogenesis-stage embryos were grouped according to the somite number (GD 9-13), and fetuses were evaluated by gestational day (GD 14-21). GSH-Px activities in the visceral yolk sac (VYS) increased on consecutive days from GD 9 to GD 13, representing a 5.7-fold increase during this period of development. GSH-Px activities in VYS decreased after GD 13, ultimately constituting a 37% decrease at GD 21. Head, heart, and trunk specific activities generally increased from GD 9 to GD 13 albeit not to the same magnitude as detected in the VYS. GSSG-Rd activities showed substantial increases in the VYS from GD 9 to GD 13, 6.3-fold and decreased thereafter to 50% by GD 21. The greatest changes in enzyme activities were noted in the period between GD 10 and GD 11, where the embryo establishes an active cardiovascular system and begins to convert to aerobic metabolism. Generally, from GD 14-21, embryonic organ GSH-Px and GSSG-Rd activities either remained constant or increased as gestation progressed. These studies suggest the importance of the VYS in dealing with ROS and protecting the embryo. Furthermore, understanding the consequences of lower antioxidant activities during organogenesis may help to pinpoint periods of teratogenic susceptibility to xenobiotics and increased oxygen.     

Differential gene expression during early murine yolk sac development

The visceral yolk sac (VYS), composed of extraembryonic mesoderm and visceral endoderm, is the initial site of blood cell development and serves important nutritive and absorptive functions. In the mouse, the visceral endoderm becomes a morphologically distinct tissue at the time of implantation (E4.5), while the extraembryonic mesoderm arises during gastrulation (E6.5–8.5). To isolate genes differentially expressed in the developing yolk sac, polymerase chain reaction (PCR) methods were used to construct cDNA from late primitive streak to neural plate stage (E7.5) murine VYS mesoderm and VYS endoderm tissues. Differential screening led to the identification of six VYS mesoderm-enriched clones: ribosomal protein L13a, the heat shock proteins hsc 70 and hsp 86, guanine-nucleotide binding protein-related gene, cellular nucleic acid binding protein, and ã-enolase. One VYS endoderm-specific cDNA was identified as apolipoprotein C2. In situ hybridization studies confirmed the differential expression of these genes in E7.5 yolk sac tissues. These results indicate that representative cDNA populations can be obtained from small numbers of cells and that PCR methodologies permit the study of gene expression during early mammalian postimplantation development. While all of the mesoderm-enriched genes were ubiquitously expressed in the embryo proper, apolipoprotein C2 expression was confined to the visceral endoderm. These results are consistent with the hypothesis that at E7.5, the yolk sac endoderm provides differentiated liver-like functions, while the newly developing extraembryonic mesoderm is still a largely undifferentiated tissue. © 1995 wiley-Liss, Inc.     

Retinoic acid induction of stress proteins in fetal mouse limb buds

Retinoic acid (RA) is teratogenic in rodent embryos. Several teratogens have been shown to induce the synthesis of a subset of heat shock proteins (stress proteins) in Drosophila. To determine if RA induces the synthesis of these proteins in rodent embryos, pregnant ICR mice were dosed with 100 mg/kg RA on Day 11 of gestation. Forelimb buds were removed from embryos 2.5 hr post-RA-treatment and nuclei were isolated, stained, and sorted from stages of the cell cycle. Nuclear proteins were extracted and analyzed by two-dimensional polyacrylamide gel electrophoresis. Nuclear proteins with molecular weights of approximately 84 and 25 kDa were synthesized in embryos in the G0 + G1 phase after pregnant dams were treated with RA. Isoelectric points, molecular weights, immunochemical blotting, and polypeptide mapping demonstrated that these proteins are indistinguishable from stress proteins isolated under a variety of conditions from rat submaxillary glands and mouse lymphoma cells. These results suggest that treatment with RA induces the synthesis of a subset of stress proteins; the role of these proteins in the teratogenic effects of RA is not known.     

Radioactive labeling of proteins in cultured postimplantation mouse embryos I. Influence of the embryo preparation method

Summary Conditions for optimum incorporation of radioactive amino acids into proteins of cultured postimplantation mouse embryos were investigated under the aspect of using these proteins for two-dimensional electrophoretic separations followed by fluorography. The aim was to obtain highly radioactive proteins under conditions as physiological as possible. Embryos at Days 10, 11, and 12 of gestation were prepared in different ways and incubated for 4 h in Tyrode’s solution containing [³H]amino acids (mixture) at a concentration of 27 μCi/ml medium. The preparations were: a) yolk sac opened, placenta and blood circulation intact; (b) yolk sac and amnion opened, placenta and blood circulation intact (Day 10 embryos only); c) placenta, yolk sac, and amnion removed (embryo “naked”); d) naked embryos cut randomly into pieces (Day 10 mebryos only). After incubation whole embryos or certain parts (tail, liver, rest body) were investigated by determining the radioactivity taken up by the protein. The results are given in dpm per mg protein per embryo. Radioactivity of proteins was about 3 times higher in naked mebryos than in embryos left in their yolk sacs. This was true for all three stages investigated. However, the degree of radioactivity in the various parts of naked embryos differed by a factor of 15, whereas radioactivity was evenly distributed in embryos incubated in their yolk sacs. Therefore, embryos prepared according to the first methods (see above) fulfilled the conditions required at the best. This work was supported by grants from the Deutsche Forschungsgemeinschaft awarded to the project K1 237/3-2 (Systematic Analysis of Cell Proteins).     

The role of the visceral yolk sac in hyperglycemia-induced embryopathies in mouse embryos in vitro.

The adverse developmental effects of hyperglycemia to rodent embryos have been shown using whole embryo culture. Although, a mechanism by which hyperglycemia-induced effects occur is unknown, recent work has focused on the visceral yolk sac as a potential target tissue. Therefore, we have evaluated the developmental effects of hyperglycemia in early head fold stage mouse embryos in vitro and assessed the histiotrophic function of the visceral yolk sac. As has been previously shown in rodents, hyperglycemia produced neural tube closure defects in a concentration dependent manner at 33, 50, and 67 mM glucose using a 44 h exposure period. However, exposure times between 6 and 12 h were sufficient to alter embryonic development when the glucose concentration was 50 or 67 mM. In contrast, early somite stage embryos (4-6 somite stage) appear to be less sensitive to dysmorphogenesis and a 48 h exposure to 67 mM glucose but not 33 or 50 mM also produced neural tube defects. Hyperglycemia (67 mM) did not alter the uptake of 35S-methionine and 35S-cysteine-labeled hemoglobin (35S-Hb) in the visceral yolk sac (VYS) in early headfold staged embryos. However, the accumulation of 35S in the embryo was reduced by 16-18% at glucose concentrations of 50 or 67 mM during the last 12 h of a 44 h exposure period. No effect on VYS uptake or embryonic accumulation of 35S-labeled products was observed at shorter exposure periods (12-24 and 24-36 h).(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the mouse visceral yolk sac in nutrition: inhibition by a somatomedin inhibitor

A low molecular weight somatomedin inhibitory serum fraction (SI), obtained from streptozotocin-induced diabetic rats, causes morphological abnormalities and growth reduction in mouse embryos grown in whole embryo culture (WEC). These abnormalities are thought to be caused, at least in part, by a failure of the visceral yolk sac (VYS) to properly degrade proteins, a process that normally provides the conceptus with amino acids and peptides for de novo protein synthesis (histiotrophic nutrition). To test this hypothesis, embryos exposed to the SI were provided with a mixture of ten essential amino acids (supplemented group) in an attempt to circumvent SI-induced VYS dysfunction. Results showed that 82.4% (14/17) of embryos in the amino acid-supplemented group exhibited improved growth and development compared to those embryos exposed to medium containing the SI alone (unsupplemented group). Supplemented embryos showed greater expansion of the brain regions, improved visceral arch development, and increased protein content compared to nonsupplemented SI-treated embryos. However, these parameters were still reduced compared to controls. VYSs from both the unsupplemented and amino acid-supplemented groups were identical with respect to alterations in morphology and increased protein content compared to VYSs from conceptuses cultured in control medium (with or without amino acid supplementation). The improvement in embryonic growth and development due to amino acid supplementation in spite of VYS abnormalities supports the hypothesis that nutritional deprivation is one aspect of SI-induced teratogenesis.     

Sex difference in mouse embryonic development at neurulation

Sixty-seven mouse embryos from 10 litters collected on the morning of Day 9 of gestation, when neurulation is beginning, were classified according to the precise stage of development reached, and sex-chromatin analysis was performed on the yolk sac. Within litters, the least developed embryos were more likely to be female than male, while the most advanced embryos were predominantly male. Taking all embryos, the mean somite number was greater in males than females.