Retinoic acid induces changes in the localization of homeobox proteins in the antero-posterior axis of Xenopus laevis embryos.

We have studied the localization of the proteins of Xeb1 and Xeb2, two homeobox (hbx)-containing genes that are expressed during the early development of Xenopus laevis. Both proteins are expressed in juxtaposed and partially overlapping domains along the antero-posterior axis of Xenopus laevis embryos, with clearly defined anterior boundaries. Xeb2 is predominantly expressed in the caudal region of the hindbrain, whereas the Xeb1 protein is located in the most rostral region of the spinal cord. Furthermore, both proteins are expressed in single cells dispersed in the lateral flanks of the embryo in positions that correlate with the expression domains in the neural tube. We suggest that these cells are migratory neural crest cells that have acquired positional information in the neural tube prior to migration. The Xeb2 protein was also detected in the most posterior branchial arches and the pronephros. In stage 45 embryos, nuclei of the IX-X cranial ganglia, the lung buds and cells spreading into the forelimb rudiment express the Xeb2 antigen. The Xeb1 protein was also detected in the lung buds and the forelimb rudiment. To examine the effect of retinoic acid on expression, gastrula embryos were treated with all-trans retinoic acid (RA). Increasing concentrations of RA caused progressive truncation of anterior structures. The most severely affected embryos lacked eyes, nasal pits, forebrain, midbrain and otic vesicles, and the anterior boundary of the hindbrain seemed to be displaced rostrally. This alteration correlates with a progressive displacement of the anterior boundary of the expression domain of Xeb2. On the other hand, 10(-6) M RA induces an ectopic site of Xeb1 expression at the anterior end of the central nervous system, located just anterior to the extended domain of Xeb2 whereas expression in the spinal cord remains unaffected.     

The differing effects of occipital and trunk somites on neural development in the chick embryo

In all higher vertebrate embryos the sensory ganglia of the trunk develop adjacent to the neural tube, in the cranial halves of the somite-derived sclerotomes. It has been known for many years that ganglia do not develop in the most cranial (occipital) sclerotomes, caudal to the first somite. Here we have investigated whether this is due to craniocaudal variation in the neural tube or crest, or to an unusual property of the sclerotomes at occipital levels. Using the monoclonal antibody HNK-1 as a marker for neural crest cells in the chick embryo, we find that the crest does enter the cranial halves of the occipital sclerotomes. Furthermore, staining with zinc iodide/osmium tetroxide shows that some of these crest-derived cells sprout axons within these sclerotomes. By stage 23, however, no dorsal root ganglia are present within the five occipital sclerotomes, as assessed both by haematoxylin/eosin and zinc iodide/osmium tetroxide staining. Moreover, despite this loss of sensory cells, motor axons grow out in these segments, many of them later fasciculating to form the hypoglossal nerve. The sclerotomes remain visible until stages 27/28, when they dissociate to form the base of the skull and the atlas and axis vertebrae. After grafting occipital neural tube from quail donor embryos in place of trunk neural tube in host chick embryos, quail-derived ganglia do develop in the trunk sclerotomes. This shows that the failure of occipital ganglion development is not the result of some fixed local property of the neural crest or neural tube at occipital levels. We therefore suggest that in the chick embryo the cranial halves of the five occipital sclerotomes lack factors essential for normal sensory ganglion development, and that these factors are correspondingly present in all the more caudal sclerotomes.     

Consequences of somite manipulation on the pattern of dorsal root ganglion development

We have investigated dorsal root ganglion formation, in the avian embryo, as a function of the composition of the paraxial somitic mesoderm. Three or four contiguous young somites were unilaterally removed from chick embryos and replaced by multiple cranial or caudal half-somites from quail embryos. Migration of neural crest cells and formation of DRG were subsequently visualized both by the HNK-1 antibody and the Feulgen nuclear stain. At advanced migratory stages (as defined by Teillet et al. Devl Biol. 120, 329-347 1987), neural crest cells apposed to the dorsolateral faces of the neural tube were distributed in a continuous, nonsegmented pattern that was indistinguishable on unoperated sides and on sides into which either half of the somites had been grafted. In contrast, ventrolaterally, neural crest cells were distributed segmentally close to the neural tube and within the cranial part of each normal sclerotome, whereas they displayed a nonsegmental distribution when the graft involved multiple cranial half-somites or were virtually absent when multiple caudal half-somites had been implanted. In spite of the identical dorsal distribution of neural crest cells in all embryos, profound differences in the size and segmentation of DRG were observed during gangliogenesis (E4-9) according to the type of graft that had been performed. Thus when the implant consisted of compound cranial half-somites, giant, coalesced ganglia developed, encompassing the entire length of the graft. On the other hand, very small, dorsally located ganglia with irregular segmentation were seen at the level corresponding to the graft of multiple caudal half-somites. We conclude that normal morphogenesis of dorsal root ganglia depends upon the craniocaudal integrity of the somites.     

Isotretinoin teratogenicity in mouse whole embryo culture

Recent clinical observations strongly suggest that isotretinoin [13-cis-retinoic acid (cis RA)] is a human teratogen causing primarily heart and craniofacial malformations including ear and palatal defects. The purpose of the present study was to determine if cis RA could induce similar craniofacial malformations in mouse embryo culture. Day 8 CD-1 mouse embryos were cultured for 48 hours in rat serum in the presence or absence of various concentrations of cis RA dissolved in DMSO. DMSO by itself had no effect on embryonic development; however, cis RA at 2 X 10(-5) M (6 micrograms/ml) was clearly toxic. At 2 X 10(-6) M cis RA, growth retardation was minimal, and approximately one-third of the embryos exhibited very specific defects including a dramatic reduction in the size of the first and second visceral arches, which eventually give rise to the maxilla, mandible, and ear. Similar observations were also made with 4-oxo-13-cis RA, which is a major metabolite of cis RA in the mouse and human. These malformations would be expected to result in defects similar to those observed in the human, and preliminary observations suggest these defects are due to cis RA-induced inhibition of cranial neural crest cell migration. Using day-10 mouse embryos cultured for 48 hours in Waymouth's medium containing 50% fetal calf serum, we observed that cis RA at 2 X 10(-5) M produced a high percentage of embryos with limb defects and median cleft lip. Our results demonstrate that labeled cis RA enters the tissues of the embryo both in vivo and in vitro. Cis RA inhibited proliferation of the frontonasal mesenchyme cells in primary culture with 31% inhibition occurring at 2 X 10(-5) M cis RA.     

Neural Tube Closure in Mouse Whole Embryo Culture

Genetic mouse models are an important tool in the study of mammalian neural tube closure (Gray & Ross, 2009; Ross, 2010). However, the study of mouse embryos in utero is limited by our inability to directly pharmacologically manipulate the embryos in isolation from the effects of maternal metabolism on the reagent of interest. Whether using a small molecule, recombinant protein, or siRNA, delivery of these substances to the mother, through the diet or by injection will subject these unstable compounds to a variety of bodily defenses that could prevent them from reaching the embryo. Investigations in cultures of whole embryos can be used to separate maternal from intrinsic fetal effects on development.Here, we present a method for culturing mouse embryos using highly enriched media in a roller incubator apparatus that allows for normal neural tube closure after dissection (Crockett, 1990). Once in culture, embryos can be manipulated using conventional in vitro techniques that would not otherwise be possible if the embryos were still in utero. Embryo siblings can be collected at various time points to study different aspects of neurulation, occurring from E7-7.5 (neural plate formation, just prior to the initiation of neurulation) to E9.5-10 (at the conclusion of cranial fold and caudal neuropore closure, Kaufman, 1992). In this protocol, we demonstrate our method for dissecting embryos at timepoints that are optimal for the study of cranial neurulation. Embryos will be dissected at E8.5 (approx. 10-12 somities), after the initiation of neural tube closure but prior to embryo turning and cranial neural fold closure, and maintained in culture till E10 (26-28 somities), when cranial neurulation should be complete.     

Contributions of placodal and neural crest cells to avian cranial peripheral ganglia

The method of embryonic tissue transplantation was used to confirm the dual origin of avian cranial sensory ganglia, to map precise locations of the anlagen of these sensory neurons, and to identify placodal and neural crest-derived neurons within ganglia. Segments of neural crest or strips of presumptive placodal ectoderm were excised from chick embryos and replaced with homologous tissues from quail embryos, whose cells contain a heterochromatin marker. Placode-derived neurons associated with cranial nerves V, VII, IX, and X are located distal to crest-derived neurons. The generally larger, embryonic placodal neurons are found in the distal portions of both lobes of the trigeminal ganglion, and in the geniculate, petrosal and nodose ganglia. Crest-derived neurons are found in the proximal trigeminal ganglion and in the combined proximal ganglion of cranial nerves IX and X. Neurons in the vestibular and acoustic ganglia of cranial nerve VIII derive from placodal ectoderm with the exception of a few neural crest-derived neurons localized to regions within the vestibular ganglion. Schwann sheath cells and satellite cells associated with all these ganglia originate from neural crest. The ganglionic anlagen are arranged in cranial to caudal sequence from the level of the mesencephalon through the third somite. Presumptive placodal ectoderm for the VIIIth, the Vth, and the VIIth, IXth, and Xth ganglia are located in a medial to lateral fashion during early stages of development reflecting, respectively, the dorsolateral, intermediate, and epibranchial positions of these neurogenic placodes.     

Pathogenesis of methanol-induced craniofacial defects in C57BL/6J mice

BACKGROUND: Methanol administered to C57BL/6J mice during gastrulation causes severe craniofacial dysmorphology. We describe dysmorphogenesis, cell death, cell cycle assessment, and effects on development of cranial ganglia and nerves observed following administration of methanol to pregnant C57BL/6J mice on gestation day (GD) 7. METHODS: Mice were injected (i.p.) on GD 7 with 0, 2.3, 3.4, or 4.9 gm/kg methanol, split into two doses. In embryos of mice treated with 0 or 4.9 gm/kg methanol, we used histology and LysoTracker red staining on GD 8 0 hr through GD 8 18 hr to examine cell death and dysmorphogenesis, and we also evaluated cell-cycle distribution and proliferation using flow cytometry (FCM) and BrdU immunohistochemistry. On GD 10, we evaluated the effect of GD 7 exposure to 0, 2.3, 3.4, or 4.9 gm/kg methanol on cranial ganglia and nerve development using neurofilament immunohistochemistry. RESULTS: Methanol treatment on GD 7 resulted in reduced mesenchyme surrounding the fore- and midbrain, and in the first branchial arches, by GD 8 12 hr. There were disruptions in the forebrain neuroepithelium and optic pit. Neural crest cell emigration from the mid- and hindbrain region was reduced in methanol-exposed embryos. Methanol had no apparent effect on BrdU incorporation or cell-cycle distribution on GD 8. Cell death was observed in the hindbrain region along the path of neural crest migration and in the trigeminal ganglion on GD 8 18 hr. Development of the cranial ganglia and nerves was adversely affected by methanol. Development of ganglia V, VIII, and IX was decreased at all dosage levels; ganglion VII was reduced at 3.4 and 4.9 gm/kg, and ganglion X was reduced at 4.9 gm/kg. CONCLUSIONS: These results suggest that gastrulation-stage methanol exposure affects neural crest cells and the anterior mesoderm and neuroepithelium. Cell death was evident in areas of migrating neural crest cells, but only at time points after methanol was cleared from the embryo, suggesting an indirect effect on these cells. Birth Defects Research (Part A), 2004. Published 2004 Wiley-Liss, Inc.     

Vitamin A deficiency results in the dose-dependent acquisition of anterior character and shortening of the caudal hindbrain of the rat embryo

The developing nervous system is particularly vulnerable to vitamin A deficiency. Retinoid has been proposed to be a posteriorizing factor during hindbrain development, although direct evidence in the mammalian embryo is lacking. In the present study, pregnant vitamin A-deficient (VAD) rats were fed purified diets containing varying levels of all-trans-retinoic acid (atRA; 0, 0.5, 1.5, 6, 12, 25, 50, 125, or 250 microg/g diet) or were supplemented with retinol. Hindbrain development was studied from embryonic day 10 to 12.5 ( approximately 6 to 40 somites). Normal morphogenesis was observed in all embryos from groups fed 250 microg atRA/g diet or retinol. The most caudal region of the hindbrain was the most sensitive to retinoid insufficiency, as evidenced by a loss of the hypoglossal nerve (cranial nerve XII) in embryos from the 125 microg atRA/g diet group. Further reduction of atRA to 50 microg/g diet led to the loss of cranial nerves IX, X, XI, and XII and associated sensory ganglia IX and X in all embryos as well as the loss of hindbrain segmentation caudal to the rhombomere (r) 3/4 border in a subset of embryos. Dysmorphic orthotopic otic vesicles or immature otic-like vesicles in both orthotopic and caudally ectopic locations were also observed. As the level of atRA was reduced, a loss of caudal hindbrain segmentation was observed in all embryos and the incidence of otic vesicle abnormalities increased. Perturbations in hindbrain segmentation, cranial nerve formation, and otic vesicle development were associated with abnormal patterning of the posterior hindbrain. Embryos from VAD dams fed between 0.5 and 50 microg atRA/g diet exhibited Hoxb-1 protein expression along the entire neural tube caudal to the r3/r4 border at a time when it should be restricted to r4. Krox-20 protein expression was expanded in r3 but absent or reduced in presumptive r5. Hoxd-4 mRNA expression was absent in the posterior hindbrain, and the rostral limit of Hoxb-5 protein expression in the neural tube was anteriorized, suggesting that the most posterior hindbrain region (r7/r8) had been deleted and/or improperly patterned. Thus, when limiting amounts of atRA are provided to VAD dams, the caudal portion of the hindbrain is shortened and possesses r4/r5-like characteristics, with this region finally exhibiting r4-like gene expression when retinoid is restricted even more severely. Thus, regions of the anterior hindbrain (i.e., r3 and r4) appear to be greatly expanded, whereas the posterior hindbrain (r5-r8) is reduced or absent. This work shows that retinoid plays a critical role in patterning, segmentation, and neurogenesis of the caudal hindbrain and serves as an essential posteriorizing signal for this region of the central nervous system in the mammal.     

Retinoic acid synthesis and hindbrain patterning in the mouse embryo

Targeted disruption of the murine retinaldehyde dehydrogenase 2 (Raldh2) gene precludes embryonic retinoic acid (RA) synthesis, leading to midgestational lethality (Niederreither, K., Subbarayan, V., Dolle, P. and Chambon, P. (1999). Nature Genet. 21, 444-448). We describe here the effects of this RA deficiency on the development of the hindbrain and associated neural crest. Morphological segmentation is impaired throughout the hindbrain of Raldh2-/- embryos, but its caudal portion becomes preferentially reduced in size during development. Specification of the midbrain region and of the rostralmost rhombomeres is apparently normal in the absence of RA synthesis. In contrast, marked alterations are seen throughout the caudal hindbrain of mutant embryos. Instead of being expressed in two alternate rhombomeres (r3 and r5), Krox20 is expressed in a single broad domain, correlating with an abnormal expansion of the r2-r3 marker Meis2. Instead of forming a defined r4, Hoxb1- and Wnt8A-expressing cells are scattered throughout the caudal hindbrain, whereas r5/r8 markers such as kreisler or group 3/4 Hox genes are undetectable or markedly downregulated. Lack of alternate Eph receptor gene expression could explain the failure to establish rhombomere boundaries. Increased apoptosis and altered migratory pathways of the posterior rhombencephalic neural crest cells are associated with impaired branchial arch morphogenesis in mutant embryos. We conclude that RA produced by the embryo is required to generate posterior cell fates in the developing mouse hindbrain, its absence leading to an abnormal r3 (and, to a lesser extent, r4) identity of the caudal hindbrain cells.     

Retinoic acid metabolizing factor xCyp26c is specifically expressed in neuroectoderm and regulates anterior neural patterning in Xenopus laevis

Anterior-posterior neural patterning is determined during gastrulation when head structure is induced. Induction of anterior neural structures requires inhibition of Wnt signaling by several Wnt antagonists. We performed microarray analysis to isolate genes regulated by canonical Wnt signaling and abundantly expressed in the anterior neuroectoderm at the early neurula stage. We identified xCyp26c, a Cyp26 (RA-metabolizing protein)-family gene. In situ hybridization showed xCyp26c expression restricted to the anterior region of neurula, while xCyp26a was expressed in both anterior and posterior regions. At the tadpole stage, xCyp26c was also expressed in restricted sets of cranial nerves. Microarray, RT-PCR and in situ hybridization analyses revealed decreased xCyp26c expression with overexpression of beta-catenin, suggesting regulation by Wnt/beta-catenin signaling. We also assessed the effects of retinoic acid (RA) on xCyp26c expression. Embryos treated with 10(-7) M RA showed an anterior shift in the spatial expression of xCyp26c, reflecting a posteriorization effect. Conversely, expression patterns in embryos treated with more than 10(-6) M RA were less affected and remained restricted to the most anterior region. Moreover, injection of xCyp26c mRNA into animal poles caused head defects, and exogenous expression of xCyp26c rescued the posteriorizing effect of RA treatment. Taken together, these results implicated a role for xCyp26c in anterior patterning via RA signaling.     

Thyroid hormone and retinoic acid interact to regulate zebrafish craniofacial neural crest development

Craniofacial and ocular morphogenesis require proper regulation of cranial neural crest migration, proliferation, survival and differentiation. Although alterations in maternal thyroid hormone (TH) are associated with congenital craniofacial anomalies, the role of TH on the neural crest has not been previously described. Using zebrafish, we demonstrate that pharmacologic and genetic alterations in TH signaling disrupt cranial neural crest migration, proliferation, and survival, leading to craniofacial, extraocular muscle, and ocular developmental abnormalities. In the rostral cranial neural crest that gives rise to the periocular mesenchyme and the frontonasal process, retinoic acid (RA) rescued migratory defects induced by decreased TH signaling. In the caudal cranial neural crest, TH and RA had reciprocal effects on anterior and posterior pharyngeal arch development. The interactions between TH and RA signaling were partially mediated by the retinoid X receptor. We conclude that TH regulates both rostral and caudal cranial neural crest. Further, coordinated interactions of TH and RA are required for proper craniofacial and ocular development.     

Quantitative aspects of the cell cycle in the cranial neural tube of the rhesus monkey (Macaca mulatta) during early stages of gestation

The generation time of ventricular cells in the cranial neural tube of the rhesus monkey embryo was estimated by means of tritiated thymidine autoradiography at stages 12, 13, and 14 (25-31 d of gestation) relative to that which occurs in the mouse at corresponding stages of development. In the rhesus monkey embryo, the generation time lengthens between stages 12 and 13 of gestation, as is the case in the mouse at comparable stages. However, the generation time in rhesus monkey embryos at stage 13 appears to be longer than that in comparable mouse embryos at 10 days of gestation. Thus, it is possible that temporal differences may occur between the rhesus monkey embryo and mouse embryo in terms of the response of the cranial neuroepithelium to teratogenic insults involving the cell cycle.     

Variation in development of rat embryos at the presomite period.

Rat embryos at a single gestational time in the presomite period were studied for their variation in development and their fate after culture. They were explanted at 8 A.M. on day 9 of gestation from timed-pregnant Sprague-Dawley rats which were obtained by mating between 8 and 10 A.M. (plug day = day 0). In the first experiment, a total of 203 embryos from 20 litters were examined for their variation in development. Several dimensions of embryo/egg cylinder were measured and development of various embryonic/extraembryonic structures were assessed using a scoring system that we developed for the present study. Embryos were then divided into different stages of development based on their scores using the staging system that we developed previously. A large variation in developmental stage was demonstrated; the youngest embryo was at the early primitive streak stage with no signs of amniotic folds and the oldest one was at the late neural plate stage with a foregut pocket but without visible somites. No strong correlation was demonstrated between developmental stage and size of embryo/egg cylinder, nor between developmental stage and development of the proamniotic tube, ectoplacental cavity, or allantois. In the second experiment, embryos were explanted at the same time and those at different stages were cultured separately in rotating bottles and their outcomes were compared after 49 hours. The difference in mean somites number of embryos cultured from the mid primitive streak and late neural plate stages was 6.1. This difference corresponds to approximately 10 hours based on the known linear increase of somites number on day 11 of approximately 0.6 somites per hour. These results indicate a large variation in development of presomite period embryos supposedly of the same gestational age and suggest the importance of careful staging at the time of explantation if precision is needed for whole embryo culture experiments.     

Temporospatial patterns of apoptosis in chick embryos during the morphogenetic period of development

We examined the temporospatial pattern of naturally occurring apoptosis in chick embryos to five days of incubation (H.H. stages 1-25; Hamburger and Hamilton, 1951) using TUNEL labeling. The initial TUNEL-positive structure was the embryonic shield at stage 1. Apoptotic cells became ubiquitously present within embryos by stage 3, which is early in gastrulation. Until stage 6, TUNEL-positive cells were restricted to the headfold region. In embryos of stages 7-8, most cell death was localized at the most anterior neural plate. TUNEL-positive neural plate, notochord and somites appeared at stage 9. Otic and optic regions became TUNEL-positive at stage 11. The aggregation of cells from which the tail bud arises contains apoptotic cells from stage 11 onwards. At stage 16, scattered TUNEL-positive cells appeared in the branchial arches. Three streams of apoptotic neural crest cells in the cranial region became most clearly visible at stage 18. The secondary neural tube from which caudal structures develop contains apoptotic cells at stage 14. Apoptotic cells are present in the branchial arches and lateral body wall for extended periods, stages 16-25 and 25 respectively. At stages 24-25, intense positive regions of cell death were confined to the caudal regions of the arches, to limb and tail buds and to the lateral body wall, the latter in relation to body wall closure. The new findings in this study are discussed along with past studies to provide the temporospatial pattern of cell death during early chick development.     

Morphological differences elicited by two weak acids, retinoic and valproic, in rat embryos grown in vitro

We compared in rat whole-embryo culture the morphological changes elicited by valproic acid (VPA) with those elicited by trans-retinoic acid (RA). Rat embryos explanted on day 9.5 of gestation were treated on day 10 with RA or VPA at concentrations producing equivalent reductions in embryonic protein. The concentrations selected for morphological assessment by scanning and transmission electron microscopy, 2.3 and 800 microM, respectively, for RA and VPA, produced approximately a 50% incidence of abnormally open anterior neuropores in initial range-finding experiments in the culture system. Protein and DNA analyses were also performed on corresponding groups of embryos at three different doses. With concurrent control groups used as reference standards, the two treatment groups were compared for differences in external and internal morphology, protein and DNA contents, and growth indices. While certain variables responded similarly in the two treatment groups, e.g., the growth variables, protein and DNA contents, each drug produced selective morphological effects. Whereas treatment with RA produced underdeveloped branchial arches, symmetrically cleft cranial defects resulting in openings in rhombencephalic and prosencephalic regions, and exteriorized neural tissue in the caudal neuropore region, VPA produced irregular clefts with wavy margins along the entire length of the neural tube, and an open caudal neuropore without eversion of the neuroepithelium, while producing no detectable effect on the branchial arches. The similar effects of these two drugs on protein and DNA contents suggest comparable degrees of overall toxicity; however, the dissimilar effects on neural tube and branchial arches, coupled with the large difference in concentration of the drug required to produce the effects, add to the evidence that their mechanisms for elicitation of abnormal development are qualitatively different.     

Requirement of a neural tube signal for the differentiation of neural crest cells into dorsal root ganglia

The influence of the neural tube on early development of neural crest cells into sensory ganglia was studied in the chick embryo. Silastic membranes were implanted between the neural tube and the somites in 30-somite-stage embryos at the level of somites 21-24, thus separating the early migrated population of neural crest cells from the neural tube. Neural crest cells and peripheral ganglia were visualized by immunofluorescence using the HNK-1 monoclonal antibody and several histochemical techniques. Separation of crest cells from the neural tube caused the selective death of the neural crest cells from which dorsal root ganglia (DRG) would have developed. Complete disappearance of HNK-1 positive cells was evident already 10 hr after silastic implantation, before early differentiation sensory neurons could have reached their peripheral targets. In older embryos, DRG were absent at the level of implantation. In contrast, the development of ventral roots, sympathetic ganglia and adrenal gland was normal, and so was somitic differentiation into cartilage and muscle, while morphogenesis of the vertebrae was perturbed. To overcome the experimentally induced crest cell death, the silastic membranes were impregnated with a 3-day-old embryonic chick neural tube extract. Under these conditions, crest cells which were separated from the tube survived for a period of 30 hr after operation, compared to less than 10 hr in respective controls. The extract of another tissue, the liver, did not protract survival of DRG progenitor cells. Among the cells which survived with neural tube extract, some even succeeded in extending neurites; nevertheless, in absence of normal connections with the central nervous system (CNS) they finally died. Treatment of silastic implanted embryos with nerve growth factor (NGF) did not prevent the experimentally induced crest cell death. These results demonstrate that DRG develop from a population of neural crest cells which depends for its survival and probably for its differentiation upon a signal arising from the CNS, needed as early as the first hours after initiation of migration. Recovery experiments suggest that the subpopulation of crest cells which will develop along the sensory pathway probably depends for its survival and/or differentiation upon a factor contained in the neural tube, which is different from NGF.     

Mediobasal prosencephalic defects, including holoprosencephaly and cyclopia, in relation to the development of the human forebrain

Four very early synophthalmic embryos were studied in serial sections and reconstructed graphically by the point-plotting method. Three belonged to stage 16 (5 weeks) and one to stages 19/20 (7 weeks). Recently completed accounts and reconstructions of the normal brains of staged human embryos served as controls for comparison with the abnormal examples. The embryos shared in common: holoprosencephaly, arhinencephaly sensu stricto (absence of olfactory nerve fibers, bulbs, and tracts), presence of a proboscis, synophthalmia with two lens vesicles, a retarded telencephalic wall, absence of the mediobasal part of the telencephalon (the future septal area and the commissural plate: future anterior commissure and corpus callosum), irregularity of the diencephalon, mensural changes in the brain, absence of the rostral part of the notochord and consequent cranial defects, and small ganglia of the cranial nerves. Where it could be determined (at least in the three less advanced specimens), the adenohypophysial primordium was either small and isolated or was absent; a tentorial condensation appeared to be missing; and disturbances of the primordia of the orbital muscles and their innervation were noted. The corpus striatum is single and corresponds to only the diencephalic part (medial eminence) of normal embryos. Interference with induction by the prechordal plate at or before stage 8 (18 days) would be expected to affect the future mediobasal part of the neural plate (median prosencephalic dysgenesis) and the future optic primordium (cyclopia sensu stricto). Insufficient formation of material from the prechordal plate would account for disorders of the orbital musculature and, possibly, for inadequacy of the tentorium cerebelli. Disturbance a couple of days later (stage 9) would result in synophthalmia. Cyclopia and synophthalmia entail arhinencephaly and holoprosencephaly, both of which may arise independently. Defective distribution of the cephalic mesenchyme points to a derangement of the mesencephalic neural crest (stages 10 and 11), causing such features as an incomplete chondrocranium and reduction in size of the ganglia of the cranial nerves. Failure of bilateral division of the telencephalon would occur at or before 4 weeks (stages 13 and 14). It is concluded that all the above conditions arise during the first 4 postovulatory weeks.     

Direct effects of retinoic acid on the development of the tail bud in chick embryos

Retinoic acid (RA) has been reported to induce vascular lesions and haematoma formation in the vicinity of the tail bud during the critical period for inducing abnormalities of tail bud development in hamsters (Wiley, '83; Tibbles and Wiley, '88), mice (Tibbles and Wiley, '88) and chicken embryos (Jelinek and Kistler, '81). Experiments were conducted to determine whether or not these vascular lesions were the primary cause of the malformations which they accompanied. Chick embryos were exposed for varying lengths of time to several dosages of RA. Primitive streaks or tail buds from treated embryos were then excised prior to vascularization and transplanted to the coelomic walls of untreated host embryos. The grafts were harvested at 3 or 6 days after grafting and processed for histological examination. Observations of serial sections of controls showed that the primitive streak and early (stage 13-14) tail bud were able to form neural tubes and a variety of other structures including ganglia, nerve fibres, and kidney tubules. Treatment of donor embryos with RA prior to grafting, however, affected the frequency and characteristics of the neural tubes and other tissues developing in the grafts. The effects of RA on development were correlated with both the dosage and length of exposure to the teratogen prior to grafting. Since the grafts were made before the appearance of blood vessels in the tail buds, we have concluded that the effects of RA on the development of tail bud tissues, and especially the secondary neural tube, are direct and are not mediated solely through the disruptive effects of vascular lesions seen in intact embryos.     

Retinoic acid inhibits migration of cranial neural crest cells in the cultured mouse embryo

Clinical observations have demonstrated that isotretinoin (13-cis-retinoic acid; cis-RA) is a human teratogen causing primarily heart and craniofacial malformations. Isotretinoin exposure to the early postimplantation mouse embryo in culture results in specific defects in craniofacial development that may be due to an interference in the early migration of cranial neural crest (CNC) cells [Goulding and Pratt, 1986]. The present study was designed to test this hypothesis by examining the migration of these cells in whole embryo culture. Day 8 CD-1 mouse embryos were cultured for 6-48 hr in the presence or absence of cis-RA at 2 X 10(-6) to 2 X 10(-5) M. Embryos either were fixed for light microscopy using Nichols' method for localization of CNC cells or were processed for scanning and transmission electron microscopy. At the light microscopic level, CNC cells in the mid-brain region of control embryos had migrated to the region of the first and second visceral arches after 6 hr in culture. Cis-RA interfered with this migration; CNC cells in treated embryos either did not leave the neuroepithelium (NE) or were aggregated near the NE. Autoradiographic studies indicated that cis-RA did not affect the overall viability or DNA synthesis of the CNC cells. However, at the TEM level, there was a dramatic increase in the number of cellular blebs in the CNC cells. Our results demonstrate a direct effect of 13-cis-RA on the CNC cells and suggest that this effect is due to alterations in the cell surface.     

The effect of the suspensor and gibberellic acid on Phaseolus vulgaris embryo protein content

The role of the suspensor in the early development of the dicot embryo has not yet been defined. It has been described as merely an anchor and also as the major route of nutrients into the embryo. In order to further elucidate the role of the suspensor, early 0.2-mm and late heart stage 0.5-mm Phaseolus vulgaris (var. Taylor's Horticultural) embryos have been examined in tissue culture. It is known that Phaseolus embryos in culture at low osmotic potential will germinate precociously and that embryos in culture at high osmotic potential will either fail to grow or form callus. Optimum sucrose concentrations for continued, normal embryonic development of 0.2 mm and 0.5 mm P. vulgaris in tissue culture with Gamborg B5 medium were determined to be 12 and 6%, respectively. Protein content was examined in embryos and suspensors. Results showed that both 0.2- and 0.5-mm embryos required an attached suspensor for maximum protein content. Protein levels were substantially decreased when the embryo was cultured detached from or without the suspensor. Gibberellic acid at 10(-6) to 10(-7) M restored the protein content to that of freshly excised embryos.