Observations on closure of the neuropores in the chick embryo.

Neuropore closure was studied in chick embryos by light and electron microscopy. Surface ectoderm reflects over the crests of the neural folds at all craniocaudal levels, merging with the neural ectoderm lining the neural groove. Apices of surface ectodermal cells have an essentially identical morphology prior to approximation of folds, both within the presumptive fusion sites and more laterally. Cells of these areas have slightly convex profiles exhibiting few cellular protrusions. Each neural fold contains a superficial half, composed of neural ectoderm covered by surface ectoderm, and a deep half consisting entirely of neural ectoderm. Initial contact between folds usually occurs near the junction between these halves in cranial regions, but is restricted primarily to surface ectoderm at caudal levels. Subsequent fusion of folds at all levels involves both ectodermal layers. Cellular protrusions and small, morphologically unspecialized intercellular junctions often interconnect cells of apposed folds in areas undergoing fusion. The anterior neuropore closes at stages 10-11, but fusion of folds in this region is not completed until stages 13-14. Fusion occurs dorsoventrally in this area and is more advanced internally than externally. Numerous pleomorphic inclusions and a few apparently necrotic cells are present in areas bordering the anterior neuropore. The posterior neuropore closes at stages 12-13 and fusion is completed in this region during stages 13-14. The caudal end of the posterior neuropore closes dorsal to the developing tail bud. Several morphological features of this closure may at least partially account for the high susceptibility to myeloschisis localized specifically at caudal spinal cord levels.     

A critical period for conversion of ectodermal cells to a neural crest fate

Previously, we found that interactions between neural and nonneural ectoderm can generate neural crest cells, with both the ectodermal and the neuroepithelial cells contributing to induced population (M. A. J. Selleck and M. Bronner-Fraser, 1995, Development 121, 525-538). To further characterize the ability of ectodermal cells to form neural crest, we have challenged their normal fate by transplanting them into the neural tube. To ensure that the ectoderm was from nonneural regions, we utilized extraembryonic ectoderm (the proamnion) and transplanted it into the presumptive midbrain of 1. 5-day-old chick embryos. We observed that the grafted ectoderm has the capacity to adopt a neural crest fate, responding within a few hours of surgery by turning on neural crest markers HNK-1 and Slug. However, the competence of the ectoderm to respond to neural crest-inducing signals is time limited, declining rapidly in donors older than the 10-somite stage. Similarly, the inductive capacity of the host midbrain declines in a time-dependent fashion. Our results show that extraembryonic ectoderm has the capacity to form neural crest cells given proper inducing signals, expressing both morphological and molecular markers characteristic of neural crest cells.     

The neural crest and neural crest cells: discovery and significance for theories of embryonic organization

The neural crest has long fascinated developmental biologists, and, increasingly over the past decades, evolutionary and evolutionary developmental biologists. The neural crest is the name given to the fold of ectoderm at the junction between neural and epidermal ectoderm in neurula-stage vertebrate embryos. In this sense, the neural crest is a morphological term akin to head fold or limb bud. This region of the dorsal neural tube consists of neural crest cells, a special population(s) of cell, that give rise to an astonishing number of cell types and to an equally astonishing number of tissues and organs. Neural crest cell contributions may be direct — providing cells — or indirect — providing a necessary, often inductive, environment in which other cells develop. The enormous range of cell types produced provides an important source of evidence of the neural crest as a germ layer, bringing the number of germ layers to four — ectoderm, endoderm, mesoderm, and neural crest. In this paper I provide a brief overview of the major phases of investigation into the neural crest and the major players involved, discuss how the origin of the neural crest relates to the origin of the nervous system in vertebrate embryos, discuss the impact on the germ-layer theory of the discovery of the neural crest and of secondary neurulation, and present evidence of the neural crest as the fourth germ layer. A companion paper (Hall, Evol. Biol. 2008) deals with the evolutionary origins of the neural crest and neural crest cells.     

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.     

Distribution of fibronectin in the early phase of avian cephalic neural crest cell migration

Immunofluorescence and immunoperoxidase labeling for fibronectin was used to study the early events of cephalic neural crest cell migration in avian embryos. Prior to crest cell appearance, fibronectin was associated with the basement membranes of all tissues. The loose mesenchymal cells were also surrounded by this glycoprotein. The crest cell individualization phase included a transient rounding up and a rapid increase in cell number in a very limited space. Whereas the neural tube basement membrane was not formed dorsally at the site of emergence of crest cells, it was partially fused laterally with the ectoderm basement membrane apparently preventing immediate crest cell emigration. Further increase in cell number occurred concomitantly with their penetration between the two developing basement membranes of the neural tube and the ectoderm. The localization of migrating crest cells is apparently greatly influenced by local interactions between the ectoderm and the neural tube, whose morphogenesis differs considerably at each axial level: at the mesencephalic-rhombencephalic levels, crest cells rapidly reached a cell-free space that was mostly devoid of fibronectin. Further migration occurred laterally in that space while pioneer crest cells became surrounded by fibronectin in their environment. Crest cells progressed as a confluent multicellular layer with an apparent velocity of 70 μm/hr. At the prosencephalic and median rhombencephalic levels, crest cells accumulated between the fibronectin-rich basement membranes of the ectoderm and the neural tube. Pioneer crest cells were arrested at the site of attachment of the ectoderm and the neural tube basement membranes (i.e., optic vesicles and otic placodes). Crest cells resumed their migration when more space became available during the constriction of the optic vesicles and the invagination of the otic placodes.     

Neural plate morphogenesis and axial stretching in “notochord-defective” Xenopus laevis embryos

The morphogenetic movements of neural ectoderm cells associated with neural plate development and neural fold fusion were examined in notochord-defective embryos. Those movements were apparently normal in embryos which displayed a notochord reduced in size or which completely lacked a notochord. Likewise, axial stretching in the anterior-posterior direction was also normal in “notochord-defective” embryos. A role for the anuran notochord in directing neural fold fusion and axial stretching can, therefore, be ruled out.     

Rohon-Beard sensory neurons are induced by BMP4 expressing non-neural ectoderm in Xenopus laevis

Rohon-Beard mechanosensory neurons (RBs), neural crest cells, and neurogenic placodes arise at the border of the neural- and non-neural ectoderm during anamniote vertebrate development. Neural crest cells require BMP expressing non-neural ectoderm for their induction. To determine if epidermal ectoderm-derived BMP signaling is also involved in the induction of RB sensory neurons, the medial region of the neural plate from donor Xenopus laevis embryos was transplanted into the non-neural ventral ectoderm of host embryos at the same developmental stage. The neural plate border and RBs were induced at the transplant sites, as shown by expression of Xblimp1, and XHox11L2 and XN-tubulin, respectively. Transplantation studies between pigmented donors and albino hosts showed that neurons are induced both in donor neural and host epidermal tissue. Because an intermediate level of BMP4 signaling is required to induce neural plate border fates, we directly tested BMP4′s ability to induce RBs; beads soaked in either 1 or 10 ng/ml were able to induce RBs in cultured neural plate tissue. Conversely, RBs fail to form when neural plate tissue from embryos with decreased BMP activity, either from injection of noggin or a dominant negative BMP receptor, was transplanted into the non-neural ectoderm of un-manipulated hosts. We conclude that contact between neural and non-neural ectoderm is capable of inducing RBs, that BMP4 can induce RB markers, and that BMP activity is required for induction of ectopic RB sensory neurons.     

Melanotropin as a Potential Regulator of Pigment Pattern Formation in Embryonic Skin

Frozen tissue sections of developing axolotl embryos were labeled by indirect immunofluorescence with anti-alpha-MSH. Anti-MSH immunoreactivity is first detectable in embryos when neural crest cells are migrating from the neural tube. Antibody labeling is visible around the lateral and ventral edges of the neural tube and in the embryonic ectoderm. As development progresses, the amount of labeling increases greatly, particularly in developing ectoderm. Western blots of soluble proteins extracted from various developmental stages of axolotl embryo ectoderm reveal that MSH activity is associated directly with several high molecular weight components that may be part of the embryonic extracellular matrix. Thus, we suggest that melanotropin activity is present in embryonic axolotl skin, is associated with the extracellular matrix, and is thereby in a position to play a supportive and/or directive role in the establishment of embryonic pigment patterns.     

Hensen's node induces neural tissue in Xenopus ectoderm. Implications for the action of the organizer in neural induction.

The development of the vertebrate nervous system is initiated in amphibia by inductive interactions between ectoderm and a region of the embryo called the organizer. The organizer tissue in the dorsal lip of the blastopore of Xenopus and Hensen's node in chick embryos have similar neural inducing properties when transplanted into ectopic sites in their respective embryos. To begin to determine the nature of the inducing signals of the organizer and whether they are conserved across species we have examined the ability of Hensen's node to induce neural tissue in Xenopus ectoderm. We show that Hensen's node induces large amounts of neural tissue in Xenopus ectoderm. Neural induction proceeds in the absence of mesodermal differentiation and is accompanied by tissue movements which may reflect notoplate induction. The competence of the ectoderm to respond to Hensen's node extends much later in development than that to activin-A or to induction by vegetal cells, and parallels the extended competence to neural induction by axial mesoderm. The actions of activin-A and Hensen's node are further distinguished by their effects on lithium-treated ectoderm. These results suggest that neural induction can occur efficiently in response to inducing signals from organizer tissue arrested at a stage prior to gastrulation, and that such early interactions in the blastula may be an important component of neural induction in vertebrate embryos.     

Homoiogenetic Neural Induction in Xenopus Chimeric Explants

We previously raised monoclonal antibodies specific for epidermis (7) and neural tissue (8) of Xenopus for use as markers of tissue differentiation in induction experiments (8). Here we have used these monoclonal antibodies to examine homoiogenetic neural induction, by which cells induced to differentiate to neural tissues can in turn induce competent ectoderm to do the same. Presumptive anterior neural plate excised from late gastrulae of Xenopus laevis was conjugated with competent ectoderm from the initial gastrula of Xenopus borealis , either side by side or with their inner surfaces together. The chimeric explants enabled us to distinguish induced neural tissues from inducing neural tissues. In both types of explant, neural tissues identified by the neural tissue-specific antibody, NEU-1, were induced in the competent ectoderm by the presumptive anterior neural plate. The results suggest that homoiogenetic neural induction does occur in Xenopus embryos.     

Mesoderm and Neural Inductions on Newt Ectoderm by Activin A

Mesoderm-inducing activity of human recombinant activin A was examined on presumptive ectoderm of the Japanese newt, Cynops pyrrhogaster , by using the animal cap assay, Activin A induced neural tissues and mesodermal tissues such as brain, neural tube, notochord, muscle, mesenchyme, coelomic epithelium and blood-like cells after 14 days cultivation. These tissues were induced by activin A at concentrations ranging from 0.5– 100 ng/ml. Dose-dependent inducing activity of activity A on newt ectoderm was slightly different from that on other animals, including Xenopus . Wide range of concentration of activin A (0.5– 100 ng/ml) could induce the neural tube, notochord, mesenchyme and coelomic epithelium on the newt ectoderm. Though the percentage of induced explants (two out of 23 explants, 8.7%) was low, the pulsating heart was induced. This paper showed first that activin could induce the mesodermal and neural tissues in newt presumptive ectoderm. Since activin homologues were present In Xenopus and chick embryos, it is likely that activin may be one of the natural inducers in a wide range of species.     

Calcium transients triggered by planar signals induce the expression of ZIC3 gene during neural induction in Xenopus

In intact Xenopus embryos, an increase in intracellular Ca(2+) in the dorsal ectoderm is both necessary and sufficient to commit the ectoderm to a neural fate. However, the relationship between this Ca(2+) increase and the expression of early neural genes is as yet unknown. In intact embryos, studying the interaction between Ca(2+) signaling and gene expression during neural induction is complicated by the fact that the dorsal ectoderm receives both planar and vertical signals from the mesoderm. The experimental system may be simplified by using Keller open-face explants where vertical signals are eliminated, thus allowing the interaction between planar signals, Ca(2+) transients, and neural induction to be explored. We have imaged Ca(2+) dynamics during neural induction in open-face explants by using aequorin. Planar signals generated by the mesoderm induced localized Ca(2+) transients in groups of cells in the ectoderm. These transients resulted from the activation of L-type Ca(2+) channels. The accumulated Ca(2+) pattern correlated with the expression of the early neural precursor gene, Zic3. When the transients were blocked with pharmacological agents, the level of Zic3 expression was dramatically reduced. These data indicate that, in open-face explants, planar signals reproduce Ca(2+) -signaling patterns similar to those observed in the dorsal ectoderm of intact embryos and that the accumulated effect of the localized Ca(2+) transients over time may play a role in controlling the expression pattern of Zic3.     

A re-examination of lens induction in chicken embryos: in vitro studies of early tissue interactions

Early studies on lens induction suggested that the optic vesicle, the precursor of the retina, was the primary inducer of the lens; however, more recent experiments with amphibians establish an important role for earlier inductive interactions between anterior neural plate and adjacent presumptive lens ectoderm in lens formation. We report here experiments assessing key inductive interactions in chicken embryos to see if features of amphibian systems are conserved in birds. We first examined the issue of specification of head ectoderm for a lens fate. A large region of head ectoderm, in addition to the presumptive lens ectoderm, is specified for a lens fate before the time of neural tube closure, well before the optic vesicle first contacts the presumptive lens ectoderm. This positive lens response was observed in cultures grown in a wide range of culture media. We also tested whether the optic vesicle can induce lenses in recombinant cultures with ectoderm and find that, at least with the ectodermal tissues we examined, it generally cannot induce a lens response. Finally, we addressed how lens potential is suppressed in non-lens head ectoderm and show an inhibitory role for head mesenchyme. This mesenchyme is infiltrated by neural crest cells in most regions of the head. Taken together, these results suggest that, as in amphibians, the optic vesicle cannot be solely responsible for lens induction in chicken embryos; other tissue interactions must send early signals required for lens specification, while inhibitory interactions from mesenchyme suppress lens-forming ability outside of the lens area.     

The effects of N-cadherin misexpression on morphogenesis in Xenopus embryos

N-cadherin is a calcium-dependent, cell adhesion molecule that has been proposed to play a role in morphogenesis in vertebrate embryos. Throughout early neural development, N-cadherin is expressed during the morphogenetic changes that occur when ectoderm, in response to neural induction, forms a neural plate and tube. To study the role of N-cadherin in these processes, cDNA clones encoding Xenopus laevis N-cadherin were isolated and used to study the expression of N-cadherin in frog embryos. These studies showed that N-cadherin RNA is not expressed at detectable levels in early cleavage embryos or in isolated ectoderm in the absence of neural induction. However, N-cadherin RNA rapidly appeared in ectoderm exposed to a heterologous neural inducer, indicating that N-cadherin expression, as an early response to induction, precedes the morphogenetic events associated with early neural development. The role of N-cadherin in these morphogenetic events was studied by ectopically expressing N-cadherin in the ectoderm of embryos prior to induction. The ectopic expression of this protein in ectoderm led to the formation of cell boundaries and to severe morphological defects. These results are consistent with the hypothesis that the morphogenetic changes associated with early neural development are controlled, in part, by the induced expression of N-cadherin in the neural plate.     

DIFFERENTIATION OF PARTIALLY MESODERMALIZED ECTODERM; HOMOIOGENETIC AND HETEROGENETIC INDUCTION BY PRIMARILY INDUCED PART OF THE ECTODERM

Using embryos of the Japanese newt, Cynops pyrrhogaster , homoiogenetic and heterogenetic induction were investigated in the partially mesodermaelzed presumptive ectoderm. Half of the isolated presumptive ectoderm was placed in contact with the swimbladder of the crucian carp, Carasius auratus , for 15 or 60 min, while the other half was stained with Nile blue sulfate at the same time. The distribution of the stained cells in the tissues evoked in the explants was examined after cultivation for 10 days.
Some mesodermal tissues were composed of both stained and unstained cells. This indicates homoiogenetic induction by the primarily induced part of the ectoderm on the other half. The neural and epidermal tissues in the explants were composed of stained cells only, except in one case. We conclude that the neural tissues are derived from cells not placed in contact with the swimbladder and that they are induced by the primarily induced part of the ectoderm.     

Comparison of DNA and RNA synthesis in dorsal and ventral frog embryo ectoderm during gastrulation

Summary A comparison of the rates of DNA and RNA synthesis of the dorsal gastrula ectoderm being induced to form neural tissue with the uninduced ventral ectoderm has been made for developing embryos ofRana pipiens. There was a higher rate of DNA synthesis per cell in the dorsal ectoderm, but the rates of RNA synthesis per cell in the induced and uninduced ectoderm were similar. The rate of RNA synthesis based on an equivalent amount of total protein was greater for the induced than for the unindueed ectoderm. This is ascribed to the presence of more cells in the induced ectoderm and this is substantiated by the higher DNA/protein ratio for the induced than for the uninduced ectoderm.This research was supported by grants from the National Institutes of Health (GM 16236-03) and the National Science Foundation (GB 8029).     

Gravitational effects on apoptosis of presumptive ectodermal cells of amphibian embryo

The effects of simulated microgravity (clinostat rotation at 6 rpm) on the presumptive ectodermal cells of amphibian embryos were examined. When morulae of Cynops pyrrhogaster developed under the influence of simulated microgravity, the thickness of the presumptive ectoderm was greater significantly. Embryonic cells isolated from the presumptive ectoderm of morulae were cultured for one day under the influence of simulated microgravity. The number of cells was greater after such clinostat rotation than in the control culture. TUNEL staining and electron microscopy revealed apoptotic cells both in embryos and among cultured cells, but the number of apoptotic cells was smaller in clinostat-treated embryos and cultured cells than in their controls. These results suggest that simulated microgravity suppresses apoptosis in the amphibian embryo, and as a result, affects the thickness of the presumptive ectoderm.     

Cell differentiation of the head ectoderm in mouse embryos in vitro

Cell differentiation has been studied in the explants of head ectoderm of 8, 9 and 10 day old mouse (CBA) embryos and of head epidermis of 13 day old embryos. Pieces of ectoderm were taken from the temporal region. It was established by indirect immunofluorescence that within 10, 15 and 20 days of cultivation spheroids with keratins or crystallins in some groups of fibres formed in the head ectoderm explants from 9 and 10 day old embryos. When cultivating the regions of head epidermis from 13 day old embryos, spheroids formed with keratin only in their cells. The data obtained suggest that there appear to be two clones of cells determined to the synthesis of keratins or crystallins in the head ectoderm of early mouse embryos. During embryogenesis, the number of cells determined to the synthesis of keratins appears to increase in the regions not related to the eye area. At the same time, the clone of cells determined to the synthesis of crystallins appears to be eliminated.     

Conditional BMP inhibition in Xenopus reveals stage-specific roles for BMPs in neural and neural crest induction

Bone morphogenetic protein (BMP) inhibition has been proposed as the primary determinant of neural cell fate in the developing Xenopus ectoderm. The evidence supporting this hypothesis comes from experiments in explanted "animal cap" ectoderm and in intact embryos using BMP antagonists that are unregulated and active well before gastrulation. While informative, these experiments cannot answer questions regarding the timing of signals and the behavior of cells in the more complex environment of the embryo. To examine the effects of BMP antagonism at defined times in intact embryos, we have generated a novel, two-component system for conditional BMP inhibition. We find that while blocking BMP signals induces ectopic neural tissue both in animal caps and in vivo, in intact embryos, it can only do so prior to late blastula stage (stage 9), well before the onset of gastrulation. Later inhibition does not induce neural identity, but does induce ectopic neural crest, suggesting that BMP antagonists play temporally distinct roles in establishing neural and neural crest identity. By combining BMP inhibition with fibroblast growth factor (FGF) activation, the neural inductive response in whole embryos is greatly enhanced and is no longer limited to pre-gastrula ectoderm. Thus, BMP inhibition during gastrulation is insufficient for neural induction in intact embryos, arguing against a BMP gradient as the sole determinant of ectodermal cell fate in the frog.