Odontogenesis and amelogenesis in interacting lizard-quail tissue combinations

In this study we examined the possible inductive role of the dental papilla from polyphyodont lizard tooth germs. Flank skin sheets of quail ectoderm enzymatically separated from dermal tissue were recombined with lizard tooth papillae and placed on semisolid medium and cultured for 2 days. Subsequently, the recombinants were removed and placed on the chorioallantoic membrane of chick hosts and incubated for 6 days. After this period of 8 days in explant, control tissues differentiated according to their own phenotypes. Lizard dental papilla alone differentiated as fibroblasts. Quail flank skin ectoderm differentiated into epithelial sheets. Intact lizard tooth buds developed into teeth with dentine and incipient enamel. In the best experimental recombinants, advanced and relatively well-constructed teeth were observed, with clear indications of hard tissue deposition in association with quail epithelium. The results show that mesenchyme of the adult lizard dental papilla and embryonic quail ectoderm of heterotopic origin are capable of carrying out the complex sequence of morphogenetic interactions involved in normal odontogenesis.     

The distribution of tenascin coincides with pathways of neural crest cell migration

The distribution of the extracellular matrix (ECM) glycoprotein, tenascin, has been compared with that of fibronectin in neural crest migration pathways of Xenopus laevis, quail and rat embryos. In all species studied, the distribution of tenascin, examined by immunohistochemistry, was more closely correlated with pathways of migration than that of fibronectin, which is known to be important for neural crest migration. In Xenopus laevis embryos, anti-tenascin stained the dorsal fin matrix and ECM along the ventral route of migration, but not the ECM found laterally between the ectoderma and somites where neural crest cells do not migrate. In quail embryos, the appearance of tenascin in neural crest pathways was well correlated with the anterior-to-posterior wave of migration. The distribution of tenascin within somites was compared with that of the neural crest marker, HNK-1, in quail embryos. In the dorsal halves of quail somites which contained migrating neural crest cells, the predominant tenascin staining was in the anterior halves of the somites, codistributed with the migrating cells. In rat embryos, tenascin was detectable in the somites only in the anterior halves. Tenascin was not detectable in the matrix of cultured quail neural crest cells, but was in the matrix surrounding somite and notochord cells in vitro. Neural crest cells cultured on a substratum of tenascin did not spread and were rounded. We propose that tenascin is an important factor controlling neural crest morphogenesis, perhaps by modifying the interaction of neural crest cells with fibronectin.     

In vitro differentiation of tooth buds from embryos and adult lizards (L. gravenhorsti): An ultrastructural comparison

It is well established that the capacity for teeth to differentiate “in vitro” depends upon: (a) the age of the embryonic rudiments at the time of excision and (b) the number of cells within each tissue type which are capable of differentiating into organ culture. This paper studies ultrastructural aspects of tooth buds grown in vitro from lizard embryos and compares these characteristics with those observed in dental germs grown in situ in older lizard embryos. Moreover, we report the self-differentiation in vitro dental tissues from adult lizard and compare this phenomenon with the main features of a morphogenetic field. Our results suggest that approximately in the first third of gestation in L. gravenhorsti the dental buds has already acquired the capacity for self-differentiation in vitro. The ultrastuctural observations show that there are no significant differences between odontoblasts and ameloblasts in situ and in vitro. The tooth from “adult lizards,” isolated by combined microsurgical and enzymatic procedure and cultured in semisolid-liquid medium were also able to differentiate teeth. This phenomenon implies that self-differentiation is not rigidly determined, and that in these animals the tooth tissues represents a continuous morphogenetic field throughout the animal's life. This property is intrinsic, resides in the isolated tooth tissues, and is relatively independent of external factors. In addition, these studies indicate that the chick chorio–allantoic membrane and the semisolid-liquid culture medium supply the majority of the factors required for development of these tissues.     

Intestinal coelomic transplants: a novel method for studying enteric nervous system development

Normal development of the enteric nervous system (ENS) requires the coordinated activity of multiple proteins to regulate the migration, proliferation, and differentiation of enteric neural crest cells. Much of our current knowledge of the molecular regulation of ENS development has been gained from transgenic mouse models and cultured neural crest cells. We have developed a method for studying the molecular basis of ENS formation complementing these techniques. Aneural quail or mouse hindgut, isolated prior to the arrival of neural crest cells, was transplanted into the coelomic cavity of a host chick embryo. Neural crest cells from the chick host migrated to and colonized the grafted hindgut. Thorough characterization of the resulting intestinal chimeras was performed by using immunohistochemistry and vital dye labeling to determine the origin of the host-derived cells, their pattern of migration, and their capacity to differentiate. The formation of the ENS in the intestinal chimeras was found to recapitulate many aspects of normal ENS development. The host-derived cells arose from the vagal neural crest and populated the graft in a rostral-to-caudal wave of migration, with the submucosal plexus being colonized first. These crest-derived cells differentiated into neurons and glial cells, forming ganglionated plexuses grossly indistinguishable from normal ENS. The resulting plexuses were specific to the grafted hindgut, with quail grafts developing two ganglionated plexuses, but mouse grafts developing only a single myenteric plexus. We discuss the advantages of intestinal coelomic transplants for studying ENS development. This work was supported by NIH K08HD46655 (to A.M.G.).     

The effect of tenascin and embryonic basal lamina on the behavior and morphology of neural crest cells in vitro

We have investigated the morphology and migratory behavior of quail neural crest cells on isolated embryonic basal laminae or substrata coated with fibronectin or tenascin. Each of these substrata have been implicated in directing neural crest cell migration in situ. We also observed the altered behavior of cells in response to the addition of tenascin to the culture medium independent of its effect as a migratory substratum. On tenascin-coated substrata, the rate of neural crest cell migration from neural tube explants was significantly greater than on uncoated tissue culture plastic, on fibronectin-coated plastic, or on basal lamina isolated from embryonic chick retinae. Neural crest cells on tenascin were rounded and lacked lamellipodia, in contrast to the flattened cells seen on basal lamina and fibronectin-coated plastic. In contrast, when tenascin was added to the culture medium of neural crest cells migrating on isolated basal lamina, a significant reduction in the rate of cell migration was observed. To study the nature of this effect, we used human melanoma cells, which have a number of characteristics in common with quail neural crest cells though they would be expected to have a distinct family of integrin receptors. A dose-dependent reduction in the rate of translocation was observed when tenascin was added to the culture medium of the human melanoma cell line plated on isolated basal laminae, indicating that the inhibitory effect of tenascin bound to the quail neural crest surface is probably not solely the result of competitive inhibition by tenascin for the integrin receptor. Our results show that tenascin can be used as a migratory substratum by avian neural crest cells and that tenascin as a substratum can stimulate neural crest cell migration, probably by permitting rapid detachment. Tenascin in the medium, on the other hand, inhibits both the migration rates and spreading of motile cells on basal lamina because it binds only the cell surface and not the underlying basal lamina. Cell surface-bound tenascin may decrease cell-substratum interactions and thus weaken the tractional forces generated by migrating cells. This is in contrast to the action of fibronectin, which when added to the medium stimulates cell migration by binding both to neural crest cells and the basal lamina, thus providing a bridge between the motile cells and the substratum.     

Culture conditions affect the cholinergic development of an isolated subpopulation of chick mesencephalic neural crest cells

Although neural crest cells are known to be very responsive to environmental cues during their development, recent evidence indicates that at least some subpopulations may be committed to a specific differentiation program prior to migration. Because the neural crest is composed of a heterogeneous mixture of cells that contributes to many vertebrate cell lineages, assessing the properties of specific subpopulations and the effect of the environment on their development has been difficult. To address this problem, we have isolated a pure subpopulation of chick mesencephalic neural crest cells by fluorescence no-flow cytometry after labeling them with monoclonal antibodies (Mabs) to a 75-kDa cell surface antigen that is associated with high affinity choline uptake. When cultures of chick mesencephalic neural crest cells are labeled with these Mabs and a fluorescent second step antibody, approximately 5% of the cells are antigen-positive (A+). After sorting, 100% of the resulting cultured mesencephalic neural crest cells are A+. The Mabs we used also label all of the neurons of the embryonic chick and quail ciliary ganglion in vivo and in vitro. We have compared the effect of various cell culture media on the isolated neural crest subpopulation and the heterogeneous chick mesencephalic neural crest from which it was derived. A+ cells were passaged and grown in a variety of media, each of which differently affected its characteristics and development. A+ cells proliferated in the presence of 15% fetal bovine serum (FBS) and high concentrations (10-15%) of chick embryo extract, but did not differentiate, although they retained basal levels of choline acetyltransferase (ChAT) activity. However, in chick serum and high (25 mM as opposed to 7 mM) K+, and heart-, iris-, or lung-conditioned medium, all of which are known to promote survival and/or cholinergic development of ciliary ganglion neurons, the cells ceased to proliferate and all of the cells in the culture became "neuron-like" within 10 days. No neuron-like cells were found in liver-, notocord-, or neural tube-conditioned media if FBS was used. When A+ cells were eliminated either by complement-mediated cytotoxicity or by laser-ablating A+ cells during no-flow cytometry, all ChAT activity was also eliminated, and no neuron-like cells or ChAT activity was found in cultures during a subsequent 3-week culture period.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of nerve growth factor binding to cultured neural crest cells: evidence of an early developmental form of the NGF receptor

Cultured neural crest cells undergoing differentiation have been shown to contain a subpopulation of cells with specific receptors for nerve growth factor (NGF). These cells are the potential targets of NGF during differentiation and development. This study was done to pharmacologically characterize the binding of NGF to long-term (1- to 3-week) cultures of quail neural crest cells. The data indicate that 125I-NGF binding was specific and saturable, with less than 20% nonspecific binding. Scatchard analysis revealed the presence of one type (class) of receptors with a binding constant (Kd) similar to that of the low-affinity binding site described for embryonic dorsal root and sympathetic ganglia (approximately 3.2 nM). This was corroborated by displacement experiments (Kd of 1.3 nM), in which 125I-NGF binding was measured in the presence of increasing concentrations of nonradioactive NGF. In addition, affinity labeling revealed that the 125I-NGF-receptor complex had a molecular weight of about 93K, characteristic of the low-affinity NGF receptor of PC12 cells. The NGF receptor of cultured neural crest cells was trypsin-sensitive, as is typical of the low-affinity NGF binding sites. These findings indicate that differentiating neural crest cells lack high-affinity 125I-NGF binding sites. In contrast, embryonic dorsal root and sympathetic ganglia cells, known NGF targets, have both high- and low-affinity receptors. Measurements of the differential release of surface-bound 125I-NGF indicated that a relatively small amount (about 14%) of NGF is internalized over a 1-hr period. Cultured neural crest cells which bear NGF receptors were also shown by light microscopic radioautographic techniques to incorporate [3H]thymidine. I suggest, therefore, that cultured neural crest cells which have not terminally differentiated, as judged by morphological criteria and continued proliferation, may express an early developmental form of the NGF receptor.     

Differentiation of peptidergic neurones in quail-chick chimaeric embryos

The problem raised in this work was whether peptidergic neurones with vasoactive intestinal peptide (VIP)-and substance P-like immunoreactivity could develop in chimaeric embryos in which quail neural crest cells had been implanted into chick at an early developmental stage. Differentiation of peptide-containing nerve somas was looked for in different situations: i) when the quail neural primordium had been grafted orthotopically and isochronically into the chick host either at the adrenomedullary (level of somites 18-24) or at the vagal (level of somites 1-7) levels of the neural axis; ii) when the quail adrenomedullary neural primordium had been heterotopically implanted at the vagal level of the chick host. In all conditions, VIP- and substance P-like immunoreactivity were observed in a number of quail neurones located either in the peripheral ganglia of the trunk at the level of the graft (in orthotopic grafts of the adrenomedullary neural primordium) or in the enteric ganglia of the chick gut (in the other types of grafts). The developmental stage at which the first neurones become detectable in the host conforms to the genetic characteristics of the effector cells, i.e. they differentiate at the same stage in normal quail neuroblasts and in quail neuroblasts transplanted into the chick host. In contrast, the distribution of the peptidergic neurones in the host depends on the tissue into which the neural crest cells migrate and not on their origin in the neural axis and their fate in normal development.     

Fate mapping in embryos of Neoceratodus forsteri reveals cranial neural crest participation in tooth development is conserved from lungfish to tetrapods

Experimental evidence that the neural crest participates in tooth development in any osteichthyan fish has so far been lacking. Using vital dye cell-lineage tracking, we demonstrate that trigeminal stream neural crest cells contribute to the dental papilla of developing teeth in the Australian lungfish. Trigeminal neural crest cells labeled before migration have been traced during the earliest stages of tooth development. Neural crest cells from a single midbrain locus were relocated as ectomesenchyme in all developing teeth of the lungfish regardless of their topographical position in the dentition. These cells remain at the dental papilla interface and become cells committed to dentine production. Our findings provide the first cell-lineage evidence that cranial neural crest is fated to ectomesenchyme for tooth development and dentine production in the living sister-group to tetrapods. This shows that cranial neural crest contribution to teeth is conserved from this node on the tetrapod phylogeny.     

Cellular fibronectin promotes adrenergic differentiation of quail neural crest cells in vitro

We have investigated the interaction of cellular fibronectin (CFN) with cultured quail neural crest cells and its possible role in crest cell migration and differentiation. In vitro, quail neural crest cells from the trunk region differentiate into at least two morphologically recognizable cell types, melanocytes and adrenergic nerve cells. The latter often aggregate spontaneously into ganglia-like structures. We found that neither melanocytes nor adrenergic nerve cells synthesize CFN. However, both cell types readily interacted with exogenous CFN: Melanocytes removed CFN from the substratum and accumulated it in an aggegated form on their upper cell surface, whereas unpigmented cells migrated on the CFN substratum, often rearranging it into a fibrillar network. The adsorption of CFN by melanocytes was apparently without further consequences. However, catecholamine-positive cells were substantially increased after treatment with exogeneous fibronectin. The stimulation of adrenergic differentiation of neural crest cells is the first evidence for a positive regulatory role of fibronectin in differentiation.     

Experimental analysis of the migration and differentiation of neuroblasts of the autonomic nervous system and of neurectodermal mesenchymal derivatives, using a biological cell marking technique

By isotopic and isochronic transplantations of fragments of quail neural tube into chick, it has been previously shown that enteric ganglion cells arise from the “vagal” (somites 1–7) and the “lumbo-sacral” (behind somite 28) levels of the neural crest, while the trunk region (somites 8–28) gives rise to orthosympathetic ganglion chain and adrenomedullary cells. The latter originate precisely from the neural crest corresponding to somites 18–24 (i.e., “adrenomedullary” level of the crest). Heterotopic transplantations of fragments of quail neural tube into chick have been carried out in the present work. When the “adrenomedullary” level of the quail neural tube is grafted into the “vagal” region of a chick, the crest cells colonize the gut and differentiate into enteric ganglia of Auerbach's and Meissner's plexi. If quail cephalic neural crest is transplanted in the “adrenomedullary” level of a chick, quail cells migrate into the suprarenal glands and differentiate into adrenomedullary cells. Mesectodermal cells migrate laterally, and differentiate into cartilage, dermis and connective tissues. Thus it appears that preferential pathways located at precise levels of the embryo lead crest cells to their definitive sites. On the other hand the differentiation of the autonomic neuroblasts is controlled by the environment in which crest cells are localized at the end of their migration. On the contrary, mesenchymal derivatives of the cephalic neural crest appear to be early determined since they differentiate according to their presumptive fate when transplanted into the trunk.     

The sympathoadrenal lineage in avian embryos. II. Effects of glucocorticoids on cultured neural crest cells

The neural crest-derived precursors of the sympathoadrenal lineage depend on environmental cues to differentiate as sympathetic neurons and pheochromocytes. We have used the monoclonal antibody A2B5 as a marker for neuronal differentiation and antisera against catecholamine synthesis enzymes to investigate the differentiation of catecholaminergic cells in cultures of quail neural crest cells. Cells corresponding phenotypically to sympathetic neurons and pheochromocytes can be identified in neural crest cell cultures after 5-6 days in vitro. Expression of the A2B5 antigen precedes expression of immunocytochemically detectable levels of tyrosine hydroxylase in cultured neural crest cells. Glucocorticoid treatment decreases the proportion of TH+ neural crest cells that express neuronal traits. We conclude that environmental cues normally encountered by sympathoadrenal precursors in vivo can influence the differentiation of a subpopulation of cultured neural crest cells in the sympathoadrenal lineage.     

Pigment patterns in neural crest chimeras constructed from quail and guinea fowl embryos

The pattern of pigmentation in bird embryos is determined by the spatial organization of melanocyte differentiation. Some of the results from recent, neural crest transplantation experiments support a model based on a prepattern in the feathers; others could be interpreted in terms of a nonspecific pattern resulting from a failure of the crest cells to read the positional values in another species. To distinguish between these possibilities, the crucial test is to construct chimeras from two species with different pigment patterns. We have examined the wing plumage of quail and guinea fowl embryos. The quail has a characteristic pattern of pigmented and unpigmented feather papillae, whereas the guinea fowl shows uniform pigmentation. Chimeras were constructed by grafting wing buds isotopically between embryos. The wing buds were transplanted before they had become invaded by neural crest cells. Quail wing buds grafted to the guinea fowl developed, in most cases, a pigment pattern resembling that of the quail and not that of the guinea fowl. A few cases became uniformly pigmented and appeared to represent nonspecific patterns. The reciprocal grafts (guinea fowl wing buds grafted to the quail) became pigmented all over. We found evidence that the timing of melanocyte differentiation is controlled by cues in the feather papillae. Some cases developed a severe inflammatory response. The model which best accounts for these findings--and which can account for inconsistencies in previous reports--is the following. A prepattern is present in the feathers and this can control the differentiation of melanoblasts, even if they come from a different species. The local cues which constitute the prepattern are not positional values. In some chimeras melanoblasts fail to respond to the prepattern and so a nonspecific pattern of uniform pigmentation is produced.     

Analysis of developmentally homogeneous neural crest cell populations in vitro: I. Formation,morphology and differentiative behavior

When early embryonic quail neural tubes are dissected free from surrounding tissues and placed in culture, small stellate neural crest cells usually migrate from the explant onto the substratum. This outgrowth has been reported to consist of a mixture of cells, some of which undergo melanogenesis, while the rest remain unpigmented. We have, in contrast to earlier observations, obtained a spatial separation of the two phenotypes. In these cultures the primary outgrowth of migrating cells remained almost free of pigment-forming cells, whereas small spherical clusters containing several hundred pigment-forming cells appeared on the explanted neural tubes. Whether the clusters remained with the tube explants or were subcultured, all cluster cells differentiated into melanocytes. Prior to melanogenesis, the appearance of the cultured cells from a cluster was indistinguishable from the cells in the outgrowth. The clusters provide a source of neural crest cells, that (1) can be easily obtained in comparatively large numbers, (2) is not contaminated with any other cell type, (3) can be isolated before the onset of differentiation, and (4) is developmentally homogeneous. Thus, the cluster population is well suited for many types of experiments, such as the identification of specific environmental factors that might control neural crest cell differentiation.     

Appearance of nerve growth factor receptors on cultured neural crest cells

Light microscopic radioautography of differentiating quail neural crest cultures (1 to 2 weeks after explanation) incubated with Iodine-125-labeled nerve growth factor (125I-NGF) revealed that approximately 35% of the cells bound NGF. The binding was specific and saturable; it was blocked by an excess of nonradioactive NGF, and was not detected following incubation with biologically inactive 125I-NGF. In addition, the binding did not appear to be blocked or diminished by insulin. Cell cultures prepared from somites or notochord showed no specific binding of 125I-NGF. Melanocytes comprised approximately 10% of the cell population in these cultures and appeared to be unlabeled. The subpopulation of cells with NGF receptors that were morphologically similar to other non-melanocyte unlabeled cells present in the neural crest cultures are probably the targets of the factor during differentiation and development. In contrast, there was no evidence of 125I-NGF binding by premigratory neural crest (adherent to the isolated neural tube) or by early migratory neural crest cells (24 hr after explantation). Both of these types of neural crest cells are relatively undifferentiated. The cells of the neural tube were also unlabeled. The binding of 125I-NGF to differentiating neural crest cells was not noticeably diminished by a brief pretreatment with trypsin or Dispase, enzymes used in the isolation of neural tubes. Hence, the absence of NGF receptors on premigratory neural crest and early migratory neural crest cultures was not due to enzymatic alterations of the receptor. It seems, therefore, that receptors for NGF appear on neural crest cells during the time when these cells are acquiring their phenotypic characteristics.     

SSEA-1 is a specific marker for the spinal sensory neuron lineage in the quail embryo and in neural crest cell cultures

Investigation of the early phases of the development of primary sensory neurons has been limited to cells obtained from sensory ganglia. Due to the lack of an early, lineage-specific marker for sensory neuroblasts, it has not been possible to use the neural crest, which gives rise to all spinal and some cranial primary sensory neurons, as a source of precursor cells. In the present study, we show that in neural crest derivatives of the quail embryo, the stage-specific embryonic antigen-1 (SSEA-1) is expressed specifically by developing sensory neuroblasts. The monoclonal antibodies anti-SSEA-1 and AC4 were used to characterize sensory neuron development in vivo and in neural crest cell cultures. In the rat and mouse, both antibodies recognize the same carbohydrate sequence [galactose beta 1-4(fucose alpha 1-3)N-acetylglucosamine] which characterizes SSEA-1. In the quail embryo, this epitope is a marker with several attractive characteristics. Among neural crest derivatives, it is specific for the sensory lineage and is expressed by all detectable sensory neuroblasts at all spinal axial levels. In addition, the carbohydrate sequence appears early and persists throughout development. Expression of SSEA-1 was also studied in neural crest cell cultures, in which two populations of sensory neuroblasts were observed. One population differentiated before or shortly after explanation into culture; these cells did not emigrate from the neural tube. A second population appeared in older cultures. Forming the leading edge of the emigrating neural crest cells, they became SSEA-1+ 3 days after the nonmigrating SSEA-1+ cells. Double staining experiments revealed no obvious differences between the two populations with regard to morphology, neurofilament expression, and neurotransmitter content.     

Epithelia-mesenchyme interaction plays an essential role in transdifferentiation of retinal pigment epithelium of silver mutant quail: localization of FGF and related molecules and aberrant migration pattern of neural crest cells during eye rudiment formation

Homozygotes of the quail silver mutation, which have plumage color changes, also display a unique phenotype in the eye: during early embryonic development, the retinal pigment epithelium (RPE) spontaneously transdifferentiates into neural retinal tissue. Mitf is considered to be the responsible gene and to function similarly to the mouse microphthalmia mutation, and tissue interaction between RPE and surrounding mesenchymal tissue in organ culture has been shown to be essential for the initiation of the transdifferentiation process in which fibroblast growth factor (FGF) signaling is involved. The immunohistochemical results of the present study show that laminin and heparan sulfate proteoglycan, both acting as cofactors for FGF binding, are localized in the area of transdifferentiation of silver embryos much more abundantly than in wild-type embryos. More intense immunohistochemical staining with FGF-1 antibody, but not with FGF-2 antibody, is also found in the neural retina, RPE, and choroidal tissue of silver embryos than in wild-type embryos. HNK-1 immunohistochemistry revealed that clusters of HNK-1-positive cells (presumptive migrating neural crest cells) are frequently located around the developing eyes and in the posterior region of the silver embryonic eye. Finally, chick-quail chimerical eyes were made by grafting silver quail optic vesicles to chicken host embryos: in most cases, no transdifferentiation occurs in the silver RPE, but in a few cases, transdifferentiation occurs where silver quail cells predominate in the choroid tissue. These observations together with our previous in vitro study indicate that the silver mutation affects not only RPE cells but also cephalic neural crest cells, which migrate to the eye rudiment, and that these crest cells play an essential role in the transdifferentiation of RPE, possibly by modifying the FGF signaling pathway. The precise molecular mechanism involved in RPE-neural crest cell interaction is still unknown, and the quail silver mutation is considered to be a good experimental model for studying the role of neural crest cells in vertebrate eye development.     

Difference in the expression of asymmetric acetylcholinesterase molecular forms during myogenesis in early avian dermomyotomes and limb buds in ovo and in vitro

The A12 (asymmetric) form of acetylcholinesterase (AChE) is generally considered to be synthesized in leg muscle tissues by myotubes under neural influence, but not by myoblasts. We have examined the expression of the different molecular forms of AChE in explants of developing limb buds and dermomyotomes (the myogenic part of the somites) obtained from 3-day-old chick and quail embryos, either directly after removal or during in vitro culture. We describe a muscular differentiation of both territories in vitro, leading to the formation of myotubes which are morphologically similar to the class of early muscle cells described by Bonner and Hauschka (1974). In vivo the A12 form is present in quail dermomyotomes which are almost entirely composed of mononucleated poorly differentiated cells; in contrast, it is absent from similar cells in chick dermomyotomes and from limb buds in both species. This shows that in the case of quail embryos the appearance of the A12 form precedes the fusion of myoblasts into myotubes. In both species, dermomyotome explants express asymmetric and globular forms of the enzyme during muscular differentiation in vitro, whereas limb buds synthesize only globular forms. After surgical removal of neural tube and/or neural crest at 2 days in ovo, the biosynthesis of the A forms in quail dermomyotomes is not suppressed and is consequently not dependent upon prior connection of the dermomyotomes to central neurons or upon the presence of autonomic precursors. Since limb bud muscle cells derive from somites our results raise questions concerning the differentiation of migrating somitic cells in this territory where a neural influence appears necessary to induce the biosynthesis of asymmetric AChE forms.     

Clonal analysis of quail neural crest cells: They are pluripotent and differentiate in vitro in the absence of noncrest cells

To determine if neural crest cells are pluripotent and establish whether differentiation occurs in the absence of noncrest cells, a cell culture method was devised in which differentiation could be examined in clones derived from single, isolated neural crest cells. Single neural crest cells, which were isolated before the onset of in vivo migration, gave rise to three types of clones: pigmented, unpigmented, and mixed. Pigmented clones consisted of melanocytes only, whereas some unpigmented cells in mixed and unpigmented clones contained catecholamines, identifying them as adrenergic cells. Extracellular matrix derived from quail somite or chick skin fibroblast cultures stimulated adrenergic differentiation and axon formation. These results demonstrate for the first time the existence of pluripotent quail neural crest cells that give rise to at least two progeny, melanocytes and neuronal cells. They also suggest that continuous direct interactions with noncrest cells are not required for the differentiation of these two cell types. However, components of the extracellular matrix derived from noncrest cells may play an important role in expression of the adrenergic phenotype.     

Analysis of migratory behavior of neural crest and fibroblastic cells in embryonic tissues

The precise migration of neural crest cells is apparently controlled by their environment. We have examined whether the embryonic tissue spaces in which crest cells normally migrate are sufficient to account for the pattern of crest cell distribution and whether other migratory cells could also distribute themselves along these pathways. To this end, we grafted a variety of cell types into the initial crest cell migratory pathway in chicken embryos. These cell types included (a) undifferentiated neural crest cells isolated from cultured neural tubes, intact crest from cranial neural folds, and crest derivatives (pigment cells and spinal ganglia); (b) normal embryonic fibroblastic cells from somite, limb bud, lateral plate, and heart ventricle; and (c) a transformed fibroblastic cell line (Sarcoma 180). Crest cells or their derivatives grafted into the crest migratory pathway all distributed normally, although in contrast to the result when neural tubes were graftedin situ, fewer cells were observed in the epithelium and few or none were localized in the nascent spinal ganglia. Grafted quail somite cells contributed to normal somitic structures and did not migrate extensively in the chicken host. Other fibroblasts did not migrate along cranial or trunk crest pathways, or invade adjacent tissues, but remained intact at the graft site. Sarcoma 180 cells, however, distributed themselves along the normal trunk crest pathway. Cranial and trunk crest cells and crest derivatives grafted ectopically in the limb bud or somite also dispersed, and were found along the ventral migratory pathway. Fibroblastic cells grafted into ectopic sites again remained intact and did not invade host tissue. We conclude (1) that neural crest cells and their derivatives are highly motile and invasive in their normal pathway, as well as in unfamiliar embryonic environments; and (2) that the crest pathway does not act solely to direct neural crest cells, since at least one transformed cell can follow the crest migratory route.