Cell cycle changes during neural crest cell differentiation in vitro

Nociceptor subtypes are born continuously over DRG development

Sensory neurogenesis in the dorsal root ganglion (DRG) occurs in two waves of differentiation with larger, myelinated proprioceptive and low-threshold mechanoreceptor (LTMR) neurons differentiating before smaller, unmyelinated (C) nociceptive neurons. This temporal difference was established from early birthdating studies based on DRG soma cell size. However, distinctions in birthdates between molecular subtypes of sensory neurons, particularly nociceptors, is unknown. Here, we assess the birthdate of lumbar DRG neurons in mice using a thymidine analog, EdU, to label developing neurons exiting mitosis combined with co-labeling of known sensory neuron markers. We find that different nociceptor subtypes are born on similar timescales, with continuous births between E9.5 to E13.5, and peak births from E10.5 to E11.5. Notably, we find that thinly myelinated Aδ-fiber nociceptors and peptidergic C-fibers are born more broadly between E10.5 and E11.5 than previously thought and that non-peptidergic C-fibers and C-LTMRs are born with a peak birth date of E11.5. Moreover, we find that the percentages of nociceptor subtypes born at a particular timepoint are the same for any given nociceptor cell type marker, indicating that intrinsic or extrinsic influences on cell type diversity are occurring similarly across developmental time. Overall, the patterns of birth still fit within the classical "two wave" description, as touch and proprioceptive fibers are born primarily at E10.5, but suggest that nociceptors have a slightly broader wave of birthdates with different nociceptor subtypes continually differentiating throughout sensory neurogenesis irrespective of myelination.

A nonneural epithelial domain of embryonic cranial neural folds gives rise to ectomesenchyme

The neural crest is generally believed to be the embryonic source of skeletogenic mesenchyme (ectomesenchyme) in the vertebrate head and other derivatives, including pigment cells and neurons and glia of the peripheral nervous system. Although classical transplantation experiments leading to this conclusion assumed that embryonic neural folds were homogeneous epithelia, we reported that embryonic cranial neural folds contain spatially and phenotypically distinct domains, including a lateral nonneural domain with cells that coexpress E-cadherin and PDGFRalpha and a thickened mediodorsal neuroepithelial domain where these proteins are reduced or absent. We now show that Wnt1-Cre is expressed in the lateral nonneural epithelium of rostral neural folds and that cells coexpressing Cre-recombinase and PDGFRalpha delaminate precociously from some of this nonneural epithelium. We also show that ectomesenchymal cells exhibit beta-galactosidase activity in embryos heterozygous for an Ecad-lacZ reporter knock- in allele. We conclude that a lateral nonneural domain of the neural fold epithelium, which we call "metablast," is a source of ectomesenchyme distinct from the neural crest. We suggest that closer analysis of the origin of ectomesenchyme might help to understand (i) the molecular-genetic regulation of development of both neural crest and ectomesenchyme lineages; (ii) the early developmental origin of skeletogenic and connective tissue mesenchyme in the vertebrate head; and (iii) the presumed origin of head and branchial arch skeletal and connective tissue structures during vertebrate evolution.

Enteric nervous system: development and developmental disturbances--part 1

This review, which is presented in two parts, summarizes and synthesizes current views on the genetic, molecular, and cell biological underpinnings of the early embryonic phases of enteric nervous system (ENS) formation and its defects. In the first part, we describe the critical features of two principal abnormalities of ENS development: Hirschsprung's disease (HSCR) and intestinal neuronal dysplasia type B (INDB) in humans, and the similar abnormalities in animals. These represent the extremes of the diagnostic spectrum: HSCR has agreed and unequivocal diagnostic criteria, whereas the diagnosis and even existence of INDB as a clinical entity is highly controversial. The difficulties in diagnosis and treatment of both these conditions are discussed. We then review the genes now known which, when mutated or deleted, may cause defects of ENS development. Many of these genetic abnormalities in animal models give a phenotype similar or identical to HSCR, and were discovered by studies of humans and of mouse mutants with similar defects. The most important of these genes are those coding for molecules in the GDNF intercellular signaling system, and those coding for molecules in the ET-3 signaling system. However, a range of other genes for different signaling systems and for transcription factors also disturb ENS formation when they are deleted or mutated. In addition, a large proportion of HSCR cases have not been ascribed to the currently known genes, suggesting that additional genes for ENS development await discovery.

GDNF and ET-3 differentially modulate the numbers of avian enteric neural crest cells and enteric neurons in vitro

Vagal (hindbrain) neural crest cells migrate rostrocaudally in the gut to establish the enteric nervous system. Glial-derived neurotrophic factor (GDNF) and its receptor(s), and endothelin-3 (ET-3) and its receptor, are crucial for enteric nervous system development. Mutations interrupting either of these signaling pathways cause aganglionosis in the gut, termed Hirschsprung's disease in humans. However, the precise functions of GDNF and ET-3 in enteric neurogenesis are still unknown. We isolated precursor cells of the enteric nervous system from the vagal level neural crest of E1.7 quail embryos prior to entry into the gut and from the developing midgut at stages corresponding to migrating (E4.7) and longer resident differentiating cells (E7) using HNK-1 immunoaffinity and magnetic beads. These cells were tested for their response to GDNF and ET-3 in culture. ET-3 and GDNF had little effect in vitro on the growth, survival, migration, or neurogenesis of E1.7 vagal neural crest cells. In contrast, GDNF increased the proliferation rate and numbers of enteric neural precursors isolated from the E4.7 and E7 gut. Also, many more neurons and neurites developed in cultures treated with GDNF, disproportionately greater than the effect on cell numbers. At high cell density and in the presence of serum, ET-3, and GDNF had an additive effect on proliferation of neuron precursor cells. In defined medium, or low cell density, ET-3 reduced cell proliferation, overriding the proliferative effect of GDNF. Regardless of the culture condition, the stimulatory effect of GDNF on neuron numbers was strikingly diminished by the simultaneous presence of ET-3. We propose first that GDNF promotes the proliferation in the migratory enteric neural precursor cell population once the cells have entered the gut and is especially crucial for the differentiation of these cells into nonmigrating, nonproliferating enteric neurons. Second, we suggest that ET-3 modulates the action of GDNF, inhibiting neuronal differentiation to maintain the precursor cell pool, so ensuring sufficient population numbers to construct the entire enteric nervous system. Third, we suggest that generalized defects in enteric neural precursor cell numbers and differentiation due to mutations in the ET-3 and GDNF systems are converted to distal gut neural deficiencies by the rostrocaudal migration pattern of the precursors. Fourth, we suggest that additional factors such as those found in serum and produced by the enteric neural cells themselves are likely also to be involved in enteric nervous system development and consequently in Hirschsprung's disease.

Timing and pattern of cell fate restrictions in the neural crest lineage

The trunk neural crest of vertebrate embryos is a transient collection of precursor cells present along the dorsal aspect of the neural tube. These cells migrate on two distinct pathways and give rise to specific derivatives in precise embryonic locations. One group of crest cells migrates early on a ventral pathway and generates neurons and glial cells. A later-dispersing group migrates laterally and gives rise to melanocytes in the skin. These observations raise the possibility that the appearance of distinct derivatives in different embryonic locations is a consequence of lineage restrictions specified before or soon after the onset of neural crest cell migration. To test this notion, we have assessed when and in what order distinct cell fates are specified during neural crest development. We determined the proportions of different types of precursor cells in cultured neural crest populations immediately after emergence from the neural tube and at intervals as development proceeds. We found that the initial neural crest population was a heterogeneous mixture of precursors almost half of which generated single-phenotype clones. Distinct neurogenic and melanogenic sublineages were also present in the outgrowth population almost immediately, but melanogenic precursors dispersed from the neural tube only after many neurogenic precursors had already done so. A discrete fate-restricted neuronal precursor population was distinguished before entirely separate fate-restricted melanocyte and glial precursor populations were present, and well before initial neuronal differentiation. Taken together, our results demonstrate that lineage-restricted subpopulations constitute a major portion of the initial neural crest population and that neural crest diversification occurs well before overt differentiation by the asynchronous restriction of distinct cell fates. Thus, the different morphogenetic and differentiative behavior of neural crest subsets in vivo may result from earlier cell fate-specification events that generate developmentally distinct subpopulations that respond differentially to environmental cues.

Growth of neural crest cells in vitro is enhanced by extracts from Silky Fowl embryonic tissues

In the Silky Fowl (SF) breed of chicken, most of the internal organs are infiltrated with melanocytes. Previous studies have shown that this generalized mesodermal pigmentation is not due to a cell autonomous abnormality of the melanocytes but to environmental factors able to promote both the homing of pigment cell precursors in abnormal embryonic sites and their proliferation and differentiation. To analyse the mode of these environmental cues, we tested the effect of SF embryo extract (SFEE) on cultured quail neural crest cells as compared with that of EE from normal chickens of the JA57 strain (JA57EE). We found that SFEE enhances crest cell proliferation as judged by 3H-TdR incorporation and cell counting. In contrast, no effect of SFEE was observed either on the proportion of cultured cells that are engaged into the melanocytic differentiation pathway or on the amount of melanin produced by each differentiated pigment cell. The simple observation, however, reveals that SFEE has a significant effect on pigmentation of the cultured quail neural crest cells. This effect has therefore to be accounted for by the general increase in cell number induced by SFEE. The question is raised as to whether the in vivo SF phenotype is generated exclusively by this mechanism.

Cell surface beta 1,4-galactosyltransferase functions during neural crest cell migration and neurulation in vivo

Mesenchymal cell migration and neurite outgrowth are mediated in part by binding of cell surface beta 1,4-galactosyltransferase (GalTase) to N-linked oligosaccharides within the E8 domain of laminin. In this study, we determined whether cell surface GalTase functions during neural crest cell migration and neural development in vivo using antibodies raised against affinity-purified chicken serum GalTase. The antibodies specifically recognized two embryonic proteins of 77 and 67 kD, both of which express GalTase activity. The antibodies also immunoprecipitated and inhibited chick embryo GalTase activity, and inhibited neural crest cell migration on laminin matrices in vitro. Anti-GalTase antibodies were microinjected into the head mesenchyme of stage 7-9 chick embryos or cranial to Henson's node of stage 6 embryos. Anti-avian GalTase IgG decreased cranial neural crest cell migration on the injected side but did not cross the embryonic midline and did not affect neural crest cell migration on the uninjected side. Anti-avian GalTase Fab crossed the embryonic midline and perturbed cranial neural crest cell migration throughout the head. Neural fold elevation and neural tube closure were also disrupted by Fab fragments. Cell surface GalTase was localized to migrating neural crest cells and to the basal surfaces of neural epithelia by indirect immunofluorescence, whereas GalTase was undetectable on neural crest cells prior to migration. These results suggest that, during early embryogenesis, cell surface GalTase participates during neural crest cell migration, perhaps by interacting with laminin, a major component of the basal lamina. Cell surface GalTase also appears to play a role in neural tube formation, possibly by mediating neural epithelial adhesion to the underlying basal lamina.

Monoclonal antibodies raised against pre-migratory neural crest reveal population heterogeneity during crest development

In order to address the problem of when heterogeneity arises within premigratory and early migratory neural crest cell populations, mouse monoclonal antibodies were raised against quail premigratory neural crest. Due to the limited availability of immunogen an intrasplenic route for immunization was used. Three monoclonal antibodies (referred to as LH2D4, LH5D3 and LH6C2) were subsequently isolated which recognized subpopulations in 24 h cultures of both quail and chick mesencephalic and trunk neural crest in immunocytochemical studies. Subsequent investigations using a range of six antibodies, including LH2D4, LH5D3 and LH6C2, showed that population heterogeneity (which was not cell cycle related) could be detected as early as 15 h following mesencephalic crest explantation, a stage at which all the neural crest cells were morphologically identical. However, premigratory neural crest from the same axial level of origin was homogeneous, as judged by immunoreactivity patterns with these antibodies. Significant differences were found in the proportion of immunoreactive cells between populations of mesencephalic and trunk neural crest cultures. Double immunofluorescence studies revealed the existence of at least four separate cell populations within individual crest cultures, each identified by their unique antibody reactivity pattern, thus providing some insight into the underlying complexity of subpopulation composition within the neural crest. Immunocytochemical studies on quail embryos from stages 7-22 showed that the epitopes detected by LH2D4, LH5D3 and LH6C2 were not necessarily confined to the neural crest or to cells of crest derivation. All three epitopes displayed a spatiotemporal regulation in their expression during early avian ontogeny. Since the differential epitope expression described in this investigation was detectable as early as 15 h after premigratory neural crest explantation, took place in vitro in the absence of any other cell type and changed progressively with time, we conclude that a certain degree of population heterogeneity can be generated very early in neural crest ontogeny and independently of the tissue interactions that normally ensue in vivo.

Substratum effects on cell dispersal, morphology, and differentiation in cultures of avian neural crest cells

Adhesive extracellular matrix (ECM) molecules appear to play roles in the migration of neural crest cells, and may also provide cues for differentiation of these cells into a variety of phenotypes. We are studying the influences of specific ECM components on crest differentiation at the levels of both individual cells and cell populations. We report here that the glycoproteins fibronectin and laminin differentially affect melanogenesis in cultures of avian neural crest-derived cells. Clusters of neural crest cells were allowed to form on explanted neural tubes for 24 and 48 hr, and then subcultured on uncoated glass coverslips or coverslips coated with fibronectin or laminin. The morphology of cells varied on the three substrata, as did patterns of cell dispersal. Crest cells dispersed most rapidly and extensively on fibronectin. In contrast, cells on laminin dispersed initially, but then assumed a stellate morphology and rapidly formed small aggregates. Cell dispersal was minimal on glass substrata, resulting in a uniformly dense distribution. These patterns of dispersal were similar in subcultures of both 24- and 48-hr clusters, although dispersal of cells from older clusters was less extensive. The rate and extent of melanogenesis correlated with patterns of cell dispersal. Cell from 24-hr clusters underwent melanogenesis significantly more slowly on fibronectin than on the other two substrata. Pigment cells began to differentiate by 2 days of subculture in the cell aggregates on laminin and in the dense centers of cultures on untreated glass. By 5 days, there was significantly more melanogenesis in cultures on laminin and glass than on fibronectin substrata. Melanogenesis in cultures of 48-hr clusters was more rapid and extensive on control (glass) substrata than on fibronectin or laminin, correlating with reduced cell dispersal. We conclude that fibronectin and laminin, which are found along neural crest migratory pathways in vivo, can affect melanogenesis in vitro by regulating patterns of cell dispersal.

Delayed neural crest cell emigration from Sp and Spd mouse neural tube explants

Splotch (Sp) and splotch-delayed (Spd) are allelic mutations on chromosome 1 of the mouse. Embryos homozygous for either allele have neural tube defects (NTDs) and deficiencies in neural crest cell (NCC) derived structures. The fact that Spd mouse mutants sometimes have deficiencies in NCC derivatives in the absence of an NTD led to the hypothesis that neurulation and the release of NCCs may depend on a regulatory event that is common to both processes. Therefore, it may be possible to understand the cause of NTDs in these mutants by examining the basis of aberrant NCC derivatives. Caudal neural tubes were excised from day 9 Sp and Spd embryos and placed into gelatin-coated tissue culture dishes, or 3-dimensional basement membrane matrigel, and cultured for 72 hours. A cytogenetic marker was used to genotype the embryos. In planar cultures, no morphological differences were observed between NCCs from neural tube explants of Spd mutants compared to those from heterozygous or wild-type embryos. However, there appeared to be a delay in the release of NCCs from the neural tube in both Sp and Spd mutants, which was particularly evident in Sp. After 24 hours in culture, the extent of NCC outgrowth, as well as the number of NCCs emigrating from explanted neural tubes, was significantly lower in Sp and Spd mutant cultures than in controls. No differences were observed in the mitotic indices among cells which had emigrated. By 72 hours, mutant cultures and their non-mutant counterparts were similar in terms of outgrowth, cell number, and migratory capability. After 24 hours in 3-dimensional basement membrane matrigel, cell outgrowth from Sp explants was also significantly less than controls. The pattern of NCC outgrowth in both types of culture conditions indicates a 24 hour delay in mutant cultures compared to controls. This stems from a delay in the release of NCCs from the neural tube, suggesting that the defect lies within the neuroepithelium with respect to the release of NCCs.

Distinct and different effects of the oncogenes v-myc and v-src on avian sympathetic neurons: retroviral transfer of v-myc stimulates neuronal proliferation whereas v-src transfer enhances neuronal differentiation

Immature avian sympathetic neurons are able to proliferate in culture for a limited number of divisions albeit expressing several neuron-specific properties. The effect of avian retroviral transfer of oncogenes on proliferation and differentiation of sympathetic neurons was investigated. Primary cultures of 6-d-old quail sympathetic ganglia, consisting of 90% neuronal cells, were infected by Myelocytomatosis virus (MC29), which contains the oncogene v-myc, and by the v-src-containing Rous sarcoma virus (RSV). RSV infection, in contrast to findings in other cellular systems, resulted in a reduction of neuronal proliferation as determined by 3H-thymidine incorporation (50% of control 4 d after infection) and in increased morphological differentiation. This is reflected by increased neurite production, cell size, and expression of neurofilament protein. In addition, RSV-infected neurons, unlike uninfected cells, are able to survive in culture for time periods up to 14 d in the absence of added neurotrophic factors. In contrast, retroviral transfer of v-myc stimulated the proliferation of immature sympathetic neurons preserving many properties of uninfected cells. The neuron-specific cell surface antigen Q211 and the adrenergic marker enzyme tyrosine hydroxylase were maintained in MC29-infected cells and in the presence of chick embryo extract the cells could be propagated over several weeks and five passages. Within 7 d after infection, the number of Q211-positive neurons increased approximately 100-fold. These data demonstrate distinct and different effects of v-src and v-myc-containing retroviruses on proliferation and differentiation of sympathetic neurons: v-src transfer results in increased differentiation, whereas v-myc transfer maintains an immature status reflected by proliferation, immature morphology, and complex growth requirements. The possibility of expanding immature neuronal populations by transfer of v-myc will be of considerable importance for the molecular analysis of neuronal proliferation and differentiation.

Stimulation of adrenergic development in neural crest cultures by a reconstituted basement membrane-like matrix is inhibited by agents that elevate cAMP

Previous work (Maxwell and Forbes: Development 101:767-776, 1987) has shown that an overlay of reconstituted basement membrane-like (RBM) gel dramatically increased the number of catecholamine-positive (CA+) cells which differentiated in neural crest cultures. We report here that this increase was inhibited when cultures were grown for 7 days in the presence of agents that elevate cAMP, such as 8-bromo-cAMP and 3-isobutyl-1-methylxanthine. The action of 8-bromo-cAMP was dose dependent with a half-maximal effect at about 50 microM. The development of CA+ cells was dramatically reduced when 8-bromo-cAMP was present from days 0-4 in vitro, but was relatively unaffected if 8-bromo-cAMP was present from days 4-7 in vitro. The development of tyrosine hydroxylase immunoreactive cells was also inhibited by 8-bromo-cAMP. The addition of 8-bromo-cAMP increased the number of melanocytes and resulted in either no change or only modest reductions in the number of E/C8 and neurofilament immunoreactive cells, indicating that the effect on CA+ cell ontogeny was selective. In contrast to the effect of 8-bromo-cAMP, addition of 8-bromo-cGMP did not inhibit CA+ cell development in the presence of the RBM gel nor did it stimulate CA+ cell development in the absence of the RBM gel overlay. Our results suggest that cAMP may be an important regulator of phenotypic expression in at least some neural crest cell lineages.(ABSTRACT TRUNCATED AT 250 WORDS)

Catecholaminergic cells and support cell precursors in neural crest cultures differentially express nerve growth factor receptors

Long-term neural crest cultures grown in the continuous absence of exogenous nerve growth factor (NGF) contain a subpopulation of cells with NGF receptors exclusively of the low affinity subtype (Kd of approximately 3.2 nM). The current studies combined immunocytochemistry, using GIN1 (a support cell marker) or tyrosine hydroxylase antibodies, with radioautography following exposure to iodinated nerve growth factor (125I-NGF). The majority of cells specifically binding 125I-NGF were found to be immunoreactive for GIN1, indicating that the primary cell phenotype expressing receptors for NGF appear to be support cell precursors, at least under these conditions. These cells are likely to be responsive to and/or dependent upon NGF; the nature of this response or dependency remains to be determined. Some cells exhibiting silver grains were not immunoreactive for GIN1, suggesting that other cell phenotypes in neural crest cultures also have NGF receptors. In addition, some neural crest cells were found that stained with GIN1 and lacked 125I-NGF binding. Tyrosine hydroxylase-like immunoreactive cells apparently did not bind 125I-NGF under these culture conditions. Catecholaminergic sympathetic and sensory neurons from embryonic ganglia, derived from the neural crest, express both the high and low affinity forms of the NGF receptor. In order to determine whether the microenvironment played a role in the type of catecholaminergic cells appearing in culture, neural crest cells were grown in the continuous presence of exogenous NGF. Under these conditions, many tyrosine hydroxylase-like immunoreactive cells were found that specifically bound 125I-NGF. In addition, silver grains were still detected on these cells following a chase with nonradioactive NGF, designed to eliminate 125I-NGF bound to low affinity sites. Therefore, the catecholaminergic cells possess both the low and high affinity forms of the receptor. NGF's ability to modulate tyrosine hydroxylase activity, as it does in mature catecholaminergic neurons, was tested in this system. Surprisingly, there was no statistically significant difference in tyrosine hydroxylase activity in cultures grown in the absence or presence of exogenous NGF. This raises the possibility that embryonic catecholaminergic cells are unable to respond to NGF in this specific way, even though the receptors for the factor are present.

Analysis of the development of cellular subsets present in the neural crest using cell sorting and cell culture

We have tested the hypothesis that developmentally significant cellular subsets are present in the early stages of neural crest ontogenesis. Cultured quail trunk neural crest cells probed with the monoclonal antibodies HNK-1 and R24 exhibited heterogeneous staining patterns. Fluorescence-activated cell sorting was used to isolate the HNK-1+ and HNK-1- cell populations at 2 days in vitro. When these cell populations were cultured, the HNK-1+ sorted cells differentiated into melanocytes, unpigmented cells, and numerous catecholamine-positive (CA+) cells. In contrast, the HNK-1- sorted cells gave rise to melanocytes and unpigmented cells, but few, if any, CA+ cells. When neural crest cells at 2 days in vitro were labeled with R24 and sorted, both the R24+ the R24- sorted cell populations produced numerous CA+ cell, melanocytes, and unpigmented cells. These results provide evidence for the existence of developmental preferences in some subsets of neural crest cells early in embryogenesis.

Neuron-like cells in long-term neural crest cultures are not targets of nerve growth factor

It has been shown previously that a subpopulation of long-term (7-14 days) cultured neural crest cells undergoing differentiation possesses receptors for nerve growth factor (NGF). These cells are likely to be targets of NGF during the early stages of embryonic development. This study was conducted to determine whether cells exhibiting neuron-like characteristics (i.e. process formation, presence of putative neurotransmitters) in neural crest cultures have NGF receptors. This was accomplished by combining 125I-NGF radioautography and immunocytochemistry using antibodies against tyrosine hydroxylase, serotonin, and vasoactive intestinal polypeptide. Examination of light microscopic radioautographs revealed that none of the neuron-like cells with tyrosine hydroxylase-like, serotonin-like, or vasoactive intestinal polypeptide-like immunoreactivity bound 125I-NGF, and, therefore, do not possess NGF receptors. It is not known whether the lack of NGF receptors on neuron-like cells is due to the early developmental stage of these cells, or is caused by a difference in the microenvironment in vitro as compared to in vivo. The identity of the cultured neural crest cells which do possess NGF receptors remains to be determined.

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.

Development of cells containing catecholamines and somatostatin-like immunoreactivity in neural crest cultures: relationship of DNA synthesis to phenotypic expression

The goal of our work is to understand the mechanisms which regulate the differentiation of embryonic neural crest cells into a number of adult cell types, including several classes of neurons. As one aspect of this analysis, the relationship between DNA synthesis and the ontogeny of cells with catecholamines and somatostatin-like immunoreactivity (SLI) in neural crest cell cultures has been investigated. Most of the precursors of the catecholamine- and SLI-positive cells carry out DNA synthesis. As these cells differentiate, their ability to carry out DNA synthesis declines. However, a small percentage of cells continue to synthesize DNA after they become catecholamine or SLI positive. There is no apparent difference between the temporal pattern of DNA synthesis in the precursors of catecholamine-positive cells with SLI and those without SLI. Thus, the time of withdrawal from the cell cycle does not distinguish the lineage of cells that are catecholamine and SLI positive from those that are catecholamine positive and SLI negative.

Establishment of proliferative, pure cultures of pigmented chicken melanocytes from neural tubes

In order to obtain pure cultures of chicken melanocytes, neural tubes were excised from 22-somite stage embryos and placed in culture dishes to allow melanoblasts to migrate out and proliferate. The growth of contaminating cells was inhibited by maintaining the primary cultures in low-calcium and low-magnesium medium supplemented with 32 nM 12-O-tetradecanoylphorbol-13-acetate (TPA). Subsequently the pure cultures of melanocytes were maintained in Ham's F-10 medium supplemented with TPA. The population doubling time was approximately 12 h. The cell density at confluency in medium containing 32 nM TPA, 80 nM TPA, or 32 nM TPA plus 1 nM cholera toxin was 3.4, 5.6, or 8.3 X 10(4) cells/cm2, respectively. The melanocytes were highly pigmented and had tyrosinase activities ranging from 0.7-5.0 mU/mg protein.

A simple method for the establishment of tissue culture melanocytes from regenerating fowl feathers

A quick and simple method for the establishment of tissue cultures of nonembryonic domestic fowl melanocytes was desired. The selected source of these cells was the 14-d-old regenerating feather. Three procedures were compared on the basis of the yield and purity of melanocytes. For the first method, 2 mm of the proximal end of the feather was cut off under sterile conditions and placed immediately in Hanks' balanced salt solution (BSS) containing antibiotics. The feather was split longitudinally and the pulp removed. The tissue was placed pulp side down in several drops of Ham's F12 medium containing 2.5 micrograms/ml Fungizone, 50 micrograms/ml gentamicin, 100 micrograms/ml streptomycin, 100 micrograms/ml penicillin, and 10% fetal bovine serum. After 2 h at 37 degrees C, the tissue was attached to the dish and new medium was added and changed every 3 d thereafter. Cells migrated from the tissue starting on Day 2 and the tissue was removed on Day 5. Large dendritic peripheral cells and small round central cells were seen. Approximately 6.5 X 10(4) cells were present on Day 10 and 8 X 10(4) cells were counted on Day 20. By Day 30, the pigmented melanocytes were large, flat, dendritic cells. Electron microscopy and the use of the dopa reaction indicated that the population of cells was almost entirely melanocytes. The second method used was similar to the first, the only difference being that the feather sheath was also removed and thus only the collar of cells remained. The third method tried was similar to the second with the difference that the collar of cells was gently agitated with 0.25% trypsin for 5, 10, and 20-min intervals at 37 degrees C. The trypsin supernatant fluid was removed by gentle centrifugation and medium plus fetal bovine serum was added to stop tryptic action. The second method showed no advantage over the first. The purity and yield of melanocytes in the third method were lower than in either of the previous two methods. The number of cells desired can be controlled by varying the number of the feather pieces used per culture.

Translocation of latex beads after laser ablation of the avian neural crest

Previous studies from this laboratory (M.E. Bronner-Fraser, 1982, Dev. Biol. 91, 50-63) have demonstrated that latex beads translocate ventrally after injection into avian embryos during the phase of neural crest migration, to settle in the vicinity of neural-crest-derived structures. In order to examine the role of host neural crest cells in the ventral translocation of implanted beads, latex beads have been injected into regions of embryos from which the neural crest cells have been ablated using a laser microbeam. Prior to their migratory phase, neural crest cells reside in the dorsal portion of the neural tube. Laser irradiation of the dorsal neural tube was used to reproducibly achieve either partial or complete ablation of neural crest cells from the irradiated regions. The effectiveness of the ablation was assessed by the degree of reduction in dorsal root ganglia, a neural crest derivative. Because of the rapidity and precision of this technique, it was possible to selectively remove neural crest cells without significantly altering other embryonic structures. The results indicate that, after injection of latex beads into the somites of embryos whose neural crest cells were removed by laser irradiation, the beads translocate ventrally in the absence of the endogenous neural crest.

The genesis and differentiation of neurons in a frog parasympathetic ganglion

The cellular mechanisms that underlie formation of an autonomic ganglion have been investigated by studying the formation of the cardiac ganglion of the frog. Analysis of the genesis of neurons with [3H]thymidine autoradiography revealed that neuronal precursors do not divide via a "stem cell lineage" but rather divide exponentially, such that both daughter cells either re-enter the mitotic cycle or differentiate. Neurogenesis in this autonomic ganglion is prolonged, beginning during the second day after fertilization and continuing for at least 2 weeks. The use of acetylcholinesterase (AChE) as a neuronal marker showed that differentiated neurons start condensing in their target 1.5 days after the first neurons are born. Neurons accumulate, concomitant with neurogenesis, at a constant rate of approximately six neurons per day. Transplantation and organ culture demonstrated that immature neurons are present well before definitive expression of the mature phenotype and that their initial expression does not depend upon maintained contact by preganglionic axons.

Quail melanoblast migration in two breeds of fowl and in their hybrids: evidence for a dominant genic control of the mesodermal pigment cell pattern through the tissue environment

In the Silkie fowl large numbers of melanocytes invade most internal tissues and organs. The factors involved in this internal pigment cell pattern were studied by grafting quail neural tube segments into White Leghorn, White Silkie, and F1 hybrids (White Silkie male X White Leghorn female). Sections of quail neural tube five somites long, excised at the level of the last formed somites, were grafted isotopically and ischoronically. Various tissues and organs (mesenteries, muscles, testis, ovary, mesonephros, metanephros, and adrenals) excised from the internal region corresponding to the peripheral transverse strip of quail melanocytes, were studied after staining by the Feulgen-Rossenbeck technique. Despite some variations in pigment cell density, Silkie and hybrid grafted embryos exhibited an extensive quail internal pigmentation similar to the melanocyte distribution in the Silkie breed. In white Leghorn host embryos, the internal pigmentation remained limited. These results show the part played by tissular factors in the expression of the Silkie pigment phenotype and that this genetic tissular character is dominant. On the contrary, White Leghorn embryos, grafted with Silkie neural tube segments, never exhibited any internal pigmentation; the melanocytes deriving from the grafted Silkie neural tube were only localized at the dermoepidermal level. Thus, the migrating and/or differentiating capabilities of the Silkie premelanoblasts are different from those of quail premelanoblasts. The sex-linked inhibitor of the White Leghorn tissue interferes at the level of the pigment cells of chickens but not of quails.

A comparative study of the cell cycles of nullipotent and multipotent embryonal carcinoma cell lines during exponential growth

Three embryonal carcinoma (EC) cell lines F9, PCC4 Azal, and PCC3 N/1 with a common origin from the transplantable ascites teratoma OTT6050 were analyzed with regard to cell cycle characteristics during exponential growth in the undifferentiated state. The three lines, in the sequence mentioned, have been shown to represent successive stages in early normal mouse embryogenesis from morula to blastocyst, as reflected in their cell surface antigens. In the multipotent lines an increased intraclonal variability in intermitotic times was found when analyzing family trees. In the PCC3 N/1 line the distribution was almost bimodal. The increased intermitotic time variability was found to be represented in the G1 period that varied from less than 1 hr up to about 6 hr in the PCC3 N/1 line, with a mean value of 3.4 hr. The G1 period of the F9 line had a range of only 3.5 hr, with a mean value of 1.5 hr. The S-G2 period was found to be very similar in length in all three lines.

Somatostatin-like immunoreactivity is expressed in neural crest cultures

Embryonic neural crest cells give rise to many adult cell types, including some neurons that contain the neuroactive peptide somatostatin. The development of somatostatin-like immunoreactive cells has been investigated in quail neural crest cultures. Somatostatin-like immunoreactive cells were first detected in such cultures after 5 days in vitro by immunocytochemistry. The number of immunoreactive cells and the intensity of the immunoreactivity increased dramatically between 5 and 6 days in vitro. The immunoreactivity was present in a small subset of cells in the culture. It was seen in the perikaryon and cellular processes, but was absent from the nucleus. Immunoreactive cells with and without processes were observed. Somatostatin immunoreactivity was absent if the anti-somatostatin serum was preincubated in the presence of somatostatin. A sequential procedure for detecting catecholamine-containing cells histochemically followed by immunocytochemistry for somatostatin-like immunoreactivity showed that about 20% of the cells which contained catecholamines also contained somatostatin-like immunoreactivity. Greater than 90% of the somatostatin-containing cells in this analysis also contained catecholamines. Somatostatin-like immunoreactivity was also detected and quantitated by radioimmunoassay. The somatostatin-like immunoreactivity developed in vitro in medium that contained horse serum and chick embryo extract, but in the absence of other embryonic cell types such as notochord and somitic mesenchyme. These in vitro results together with prior in vivo data indicate that expression of somatostatin-like immunoreactivity is an early event in the development of some neural crest cells which also express adrenergic properties.

Proliferation of cells undergoing chondrogenesis in vitro

Continuous exposure of chicken embryo limb bud mesenchyme cells undergoing chondrogenesis in vitro to [3H] thymidine thymidine [(3H]TdR) revealed that more than 90% of the cells synthesized DNA at least once during 120 h of culture. When cells were exposed to [3H]TdR for 24 h beginning at various times throughout the culture period, the percentage of cells which incorporated [3H]TdR during each period was approximately 92%. However, when the period for incorporation of radioisotope was limited to two hours, the number of cells which incorporated [3H]TdR was found to decline during chondrogenesis in vitro. This decline was coincident with the appearance of extracellular matrix material and occurred in those cells which had, and had not, expressed the cartilage phenotype. We conclude from these studies that (1) practically all of the cells continue to proliferate while chondrogenesis is occurring in vitro, (2) there is an increase in the length of the cell cycle during chondrogenesis in vitro, and (3) withdrawal from the cell cycle is not required for differentiation of mesenchyme into cartilage.

A method for culturing chick melanocytes: the effect of BRL-3A cell conditioning and related additives

A method for growing chick embryo melanocytes is described that utilizes medium conditioned by Buffalo Rat liver (BRL-3A) cells. The dissected trunk region of each 72 h (Stages 14 to 19) embryo produces approximately 200,000 melanocytes (purity, 80%) when processed and cultured for 8 d. Thus, a typical experiment involving 20 embryos would produce a total of 4 x 10(6) melanocytes. Choice of serum, serum concentration, and cell density were determined experimentally. Partially purified multiplication stimulating activity (MSA) from BRL-3A cells and insulin were also tested as medium additives. MSA was not stimulatory, whereas insulin gave a positive response in 2% but not 10 or 0% serum. The final protocol used a modified F12 medium with 10% bovine calf serum conditioned by BRL-3A cells. Cultures were fed every other day. Small colonies of cells became evident by culture Day 3 and increased rapidly to Day 5 when pigmentation became obvious. Colony size continued to increase but more slowly from Days 5 to 8, whereas pigmentation increased rapidly and maximized on Day 8. There is a factor, or factors, present in BRL-3A conditioned medium that stimulates embryonic chick melanocytes to divide preferentially over contaminating cell types. This results in cultures that can provide adequate numbers and purity for biochemical studies.

Differentiation of avian neural crest cells in vitro: absence of a developmental bias toward melanogenesis

Neural crest cells from quail embryos grown in standard culture dishes differentiate almost entirely into melanocytes within 4 or 5 days when chick embryo extract (CEE) or occasional lots of fetal calf serum (FCS) are included in the medium. Gel fractionation showed that the pigment inducing factor(s) present in these media is of high molecular weight (greater than 400K daltons). In the absence of CEE, the neural tube can also stimulate melanocyte differentiation. Culture medium supplemented by selected lots of FCS permits crest cell proliferation but little overt differentiation after up to 2 weeks in culture if the neural tube is removed within 18 h of explantation in vitro. Subsequent addition of CEE to such cultures promotes complete melanocyte differentiation. Crest cells from White leghorn chick embryos also differentiate into melanocytes in the presence of CEE, but do not survive well in its absence. Melanocyte differentiation of crest cells from both quail and chick embryos can by suppressed by culturing under a dialysis membrane, even in the presence of the neural tube and CEE, but neuronal differentiation appears greatly enhanced.

Development of neuron-specific enolase immunoreactivity in avian nervous tissue in vivo and in vitro

Neuron-specific enolase (NSE) is a glycolytic isoenzyme that is primarily located in neurons and neuroendocrine cells. The development of NSE immunoreactivity in th avian nervous system at the level of the hind limb has been examined using immunocytochemical methods. NSE immunoreactivity is first detected in ventral horn motor neurons and dorsal root ganglion neurons at embryonic day 9-10. This is at least 2-3 days after some neurons in both these populations are capable of electrical activity. The glycogen body, a non-neuronal structure, also exhibits NSE (+) staining, but the onset of this immunoreactivity is earlier, at 8 days of embryonic development. NSE immunoreactivity was absent from the cell bodies of paravertebral sympathetic ganglia throughout development, but was present in cellular processes and terminals in the adult ganglia. NSE immunoreactivity also develops in tissue cultures containing cells of neural tube and neural crest origin.

Analysis of developmentally homogeneous neural crest cell populations in vitro. IV. Cell proliferation and synthesis of glycosaminoglycans

Glycosaminoglycans (GAG) have been implicated as regulators of morphogenesis and differentiation. We have cultured two different homogeneous populations of quail trunk neural crest cell with different predictable phenotypes after equivalent times in culture, and used these populations to distinguish changes in GAG synthesis before and after cell differentiation from changes that depend on time in culture, and that thus may reflect a non-specific response to in vitro culture conditions. Cells derived from the outgrowths surrounding explanted neural tubes remained undifferentiated. These crest cells showed a decrease in [3H]glucosamine incorporation into total GAG with time in culture. A similar decrease in total GAG, and, in addition, a slight decrease in the proportion of hyaluronic acid (HA) was observed in cultures of cluster-derived cells that homogeneously differentiated into melanocytes. Putative mouse neural crest cells that did not form melanin under the present culture conditions showed, similarly to the quail neural crest cells, a high incorporation of [3H]glucosamine into HA relative to sulfated GAG. The proportion of HA did not decrease with time in culture in these mouse crest cells. When pigment granules appeared in avian crest cells, the proliferation rate decreased drastically, whereas the proliferation rate of cells that did not form pigment granules remained constant. The results indicate that time in culture rather than either a differentiation per se or a change in the rate of proliferation, is largely responsible for the observed changes in GAG synthesis.

Glycosaminoglycan and glycoprotein synthesis by cranial neural crest cells in vitro

In the developing chick embryo, cranial neural crest cells, that will subsequently give rise to facial mesenchyme tissues, migrate beneath the surface ectoderm in a cell-free and hyaluronate-rich matrix. To determine how the crest cells could contribute to this matrix, we cultured crest cells from stage 9 embryos for 2 days and then labeled them for 18--20 h with various precursors of glycosaminoglycans (GAG) and glycoproteins. [3H]fucose and [3H]glucosamine were incorporated into Pronase-sensitive macromolecules associated with the cell layer, but little labeled glycoprotein was released into the medium. Hyaluronate was the major GAG synthesized and was distributed between the cells and medium. Less chondroitin-sulfate was synthesized. In comparison, older cultures as well as fibroblasts produced different proportions of GAG. Our results confirm the autoradiographic findings of Pratt et al. (1975) and suggest that crest cells may contribute GAG to the matrix during migration.

Substrate dependence of cell migration from explanted neural tubes in vitro

Embryonic chick neural tubes containing neural crest cells were cultured in vitro on tissue culture plastic and collagen. Two parameters, the time of onset of cell migration from the neural tube and the rate of movement of the cell front away from the neural tube explant, were determined. On collagen, cell migration consistently began after four to six h in vitro, about five h prior to the onset of cell migration on tissue culture plastic. The identity of the migrating cells as neural crest cells is established by their eventual differentiation into melanocytes. Ablation experiments reveal that collagen also causes the early onset of migration of cells not of neural crest origin. These results provide in vitro support for the idea that extracellular materials may alter cell migratory behaviour in morphogenesis.