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.     

Differential development of cholinergic neurons from cranial and trunk neural crest cells in vitro

Several studies have suggested that the development of cholinergic properties in cranial parasympathetic neurons is determined by these cells' axial level of origin in the neural crest. All cranial parasympathetic neurons normally derive from cranial neural crest. Trunk neural crest cells give rise to sympathetic neurons, most of which are noradrenergic. To determine if there is an intrinsic difference in the ability of cranial and trunk neural crest cells to form cholinergic neurons, we have compared the development of choline acetyltransferase (ChAT)-immunoreactive cells in explants of quail cranial and trunk neural crest in vitro. Both cranial and trunk neural crest explants gave rise to ChAT-immunoreactive cells in vitro. In both types of cultures, some of the ChAT-positive cells also expressed immunoreactivity for the catecholamine synthetic enzyme tyrosine hydroxylase. However, several differences were seen between cranial and trunk cultures. First, ChAT-immunoreactive cells appeared two days earlier in cranial than in trunk cultures. Second, cranial cultures contained a higher proportion of ChAT-immunoreactive cells. Finally, a subpopulation of the ChAT-immunoreactive cells in cranial cultures exhibited neuronal traits, including neurofilament immunoreactivity. In contrast, neurofilament-immunoreactive cells were not seen in trunk cultures. These results suggest that premigratory cranial and trunk neural crest cells differ in their ability to form cholinergic neurons.     

Plasticity and predetermination of mesencephalic and trunk neural crest transplanted into the region of the cardiac neural crest

The cardiac neural crest contains ectomesenchymal and neural anlagen that are necessary for normal heart development. It is not known whether other regions of the neural crest are capable of supporting normal heart development. In the experiments reported herein, quail donor embryos provided cardiac, trunk, or mesencephalic neural crest to replace or add to the chick host cardiac neural crest. Neither trunk nor mesencephalic neural crest was capable of generating ectomesenchyme competent to effect truncal septation. Addition of mesencephalic neural crest resulted in a high incidence of persistent truncus arteriosus, suggesting that ectomesenchyme derived from the mesencephalic region interferes with ectomesenchyme derived from the cardiac neural crest. Derivatives from the trunk neural crest, on the other hand, did not result in abnormal development of the truncal septum. While mesencephalic neural crest seeded the cardiac ganglia with both neurons and supporting cells, this capability was limited in the trunk neural crest to the more mature regions. These studies indicate a predetermination of the ectomesenchymal derivatives of the cranial neural crest and a possible competition of neural anlagen to form neurons and supporting cells in the cardiac ganglia.     

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.     

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.     

Delta signaling mediates segregation of neural crest and spinal sensory neurons from zebrafish lateral neural plate

We examined the role of Delta signaling in specification of two derivatives in zebrafish neural plate: Rohon-Beard spinal sensory neurons and neural crest. deltaA-expressing Rohon-Beard neurons are intermingled with premigratory neural crest cells in the trunk lateral neural plate. Embryos homozygous for a point mutation in deltaA, or with experimentally reduced delta signalling, have supernumerary Rohon-Beard neurons, reduced trunk-level expression of neural crest markers and lack trunk neural crest derivatives. Fin mesenchyme, a putative trunk neural crest derivative, is present in deltaA mutants, suggesting it segregates from other neural crest derivatives as early as the neural plate stage. Cranial neural crest derivatives are also present in deltaA mutants, revealing a genetic difference in regulation of trunk and cranial neural crest development.     

Expression of Schwann cell markers by mammalian neural crest cells in vitro

During embryonic development, neural crest cells differentiate into a wide variety of cell types including Schwann cells of the peripheral nervous system. In order to establish when neural crest cells first start to express a Schwann cell phenotype immunocytochemical techniques were used to examine rat premigratory neural crest cell cultures for the presence of Schwann cell markers. Cultures were fixed for immunocytochemistry after culture periods ranging from 1 to 24 days. Neural crest cells were identified by their morphology and any neural tube cells remaining in the cultures were identified by their epithelial morphology and immunocytochemically. As early as 1 to 2 days in culture, approximately one third of the neural crest cells stained with m217c, a monoclonal antibody that appears to recognize the same antigen as rat neural antigen-1 (RAN-1). A similar proportion of cells were immunoreactive in cultures stained with 192-IgG, a monoclonal antibody that recognizes the rat nerve growth factor receptor. The number of immunoreactive cells increased with time in culture. After 16 days in culture, nests of cells, many of which had a bipolar morphology, were present in the area previously occupied by neural crest cells. The cells in the nests were often associated with neurons and were immunoreactive for m217c, 192-IgG and antibody to S-100 protein and laminin, indicating that the cells were Schwann cells. At all culture periods examined, neural crest cells did not express glial fibrillary acidic protein. These results demonstrate that cultured premigratory neural crest cells express early Schwann cell markers and that some of these cells differentiate into Schwann cells. These observations suggest that some neural crest cells in vivo may be committed to forming Schwann cells and will do so provided that they then proceed to encounter the correct environmental cues during embryonic development.     

A paraxial exclusion zone creates patterned cranial neural crest cell outgrowth adjacent to rhombomeres 3 and 5.

Cranial neural crest cell migration is patterned, with neural crest cell-free zones adjacent to rhombomere (R) 3 and R5. These zones have been suggested to result from death of premigratory neural crest cells via upregulation of BMP-4 and Msx-2 in R3 and R5, consequent to R2-, R4-, and R6-derived signals. We reinvestigated this model and found that cell death detected by acridine orange staining in avian embryos varied widely numerically and in pattern, but with a tendency for an elevated zone centered at the R2/3 boundary. In situ hybridization of BMP-4 mRNA resolved to centers at R3 and R5 but Msx-2 resolved to the R2/3 border with only a faint smear from R5 to R6. Outgrowth of neural crest cells was less in isolated R3 cultures than in R1+2, R2, and R4 cultures, but R3 showed neither a decrease in outgrowth of neural crest cells nor an increase in cell death when cocultured with R1+2, R2, or R4. In addition, in serum-free culture, exogenous BMP-4 strikingly reduced neural crest cell outgrowth from R1+2 and R4 as well as R3. Thus we cannot confirm the role of intraneural cell death in patterning rhombomeric neural crest outgrowth. However, grafting quail R2 or R4 adjacent to the chick hindbrain demonstrated a neural crest cell exclusion zone next to R3 and R5. We suggest that one important pattern determinant for rhombomeric neural crest cell migration involves the microenvironment next to the neural tube.     

Analysis of neural crest cell lineage and migration.

In this review, we describe the results of recent experiments designed to investigate various aspects of neural crest cell lineage and migration. We have analyzed the lineage of individual premigratory neural crest cells by injecting a fluorescent lineage tracer dye, lysinated fluorescein dextran, into cells within the dorsal neural tube. Individual clones contained cells that were located in very diverse sites consistent with their being sensory neurons, prepigment cells, Schwann cells, adrenergic cells, and neural tube cells. These results suggest that some neural crest cells in the trunk and cranial regions are multipotent prior to their emigration from the neural tube. The environment through which neural crest cells move influences both the pattern and direction of their migration. We have shown that the sclerotomal portion of the somites are responsible for the rostrocaudal pattern of trunk neural crest cell movement, whereas the neural tube appears to govern the dorsoventral position of neural crest-derived ganglia. In addition, the notochord inhibits the movement of neural crest cells. In order to understand necessary cell-matrix interactions in neural crest migration, we have performed perturbation experiments, in which antibodies directed against cell surface or extracellular matrix molecules were introduced along neural crest pathways. We find that integrins, fibronectin, laminin, and tenascin all play some role in cranial neural crest emigration. Thus, multiple factors may be involved in controlling neural crest cell migration, and different factors may be important for migration in different regions of the embryo.     

Temporospatial study of the migration and distribution of cardiac neural crest in quail-chick chimeras.

It has been demonstrated that the septation of the outflow tract of the heart is formed by the cardiac neural crest. Ablation of this region of the neural crest prior to its migration from the neural fold results in anomalies of the outflow and inflow tracts of the heart and the aortic arch arteries. The objective of this study was to examine the migration and distribution of these neural crest cells from the pharyngeal arches into the outflow region of the heart during avian embryonic development. Chimeras were constructed in which each region of the premigratory cardiac neural crest from quail embryos was implanted into the corresponding area in chick embryos. The transplantations were done unilaterally on each side and bilaterally. The quail-chick chimeras were sacrificed between Hamburger-Hamilton stages 18 and 25, and the pharyngeal region and outflow tract were examined in serial paraffin sections to determine the distribution pattern of quail cells at each stage. The neural crest cells derived from the presumptive arch 3 and 4 regions of the neuraxis occupied mainly pharyngeal arches 3 and 4 respectively, although minor populations could be seen in pharyngeal arches 2 and 6. The neural crest cells migrating from the presumptive arch 6 region were seen mainly in pharyngeal arch 6, but they also populated pharyngeal arches 3 and 4. Clusters of quail neural crest cells were found in the distal outflow tract at stage 23.     

Environmental signals and cell fate specification in premigratory neural crest

Neural crest cells are multipotent progenitors, capable of producing diverse cell types upon differentiation. Recent studies have identified significant heterogeneity in both the fates produced and genes expressed by different premigratory crest cells. While these cells may be specified toward particular fates prior to migration, transplant studies show that some may still be capable of respecification at this time. Here we summarize evidence that extracellular signals in the local environment may act to specify premigratory crest and thus generate diversity in the population. Three main classes of signals-Wnts, BMP2/BMP4 and TGFbeta1,2,3-have been shown to directly influence the production of particular neural crest cell fates, and all are expressed near the premigratory crest. This system may therefore provide a good model for integration of multiple signaling pathways during embryonic cell fate specification.     

Stimulation of initial neural crest cell migration in the axolotl embryo by tissue grafts and extracellular matrix transplanted on microcarriers

The present experiments were designed to test whether the onset of neural crest cell migration in the embryonic axolotl trunk is stimulated by surrounding tissues and their associated extracellular matrix (ECM). Tissue grafts, or embryonic ECM adsorbed in vivo onto inert "microcarriers" prepared from Nuclepore filters, were placed close to the premigratory neural crest cells, and the embryos were then incubated to a specific stage. The experiments were evaluated with light microscopy, SEM, and TEM. It was found that grafts from the dorsal epidermis were especially effective in locally stimulating initial neural crest cell migration in the region under the graft. The microcarrier experiments showed that the subepidermal ECM alone could initiate neural crest cell migration, implying that the ECM of the epidermal grafts was the stimulating factor. These results indicate that the premigratory neural crest cells along the trunk have migratory capability but that they need to be triggered from the environment, probably from the surrounding ECM, to start migration. It is proposed that ECM, as substrate for cell locomotion, initiates and regulates the onset of neural crest cell migration.     

Coexpression of somatostatin-like immunoreactivity and catecholaminergic properties in neural crest derivatives: comodulation of peptidergic and adrenergic differentiation in cultured neural crest

In the avian embryo, somatostatin-like immunoreactivity (SLI) and adrenergic characteristics appear virtually simultaneously in the developing sympathetic nervous system and adrenal medulla. We have used double-labeling techniques to show that both properties coexist in the same cells. In the quail, not only do all somatostatin-containing cells in the adrenosympathetic system exhibit tyrosine hydroxylase immunoreactivity and possess catecholamines (CA), but this coexistence of the peptidergic and adrenergic phenotypes is already present very early in ontogeny. However, not all adrenergic cells express SLI. The development of sympathoadrenal precursors can be followed in vitro. Adrenergic precursor cells, obtained from the migrating neural crest, differentiate in culture into neuron-like cells that contain SLI and CA. This coexpression can be regulated by the same factors. For instance, corticosterone and progesterone increase SLI content and CA production in the neural crest cell cultures. The ontogeny of the autonomic lineage is discussed in the light of these results.     

The effects of epidermal growth factor on neural crest cells in tissue culture

Epidermal growth factor (EGF) stimulates the release of hyaluronic acid (HA) and chondroitin sulfate proteoglycan (CSPG) from quail trunk neural crest cultures in a dose-dependent fashion. It also promotes the expression of cell-associated heparan sulfate proteoglycan (HSPG) as detected by immunofluorescence and immunoprecipitation of the 3H-labeled proteoglycan. Furthermore, EGF stimulates [3H]thymidine incorporation into total cell DNA. These results raise the possibility that EGF or an analogous growth factor is involved in regulation of neural crest cell morphogenesis.     

Cholinergic traits in the neural crest: Acetylcholinesterase in crest cells of the chick embryo

Previous work by our group has demonstrated that mesencephalic neural crest cells at an early stage of migration are able to synthesize acetylcholine (ACh). Acetylcholinesterase (AChE), the enzyme responsible for ACh degradation, was examined in neural crest cells of the chick embryo, using cytochemical and biochemical methods. Observations at the light microscope level showed that cholinesterase activity, identified as true AChE, was present at all axial levels in presumptive crest cells of the neural folds, soon after closure of the neural tube. Subsequently, AChE activity was found in cells of the individualized neural crest and in crest cells migrating at cephalic and trunk levels. Cell counts revealed that 88–94% of the total crest population was AChE-positive. Electron microscope observations indicated that the enzyme was confined to perinuclear and endoplasmic reticulum cisternae. The AChE of migrating mesencephalic neural crest cells was identified as the dimeric form (sedimentation coefficient 6.9 S) of the catalytic subunit. These results indicate that the specific AChE is present in the majority of neural crest cells all along the neural axis. Thus the ability to synthesize and degrade ACh is expressed at least in some neural crest cells at an early stage of development.     

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)