Generation of radical oxygen species by neural crest cells treated in vitro with isotretinoin and 4-oxo-isotretinoin

The effects of isotretinoin (IR) and its primary metabolite (in the human), 4-oxo-isotretinoin (4-OIR or OIR), on isolated chick neural crest cells (NCC's) in culture were studied. NCC's were found to be deficient in both superoxide dismutase (SOD) and catalase, two of the enzymes known to function in the "scavenging" (dismutation) of toxic radical oxygen species (ROS) such as the superoxide anion and hydrogen peroxide. The addition of IR or OIR to the culture medium significantly depressed the viability of the NCC's when compared to untreated cells. OIR was more potent in this regard than IR. In the presence of either IR or OIR, NCC's generated superoxide anions (O2.), hydrogen peroxide (H2O2), and hydroxyl anions (OH.). OIR was again more potent. The cytotoxicity of IR or OIR was demonstrated by the "leakage" of radioactive chromium from prelabeled cells. The latter is suggestive of a primary surface membrane defect, most logically via the induction of lipid peroxides by the retinoids. The latter is accompanied by an increase in membrane permeability and porosity as evidenced by the fact that various fluorescently labeled molecules, including BSA-FITC (MW 69,000), gain entrance into the cytoplasm of the retinoid treated cells. No label was seen in the cytoplasm of similarly treated control cells. When SOD (200 units/ml) or catalase (400 units/ml) was added to the culture media of IR- or OIR-treated NCCs, cell viability was increased and the concentration of the various ROS generated was decreased. Membrane leakiness to chromium and FITC-BSA was also decreased in the presence of these enzymes. Free radicals, when not inactivated (dismutated), are known to be pathobiotic to most cells. Cell membranes are at a particular high risk from ROS which induce structural, physiological, and biochemical alterations in the cell membrane. The latter can have a negative effect on cell permeability, maintenance of normal ionic gradients, membrane enzyme activity, cell-to-cell communication, etc. Such defects can ultimately culminate in hypoplasia, aplasia, and cell necrosis. This study has shown that NCC's may be overtly sensitive to ROS, especially since these undifferentiated cells apparently lack inherent SOD and/or catalase activity. From this study it appears as if both IR and OIR perturb the normal functional state of NCC's by "triggering" the generation of ROS. This may certainly explain the teratogenicity of these drugs as related to the viability of neural crest derived ectomesenchymal cells and normal craniofacial morphogenesis.     

Invasive characteristics of neural crest cells in vitro

An investigation of the invasiveness of avian neural crest cells and neural crest-derived melanocytes through a human amniotic basement membrane (BM) was undertaken. Avian neural tube explants or derived melanocyte populations were seeded directly onto BMs in membrane invasion culture system (MICS) chambers for periods of 24, 48, and 72 h. In 36 experimental trials for each group, neither neural crest nor neural crest-derived melanocytes were observed to have invaded the BMs. In concert with these studies, coculturing of B16F10 murine melanoma cells with avian neural crest-derived melanocytes was performed in MICS chambers. Under these experimental conditions, the neural crest-derived melanocytes were able to successfully invade the BMs and to a greater extent than the B16F10 tumor cells. These data suggest that neural crest cells and neural crest-derived melanocytes do not have the ability to invade the BM alone; however, they can be induced to be invasive when cocultured in the presence of B16F10 cells. Alternatively, the B16F10 cells may create weaknesses within the BM that facilitate migration of the pigmented crest cells.     

Neuronal differentiation of mouse neural crest cells in vitro

The purpose of the present study is to analyze the effect of serum or chick embryo extract (CEE) on the neuronal differentiation of the mouse neural crest cells. When the crest cells were cultured in the medium containing serum at low concentration (5% calf serum), neurite outgrowth was observed. The active outgrowth was detected at 3-4 days in culture. However, in the medium supplemented with 20% calf serum, no neurite appeared, and the crest cells remained fibroblast-like. The differentiation of adrenergic neurons was observed when the crest cells were cultured in the medium containing CEE along with serum.     

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.     

Morphology and behaviour of neural crest cells of chick embryo in vitro

Summary Neural primordia of chick embryos were cultured for three days and the behaviour of migrating neural crest cells studied. Somite cells were used as a comparison. Crest cells were actively multipolar with narrow projections which extended and retracted rapidly, contrasting to the gradual extension of somite-cell lamellae. On losing cell contact, somite cells were also more directionally persistent. The rate of displacement of isolated crest cells was particularly low when calculated over a long time base. Both crest and somite cells were monolayered; contact paralysis occurred in somite cell collisions but was not ascertained for crest cells. However, crest cells in a population were far more directionally persistent than isolated cells. Contact duration between crest cells increased with time and they formed an open network. Eventually, retraction clumping occurred, initially and chiefly at the periphery of the crest outgrowth. Crest cells did not invade cultured embryonic mesenchymal or epithelial populations but endoderm underlapped them. No effects were observed on crest cells prior to direct contact. Substrate previously occupied by endoderm or ectoderm caused crest cells to flatten while substrate previously occupied by the neural tube caused them to round up and clump prematurely.     

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.     

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.     

Melanocyte-stimulating hormone affects melanogenic differentiation of quail neural crest cells in vitro

Quail neural crest cells were treated in vitro with alpha-melanocyte-stimulating hormone (alpha-MSH) or dibutyryl cyclic AMP (dbcAMP) plus theophylline. These treatments increased the proportion of melanocytes to total cells in crest cell outgrowth cultures. Pigmentation of neural crest cell clusters proceeded more rapidly when cultures were treated with alpha-MSH or dbcAMP plus theophylline than when untreated. In clonal cell cultures, the proportion of pigmented colonies to total colonies was increased by MSH treatment. From these results, MSH seems not only to accelerate melanogenic differentiation but also to affect the state of commitment of neural crest cells to melanogenic differentiation in vitro, and this action of MSH appears to be mediated by cAMP.     

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.     

Ethanol induces the generation of reactive free radicals by neural crest cells in vitro

Developmental craniofacial anomalies related to the neural crest derived ectomesenchymal cell population are associated with fetal alcohol syndrome (FAS). Information regarding any potential relationship between ethanol, free radicals, and the viability, proliferation, etc., of isolated neural crest cells was sought. The hypersensitivity of neural crest cells to ethanol was observed. This drug severely depressed cell viability while simultaneously inducing the generation of such reactive oxygen intermediates (ROI) as superoxide, hydrogen peroxide, and hydroxyl anions. Addition of the free radical scavenging enzyme superoxide dismutase to the culture medium significantly reversed these effects of ethanol. The cytotoxicity of ethanol was further confirmed by the release of radiolabeled chromium (51Cr) from cells prelabeled prior to ethanol treatment. This effect was also depressed by the addition of superoxide dismutase. Interestingly, an assay for superoxide dismutase activity showed that neural crest cells may be devoid of this enzyme. The latter may help to explain the overt sensitivity of these cells to such a broad spectrum of teratogens, many of which can either dissociate directly into ROI, or cause the radicalization of biological structures and molecules. Plasmalemmal lipids (via lipid peroxidation) and DNA are at an especially high risk from uncontrolled ROI. Changes in neural crest cell surface morphology, i.e., loss of microvilli, formation of xeiotic blebs, as well as the "leakage" of radiolabeled Cr from prelabeled cells, would seem to show that ethanol, as a result of induced free radical formation, alters the physiology and biochemistry of the cell membrane. These findings however, should not exclude other potential sites for ETOH-induced cell injury related to free radicals, especially the nuclei (DNA), mitochondria, organelle membranes, and the cytoskeleton.     

A mammalian in vitro model to study gangliogenesis from neural crest cells

In spite of considerable advances towards understanding lineages derived from neural crest cells using amphibian and avian embryos, the molecular mechanisms involved in the formation of mammalian peripheral ganglia remain largely unknown, mainly because of the lack of experimental systems that will allow their in vitro manipulation. Here, we present a novel mammalian in vitro model permitting to study gangliogenesis from neural crest cells. This model allowed us to manipulate molecules involved in cell-cell interactions. Our data are in favour of the existence of a hierarchy among adhesion molecules.     

Morphology and behavior of quail neural crest cells in artificial three-dimensional extracellular matrices

Neural crest cells migrate extensively through a complex extracellular matrix (ECM) to sites of terminal differentiation. To determine what role the various components of the ECM may play in crest morphogenesis, quail (Coturnix coturnix japonica) neural crest cells have been cultured in three-dimensional hydrated collagen lattices containing various combinations of macromolecules known to be present in the crest migratory pathways. Neural crest cells migrate readily in native collagen gels whereas the cells are unable to use denatured collagen as a migratory substratum. The speed of movement decreases linearly as the concentration of collagen in the gel increases. Speed of movement of crest cells is stimulated in gels containing 10% fetal calf serum and chick embryo extract, 33 micrograms/ml fibronectin cell-binding fragments, 3 mg/ml chondroitin sulfate, or 3 mg/ml chondroitin sulfate proteoglycan when compared to rates of movement through collagen lattices alone. Low concentrations of hyaluronate (250-500 micrograms/ml) in a 750 micrograms/ml collagen gel do not alter rates of movement over collagen alone, but higher concentrations (4 mg/ml) greatly inhibit migration. Conversely, hyaluronate (250 micrograms/ml) significantly increases speed of movement if the crest cells are cultured in high concentration collagen gels (2.5 mg/ml), suggesting that hyaluronate is expanding spaces and consequently enhancing migration. The morphology and mode of movement of neural crest cells vary with the matrix in which they are grown and can be correlated with their speed of movement. Light and scanning electron microscopy reveal rounded, blebbing cells in matrices associated with slower translocation, whereas rounded cells with branching filopodia or lamellipodia are associated with rapid translocation. Bipolar cells with long processes are observed in cultures of rapidly moving cells that appear to be adhering strongly, as well as in cultures of cells that are stationary for long periods. These data, considered with the known distribution of macromolecules in the early embryo, suggest the following: (1) Both collagen and fibronectin can act as preferred substrata for migration. (2) Chondroitin sulfate and chondroitin sulfate proteoglycan increase speed of movement, but probably do so by decreasing adhesiveness and thereby producing more frequent detachment. In the embryo, crest cells would most likely avoid regions containing high concentrations of chondroitin sulfate. (3) Hyaluronate cannot act as a substratum for migration, but in low concentrations it can open spaces in the matrix and consequently may stimulate movement. The complex interactions of combined matr     

The stem cells of the neural crest

In the vertebrate embryo, the neurectodermal neural crest cells (NCC) have remarkably broad potencies, giving rise, after a migratory phase, to neurons and glial cells in the peripheral nervous system, and to skin melanocytes, being all designated here as “neural” derivatives. NC-derived cells also include non-neural, “mesenchymal” cell types like chondrocytes and bone cells, myofibroblasts and adipocytes, which largely contribute to the head structures in amniotes. Similar to the blood cell system, the NC is therefore a valuable model to investigate the mechanisms of cell lineage diversification in vertebrates. Whether NCC are endowed with multiple differentiation potentials or if, conversely, they are a mosaic of different committed cells is an important ongoing issue to understand the ontogeny of NC derivatives in normal development and pathological conditions. Here we focus on recent findings that established the presence in the early migratory NC of the avian embryo, of a multipotent progenitor endowed with both mesenchymal and neural differentiation capacities. This “mesenchymal-neural” clonogenic cell lies upstream of all the other NC progenitors known so far and shows increased frequency when single cell cultures are treated with the Sonic Hedgehog signaling molecule. These findings are discussed in the context of the broad potentials of NC stem cells recently evidenced in certain adult mammalian tissues.     

Immortalization and controlled in vitro differentiation of murine multipotent neural crest stem cells

To isolate mouse neural crest stem cells, we have generated a rat monoclonal antibody to murine neurotrophin receptor (p75). We have immortalized p75⁺ murine neural crest cells by expression of v-myc, and have isolated several clonal cell lines. These lines can be maintained in an undifferentiated state, or induced to differentiate by changing the culture conditions. One of these cell lines, MONC-1, is capable of generating peripheral neurons, glia, and melanocytic cells. Importantly, most individual MONC-1 cells are multipotent when analyzed at clonal density. The neurons that differentiate under standard conditions have an autonomic-like phenotype, but under different conditions can express markers of other peripheral neuronal lineages. These lines therefore exhibit a similar differentiation potential as their normal counterparts. Furthermore, they can be genetically modified or generated from mice of different genetic backgrounds, providing a useful tool for molecular studies of neural crest development. © 1997 John Wiley & Sons, Inc. J Neuroblol 32 : 722–746, 1997     

In vitro analysis of sympathetic neuron differentiation from chick neural crest cells

Sympathetic neuron differentiation was studied using a fluorescence histochemical assay to detect the appearance of cell-bound catecholamines. Results from in vitro organ cultures indicate that chick neural crest cells must interact with both ventral neural tube (defined throughout as the ventral neural tube plus the notochord) and somitic mesenchyme in order to differentiate into sympathoblasts. Somite, ventral neural tube, and crest were cultured transfilter in various combinations to define these tissue interactions more precisely. Results from these experiments indicate that neural crest cells must be contiguous to somite in order to differentiate into sympathoblasts, but ventral neural tube may act across a Millipore filter membrane (type TH, 25 μm thick) either on somite, crest, or both. To distinguish among these possibilities, somite was cultured transfilter to ventral tube for a short period, after which ventral tube was removed and fresh crest was added to the somite. The results from this and other experiments support the hypothesis that the ventral tube does not act directly on crest cells, but elicits a developmental change in somitic mesenchyme, which then promotes sympathoblast differentiation. To study the relationship of nerve growth factor (NGF) to the differentiation of sympathetic neurons, cultures of somite + crest were temporarily exposed transfilter to ventral tube, in the presence or the absence of exogenous NGF. The results of these and other experiments are consistent with the hypothesis that the continued presence of ventral tube is required to ensure the survival of the differentiating sympathetic neurons. With respect to this second function, ventral tube can be replaced by exogenous NGF.     

Ultrastructure of the cells of the neural crest

Ultrastructure of the neural crest cells (NCC) has been studied in 9-day-old white rat embryos. Mechanisms, determining the amount of the NCC that get out of the neuroepithelium of the nervous tube have been discussed. By means of ruthenium red components of the extracellular matrix are demonstrated in the area where the NCC get out and in the ventromedial pathway of migration. Certain peculiarities of ruthenium red fixation by the cells are presented.     

An assay system to study migratory behavior of cranial neural crest cells in Xenopus

An increasing number of genes are known to show expression in the cranial neural crest area. So far it is very difficult to analyze their effect on neural crest cell migration because of the lack of transplantation techniques. This paper presents a simple method to study the migratory behavior of cranial neural crest cells by homo- and heterotopic transplantations: Green fluorescent protein (GFP) RNA was injected into one blastomere of Xenopus laevis embryos at the 2-cell stage. The cranial neural crest area of stage 14 embryos was transplanted into the head or trunk region of an uninjected host embryo, and the migration was monitored by GFP fluorescence. The transplants were further examined by double immunostaining and confocal microscopy to trace migratory routes inside the embryo, and to exclude contaminations of grafts with foreign tissues. Our results demonstrate that we developed a highly efficient and reproducible technique to study the migratory ability of cranial neural crest cells. It offers the possibility to analyze genes involved in neural crest cell migration by coinjecting their RNA with that of GFP. Received: 28 September 1999 / Accepted: 17 November 1999     

Migration and proliferation of cultured neural crest cells in W mutant neural crest chimeras.

Chimeric mice, generated by aggregating preimplantation embryos, have been instrumental in the study of the development of coat color patterns in mammals. This approach, however, does not allow for direct experimental manipulation of the neural crest cells, which are the precursors of melanoblasts. We have devised a system that allows assessment of the developmental potential and migration of neural crest cells in vivo following their experimental manipulation in vitro. Cultured C57Bl/6 neural crest cells were microinjected in utero into neurulating Balb/c or W embryos and shown to contribute efficiently to pigmentation in the host animal. The resulting neural crest chimeras showed, however, different coat pigmentation patterns depending on the genotype of the host embryo. Whereas Balb/c neural crest chimeras showed very limited donor cell pigment contribution, restricted largely to the head, W mutant chimeras displayed extensive pigmentation throughout, often exceeding 50% of the coat. In contrast to Balb/c chimeras, where the donor melanoblasts appeared to have migrated primarily in the characteristic dorsoventral direction, in W mutants the injected cells appeared to migrate in the longitudinal as well as the dorsoventral direction, as if the cells were spreading through an empty space. This is consistent with the absence of a functional endogenous melanoblast population in W mutants, in contrast to Balb/c mice, which contain a full complement of melanocytes. Our results suggest that the W mutation disturbs migration and/or proliferation of endogenous melanoblasts. In order to obtain information on clonal size and extent of intermingling of donor cells, two genetically marked neural crest cell populations were mixed and coinjected into W embryos. In half of the tricolored chimeras, no co-localization of donor crest cells was observed, while, in the other half, a fine intermingling of donor-derived colors had occurred. These results are consistent with the hypothesis that pigmented areas in the chimeras can be derived from extensive proliferation of a few donor clones, which were able to colonize large territories in the host embryo. We have also analyzed the development of pigmentation in neural crest cultures in vitro, and found that neural tubes explanted from embryos carrying wt or weak W alleles produced pigmented melanocytes while more severe W genotypes were associated with deficient pigment formation in vitro.     

The origins of neural crest cells in the axolotl

We address the question of whether neural crest cells originate from the neural plate, from the epidermis, or from both of these tissues. Our past studies revealed that a neural fold and neural crest cells could arise at any boundary created between epidermis and neural plate. To examine further the formation of neural crest cells at newly created boundaries in embryos of a urodele (Ambystoma mexicanum), we replace a portion of the neural folds of an albino host with either epidermis or neural plate from a normally pigmented donor. We then look for cells that contain pigment granules in the neural crest and its derivatives in intact and sectioned host embryos. By tracing cells in this manner, we find that cells from neural plate transplants give rise to melanocytes and (in one case) become part of a spinal ganglion, and we find that epidermal transplants contribute cells to the spinal and cranial ganglia. Thus neural crest cells arise from both the neural plate and the epidermis. These results also indicate that neural crest induction is (at least partially) governed by local reciprocal interactions between epidermis and neural plate at their common boundary.