Coexpression of sensory and autonomic neurotransmitter traits by avian neural crest cells in vitro

This study shows that explants of quail neural crest cultured in a medium containing serum and chick embryo extract give rise to large numbers of cells expressing immunoreactivity for substance P (SP), a neuropeptide found in sensory neurons. These cells arise from cycling precursors, but do not appear to divide after expressing SP. The SP-positive cells in cranial neural crest cultures express both neurofilament and the Q211 antigen, but those in trunk cultures express only the Q211 antigen. In both cranial and trunk cultures, large subpopulations of the SP-positive cells express tyrosine hydroxylase and/or choline acetyltransferase, neurotransmitter markers characteristic of autonomic neurons. This finding argues against the idea that SP expression necessarily indicates commitment to the sensory neuron lineage. I further show that embryonic dorsal root ganglion (DRG) cells retain the ability to coexpress SP and tyrosine hydroxylase in vitro although to a lesser extent than do neural crest cells.     

Cell lineages in peripheral nervous system ontogeny: medium-induced modulation of neuronal phenotypic expression in neural crest cell cultures

Neural crest, taken from cephalic and trunk levels of quail embryos, was grown in vitro in conventional tissue culture medium (Dulbecco's modified Eagle's medium containing 15% fetal calf serum and either 2 or 15% chick embryo extract (CEE] or in a chemically defined serum- and CEE-free medium. Depending on the conditions employed, different types of neuronal or neuronlike cells developed in the cultures. Thus, in medium containing 15% CEE, adrenergic cells (identified by tyrosine hydroxylase immunoreactivity and catecholamine histofluorescence) emerged after 5-6 days. These cells lacked tetanus toxin binding sites and did not react with an antibody directed against 70-kDa neurofilament protein. In the fully defined medium, a neuronal cell type exhibiting neurofilament and substance P (SP) immunoreactivity differentiated from noncycling precursors within 1 or 2 days of culture. If serum was added to the medium, the neurites disintegrated and the neuronal cells ultimately died. By sequentially culturing neural crest, first in the wholly synthetic medium for 1-3 days and then in the conventional medium supplemented with serum and 15% CEE, the disappearance of the SP-positive neurons was followed, several days later, by the emergence of adrenergic cells. The majority of these cells and/or their precursors were found to undergo cell division in culture. We conclude that the cells expressing the adrenergic phenotype (characteristic of the sympathetic nervous system) and those displaying SP immunoreactivity, comparable to a category of neurons in dorsal root and cranial sensory ganglia, derive from distinct sets of precursors. Our results reinforce the contention, deduced from in ovo transplantation experiments (see N. M. Le Douarin, (1984) In Cellular and Molecular Biology of Neuronal Development (I. Black, Ed.), pp. 3-28. Plenum, New York), that at least two lineages, from which sensory and autonomic cell types are derived respectively, are segregated early during neural crest ontogeny and have extremely different survival and trophic requirements.     

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.     

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

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

Role of the transforming growth factor-β family in the expression of cranial neural crest-specific phenotypes

Cranial and trunk neural crest cells produce different derivatives in vitro. Cranial neural crest cultures produce large numbers of cells expressing fibronectin (FN) and procollagen I (PCol I) immunoreactivities, two markers expressed by mesenchymal derivatives in vivo. Trunk neural crest cultures produce relatively few FN or PCol I immunoreactive cells, but they produce greater numbers of melanocytes than do cranial cultures. Treatment of trunk neural crest cultures with transforming growth factor-β1 (TGF-β1) stimulates them to express both FN and PCol I immunoreactivities at levels comparable to those normally seen in cranial cultures and simultaneously decreases their expression of melanin. These observations raised the possibility that endogenous TGF-β is involved in specifying differences in the phenotypes expressed by cranial and trunk neural crest cells in vitro. Consistent with this idea, we found that treatment of cranial cultures with a function-blocking TGF-β antiserum inhibits the development of FN immunoreactive cells and stimulates the development of melanocytes. Cranial and trunk neural crest cells express approximately equal levels of TGF-β mRNA. However, trunk neural crest cells are significantly less sensitive to the FN-inducing effect of TGF-β1 than are cranial neural crest cells. These results suggest that: (1) endogenous TGF-β is required for the expression of mesenchymal phenotypes by cranial neural crest cells, and (2) differences in the phenotypes expressed by cranial and trunk neural crest cells in vitro result in part from differences in the sensitivities of these two cell populations to TGF-β. © 1995 John Wiley & Sons, Inc.     

Embryonic origin of substance P containing neurons in cranial and spinal sensory ganglia of the avian embryo

The ontogeny of the neurons exhibiting substance P-like immunoreactivity (SPLI) was examined in the spinal and cranial sensory ganglia of chick and quail embryos. It was shown that in dorsal root ganglia (DRG) virtually all neuronal somas occupying the mediodorsal (MD) region of the ganglia are SPLI-positive while the larger neurons of the lateroventral (LV) area are SPLI-negative. In the cranial nerve ganglia, both types of neurons coexist in the trigeminal ganglion but with a different distribution: small neurons with SPLI are proximal while large neurons without SPLI occupy the maxillomandibular and ophthalmic lobes. The distal ganglia of nerves VII and IX (i.e., geniculate, petrosal) do not show cell bodies with SPLI in the two species considered. A few of them only (about 12%) are found in the nodose (distal ganglion of nerve X). The proximal ganglia of nerves IX and X (i.e., superior-jugular complex) are composed of small neurons which virtually all exhibit SPLI. Chimaeric cranial sensory ganglia were constructed by grafting the quail hind-brain primordium into chick embryos. Revelation of SPLI was combined with acridine orange staining on the same sections in order to ascertain the placodal (chick host) or neural crest (quail donor) origin of the SP-positive neurons in each type of ganglion. We found that all the neurons showing SPLI are derived from the neural crest in the trigeminal and in the superior and jugular ganglia. In the geniculate, petrosal, and nodose all the neurons are derived from the placodal ectoderm. The small number of SPLI-positive cells of the nodose ganglia are not an exception to this rule. Therefore, generally speaking, the sensory neurons of the cranial ganglia that express the SP phenotype are derived from the crest, with the exception of some neurons present in the nodose of both quail and chick embryos and which are of placodal origin. The vast majority of placode-derived neurons do not have amounts of SP that can be detected under the conditions of the present study.     

Pax3-expressing trigeminal placode cells can localize to trunk neural crest sites but are committed to a cutaneous sensory neuron fate

The cutaneous sensory neurons of the ophthalmic lobe of the trigeminal ganglion are derived from two embryonic cell populations, the neural crest and the paired ophthalmic trigeminal (opV) placodes. Pax3 is the earliest known marker of opV placode ectoderm in the chick. Pax3 is also expressed transiently by neural crest cells as they emigrate from the neural tube, and it is reexpressed in neural crest cells as they condense to form dorsal root ganglia and certain cranial ganglia, including the trigeminal ganglion. Here, we examined whether Pax3+ opV placode-derived cells behave like Pax3+ neural crest cells when they are grafted into the trunk. Pax3+ quail opV ectoderm cells associate with host neural crest migratory streams and form Pax3+ neurons that populate the dorsal root and sympathetic ganglia and several ectopic sites, including the ventral root. Pax3 expression is subsequently downregulated, and at E8, all opV ectoderm-derived neurons in all locations are large in diameter, and virtually all express TrkB. At least some of these neurons project to the lateral region of the dorsal horn, and peripheral quail neurites are seen in the dermis, suggesting that they are cutaneous sensory neurons. Hence, although they are able to incorporate into neural crest-derived ganglia in the trunk, Pax3+ opV ectoderm cells are committed to forming cutaneous sensory neurons, their normal fate in the trigeminal ganglion. In contrast, Pax3 is not expressed in neural crest-derived neurons in the dorsal root and trigeminal ganglia at any stage, suggesting either that Pax3 is expressed in glial cells or that it is completely downregulated before neuronal differentiation. Since Pax3 is maintained in opV placode-derived neurons for some considerable time after neuronal differentiation, these data suggest that Pax3 may play different roles in opV placode cells and neural crest cells.     

Altered neuronal lineages in the facial ganglia of Hoxa2 mutant mice

Neurons of cranial sensory ganglia are derived from the neural crest and ectodermal placodes, but the mechanisms that control the relative contributions of each are not understood. Crest cells of the second branchial arch generate few facial ganglion neurons and no vestibuloacoustic ganglion neurons, but crest cells in other branchial arches generate many sensory neurons. Here we report that the facial ganglia of Hoxa2 mutant mice contain a large population of crest-derived neurons, suggesting that Hoxa2 normally represses the neurogenic potential of second arch crest cells. This may represent an anterior transformation of second arch neural crest cells toward a fate resembling that of first arch neural crest cells, which normally do not express Hoxa2 or any other Hox gene. We additionally found that overexpressing Hoxa2 in cultures of P19 embryonal carcinoma cells reduced the frequency of spontaneous neuronal differentiation, but only in the presence of cotransfected Pbx and Meis Hox cofactors. Finally, expression of Hoxa2 and the cofactors in chick neural crest cells populating the trigeminal ganglion also reduced the frequency of neurogenesis in the intact embryo. These data suggest an unanticipated role for Hox genes in controlling the neurogenic potential of at least some cranial neural crest cells.     

Gangliosides and neuronal differentiation.

Using the GD3-specific mAb R24 we demonstrate by immunohistochemistry that the first embryonic cells of chicken expressing GD3 represent heavily proliferating cells of mesodermal origin (mesenchymal stem and endothelial cells). At this developmental stage (E1-1.5) neuroectodermal cells of the forming neural tube are not stained by R24 or any other available anti-ganglioside antibodies. These cells of the neural tube start to express GD3 at around E1.5 in parallel with increasing proliferative activity. Likewise proliferating and migrating neuronal crest derivates as well as undifferentiated retinal cells, the forming lens and otic placodes increasingly express GD3 in an organ-specific pattern following the spatiotemporal increase in mitotic activity. Immunostaining of GD1b (mAb D21b) or c-pathway polysialogangliosides (mAb Q211) is not obtained before E2.5, is nervous tissue specific and restricted to "new-born" neurons, which start to migrate and form first neurites. This striking change in ganglioside synthesis and expression also occurs in primary cell cultures (after or without previous Q211-mediated complement kill of neurons) during differentiation of mitotic progenitor cells to neurons (neurogenesis). In cell culture, the fluorescence staining is evenly distributed over the whole neuronal surface including filopodia at the growth cones. Monensin (10(-8) M) prevents expression of GD1b and c-polysialogangliosides and simultaneously differentiation of neuronal morphology (neurogenesis). The presence of exogenous gangliosides from bovine brain leads to a decrease of the monensin effect or even abolishes it.     

Neuregulin-mediated ErbB3 signaling is required for formation of zebrafish dorsal root ganglion neurons

Dorsal root ganglia (DRGs) arise from trunk neural crest cells that emerge from the dorsal neuroepithelium and coalesce into segmental streams that migrate ventrally along the developing somites. Proper formation of DRGs involves not only normal trunk neural crest migration, but also the ability of DRG progenitors to pause at a particular target location where they can receive DRG-promoting signals. In mammalian embryos, a receptor tyrosine kinase proto-oncogene, ErbB3, is required for proper trunk neural crest migration. Here, we show that in zebrafish mutants lacking ErbB3 function, neural crest cells do not pause at the location where DRGs normally form and DRG neurons are not generated. We also show that these mutants lack trunk neural crest-derived sympathetic neurons, but that cranial neural crest-derived enteric neurons appear normal. We isolated three genes encoding neuregulins, ErbB3 ligands, and show that two neuregulins function together in zebrafish trunk neural crest cell migration and in DRG formation. Together, our results suggest that ErbB3 signaling is required for normal migration of trunk, but not cranial, neural crest cells.     

Tissue effects on the expression of serotonin, tyrosine hydroxylase and GABA in cultures of neurogenic cells from the neuraxis and branchial arches

The phenotypically diverse neurones of the enteric nervous system are developmentally derived from precursors that migrate to the bowel from the vagal and sacral regions of the neuraxis. In order to gain insight into the generation of enteric neuronal diversity, we examined the expression of serotonin (5-HT), tyrosine hydroxylase and GABA in vitro. In the mature avian intestine, intrinsic neurones contain 5-HT or GABA but not tyrosine hydroxylase. These markers were demonstrated immunocytochemically, singly or simultaneously. All three phenotypic markers developed in cultures of cranial, vagal or truncal neural crest when the cultures were grown in enriched medium, containing horse serum and chick embryo extract; however, 5-HT and GABA, but not tyrosine hydroxylase-immunoreactive cells, also developed in cultures that were grown in partially defined medium. Tyrosine hydroxylase immunoreactivity was seen when partially defined medium was supplemented with nerve growth factor (NGF). Cultures of branchial arches (III and IV) contained cells that displayed tyrosine hydroxylase immunoreactivity, but not that of 5-HT- or GABA-; however, 5-HT immunoreactivity was seen when branchial arches were cocultured with aneuronal hindgut (from 4-day chick embryos). Cultures of cells from chick gut dissociated at 7 days contained tyrosine hydroxylase as well as 5-HT and GABA immunoreactivities; however, no cultures of bowel dissociated at 8 days or later expressed tyrosine hydroxylase immunoreactivity. When neuraxial cells were cocultured with branchial arches or heart instead of gut, no 5-HT-immunoreactive cells were seen; nevertheless, the further addition of explants of gut to the heart/crest cocultures did permit the expression of 5-HT immunoreactivity. These results are consistent with the hypotheses that precursors with the potential to give rise to cells that express 5-HT, GABA and tyrosine hydroxylase are found at several levels of the neuraxis; however, the ability to express these phenotypes may be suppressed either while the crest cells are migrating (for example, 5-HT and GABA expression by crest cells passing through the branchial arches) or in their final destination (for example, tyrosine hydroxylase in the gut). This suppression may be transient and reversed by the microenvironment of the target organs.     

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.     

Dual function of Slit2 in repulsion and enhanced migration of trunk,but not vagal,neural crest cells

Neural crest precursors to the autonomic nervous system form different derivatives depending upon their axial level of origin; for example, vagal, but not trunk, neural crest cells form the enteric ganglia of the gut. Here, we show that Slit2 is expressed at the entrance of the gut, which is selectively invaded by vagal, but not trunk, neural crest. Accordingly, only trunk neural crest cells express Robo receptors. In vivo and in vitro experiments demonstrate that trunk, not vagal, crest cells avoid cells or cell membranes expressing Slit2, thereby contributing to the differential ability of neural crest populations to invade and innervate the gut. Conversely, exposure to soluble Slit2 significantly increases the distance traversed by trunk neural crest cells. These results suggest that Slit2 can act bifunctionally, both repulsing and stimulating the motility of trunk neural crest cells.     

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.     

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.