Basic fibroblast growth factor stimulates survival of nonneuronal cells developing from trunk neural crest

FGF2 Stimulates the Growth and Improves the Melanocytic Commitment of Trunk Neural Crest Cells

Neural crest cells (NCCs) comprise a population of multipotent progenitors and stem cells at the origin of the peripheral nervous system (PNS) and melanocytes of skin, which are profoundly influenced by microenvironmental factors, among which is basic fibroblast growth factor 2 (FGF2). In this work, we further investigated the role of this growth factor in quail trunk NC morphogenesis and demonstrated its huge effect in NCC growth mainly by stimulating cell proliferation but also reducing cell death, despite that NCC migration from the neural tube explant was not affected. Moreover, following FGF2 treatment, reduced expression of the early NC markers Sox10 and FoxD3 and improved proliferation of HNK1-positive NCC were observed. Since these markers are involved in the regulation of glial and melanocytic fate of NC, the effect of FGF2 on NCC differentiation was investigated. Therefore, in the presence of FGF2, increased proportions of NCCs positives to the melanoblast marker Mitf as well as NCCs double stained to Mitf and BrdU were recorded. In addition, treatment with FGF2, followed by differentiation medium, resulted in increased expression of melanin and improved proportion of melanin-pigmented melanocytes without alteration in the glial marker Schwann myelin protein (SMP). Taken together, these data further reveal the important role of FGF2 in NCC proliferation, survival, and differentiation, particularly in melanocyte development. This is the first demonstration of FGF2 effects in melanocyte commitment of NC and in the proliferation of Mitf-positive melanoblasts. Elucidating the differentiation process of embryonic NCCs brings us a step closer to understanding the development of the PNS and then undertaking the search for advanced technologies to prevent, or treat, injuries caused by NC-related disorders, also known as neurocristopathies.

A local source of FGF initiates development of the unmyelinated lineage of sensory neurons

The principle by which unmyelinated primary sensory neurons transducing thermal, itch and pain perception are specified in early development is unknown. These classes of sensory neurons diversify from a common population of late-born neurons, which initiate expression of Runt homology domain transcription factor RUNX1 and the nerve growth factor receptor TrkA. Here, we report that signals emanating from within the mouse dorsal root ganglion mediated partly by early-born neurons destined to a myelinated phenotype participate in fating late-born RUNX1(+)/TrkA(+) neurons. Inductive factors include FGFs via activation of FGF receptor 1 (FGFR1). Consistently, FGF2 is sufficient to induce expression of RUNX1, and Fgfr1 conditional mutant mice display deficits in fating of the common population of late-born RUNX1(+)/TrkA(+) neurons that develop into unmyelinated neurons. Thus, the distinct lineages of sensory neurons are acquired in response to increasing FGF levels provided by a rising number of born neurons.

Epidermal growth factor (EGF) promotes the in vitro differentiation of neural crest cells to neurons and melanocytes

Proliferation of neural crest (NC) stem cells and their subsequent differentiation into different neural cell types are key early events in the development of the peripheral nervous system. Soluble growth factors present at the sites where NC cells migrate are critical to the development of NC derivatives in each part of the body. In the present study, we further investigate the effect of microenvironmental factors on quail trunk NC development. We show for the first time that EGF induces differentiation of NC to the neuronal and melanocytic phenotypes, while fibroblast growth factor 2 (FGF2) promotes NC differentiation to Schwann cells. In the presence of both EGF and FGF2, the neuronal differentiation predominates. Our results suggest that FGF2 stimulates gliogenesis, while EGF promotes melanogenesis and neurogenesis. The combination of both growth factors stimulates neurogenesis. These findings suggest that these two growth factors may play an important role in the fate decision of NC progenitors and in the development of the peripheral nervous system.

BMP and FGF-2 regulate neurogenin-2 expression and the differentiation of sensory neurons and glia

We have examined the effects of signaling molecules and Notch signaling on the mechanisms regulating neurogenin (ngn)-2 expression. This ngn-2 is a transcription factor that is essential for the specification of early differentiating sensory neurons in the dorsal root ganglia. In the presence of bone morphogenetic protein (BMP), anti-ngn-2-positive cells appeared in mouse trunk neural crest cell cultures, and they expressed Brn3, indicating that ngn-2-expressing cells are sensory neurons. These cells did not differentiate after fibroblast growth factor (FGF)-2 treatment or after Notch activation. The suppression of ngn-2 expression by FGF-2 was recovered by treatment with a Notch signaling inhibitor. Thus, FGF-2 may prevent ngn-2 expression through Notch activation. Whereas BMP-4 inhibited glial differentiation, FGF-2 promoted gliogenesis by means of Notch activation. Our data suggest that BMP and FGF-2 act as positive and negative regulators in ngn-2 expression, respectively, and that these signaling molecules regulate the differentiation of sensory neurons and glia.

Neural crest delamination and migration: integrating regulations of cell interactions, locomotion, survival and fate

During the entire process of neural crest development from specification till final differentiation, delamination and migration are critical steps where nascent crest cells face multiple challenges: within a relatively short period of time that does not exceed several hours, they have to change drastically their cell- and substrate-adhesion properties, lose cell polarity and activate the locomotory machinery, while keeping proliferating, surviving and maintaining a pool of precursors in the neural epithelium. Then, as soon as they are released from the neural tube, neural crest cells have to adapt to a new, rapidly-changing environment and become able to interpret multiple cues which guide them to appropriate target sites and prevent them from distributing in aberrant locations. It appears from recent studies that, behind an apparent linearity and unity, neural crest development is subdivided into several independent steps, each being governed by a multiplicity of rules and referees. Here resides probably one of the main reasons of the success of neural crest cells to accomplish their task.

Tamoxifen-induced cell death and expression of neurotrophic factors in cultured C6 glioma cells

The effects of ( Z)-2[ p -(1,2-diphenyl-1-butenyl)phenoxy]-N ,N -dimethylamine citrate (tamoxifen) on cell survival and the expression of neurotrophic factors (NTF) were investigated in rat C6 glioma cells (C6). C6 cells do not express the estrogen receptor. Cytotoxic effect was detected from 24 h after the treatment with 10 microM tamoxifen and increased with time in a dose-dependent manner. C6 cells treated with tamoxifen also displayed various morphological types such as elliptical, round and aggregated form. As the treatment time increased, the proliferation of C6 cells was reduced remarkably and most of them became the round or aggregated form. To examine the relationship of the expression of NTF and the cytotoxicity of tamoxifen, the mRNA level of brain-derived neurotrophic factor (BDNF), glial-derived neurotrophic factor (GDNF), and basic fibroblast growth factor (bFGF) was measured after 24 h treatment with tamoxifen by RT-PCR. The expression of mRNA of BDNF or GDNF in C6 cells treated with various concentrations of tamoxifen was comparable to controls. The expression of bFGF mRNA was significantly reduced in C6 cells treated with 10 or 15 microM tamoxifen. The results suggest that tamoxifen exerts cytotoxic effect on estrogen receptor-negative C6 cells through the inhibition of the transcription of bFGF.

Dct::lacZ ES Cells: A Novel Cellular Model to Study Melanocyte Determination and Differentiation

Embryonic stem (ES) cells differentiate into various cell lineages in vitro. A procedure was previously designed to promote the differentiation of ES cells towards the melanocyte lineage and to obtain large and reproducible amounts of melanocytes. To elucidate the main events that lead to the development of melanocytes in vitro, we used transgenic Dct::lacZ mouse blastocysts to establish ES cell lines expressing the lacZ reporter gene under the control of the Dct promoter. Dct, a melanoblast marker, is expressed just after melanoblast determination in vivo. We evaluated the importance of recruitment, proliferation and differentiation during melanocyte ontogeny after the in vitro differentiation of Dct::lacZ ES cells into melanocytes. We showed that bFGF and cholera toxin induce precocious melanoblast determination, associated with early melanocyte differentiation. Edn3 induced melanoblast proliferation and long-term melanoblast recruitment, but not precocious determination. The lack of basic Fibroblast Growth Factor (bFGF) and cholera toxin can be partially compensated by Edn3. Thus, Dct::lacZ ES cells can be used as a model to study determination, proliferation and differentiation in the melanocyte lineage in vitro.

Fgf signalling is required for formation of cartilage in the head

Characterisation of human craniofacial syndromes and studies in transgenic mice have demonstrated the requirement for Fgf signalling during morphogenesis of membrane bone of the cranium. Here, we report that Fgf activity is also required for development of the oro-pharyngeal skeleton, which develops first as cartilage with some elements subsequently becoming ossified. We show that inhibition of FGF receptor activity in the zebrafish embryo following neural crest emigration from the neural tube results in complete absence of neurocranial and pharyngeal cartilages. Moreover, this Fgf signal is required during a 6-h period soon after initiation of neural crest migration. The spatial and temporal expression of Fgf3 and Fgf8 in pharyngeal endoderm and ventral forebrain and its correlation with patterns of Fgf signalling activity in migrating neural crest makes them candidate regulators of cartilage development. Inhibition of Fgf3 results in the complete absence of cartilage elements that normally form in the third, fourth, fifth, and sixth pharyngeal arches, while those of the first, second, and seventh arches are largely unaffected. Inhibition of Fgf8 alone has variable, but mild, effects. However, inhibition of both Fgf3 and Fgf8 together causes a complete absence of pharyngeal cartilages and the near-complete loss of the neurocranial cartilage. These data implicate Fgf3 and Fgf8 as key regulators of cartilage formation in the vertebrate head.

The trunk neural crest and its early glial derivatives: a study of survival responses, developmental schedules and autocrine mechanisms

Regulation of survival during gliogenesis from the trunk neural crest is poorly understood. Using adapted survival assays, we directly compared crest cells and the crest-derived precursor populations that generate satellite cells and Schwann cells. A range of factors that supports Schwann cells and glial precursors does not rescue crest, with the major exception of neuregulin-1 that rescues crest cells provided they contact the extracellular matrix. Autocrine survival appears earlier in developing satellite cells than Schwann cells. Satellite cells also show early expression of S100beta, BFABP and fibronectin and early survival responses to IGF-1, NT-3 and PDGF-BB that in developing Schwann cells are not seen until the precursor/Schwann cell transition. These experiments define novel differences between crest cells and early glia and show that entry to the glial lineage is an important point for regulation of survival responses. They show that survival mechanisms among PNS glia differ early in development and that satellite cell development runs ahead of schedule compared to Schwann cells in several significant features.

In vivo and in vitro localization of brain-derived neurotrophic factor, fibroblast growth factor-2 and their receptors in the bullfrog vestibular end organs

The inner ear sensory epithelia of vertebrates are composed mainly of supporting cells and hair cells (HCs). Brain-derived neurotrophic factor (BDNF) and fibroblast growth factor-2 (FGF-2) are trophins that are believed to play an essential role in the development and innervation of inner ear epithelia. Both trophins also may play a crucial role in the maintenance and regeneration of hair cells in the adult vertebrate ear. In the bullfrog vestibular system, hair cells are produced throughout life, and the epithelia regenerates following ototoxicity. The expression of BDNF and FGF-2 in the vestibular organs of the adult bullfrog was investigated at a cellular level both in histological sections and in vitro in dissociated cell cultures. In histological sections of the crista ampullaris, in situ hybridization and immunocytochemical techniques demonstrated that HCs express both BDNF and its receptor trkB, while the supporting cells express the receptor trkB alone. Following dissociation and in vitro cell culture no changes in the pattern of BDNF and trkB receptor were observed. Immunocytochemical studies demonstrated that in vivo hair cells express FGF-2 and the receptors FGFR-1 and FGFR-2 while supporting cells do not express either molecule. Following dissociation, HCs continue to express FGF-2 and its two receptors, while supporting cells upregulate the expression of FGF-2 and its receptor FGFR-2. These data confirm the potential role of BDNF and FGF-2 trophic regulation of the sensory epithelia of the adult inner ear. The findings suggest that BDNF has a role in the maintenance of the vestibular epithelia while FGF-2 may regulate the proliferation of supporting cells.

Neurogenesis in postnatal mouse dorsal root ganglia

Neurogenesis continues in various regions of the central nervous system (CNS) throughout life. As the mitogen basic fibroblast growth factor (bFGF) can proliferate neuronal precursors of CNS neurons in culture, and is also upregulated within adult dorsal root ganglia following axotomy, it is possible that the postnatal dorsal root ganglia contain bFGF-responsive neuronal precursors. We undertook cell culture of postnatal mouse dorsal root ganglia to demonstrate neurogenesis. Basic FGF induced a cellular proliferative response in dorsal root ganglia cell culture. After 2 weeks in serum-free medium containing bFGF, neurons were rarely observed. However, following removal of bFGF and addition of trophic factors, many cells were observed that morphologically resembled dorsal root ganglia neurons, stained for neuronal markers, and generated action potentials. Furthermore, bromodeoxyuridine, used as a marker of cytogenesis, was detected in neurofilament-160(+) and/or microtubule-associated protein-2(+) cells that morphologically resembled neurons. In addition to bFGF, epidermal growth factor, nerve growth factor, and sonic hedgehog were also capable of generating spherical cell clusters that contained cells that stained for neuronal markers following the addition of trophic factors. These results suggest that early postnatal dorsal root ganglia contain neural precursors that appear to proliferate in response to various factors and can then be induced to differentiate into neurons. In conclusion, the existence of neural precursors and the possibility of neurogenesis in postnatal dorsal root ganglia may provide a greater range of plasticity available to somatosensory systems during growth or following injury, perhaps to replace ineffectual or dying neurons.

Prenatal localization of the dorsal root ganglion in different segments of the normal human vertebral column

STUDY DESIGN

Vertebral columns from 11 normal human fetuses (10-24 weeks of gestation) derived from spontaneous abortions were examined as part of the legal autopsy procedure including spinal cord analysis.

OBJECTIVES

To study the localization of the dorsal root ganglion in the normal fetal spine and to relate the dorsal root ganglion location to the ossification of the vertebral bodies and vertebral arches.

SUMMARY OF BACKGROUND DATA

The normal and pathologic ossification pattern of the fetal human spine has been studied. There has been no study addressing the localization of the dorsal root ganglion in normal and pathologic axial development.

METHODS

The dorsal root ganglion were studied by using histology (horizontal sections) and morphometric measurement.

RESULTS

The study showed: 1) The dorsal root ganglion appeared before ossification of the spine; 2) The dorsal root ganglion had an oval shape in all cases; 3) The longitudinal axis of dorsal root ganglion was directed anterolaterally in the cervical and lumbosacral segments and mainly laterally in the thoracic segment; 4) During development, the dorsal root ganglion changed position according to the body axis; and 5) The para-axial ossification protected the dorsal root ganglion differently in the different axial segments.

CONCLUSIONS

The dorsal root ganglion appeared before ossification. The distance from the dorsal root ganglion to the body axis increased during development. In the different segments of the spine, different orientations and different locations of the dorsal root ganglion were observed in relation to osseous spine components. The results can be used as reference data for future studies on the dorsal root ganglion in pathologic spines.

Glial growth factor-2 promotes the survival, migration and bromodeoxyuridine incorporation of mammalian neural crest cells in caudal neural tube explant cultures

Using an in vitro assay system, we found that GGF-2 increases the number of nascent trunk neural crest cells (NCC) present in the dorsal outgrowth derived from E12 caudal neural tube explants. Data is presented which suggests that this increased outgrowth was due to a combination of GGF-2 mediated effects, including its ability to promote (A) NCC survival by decreasing the percentage of NCC that undergo cell death via a mechanism involving DNA fragmentation, (B) the initial phases of NCC migration, (C) mitosis of peripherally migrating NCC. We also show that GGF-2 can promote the long-term survival of NCC in the absence of the neural tube. An immunohistochemical analysis indicates that NCC express erbB-2 and erbB-4 neuregulin receptors.

Early migratory rat neural crest cells express functional gap junctions: evidence that neural crest cell survival requires gap junction function

Gap junctions mediate crucial intercellular interactions during development. This study provides evidence that early migrating rat neural crest cells assemble functional gap junctions, as demonstrated by dye transfer following microinjection of single cells, which were phenotypically identified as neural crest cells by their expression of the low- affinity nerve growth factor receptor. An immunohistochemical analysis using connexin- specific antibodies revealed that migrating rat neural crest cells express the gap junction constituents connexins 43 (Cx 43) and Cx 46. We tested the hypothesis that gap junctions play an important role during early neural crest cell development by perturbing their function in migrating neural crest cells. Our data show that markedly decreasing gap junction communication between these neural crest cells in vitro with either 18alpha-glycyrrhetinic acid or anandamide decreases their survival, whereas oleamide, a less effective blocker of connexon function, had quantitatively less effect on neural crest cell death. This cell death was associated with the occurrence of DNA nicking as detected by the terminal deoxynucleotidyl transferase (TdT)-mediated dUTP-biotin nick end-labelling (TUNEL) procedure, suggesting cell death via apoptosis. The effect of 18alpha-glycyrrhetinic acid and anandamide on neural crest cell survival was reversible and was not mimicked by the structurally related compounds glycyrrhizic acid and palmitoylethanolamide, respectively, which do not uncouple cells. These results indicate that gap junctions are necessary for the survival of spinal neural crest cells.

In vitro identification of dividing neuronal precursors from chick embryonic ciliary ganglion

In chick parasympathetic ciliary ganglion the neuronal birthdate is well defined, between 2.5 and 5.5 days of embryonic development, and neuronal precursor cells that are able to differentiate into neurons in vitro can be isolated from E4.5 ganglia. In this report, using bromodeoxyuridine incorporation and Maplb immunostaining, we demonstrate that these cells can be isolated from E7-E8 chick embryos as well, suggesting that neuronal precursor cells are still present in the ciliary ganglion after the end of the in vivo neurogenesis. These precursor cells retain the ability to divide and generate newly differentiated neurons in vitro when cultured in a chemically defined medium. Such a capacity is highly stimulated by bFGF but not by CNTF.

Chemotactic migration of mesencephalic neural crest cells in the mouse

We examined the roles of fibroblast growth factor (FGF)-2 and FGF-8 in the migration of mesencephalic mouse neural crest cells. Our in vitro migration assay has shown that FGF-2 (basic FGF) and FGF-8 have chemotactic activity for these cells. Chemotaxis was inhibited by anti-FGF-2 and anti-FGF-8 neutralizing antibodies. In addition, anti-FGF-2 blocked neural crest cell migration in cranial organ cultures. This observation suggests that FGF-2 functions as a chemoattractant in migration of mesencephalic neural crest cells in vivo. In organ culture, the antagonist of FGF binding to a low-affinity fibroblast growth factor receptor (FGFR) heparan sulfate, inositolhexakisphosphate (InsP6), inhibited migration as well. Mesencephalic neural crest cells had high-affinity FGFRs, in particular FGFR-1 and FGFR-3. Thus, the chemotactic activities of FGF-2 can be mediated by the low-affinity FGFR alone or by a combination of low- and high-affinity FGFRs (FGFR-1, FGFR-3, or both). Moreover, differential localization of FGF-2 was found at the mesencephalic axial level of intact embryos during neural crest cell migration. FGF-2 protein expression was predominant in the target regions, in particular the mandibular mesenchyme, that are colonized by mesencephalic neural crest cells. This characteristic distribution supports the notion that FGF-2 acts as a chemoattractant in the mouse embryo that directs mesencephalic neural crest cell migration. Whereas FGF-8 showed chemotactic activity in vitro, neural crest cell dispersion was observed in explants that had been treated with anti-FGF-8 neutralizing antibodies. This result suggests that FGF-8 may not be a chemoattractant in vivo. However, the distribution of neural crest cells in explants treated with anti-FGF-8 differed from that in control explants or in intact embryos. Extreme FGF-2 distribution was observed in the mandibular arch and FGF-8 is expressed in the epithelium. FGF-8 may play a role in mesencephalic neural crest cell migration, and its role may be concerned with the differential localization of FGF-2. To establish this notion, we performed immunohistochemical examination of FGF-2 distribution in explants treated with FGF-8 and analysis of FGF-2 gene expression levels by reverse transcriptase-polymerase chain reaction by using RNA from explants. The data indicate that FGF-2 is distributed throughout the mesenchyme in FGF-8-treated explants and that expression of FGF-2 is promoted by FGF-8. Therefore, we conclude that the expression of FGF-8 in the mandibular arch epithelium is a prerequisite for the differential localization of FGF-2 and that the FGF-2 distribution pattern is essential for chemotaxis of mesencephalic neural crest cell migration.

Cre-mediated gene inactivation demonstrates that FGF8 is required for cell survival and patterning of the first branchial arch

In mammals, the first branchial arch (BA1) develops into a number of craniofacial skeletal elements including the jaws and teeth. Outgrowth and patterning of BA1 during early embryogenesis is thought to be controlled by signals from its covering ectoderm. Here we used Cre/loxP technology to inactivate the mouse Fgf8 gene in this ectoderm and have obtained genetic evidence that FGF8 has a dual function in BA1: it promotes mesenchymal cell survival and induces a developmental program required for BA1 morphogenesis. Newborn mutants lack most BA1-derived structures except those that develop from the distal-most region of BA1, including lower incisors. The data suggest that the BA1 primordium is specified into a large proximal region that is controlled by FGF8, and a small distal region that depends on other signaling molecules for its outgrowth and patterning. Because the mutant mice resemble humans with first arch syndromes that include agnathia, our results raise the possibility that some of these syndromes are caused by mutations that affect FGF8 signaling in BA1 ectoderm.

Apoptosis in the chick wing bud and the permanence of FGF-2 rescue

Two regions of programmed cell death that occur in the mesoderm of developing chick wing buds were studied in vitro. The opaque patch (OP) and posterior necrotic zone (PNZ) were examined for the presence of internucleosomal DNA degradation and for rescue by protein synthesis inhibition, two defining characteristics of apoptosis. Agarose gel electrophoresis showed that DNA from OP and PNZ tissue was cleaved into nucleosome size pieces and this cleavage was prevented by inhibition of protein synthesis with cycloheximide. Both regions showed rescue with cycloheximide as determined by the chromium release assay and examination of electron micrographs. Also, the permanence of basic fibroblast growth factor (EGF-2) rescue in the OP and NPZ was examined using the chromium release assay. While rescue in the OP was found to be permanent, rescue in the PNZ only delayed death while FGF-2 was present in the culture medium. This research shows that death in the OP and PNZ exhibits internucleosomal DNA fragmentation and is prevented by inhibition of protein synthesis with cycloheximide, biochemically characterizing this death as apoptosis. It also suggests that in vitro FGF-2 rescue is permanent in the OP but is merely a delay of cell death in the PNZ.

The avian embryo as a model in developmental studies: chimeras and in vitro clonal analysis

The avian embryo is a model in which techniques of experimental embryology and cellular and molecular biology can converge to address fundamental questions of development biology. The first part of the chapter describes two examples of transplantation and cell labeling experiments performed in ovo. Thanks to the distinctive histologic and immunocytochemical characteristics of quail and chick cells, the migration and development of definite cells are followed in suitably constructed chimeric quail-chick embryos. Isotopic transplantations of neural tube portions between quail and chick, combined with in situ hybridization with a nucleic probe specific for a quail oligodendrocyte marker, allowed study of the origin and migration of oligodendroblasts in the spinal cord. Heterotopic transplantations of rhombomeres were performed to establish the degree of plasticity of these segments of the hindbrain regarding Hox gene expression, which was revealed by labeling with chick-specific nucleic probes. The second part describes in vitro cell cloning experiments devised to investigate cell lineage segregation and diversification during development of the NC. An original cloning procedure and optimal culture conditions permitted analysis of the developmental potentials of individual NC cells taken at definite migration stages. The results revealed a striking heterogeneity of the crest cell population, which appeared to be composed of precursors at different states of determination. Clonal cultures also provide a means to identify subsets of cells that are the target of environmental factors and to understand how extrinsic signals influence the development of responsive cells.

The control of cell death in the early chick embryo wing bud

Developmentally programmed cell death occurs in several regions of the chick wing bud. We have studied the nature and control of this cell death in vitro in tissues from two of these regions, the posterior necrotic zone (PNZ) and the opaque patch (OP). When tissue from these regions is excised prior to normal cell death and placed into organ culture, cell death ensues. Under these conditions, cell death in tissue from both of these regions is inhibited by fibroblast growth factor-2 (FGF-2). The only other growth factor we have found to have this function is insulin-like growth factor-II. Cell death in tissue from the OP and PNZ occurs by apoptosis, as indicated by the internucleosomal degradation of DNA and the inhibition of cell death by cycloheximide, an inhibitor of protein synthesis. If cell death is inhibited by FGF-2 and then the growth factor is washed away, a compensatory burst of cell death occurs in the PNZ tissue but not the OP tissue. This finding may indicate that in the PNZ, a death program progresses in the face of FGF-2 inhibition, resulting in more cells on the brink of death when the growth factor is removed.

A paracrine effect for neuron-derived BDNF in development of dorsal root ganglia: stimulation of Schwann cell myelin protein expression by glial cells

Addition of neurons to cultures of non-neuronal cells derived from quail embryonic dorsal root ganglia causes a 2.5-fold increase in the proportion of cells that express the glial marker Schwann cell myelin protein (SMP) when compared to cultures devoid of neurons. This effect is mediated by BDNF because incubation with a trkB immunoadhesin that sequesters BDNF, but not with trkA or trkC immunoadhesins, abolishes this stimulation. This neuronal activity can be mimicked by treatment with soluble BDNF that stimulates specifically the conversion of SMP-negative glial cells into cells that express this phenotype. That BDNF is the endogenous neuron-derived factor affecting glial development is further supported by the observation that BDNF is extensively expressed in developing sensory neurons of the avian ganglia both in vivo and in vitro, but not by the satellite cells. These results show for the first time a paracrine role for neuronal BDNF on differentiation of peripheral glial cells. This effect of BDNF is likely to be mediated by the p75 neurotrophin receptor because: (1) p75 immunoreactive protein is expressed by a subset of satellite cells; (2) neutralization of p75 abolishes the BDNF-induced stimulation; (3) a treatment of non-neuronal cell cultures with equimolar concentrations of either soluble NGF or NT-3 also affects the proportion of cells that become SMP-positive. Whereas NGF stimulates the acquisition of this glial antigen to a similar extent as BDNF, NT-3 inhibits its expression, suggesting that distinct neurotrophins signal differentially through p75. These findings also suggest that the definitive phenotype of peripheral glia is determined by a balance between positive and inhibitory signals arising in adjacent neurons.

Spatial and temporal shifts in the regulation of neurogenesis in a peripheral ganglion

In the cardiac ganglion of the frog Xenopus laevis, the number of cholinergic neurons increases over several months. During this time, each neuron must insert itself into the control circuit of the functioning heart. Like all neurons, increases in cell number depend on the timing of both proliferation and differentiation of neuronal precursors. The characteristics of the cardiac ganglion provided an opportunity to test how proliferation and differentiation regulate the production of a specific population of neurons. The prolonged accumulation of cardiac neurons suggested that their site of origin shifted from the neural crest migratory pathway to the heart at later stages of development. 3H-thymidine labeling of neurons in organ culture confirmed that neuronal precursors in the heart divide over a period of at least 3 weeks of development. Quantitative analysis of individual cardiac neurons subjected to different labeling and sampling protocols provided an estimate of their cell cycle length. It also showed that the rate of neuron proliferation during normal development matched the rate of neuron accumulation. Labeling DNA and blocking its synthesis indicated that the time of cardiac neuron differentiation was variable, but the range did not change as the site of cardiac neurogenesis shifted. On the other hand, the regular proliferation of cardiac neuron precursors during the first few days of development slowed or stopped at later times. This change in regulation of neuronal precursor proliferation occurred during their change in location.

Endothelin-B receptor is expressed by neural crest cells in the avian embryo

Disruptions of the genes encoding endothelin 3 (EDN3) and its receptor endothelin-B receptor (EDNRB) in the mouse result in defects of two neural crest (NC)-derived lineages, the melanocytes, and the enteric nervous system. To assess the mechanisms through which the EDN3/EDNRB signaling pathway can selectively act on these NC derivatives, we have studied the spatiotemporal expression pattern of the EDNRB gene in the avian embryo, a model in which NC development has been extensively studied. For this purpose, we have cloned the quail homologue of the mammalian EDNRB cDNA. EDNRB transcripts are present in NC cells before and during their emigration from the neural tube at all levels of the neuraxis. At later developmental stages, the receptor remains abundantly expressed in the peripheral nervous system including the enteric nervous system. In a previous study, we have shown that EDN3 enhances dramatically the proliferation of NC cells when they are at the pluripotent stage. We propose that the selective effect of EDN3 or EDNRB gene inactivation is due to the fact that both melanocytes and enteric nervous system precursors have to colonize large embryonic areas (skin and bowel) from a relatively small population of precursors that have to expand considerably in number. It is therefore understandable that a deficit in one of the growth-promoting pathways of NC cells has more deleterious effects on long-range migrating cells than on the NC derivatives which develop close to the neural primordium like the sensory and sympathetic ganglia.

The role of neurotrophins in development of neural-crest cells that become sensory ganglia

A fundamental issue of neural-crest ontogeny is understanding how different types of cells are created at the right time and in the correct numbers. Sensory ganglia are among the many derivatives of the vertebrate neural crest. Their proper formation requires the regulation of several processes such as cell fate specification, proliferation, survival, and terminal differentiation. The timescale of the occurrence of processes involved in the regulation of cell number and identity, coincides with key morphogenetic events such as cell migration, homing and gangliogenesis. To gain insight into these processes, we characterized the cellular basis of metameric migration of neural-crest cells and of consequent ganglion organization, which are imposed by intrinsic differences within rostral and caudal sclerotomal compartments. We also established a transient requirement for neural tube-derived factors in regulating the proliferation, survival and differentiation of prospective DRG cells. Additionally, we showed that cooperation between the mesodermal cells and the neural tube is necessary for modulating cell number in the nascent ganglia. BDNF, NT-3 and basic FGF were found to mediate this environmental signalling. All the above factors display neurogenic activity for a subset of early-committed sensory neuron progenitors. This observation raises the possibility of an early redundancy in the response of individual neural-crest progenitors to distinct factors. This overlap in responsiveness progressively disappears upon the colonization of specific ganglionic sites and the subsequent establishment of selective innervation patterns by post-mitotic sensory neurons.

Number of adrenergic and islet-1 immunoreactive cells is increased in avian trunk neural crest cultures in the presence of human recombinant osteogenic protein-1

OP-1, also known as BMP-7, is a member of the TGF-beta superfamily of proteins and was originally identified on the basis of its ability to induce new bone formation in vivo. OP-1 mRNA is found in the developing kidney and adrenal gland as well as in some brain regions (Ozkaynak et al. [1991] Biochem. Biophys. Res. Commun. 179:116-123). We have tested the effect of recombinant human OP-1 on quail trunk neural crest cultures. The number of catecholamine-positive cells which developed after 7 days in vitro in the presence of OP-1 was increased in a dose-dependent manner, with a greater than 100-fold maximal stimulation observed. The increase in the number of catecholamine-positive cells in the presence of OP-1 was paralleled by an increase in the number of tyrosine hydroxylase (TH)-positive cells. In contrast, total and melanocyte cell number were unaffected by the presence of OP-1. The number of Islet-1-immunoreactive cells was also increased by OP-1, but to only about half the value seen for TH. Double label experiments revealed these Islet-1-positive cells were a subset of the TH-positive cells. Inhibitors of DNA synthesis prevented the OP-1-mediated increase in adrenergic cell number, indicating that OP-1 does not act on a postmitotic cell population. However, labeling studies with bromodeoxyuridine indicated that OP-1 did not increase the proportion of the cell population engaged in DNA synthesis. Thus, the OP-1-mediated increase in adrenergic cell number most likely occurs as a result of the enhanced survival of a subpopulation of adrenergic precursors or an increase in their probability of adrenergic differentiation, but not by increasing the mitotic rate of adrenergic precursors or adrenergic cells themselves. In contrast to OP-1, TGF-beta 1 decreased adrenergic cell number. When OP-1 and TGF-beta 1 were added simultaneously, TGF-beta 1 antagonized the OP-1-mediated increase in adrenergic cell number in a dose-dependent manner.

Basic fibroblast growth factor opens calcium-permeable channels in quail mesencephalic neural crest neurons

In order to investigate the action of basic fibroblast growth factor (bFGF) in the nervous system, we have studied the ionic signals elicited by this peptide in cultured quail mesencephalic neural crest neurons using patch-clamp and cytofluorimetric techniques. In this preparation stimulation with bFGF induced, with a delay of some tens of seconds, an inward cationic current. Single-channel experiments provided evidence for the activation of a calcium-permeable channel. In single-cell cytofluorimetric measurements, a sustained rise in [Ca2+]i was observed, which was dependent on the presence of external calcium. These events may play a role in the developmental effects of bFGF.

Fibroblast growth factors and insulin growth factors combine to promote survival of rat Schwann cell precursors without induction of DNA synthesis

In embryonic rat nerves, we recently identified an early cell in the Schwann cell lineage, the Schwann cell precursor. We found that when these cells were removed from contact with axons they underwent rapid apoptotic death, and that in a proportion of the cells this death could be prevented by basic fibroblast growth factor (bFGF, FGF-2). We now report that 100% of Schwann cell precursors isolated from peripheral nerves of 14-day-old-rat embryos can be rescued by a combination of insulin-like growth factor (IGF) 1 or 2 in combination with either acidic FGF (aFGF, FGF-1), bFGF or Kaposi's sarcoma FGF (K-FGF; FGF-4). The precursors display an absolute requirement for both an IGF and an FGF to achieve maximal survival. Elevation of intracellular levels of cAMP by forskolin does not result in a significant shift in the IGF/FGF dose-response curves. In contrast, the percentage of precursors rescued by FGF in the presence of insulin is dramatically increased by elevation of cAMP. These growth factor combinations did not stimulate DNA synthesis significantly in Schwann cell precursors. These findings show that cooperation between growth factors is required to suppress cell death in Schwann cell precursors, and suggest that survival and DNA synthesis are regulated by distinct growth factor combinations in these cells. The observations are consistent with the idea that survival regulation by FGFs and IGFs plays an important role in the development of glial cells in early embryonic nerves.

FGF2 regulates proliferation of neural crest cells, with subsequent neuronal differentiation regulated by LIF or related factors

Two of the key early events in the development of the peripheral nervous system are the proliferation of neural crest precursor cells and their subsequent differentiation into different neural cell types. We present evidence that members of the fibroblast growth factor family, (FGF1 or FGF2) act directly on the neural crest cells in vitro to stimulate proliferation in the presence of serum. These findings correlate with in situ hybridisation analysis, which shows FGF2 mRNA is expressed in cells both in the neural tube and within newly formed sensory ganglia (dorsal root ganglia, DRG) at embryonic day 10 in the mouse, when neural crest precursors are proliferating within the DRG. This data infers an autocrine/paracrine loop for FGF regulation of proliferation. Evidence supporting this notion is provided by the finding that part of the endogenous proliferative activity in the NC cultures is related to FGF. It was also found, in early neural crest cultures, that exogenous FGF completely inhibited neuronal differentiation, probably as a direct consequence of its mitogenic activity. In order to stimulate neuronal differentiation significantly, it was necessary to remove the FGF and replace it with leukemia inhibitory factor (LIF) or related factors. Under these conditions, 50% of the cells differentiated into neurons, which developed a sensory neuron morphology and were immunoreactive for the sensory markers CGRP and substance P. These data support a model of neural crest development, whereby multipotential neural crest precursor cells are stimulated to divide by FGF and subsequent development into sensory neurons is regulated by LIF or other cytokines with a similar signalling mechanism.

Acidic and basic fibroblast growth factors delay the maturation of neural crest-derived neurons

Neural crest (NC) cultures were prepared from lumbosacral segments of 12 day rat embryos and maintained in a defined medium. Post-mitotic, flat, neurofilament+ neurons with broad neuritic processes ('nascent neurons') appeared within 24 h. Timing of the next stage in neuronal differentiation, the formation of bipolar, phase-bright cells that bound tetanus toxin with long, slender neurites ('bipolar neurons'), was markedly influenced by acidic or basic fibroblast growth factor (FGF). The transition from nascent to bipolar neuron occurred several days prematurely in medium without added FGF, but took place with a time-course like that in vivo when 10 ng/ml of acidic or basic FGF was added.

Fibroblast growth factors in the nervous system

Fibroblast growth factors (FGFs) exhibit widespread mitogenic and neurotrophic activities. Nine members of the family are currently known, and FGF-1 and FGF-2 are present in relatively high levels in CNS. FGF-1 is expressed by a subset of neuronal populations, while FGF-2 is expressed by astrocytes. FGF-1 and FGF-2 lack signal peptides and appear to be present mainly in intracellular compartments. This suggests that the factors may act as initiators of a repair response after injury. Support for this notion comes from observations that FGF-1 and FGF-2 levels are low during critical phases of development, but high in the adult CNS. A family of transmembrane tyrosine kinase receptors (FGFRs) mediates the effects of FGFs. Four different genes coding for FGF receptors are currently known, three of which are expressed in cell type-specific patterns in the CNS. The main receptor variants present in this tissue, however, can by themselves not distinguish between FGF-1 and FGF-2. Additional selectivity may be established by interaction of the FGFs and their receptors with select heparan proteoglycans (HSPGs). Therefore, the precise physiological role of FGFs is determined by the combination of cell type-specific patterns of expression of FGFs, FGFRs and HSPGs together with the mechanisms that regulate the extracellular availability of FGFs.

The Schwann cell precursor and its fate: a study of cell death and differentiation during gliogenesis in rat embryonic nerves

We have characterized a cell, the Schwann cell precursor, that represents a distinct intermediate differentiation stage in the process by which Schwann cells are generated from neural crest cells. The Schwann cell precursor shows radical differences from Schwann cells which include death regulation, antigenic phenotype, pattern of cell-cell interaction, migratory behavior, and morphology. In the nerves of the rat hind limb, Schwann cells are irreversibly generated from these during a brief period, essentially embryonic days 15-17. We also provide evidence that the survival of Schwann cell precursors is regulated by neurons and identify basic fibroblast growth factor as a potential key regulator of apoptosis in Schwann cell precursors and of precursor to Schwann cell conversion. These findings have implications for our understanding of gliogenesis in the peripheral nervous system.

Environmental signals and neural crest cells

Cell lineage analysis in both the central and peripheral nervous system of vertebrates has revealed that many neural progenitor cells are multipotent. These observations have raised the general issue of when and how such multipotent progenitors generate their various differentiated progeny. The environment of these progenitors controls the cell lineage decisions in the neural crest. This review considers the roles of the environmental signals in the context of the development of several different neural crest-derived lineages.

Regulation of the early development of the nervous system by growth factors

Development of the nervous system, although patterned by intrinsic genetic expression, appears to be dependent on growth factors for many of the differentiation steps that generate the wide variety of neurons and glia found in the both the central and peripheral nervous system. By using in vitro assays, including clonal analysis, the precise function of the various growth factors and the differentiation potential of the various neural populations has begun to be described. This review discusses some of the recent findings and examines how neuronal differentiation may result from the interaction of several growth factors.

Neurotrophin-3 affects proliferation and differentiation of distinct neural crest cells and is present in the early neural tube of avian embryos

Neurotrophin-3 is mitogenic for cultured quail neural crest cells (Kalcheim et al., 1992, Proc. Natl. Acad. Sci. USA 89:1661-1665). We now report that neurotrophin-3 also influences the survival and/or differentiation of a subset of postmitotic neural crest precursors into neurons, provided these progenitors are grown on a cellular substrate. When cultured for 1 day on monolayers of NT-3-producing, chinese hamster ovary cells, 59% of the neural crest clusters growing on the transfected line revealed the presence of intense neuronal outgrowth, compared to 25% of that in controls. Moreover, dissociated neural crest cells grown for 20 h on top of mesodermal cells in the presence of various concentrations of purified recombinant neurotrophin-3 displayed a dose-dependent increase in neuronal number. Localization experiments using specific polyclonal antibodies, revealed that neurotrophin-3 is confined to neuroepithelial cells of quail neural tubes in situ on E2 and E3, and to E2 neural tubes grown in culture for 24 h. At this stage, neural crest cells and somites were negative. At later stages, staining was likewise apparent in peripheral nerves and dorsal root ganglia. We, therefore, propose that NT-3, a factor that is expressed in the early avian central nervous system, has multiple effects both on the proliferation and differentiation of distinct neural crest cells, which depend on the state of commitment of the responsive progenitors.

Protein growth factor requirements of rat neural crest cells

Nascent neural crest cells derived from explanted E12 embryonic rat caudal neural tubes were used as an assay system to investigate the effects of fibroblast growth factors on neural crest cell (NCC) survival, proliferation, migration, and differentiation. In vitro and in vivo all NCC express low affinity nerve growth factor receptors (p75-LNGFR), whereas a subpopulation of NCC expresses the carbohydrate epitope recognized by the monoclonal antibody HNK-1 (Bannerman and Pleasure, manuscript in preparation). Both acidic and basic fibroblast growth factor (FGF) promoted the survival of proportionally greater numbers of p75-LNGF+/HNK-1- than P75-LNGFR+/HNK-1+ NCC. An as yet uncharacterized factor present in neural tube-conditioned medium was also required for NCC survival. Mitosis was frequent in those NCC closest to the neural tube, less so as the cells migrated away. Neither basic nor acidic fibroblast growth factor (FGF) influenced rates of NCC mitosis in either of these locations, nor did these FGFs alter the rate at which nascent NCC migrated away from the neural tube. However, acidic and basic FGFs did delay the differentiation of neural crest derived neurons in the cultures. FGF is abundant in the embryonic rat neural crest outgrowth zone, and the present study strongly supports an essential role for FGF in early development of the mammalian neural crest.

Basic fibroblast growth factor (bFGF) acts intracellularly to cause the transdifferentiation of avian neural crest-derived Schwann cell precursors into melanocytes

We previously found that cultured neural crest-derived cells from embryonic quail peripheral nerves, which consist mostly of Schwann cell precursors, gave rise to melanocytes following treatment with basic fibroblast growth factor (bFGF) or 12-O-tetradecanoyl phorbol-13-acetate (TPA). Here, we show that antisense deoxyoligonucleotides targeted against two regions of the bFGF mRNA transcript blocked this TPA-induced transdifferentiation of Schwann cell precursors. Neither sense nor scrambled antisense control oligonucleotides had any effect in this regard. TPA increased bFGF protein expression in cell lysates but not in conditioned media from these cultures, and this expression was localized to the nucleus and cytoplasm. Furthermore, bFGF-neutralizing antibodies and inositol-hexakisphosphate (InsP6) both inhibited pigmentation caused by exogenous bFGF, but had no affect on TPA-induced melanogenesis, suggesting that bFGF is not released by these cells. These data indicate that bFGF is necessary for the TPA-induced transdifferentiation of Schwann cell precursors into melanocytes and that bFGF acts via an intracrine mechanism.

Molecular regulation of neural crest development

The neural crest is a transient embryonic structure that gives rise to a multitude of different cell types in the vertebrate. As such, it is an ideal model to study the processes of vertebrate differentiation and development. This review focuses on two major questions related to neural crest development. The first question concerns the degree and time of commitment of the neural crest cells to different cell lineages and the emerging role of the homeobox containing genes in regulating this process. Evidence from the cephalic crest suggests that the commitment process does start before the neural crest cells migrate away from the neural tube and gene ablation experiments suggest that different homeobox genes are required for the development of neural and mesenchymal tissue derivatives. However, clonal analysis of neural crest cells before migration suggests that many of the cells remain multi-potential indicating that the final determinative steps occur progressively during migration and in association with environmental influences. The second question concerns the nature of the environmental factors that determine the differentiation of neural crest cells into discrete lineages. Evidence is provided, mainly from in vitro experiments, that purified growth factors selectively promote the differentiation of neural crest cells down either sympathetic, adrenal, sensory, or melanocytic cell lineages.

Cell lineage analysis in neural crest ontogeny

The neural crest is a transitory and pluripotent structure of the vertebrate embryo composed of cells endowed with developmentally regulated migratory properties. We review here a series of studies carried out both in vivo and in vitro on the ontogeny of the neural crest in the avian embryo. Through in vivo studies we established the fate map of the neural crest along the neuraxis prior to the onset of the migration and we demonstrated the crucial role played by the tissue environment in which the crest cells migrate in determining their fate. Moreover, the pathways of neural crest cell migration could also be traced by the quail-chick marker system and the use of the HNK1/NC1 monoclonal antibody (Mab). A large series of clonal cultures of isolated neural crest cells showed that, at migration time, most crest cells are pluripotent. Some, however, are already committed to a particular pathway of differentiation. The differentiation capacities of the pluripotent progenitors are highly variable from one to the other cell. Rare totipotent progenitors able to give rise to representatives of all the phenotypes (neuronal, glial, melanocytic, and mesectodermal) encountered in neural crest derivatives were also found. As a whole we propose a model according to which totipotent neural crest cells become progressively restricted (according to a stochastic rather than a sequentially ordered mechanism) in their potentialities, while they actively divide during the migration process. At the sites of gangliogenesis, selective forces allow only certain crest cells potentialities to be expressed in each type of peripheral nervous system (PNS) ganglia.

Role of growth factors in catecholaminergic expression by neural crest cells: in vitro effects of transforming growth factor beta 1

The differentiation of neural crest cells into catecholaminergic neurons is dependent upon both intrinsic properties and signals from the embryonic microenvironment. In tissue culture, the development of catecholaminergic traits is dependent upon factors present in chick embryo extract (CEE). This dependency suggests that soluble growth factors affect catecholaminergic differentiation in vivo. We have studied the role of CEE-derived factors and the potentially related influence of characterized growth factors on catecholaminergic phenotypic expression in avian neural crest cells. In this report, we show that CEE-derived factors and transforming growth factor beta1 (TGF-beta 1) differentially influence catecholaminergic phenotypic expression as well as melanogenesis. TGF-beta 1 substituted for CEE-derived factors and supported the in vitro differentiation of tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH) immunoreactivities, as well as catecholamine biosynthesis and storage. Differentiation of catecholaminergic cells was dependent on factors present in 10% CEE during the first 1-4 days in culture suggesting an initial critical period for exposure. One day of initial exposure to either CEE-derived factors or TGF-beta 1 was sufficient to support the subsequent expression of catecholaminergic phenotypic characteristics. The time course of responsiveness to TGF-beta 1 was different than for CEE-derived factors. Neural crest cells remain responsive to TGF-beta 1 for at least 5 days, which is past the critical period for CEE-derived factors. Bioassay of CEE shows that endogenous levels of TGF-beta are less than or equal to 0.5 ng/ml. Immunoprecipitation of TGF-beta from CEE or blockade by neutralizing antibodies did not result in a loss of catecholaminergic differentiation by neural crest cells. Although CEE supports melanogenesis under all of the growth conditions tested, TGF-beta 1 was found to be inhibitory.

Expression of the gene encoding tyrosine hydroxylase in a subpopulation of quail dorsal root ganglion cells cultured in the presence of insulin or chick embryo extract

Avian sensory ganglia contain a population of normally latent autonomic precursors with catecholaminergic potentialities. The present study examines the expression of the tyrosine hydroxylase (TH) gene in quail dorsal root ganglia (DRG) by both in situ hybridization and polymerase chain reaction (PCR) techniques. In situ hybridization using quail TH cDNA as a probe demonstrated the presence in DRG cell cultures of TH mRNA in a subpopulation of cells that never express the adrenergic phenotype in vivo. Expression of the TH gene in autonomic precursor cells of DRG in culture is totally dependent on the presence either of insulin or chick embryo extract. The numbers of catecholaminergic cells expressing TH mRNA and TH immunoreactivity evolve in a closely similar manner during the culture period. Using two primers, specific for highly conserved 5' regions of TH cDNA, it was possible to detect the same band of DNA amplified by PCR in total RNA from DRG cultures grown in the presence of insulin, sympathetic ganglia and adrenal gland. No amplified DNA was detected in uncultured DRG cells. These data further indicate that, under the influence either of insulin or a still unknown factor contained in the CEE, the TH gene is induced in a subpopulation of DRG cells.

Effect of insulin and insulin-like growth factor I on the expression of the catecholaminergic phenotype by neural crest cells

Neural crest-derived catecholaminergic precursors have been used as a model to study the role of signals supplied by the environment during avian neurogenesis. A new culture system consisting of dissociated sclerotomes or somites isolated at embryonic day 3 (E3) or 2.5 (E2.5) has been established, which allows quantitative comparison of various culture conditions. As a first step of this study, the role of insulin and insulin-like growth factor I (IGF-I) in catecholaminergic differentiation has been investigated. Our results show that both factors are able to increase by a factor 2 to 3 the number of catecholaminergic cells present in the culture of sclerotomes after 24 h of culture. The effect is dose-dependent and the half-maximal effect is obtained with low concentrations of each peptide. Since insulin, IGF-I and their respective receptors are present at this stage of development in avian embryo, our observations suggest that an early step in catecholaminergic differentiation could be under at least the partial control of insulin and insulin-related peptides. On the other hand, neural crest precursors isolated at E2.5 are not able to generate catecholaminergic cells and to respond to insulin when cultivated for one day, indicating that these precursors are subjected in vivo to a maturation step, within the somite/sclerotome between E2.5 and E3; this step could be obtained in vitro by cultivating the precursors for 1 day, which resulted in the development of insulin responsiveness by catecholaminergic precursors.

BHK-21-derived cell lines that produce basic fibroblast growth factor, but not parental BHK-21 cells, initiate neuronal differentiation of neural crest progenitors

We present evidence that basic fibroblast growth factor (bFGF)-producing cells stimulate primary differentiation of neurons from neural crest progenitors. Baby hamster kidney (BHK-21) cells were stably cotransfected with plasmid pSV2/neo, which contains the gene conferring resistance to the neomycin analog G418 and expression vectors containing the human bFGF cDNA. Various clones, which differed in their bFGF production levels, were isolated. Homogeneous neural crest cells were cultured on monolayers of bFGF-producing, BHK-21-derived cell lines. While the parental BHK-21 cells, which do not produce detectable bFGF, had poor neurogenic ability, the various bFGF-producing clones promoted a 1.5- to 4-fold increase in neuronal cell number compared to the parental cells. This increase was correlated with the levels of bFGF produced by the different transfected clones, which ranged between 2.3 and 140 ng/mg protein. In contrast, no stimulation of neuronal differentiation was observed when neural crest cells were grown on monolayers of parental BHK cells transfected with plasmid pSV2/neo alone, or on a parental BHK-derived clone, which secretes high amounts of recombinant vascular endothelial growth factor (VEGF). Furthermore, the neuron-promoting ability of bFGF-producing cells could be mimicked by addition of exogenous bFGF to neural crest cells grown on the parental BHK line. A similar treatment of neural crest cells grown on laminin substrata, instead of BHK cells, resulted in increased survival of non-neuronal cells, but not of neurons (see also Kalcheim, C. 1989, Dev. Biol. 134, 1–10). Taken together, these results suggest that bFGF stimulates neuronal differentiation of neural crest cells by a cell-mediated signalling mechanism.

A positive correlation between permissiveness of mesoderm to neural crest migration and early DRG growth

The microenvironment created by grafting rostral somitic halves in place of normal somites leads to the formation of nonsegmented peripheral ganglia (Kalcheim and Teillet, 1989; Goldstein and Kalcheim, 1991) and is mitogenic for neural crest (NC) cells that become dorsal root ganglia (DRG) (Goldstein et al., 1990). We have now extended these studies by using three surgical manipulations to determine how additional mesodermal tissues affected DRG growth in chick embryos. The following experimental manipulations were performed: (1) unilateral deletion of epithelial somites, similar deletions followed by replacing the somites with (2) a three-dimensional collagen matrix, or (3) fragments of quail lateral plate mesoderm. When somites were absent or replaced by collagen matrix, ganglia were unsegmented, and their volumes were decreased by 21% and 12%, respectively, compared to contralateral intact DRG. In contrast, when lateral plate mesoderm was transplanted in place of somitic mesoderm, NC cells migrated into the grafted mesoderm and formed unsegmented DRG whose volumes were increased by 62.6% compared to the contralateral ganglia. These results suggest that although DRG precursors do not require sclerotome to begin migration and condensation processes, DRG size is modulated by the properties of the mesoderm. Permissiveness to migration is positively correlated with an increase in DRG volume. This volume increase observed in grafts of lateral plate mesoderm is likely to result from enhanced proliferation of neural crest progenitors, previously demonstrated for DRG cells in rostral somitic grafts.

Neurotrophin 3 is a mitogen for cultured neural crest cells

Neurotrophin 3 (NT-3) promotes the survival and induces neurite outgrowth from a subset of neural crest (NC) and placode-derived neurons. We now report that this growth factor regulates the proliferation of cultured NC progenitor cells grown in a serum-free defined medium. In cultures of somites containing NC cells at migratory stages, NT-3 promotes a 2- to 8.4-fold increase in the number of NC cells incorporating [3H]thymidine into nuclei and a 1.8- to 4.8-fold increase in NC cell number compared to controls without added factor. NT-3 also promoted, to a lesser extent, the proliferation of NC cells in homogeneous cultures established from NC clusters. In addition to its effect on NC cells, NT-3 was mitogenic to somite cells in the mixed NC/somite cultures. These data demonstrate that NT-3 can act directly on the NC cells. They also indicate that the response of NC cells to NT-3 may be modulated by the presence of somitic cells. We suggest that NT-3 may be one of the central nervous system-derived factors that mediate NC cell proliferation in vivo.

Growth factor interactions in cultures of dissociated adult acoustic ganglia: neuronotrophic effects

Auditory neurons cultured from adult rat acoustic ganglia require for survival either a substrate bound factor(s) present in astrocyte conditioned medium or substrate bound basic fibroblast growth factor (bFGF). Nerve growth factor (NGF) is not a survival factor for these neurons in vitro, but when used in combination with substrate bound bFGF, NGF does vigorously stimulate a neuritogenesis response by these neurons. Transforming growth factor beta (TGF beta 1) enhances the survival effect that bFGF has on these adult auditory neurons but does not by itself promote their survival in dissociated acoustic ganglion cultures. We propose that there may be complex interactions and synergy exerted by these growth factors (i.e. bFGF, NGF, TGF beta 1) during injury to the inner ear.

Development of the neural crest

Mutations that affect the morphogenetic behaviour and differentiation of neural crest-derived cells in mouse embryos have been shown to alter genes that code for growth factors or growth factor receptors. Identification of these and other gene products provide opportunities to understand when and how developmentally distinct embryonic cell populations arise, and how interactions between localized developmental cues and responsive cell subpopulations can be modulated during development.