Selective expression of high-affinity nerve growth factor receptors on tyrosine hydroxylase-containing neuron-like cells in neural crest cultures

A subpopulation of cultured neural crest cells undergoing differentiation have receptors for nerve growth factor (NGF) that exhibit a binding constant similar to that of the low-affinity NGF binding site (3.2 nM). Recent studies have shown that NGF receptors are not present on neuron-like cells immunoreactive for tyrosine hydroxylase (TH), serotonin, or vasoactive intestinal polypeptide. Since tissues innervated by sympathetic neurons in vivo produce NGF, we sought to determine whether NGF deficits in the tissue culture microenvironment may be one parameter preventing the expression of NGF receptors on TH-containing neuron-like cells. Neural crest cultures were therefore grown in complete tissue culture medium (15% fetal bovine serum and 5% chicken embryo extract), with or without exogenous NGF (50 ng/ml). Examination of light-microscopic radioautographs following incubation with 125I-NGF revealed that, if the cultures were supplemented with NGF for 7 d, approximately 33% of neuron-like cells exhibiting TH-like immunoreactivity possessed NGF receptors. There were no obvious morphological differences between TH-containing cells that did or did not have NGF receptors. Scatchard analysis of cultures grown under these conditions again demonstrated the sole presence of the low-affinity form of the NGF receptor (Kd, 3.4 nM). Embryonic catecholaminergic sympathetic neurons exhibit both high- and low-affinity forms of the NGF receptor, raising the possibility that the Scatchard analysis may not have been sensitive enough to detect the high-affinity form of the receptor on a relatively small population of cells. Therefore we used a morphological approach that took advantage of the different dissociation rates of the 2 receptor types.(ABSTRACT TRUNCATED AT 250 WORDS)     

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

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

Identification of nerve growth factor receptors in primary cultures of chick neural crest cells

Primary cultures of chick neural crest cells obtained from explanted neural tubes have binding sites for radioiodinated nerve growth factor ([125I]NGF) but not for radioiodinated epidermal growth factor ([125I]EGF). The binding of [125I]NGF was shown to be a specific and saturable process with a high affinity (Kd = 0.3 nM) for the ligand. Despite the expression of these NGF binding sites, incubation of the neural crest cultures with nerve growth factor did not induce neurite outgrowth; no morphological alterations were observed. This was not due to an inability of the cells to express a neuronal phenotype, since the neural crest cells spontaneously differentiated into neurite-bearing cells. However, the nerve growth factor binding sites do appear to be functional receptors, since nerve growth factor could produce a modest induction of ornithine decarboxylase. The quantity of nerve growth factor binding sites seemed to be independent of the phenotype expressed by the neural crest cells, since both pigmented cells and neuron-like neural crest cells exhibited binding. These findings suggest that the differentiation of neural crest cells into mature nerve growth factor-responsive neurons may involve the coupling of nerve growth factor receptors to cellular responses important in the expression of the neuronal phenotype.     

Nerve growth factor receptors on cultured rat Schwann cells

Neonatal rat Schwann cells were grown in tissue culture and assayed for NGF receptors with time in culture. NGF receptor levels on freshly prepared Schwann cells (day 0) were low but increased dramatically during the first week in culture. Characterization of 125I-NGF binding to resuspended cells grown for 4 d in culture revealed that binding was not saturable at high ligand concentrations (50-70 nM) and that a high-capacity, low-affinity NGF binding component existed on these cells as compared to PC12 cells. The monoclonal antibody, 192-IgG, which recognizes the rat NGF receptor, was used as an immunohistochemical tool to verify the presence of NGF receptors on the cultured rat Schwann cells. In contrast to radiolabeled NGF, 125I-192-IgG demonstrated saturable binding to Schwann cells in suspension, with Kd and Bmax values of 4 nM and 115 fmol/10(6) cells, respectively. Schwann cells showed no evidence of slow dissociation or internalization of NGF binding at any of several NGF concentrations. 192-IgG was used to immunoprecipitate 125I-NGF chemically crosslinked to cell membranes. SDS-PAGE and subsequent autoradiography of the immunoprecipitated NGF receptors revealed that 2 species of NGF receptors were precipitated from Schwann cells and PC12 cells. In PC12 cells, 2 bands with molecular weights of 90 and 210 kDa were identified. The Schwann cell NGF receptor species migrated slower on the gels, with apparent molecular weights of 95 and 220 kDa. Further analysis of glial cell NGF receptors showed that Schwann cells isolated from the vagus nerve of neonatal rats also expressed NGF receptors in culture; however, astrocytes cultured from neonatal rat cerebral cortex, cultured under conditions reported here, were devoid of detectable NGF receptors. These results show that NGF receptor levels on Schwann cells increase with time in culture, and this resembles what is observed in Schwann cells in vivo when adult peripheral nerve is injured. The data are discussed in terms of a supportive role for the Schwann cell in facilitating peripheral nerve development and regeneration.     

Cultured rat Schwann cells express low affinity receptors for nerve growth factor

Schwann cell cultures prepared from postnatal Sprague-Dawley rat sciatic nerves were used to demonstrate the presence of specific receptors for the beta-subunit of nerve growth factor (NGF) on rat Schwann cells. Indirect immunofluorescence microscopy with a monoclonal antineuronal NGF receptor (NGFR) antibody indicated that NGFR antigen was expressed on the surface of Schwann cells but not of endoneurial fibroblasts. Studies with 125I-NGF confirmed this distribution of NGFR in the cultures and showed that the Schwann cell NGFR had a single NGF binding affinity (Kd of 1.8 x 10(-9) M). 125I-NGF binding by the cultured Schwann cells increased with time in vitro, reaching a plateau level on the 4th day, but decreased with increasing age, reaching 40% of the neonatal value in Schwann cells isolated from 12-day-old rats. Treatment of the cultures with NGF did not alter Schwann cell phenotype, survival or proliferation.     

Nerve growth factor effects and receptors in cultured human neuroblastoma cell lines

We studied the effects of nerve growth factor (NGF) to determine whether neuroblastoma (NB) cells share the pattern of altered response to growth regulatory factors shown by various malignant transformed cells. NGF induces neurite outgrowth, arrests growth, and enhances survival in normal neurons and in the rat pheochromocytoma, a tumor cell closely related to NB. With respect to neurite outgrowth, lines SK-N-SH, SH-SY5Y, LA-N-5, and CHP-126 were sensitive, IMR-32 was resistant, and SH-EP1, SK-N-MC, MC-IXC, CHP-100, and CHP-134 were unresponsive. Conditioned media from unresponsive cells did not inhibit response in sensitive cells. Unexpectedly, NGF neither reduced the growth rate nor enhanced survival in any NB cell line. Conditioned medium from all NB cell lines enhanced 125I-NGF binding in embryonic sensory cells. Regulation of growth rate and neurite outgrowth, then, are separable. A fundamental defect in NB may be the acquisition of a capacity for growth and survival independent of NGF. 125I-NGF was bound to both Fast and Slow receptors in MC-IXC cells, but only to Slow receptors in NGF-responsive SH-SY5Y and LA-N-5 cells, showing Fast receptors are not required for neurite outgrowth. Independence from NGF-regulated growth and survival is unexplainable by an absence of NGF receptors.     

Rat NGF receptor is recognized by the tumor-associated antigen monoclonal antibody 217c.

The expression of the epitope recognized by the tumor-associated antigen monoclonal antibody 217c increased on cultured rat Schwann cells with time. The same phenomenon has previously been reported for the rat nerve growth factor (NGF) receptor by using monoclonal antibody 192-IgG. The distribution of 217c antibody immunoreactivity closely paralleled that observed for NGF receptors on NGF-primed pheochromocytoma (PC12) cells in culture and a number of central neurons in vivo. Immunoprecipitation of affinity-labeled NGF receptors was used to examine whether these two antibodies shared common or unique antigens. Both the quantitative data and the electrophoretic mobility of the immunoprecipitated 125I-NGF/receptor complex indicate that the antigen recognized by the 217c mAb monoclonal antibody is, in fact, the NGF receptor. Furthermore, binding studies indicated that 192-IgG and 217c recognize different epitopes on the same molecule. The characterization of the 217c antibody should provide a valuable new tool in the study of NGF receptors.     

Age-dependent differences in 125I-nerve growth factor binding properties of rat adrenal chromaffin cells

Nerve growth factor (NGF) has been shown to influence survival, morphology, and transmitter phenotype of young postnatal rat chromaffin cells in vitro. Significant differences in NGF responses of chromaffin cells from newborn rats compared to 8-10-day-old ones have been reported. For this reason we studied equilibrium binding and dissociation kinetics of 125I-NGF on newborn (D1) and 10-day-old (D10) rats. Under equilibrium conditions no differences were found between the two cell types, with respect to dissociation constant (approximately 2.5 X 10(-9) M) and receptor number (10-22,000 per cell). In dissociation experiments D10 chromaffin cells exhibited two classes of NGF receptors, similar to those found in other NGF-responsive cells. From fast receptors 125I-NGF was released rapidly both at 4 degrees C and at 37 degrees C, whereas dissociation from "slow" receptors was observed only at 37 degrees C. The slow receptor class was not found on D1 cells. Instead, more than 50% of specifically bound 125I-NGF did not dissociate in the presence of excess unlabeled NGF at 37 degrees C. These age-dependent differences seem to indicate regulatory developmental changes in NGF-binding properties of rat chromaffin cells.     

Expression of nerve growth factor during the development of nervous system in early chick embryo

In the chick gastrula, nerve growth factor (NGF) is localized to the endoblast mesoblast presumptive head ectoderm but not in the presumptive neuroectoblast. During early morphogenesis the dorsal body ectoderm presumptive neural crest cells exhibit strong NGF positive cell surface reaction. NGF appears to be a marker of cells participating in morphogenetic movements but not early neural differentiation. NGF is localized where neural folds fuse and cells die allowing detachment of the neural tube from head ectoderm as well as in dead cells in the neurocoele. NGF reactivity in cells lining the evaginated extremities of the optic vesicle the floor of the neural tube the splanchnopleure heart primordia the inner outer surfaces of somites is suggestive of the role of NGF in primitive organ shaping.     

Ontogeny of the nerve growth factor receptor in primary cultures of neural crest cells

Neural crest cells maintained as primary cultures for 4-7 days demonstrated specific binding of radioiodinated nerve growth factor ([125I]NGF); occasionally, significant binding of ([125I]NGF could be detected in 3-day cultures. Parallel cultures processed for indirect immunofluorescence revealed that the NGF receptor-positive neural crest cells represented a subpopulation of the total cells in culture. Cultures aged 4-7 days demonstrated fluorescent cells which were often grouped as aggregates. Some 3-day cultures contained faintly fluorescent cells. One- and two-day cultures were non-fluorescent. Melanocytes did not appear to bind NGF. Preliminary flow cytofluorometric analysis indicated that ca. 28% of neural crest cells in 5-day cultures possessed specific receptors for NGF.     

Production of "ectopic" vasoactive intestinal peptide-like and neurotensin-like immunoreactivity in human pheochromocytoma cell cultures

Neoplastic chromaffin cells from human pheochromocytomas can exhibit extensive spontaneous and nerve growth factor (NGF)-induced outgrowth of neurite-like processes in vitro, despite the absence of such processes in vivo. To determine whether acquisition of neuron-like features by human pheochromocytoma cells in culture is accompanied by functional alterations, process outgrowth, vasoactive intestinal peptide-like immunoreactivity ( VIPLI ), neurotensin-like immunoreactivity (NTLI), and catecholamine content were studied in freshly dissociated cells and in 21-day-old cultures from six human pheochromocytomas. All of the cultures produced VIPLI and exhibited spontaneous process outgrowth. NGF stimulated process outgrowth and enhanced production of VIPLI . Dexamethasone inhibited process outgrowth and tended to decrease production of VIPLI . NTLI was detected in cells from only one of the tumors, and its production appeared to be regulated comparably to that of VIPLI . Catecholamine content decreased markedly in all of the cultures and was not regulated in parallel with either VIPLI or NTLI. The findings suggest that human pheochromocytoma cultures may help to elucidate cellular and molecular mechanisms regulating ectopic and normal VIP production.     

NGF stimulation of erk phosphorylation is impaired by a point mutation in the transmembrane domain of trkA receptor

The nerve growth factor (NGF) trkA receptor is a transmembrane glycoprotein composed of a large extracellular ligand-binding region connected to the cytoplasmic tyrosine kinase region by a single transmembrane domain (TMD). To explore the role of TMD in the process of receptor activation, we substituted the hydrophobic amino-acid residue valine 432 with the charged amino-acid glutamic acid (designated V432E mutant) by utilizing in vitro site-directed mutagenesis. NIH 3T3 cells lacking endogenous NGF receptors were stably transfected with a pRc/CMV vector carrying either wild-type (trkA) or mutated (V432E) receptors. Stable transfectants were shown, using ¹²⁵I-NGF binding and Western-blot analysis, to express the trkA recombinant receptors. Scatchard analysis revealed similar affinity for NGF in wild-type and V432E receptors. Although the level of basal trkA receptor tyrosine phosphorylation was higher in the mutant than in the wild-type, NGF stimulation of WT 11 and V432E transfectants resulted in a rapid increase in receptor tyrosine phosphorylation and of its intracellular adaptor protein SHC. In contrast to WT 11, V432E mutants showed very low levels of NGF-, and moderate levels of FGF-induced erks phosphorylation, respectively. Collectively, these findings suggest that a single substitution (V432E) in the trkA TMD results in a selective impairment of trkA-mediated erks signaling pathway.     

Localization of muscarinic receptors on peptide-containing neurones of the guinea pig myenteric plexus in tissue culture

A combined autoradiographic and immunocytochemical procedure has been used to identify neurochemically the subpopulation of cultured myenteric neurones which expresses muscarinic receptors. Antibodies to substance P (SP), [Met]enkephalin (ENK), vasoactive intestinal polypeptide (VIP) and somatostatin (SOM) were used to immunostain cultures that had previously been labelled with the irreversible muscarinic antagonist, [3H]propylbenzilylcholine mustard. Most neurites which displayed SP-like, ENK-like or SOM-like immunoreactivity did not possess muscarinic receptors. In contrast, many VIP-like immunopositive fibres also possessed muscarinic receptors. The identity of the majority of neurones which express muscarinic receptors, that do not contain VIP, remains to be determined.     

In vitro differentiation of quail neural crest cells into sensory-like neuroblasts

This study shows that quail neural crest cells can differentiate in vitro into sensory-like neuroblasts. The putative sensory neuroblasts were large and spherical, possessing large diameter, bipolar or pseudo-unipolar, long processes that lacked multiple varicosities characteristic of autonomic neurons. They bound HNK-1, a monoclonal antibody against a cell surface epitope expressed by early neural crest cells but not by young neural tube-derived cells. Many of the sensory-like neuroblasts had substance P (SP)-like immunoreactivity. Some exhibited histochemical carbonic anhydrase activity; carbonic anhydrase is shown in this study to stain a subpopulation of spinal sensory neurons in adult quail and embryos 9 days and older, whereas ventral root axons and neurons in sympathetic ganglia are non-reactive at all ages. Double staining indicated that unlike the multipolar neuroblasts developing in the same cultures, SP-like immunoreactive neuroblasts do not contain detectable levels of tyrosine hydroxylase or dopamine-beta-hydroxylase. Finally, the neuronal nature of the cultured sensory-like neuroblasts was further documented by double labeling for antibodies against the 68 kDa neurofilament polypeptide and substance P.     

Reciprocal modulation of TrkA and p75NTR affinity states is mediated by direct receptor interactions

Equilibrium binding of ¹²⁵I-nerve growth factor (¹²⁵I-NGF) to cells coexpressing the tyrosine kinase receptor A (TrkA) and common neurotrophin receptor (p75^NTR), cells coexpressing both receptors where p75^NTR is occupied, and cells expressing only p75^NTR, revealed reciprocal modulation of receptor affinity states. Analysis of receptor affinity states in PC12 cells, PC12 cells in the presence of brain-derived neurotrophic factor (BDNF), and PC12^nnr5 cells suggested that liganded and unliganded p75^NTR induce a higher affinity state within TrkA, while TrkA induces a lower affinity state within p75^NTR. These data are consistent with receptor allosterism, and prompted a search for TrkA/p75^NTR complexes in the absence of NGF. Chemical crosslinking studies revealed high molecular weight receptor complexes that specifically bound ¹²⁵I-NGF, and were immunoprecipitated by antibodies to both receptors. The heteroreceptor complex of TrkA and p75^NTR alters conformation and/or dissociates in the presence of NGF, as indicated by the ability of low concentrations of NGF to prevent heteroreceptor crosslinking. These data suggest a new model of receptor interaction, whereby structural changes within a heteroreceptor complex are induced by ligand binding.     

Trophic regulation of nodose ganglion cell development: evidence for an expanded role of nerve growth factor during embryogenesis in the rat

Peripheral sensory neurons are derived from two distinct embryonic tissues, the neural crest and epibranchial placodes. Studies in the chick suggest that embryonic lineage and trophic dependence are interrelated, such that many crest-derived cells depend on NGF for survival during development, whereas placodal derivates, including nodose ganglion neurons, do not (30). It remains controversial, however, whether or not a similar dichotomy exists in mammalian species, in which trophic requirements during early development of placodal ganglia have not been defined. To approach this issue, the present study examined the effects of nerve growth factor (NGF) on neuronal survival in embryonic rat nodose ganglion cultures. Treatment of E13.5-14.5 nodose explants with 20 ng/ml NGF resulted in a four-fold increase in neuronal survival that was blocked by anti-NGF antiserum. Increased neuronal survival and neurite outgrowth were also observed in neuron-enriched dissociated cell cultures; these effects were seen within 12 h of plating, indicating that NGF-responsive neurons or neuroblasts were already present in the ganglion at the time of explantation. This was further supported by immunocytochemical staining of nodose cell bodies in situ with the monoclonal antibody 192-IgG against the NGF receptor (12). These findings indicate that NGF may be important in regulating nodose development during early gangliogenesis in mammals and suggest that NGF plays a more widespread role in peripheral nervous system ontogeny than previously recognized.     

Fast and slow nerve growth factor binding sites in human neuroblastoma and rat pheochromocytoma cell lines: relationship of sites to each other and to neurite formation

We studied (a) the distribution and properties of fast and slow 125I-nerve growth factor (125I-NGF) binding sites in cultured human neuroblastoma (NB) cell lines that were categorized as responsive (N+) or unresponsive (N-) to NGF by neurite outgrowth, (b) whether fast or slow sites mediate actions of NGF, and (c) whether NGF-mediated conversion of fast to slow sites occurs in human NB and pheochromocytoma PC 12 cells. In human NB SH-SY5Y cells, the slow sites were trypsin resistant and binding was of high affinity. Loss of binding to the slow sites had a half-time of 25 to 30 min at 37 degrees C and was very slow at 4 degrees C. In contrast, the fast sites were trypsin sensitive and binding was of lower affinity; its dissociation half-time was less than 1 min at 4 degrees C and 37 degrees C. The association rate constants of both sites were about 0.8 to 1.2 X 10(7) M-1 sec-1. Some human NB cells had both fast and slow sites. The N+ human NB lines SH-SY5Y and LA-N-5 had only slow sites. Despite the virtual elimination of fast sites by trypsin in NB MC-IXC cells, remaining slow sites could still efficiently bind 125I-NGF. These observations showed that fast sites are not required for slow site binding, neurite outgrowth, or other demonstrated actions of NGF in some NB cells. In PC 12 cells, 125I-NGF initially bound to fast sites was not directly transferred to slow sites as required for NGF-mediated conversion. The association rate constants of fast and slow sites in PC12 cells were both about 2 X 10(7) M-1 sec-1. The association kinetics were consistent with simple bimolecular reactions in both NB and PC12 cells. The combined evidence in NB and PC12 cells did not support the hypothesis of NGF-mediated conversion of fast to slow sites.     

Characteristics of the association of nerve growth factor with primary cultures of rat sympathetic neurons

Long-term primary cultures of rat sympathetic neurons require NGF for survival and development. The kinetics of the interaction of 125I-NGF with sympathetic neuron cultures suggests the presence of diffusional barriers preventing a determination of true dissociation and association rate constants. Although the observed rate constants do not accurately reflect the microscopic interaction of NGF with receptor, the ratio of the observed rate constants does provide a good estimate of the KD. This value (1 X 10(-9)M) agrees with earlier steady state measurements of the KD. The association of 125I-NGF with neuronal cultures is temperature-dependent with internalization and retrograde transport occurring at 37 degrees C. The retrograde transport of 125I-NGF in compartmentalized neuronal cultures is concentration dependent and saturates at about 100 ng/ml (4 X 10(-9)M). The amount of 125I-NGF accumulated by retrograde transport appears to be increased subsequent to a period of NGF-starvation. The increase in uptake does not appear to be due to an increase in NGF receptor number since the number of binding sites is not greatly increased upon NGF starvation.     

Dibutyryl cAMP stimulates analgesia in rats bearing a ventricular adrenal medulla transplant

In the present study, a significant increase in pain threshold (current to elicit vocalization to tail shock) was found 15 and 60 min after injection of dibutyryl cyclic AMP (db cAMP) (30 micrograms) into the lateral ventricle in rats bearing a transplant of fetal adrenal medulla (AM). By contrast, no effect on pain threshold was observed in rats bearing an AM transplant but receiving no db cAMP, or in rats receiving db cAMP but not bearing an AM transplant. In primary cultures of rat fetal chromaffin cells, db cAMP increased the number of neuron-like cells that showed both vasoactive intestinal polypeptide (VIP)- and tyrosine hydroxylase (TH)-like immunoreactivity. These findings indicate that db cAMP exerts a pharmacological modulation of the functional activity (i.e. elevation in pain thresholds) of fetal adrenal AM transplants, and induces phenotypic changes in cultured chromaffin cells with expression of a peptide that elevates pain threshold.     

Analysis of the neurogenic potential of multipotent skin-derived precursors

Multipotent precursors similar to stem cells of the embryonic neural crest (NC) have been identified in several postnatal tissues, and are potentially useful for research and therapeutic purposes. However, their neurogenic potential, including their ability to produce electrophysiologically active neurons, is largely unexplored. We investigated this issue with regard to skin-derived precursors (SKPs), multipotent NC-related precursors isolated from the dermis of skin. SKP cultures follow an appropriate pattern and time-course of neuronal differentiation, with proliferating nestin-expressing SKPs generating post-mitotic neuronal cells that co-express pan-neuronal and peripheral autonomic lineage markers. These SKP-derived neuron-like cells survive and maintain their peripheral phenotype for at least 5 weeks when transplanted into the CNS environment of normal or kainate-injured hippocampal slices. Undifferentiated SKPs retain key neural precursor properties after multi-passage expansion, including growth factor dependence, nestin expression, neurogenic potential, and responsiveness to embryonic neural crest fate determinants. Despite undergoing an apparently appropriate neurogenic process, however, SKP-derived neuron-like cells possess an immature electrophysiological profile. These findings indicate that SKPs retain latent neurogenic properties after residing in a non-neural tissue, but that additional measures will be necessary to promote their differentiation into electrophysiologically active neurons.