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

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

Membrane-bound neuregulin1 type III actively promotes Schwann cell differentiation of multipotent Progenitor cells

Many steps of peripheral glia development appear to be regulated by neuregulin1 (NRG1) signaling but the exact roles of the different NRG1 isoforms in these processes remain to be determined. While glial growth factor 2 (GGF2), a NRG1 type II isoform, is able to induce a satellite glial fate in neural crest stem cells, targeted mutations in mice have revealed a prominent role of NRG1 type III isoforms in supporting survival of Schwann cells at early developmental stages. Here, we investigated the role of NRG1 isoforms in the differentiation of Schwann cells from neural crest-derived progenitor cells. In multipotent cells isolated from dorsal root ganglia, soluble NRG1 isoforms do not promote Schwann cell features, whereas signaling by membrane-associated NRG1 type III induces the expression of the Schwann cell markers Oct-6/SCIP and S100 in neighboring cells, independent of survival. Thus, axon-bound NRG1 might actively promote both Schwann cell survival and differentiation.     

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

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

P0 and PMP22 mark a multipotent neural crest-derived cell type that displays community effects in response to TGF-beta family factors.

Protein zero (P0) and peripheral myelin protein 22 (PMP22) are most prominently expressed by myelinating Schwann cells as components of compact myelin of the peripheral nervous system (PNS), and mutants affecting P0 and PMP22 show severe defects in myelination. Recent expression studies suggest a role of P0 and PMP22 not only in myelination but also during embryonic development. Here we show that, in dorsal root ganglia (DRG) and differentiated neural crest cultures, P0 is expressed in the glial lineage whereas PMP22 is also detectable in neurons. In addition, however, P0 and PMP22 are both expressed in a multipotent cell type isolated from early DRG. Like neural crest stem cells (NCSCs), this P0/PMP22-positive cell gives rise to glia, neurons and smooth-muscle-like cells in response to instructive extracellular cues. In cultures of differentiating neural crest, a similar multipotent cell type can be identified in which expression of P0 and PMP22 precedes the appearance of neural differentiation markers. Intriguingly, this P0/PMP22-positive progenitor exhibits fate restrictions dependent on the cellular context in which it is exposed to environmental signals. While single P0/PMP22-positive progenitor cells can generate smooth muscle in response to factors of the TGF-(beta) family, communities of P0/PMP22-positive cells interpret TGF-(beta) factors differently and produce neurons or undergo increased cell death instead of generating smooth-muscle-like cells. Our data are consistent with a model in which cellular association of postmigratory multipotent progenitors might be involved in the suppression of a non-neural fate in forming peripheral ganglia.     

Restriction of developmental potential during divergence of the enteric and sympathetic neuronal lineages.

In the peripheral nervous system, enteric and sympathetic neurons develop from multipotent neural crest cells. While local environmental signals in the gut and in the region of the sympathetic ganglia play a role in the choice of cell fate, little is known about the mechanisms that underlie restriction to specific neuronal phenotypes. We investigated the divergence and restriction of the enteric and sympathetic neuronal lineages using immuno-isolated neural crest-derived cells from the gut and sympathetic ganglia. Analysis of neuronal and lineage-specific mRNAs and proteins indicated that neural crest-derived cells from the gut and sympathetic ganglia had initiated neuronal differentiation and phenotypic divergence by E14.5 in the rat. We investigated the developmental potential of these cells using expression of tyrosine hydroxylase as a marker for a sympathetic phenotype. Tyrosine hydroxylase expression was examined in neurons that developed from sympathetic and enteric neuroblasts under the following culture conditions: culture alone; coculture with gut monolayers to promote enteric differentiation; or coculture with dorsal aorta monolayers to promote noradrenergic differentiation. Both enteric and sympathetic neuroblasts displayed developmental plasticity at E14.5. Sympathetic neuroblasts downregulated tyrosine hydroxylase in response to signals from the gut environment and enteric neuroblasts increased expression of tyrosine hydroxylase when grown on dorsal aorta or in the absence of other cell types. Tracking of individual sympathetic cells displaying a neuronal morphology at the time of plating indicated that neuroblasts retained phenotypic plasticity even after initial neuronal differentiation had occurred. By E19.5 both enteric and sympathetic neuroblasts had undergone a significant loss of their developmental potential, with most neuroblasts retaining their lineage-specific phenotype in all environments tested. Together our data indicate that the developmental potential of enteric and sympathetic neuroblasts becomes restricted over time and that this restriction takes place not as a consequence of initial neuronal differentiation but during the period of neuronal maturation. Further, we have characterized a default pathway of adrenergic differentiation in the enteric nervous system and have defined a transient requirement for gut-derived factors in the maintenance of the enteric neuronal phenotype.     

A spatial and temporal analysis of dorsal root and sympathetic ganglion formation in the avian embryo

The present study explores the formation of the dorsal root and sympathetic ganglia in the trunk of the avian embryo. Particular emphasis was given to the timing of gangliogenesis and the relative positions of the neural crest-derived ganglia with respect to the somites. Neural crest cells and their derivatives were recognized by the HNK-1 antibody. The time at which neural crest cell coalesced to form ganglia was assessed by the state of cellular aggregation. The state of ganglionic differentiation was assessed by the expression of neurofilament proteins and the neural cell adhesion molecule (N-CAM). At the level of the 15th somite, neural crest cells were observed in the rostral half of the somite at stage 15, during active neural crest migration, and occupied the rostral two-thirds of the somite at progressive stages. HNK-1 positive cells appeared to be organized in three to four streams of cells oriented mediolaterally and dorsoventrally. The dorsal root ganglia and sympathetic ganglia were first detectable at stages 20 and 21, respectively. Both ganglionic rudiments were aligned with the rostral portion of the somite. The dorsal root ganglia occupied the rostral two-thirds of each somite, whereas cells in the sympathetic ganglia occupied a region corresponding to approximately one-third of each somite. At the time of condensation of the dorsal root ganglia, abundant neurofilament staining was observed within the ganglia. However, no N-CAM immunoreactivity was detected until three stages later at stage 23. In contrast, the sympathetic ganglia demonstrated both neurofilament and N-CAM immunoreactivity at the time of condensation. The observation that both dorsal root and sympathetic ganglia form in register with the rostral portion of somite suggests that cues localized at these axial levels, perhaps within the rostral somite, may influence the position where neural crest cells condense to form ganglia. In sensory ganglia, N-CAM expression does not correlate with the onset of gangliogenesis, suggesting that molecules other than N-CAM may play an important role in the aggregation of some neuronal populations.     

Multiple roles of mouse Numb in tuning developmental cell fates.

BACKGROUND: Notch signaling regulates multiple differentiation processes and cell fate decisions during both invertebrate and vertebrate development. Numb encodes an intracellular protein that was shown in Drosophila to antagonize Notch signaling at binary cell fate decisions of certain cell lineages. Although overexpression experiments suggested that Numb might also antagonize some Notch activity in vertebrates, the developmental processes in which Numb is involved remained elusive. RESULTS: We generated mice with a homozygous inactivation of Numb. These mice died before embryonic day E11.5, probably because of defects in angiogenic remodeling and placental dysfunction. Mutant embryos had an open anterior neural tube and impaired neuronal differentiation within the developing cranial central nervous system (CNS). In the developing spinal cord, the number of differentiated motoneurons was reduced. Within the peripheral nervous system (PNS), ganglia of cranial sensory neurons were formed. Trunk neural crest cells migrated and differentiated into sympathetic neurons. In contrast, a selective differentiation anomaly was observed in dorsal root ganglia, where neural crest--derived progenitor cells had migrated normally to form ganglionic structures, but failed to differentiate into sensory neurons. CONCLUSIONS: Mouse Numb is involved in multiple developmental processes and required for cell fate tuning in a variety of lineages. In the nervous system, Numb is required for the generation of a large subset of neuronal lineages. The restricted requirement of Numb during neural development in the mouse suggests that in some neuronal lineages, Notch signaling may be regulated independently of Numb.     

Progenitor cells from embryonic chick dorsal root ganglia differentiate in vitro to neurons: biochemical and electrophysiological evidence.

We have analyzed the appearance of neurons and glial cells in chick dorsal root ganglia during development. Neurons were identified by the presence of polysialogangliosides recognized by tetanus toxin (GD1b, GT1) or by the monoclonal antibody Q211 directed against polysialogangliosides containing four, five and six sialic acid residues. Glial cells were identified by the presence of 04 antigen. A population of undifferentiated cells, i.e., cells which express neither neuronal nor glial cell surface antigens, present in dorsal root ganglia until embryonic day 7, was separated from the neuronal and glial population. This cell population contains neuronal progenitor cells which differentiate to neurons within 1 day in culture. This differentiation process is characterized by the appearance of neuronal morphology, of neuron-specific gangliosides and by the appearance of voltage-dependent sodium and calcium channels.     

Notochord grafts do not suppress formation of neural crest cells or commissural neurons.

Grafting experiments previously have established that the notochord affects dorsoventral polarity of the neural tube by inducing the formation of ventral structures such as motor neurons and the floor plate. Here, we examine if the notochord inhibits formation of dorsal structures by grafting a notochord within or adjacent to the dorsal neural tube prior to or shortly after tube closure. In all cases, neural crest cells emigrated from the neural tube adjacent to the ectopic notochord. When analyzed at stages after ganglion formation, the dorsal root ganglia appeared reduced in size and shifted in position in embryos receiving grafts. Another dorsal cell type, commissural neurons, identified by CRABP and neurofilament immunoreactivity, differentiated in the vicinity of the ectopic notochord. Numerous neuronal cell bodies and axonal processes were observed within the induced, but not endogenous, floor plate 1 to 2 days after implantation but appeared to be cleared with time. These results suggest that dorsally implanted notochords cannot prevent the formation of neural crest cells or commissural neurons, but can alter the size and position of neural crest-derived dorsal root ganglia.     

Neuronal differentiation from postmitotic precursors in the ciliary ganglion

In the chick ciliary ganglion, neuronal number is kept constant between St. 29 and St. 34 (E6-E8) despite a large amount of cell death. Here, we characterize the source of neurogenic cells in the ganglion as undifferentiated neural crest-derived cells. At St. 29, neurons and nonneuronal cells in the ciliary ganglion expressed the neural crest markers HNK-1 and p75(NTR). Over 50% of the cells were neurons at St. 29; of the nonneuronal cells, a small population expressed glial markers, whereas the majority was undifferentiated. When placed in culture, nonneuronal cells acquired immunoreactivity for HuD, suggesting that they had commenced neuronal differentiation. The newly differentiated neurons arose from precursors that did not incorporate bromodeoxyuridine. To test whether these precursors could undergo neural differentiation in vivo, purified nonneuronal cells from St. 29 quail ganglia were transplanted into chick embryos at St. 9-14. Subsequently, quail cells expressing neuronal markers were found in the chick ciliary ganglion. The existence of this precursor pool was transient because nonneuronal cells isolated from St. 38 ganglia failed to form neurons. Since all ciliary ganglion neurons are born prior to St. 29, these results demonstrate that there are postmitotic neural crest-derived precursors in the developing ciliary ganglion that can differentiate into neurons in the appropriate environment.     

The cranial sensory ganglia in culture: Differences in the response of placode-derived and neural crest-derived neurons to nerve growth factor

Explants of cranial sensory ganglia and dorsal root ganglia from embryonic chicks of 4 to 16 days incubation (E4 to E16) were grown for 24 hr in collagen gels with and without nerve growth factor (NGF) in the culture medium. NGF elicited marked neurite outgrowth from neural crest-derived explants, i.e., dorsal root ganglia, the dorsomedial part of the trigeminal ganglion, and the jugular ganglion. This response was first observed in ganglia taken from E6 embryos, reached a maximum between E8 and E11, and gradually declined through E16. Explants in which the neurons were of placodal origin varied in their response to NGF. There was negligible neurite outgrowth from explants of the ventrolateral part of the trigeminal ganglion and the vestibular ganglion grown in the presence of NGF. The geniculate, petrosal, and nodose ganglia exhibited an early moderate response to NGF. This was first evident in ganglia taken from E5 embryos, reached a maximum by E6, and declined through later ages, becoming negligible by E13. Dissociated neuron-enriched cultures of vestibular, petrosal, jugular, and dorsal root ganglia were established from embryos taken at E6 and E9. At both ages NGF elicited neurite outgrowth from a substantial proportion of neural crest-derived neurons (jugular and dorsal root ganglia) but did not promote the growth of placode-derived neurons (vestibular and petrosal ganglia). Our findings demonstrate a marked difference in the response of neural crest and placode-derived sensory neurones to NGF. The data from dissociated neuron-enriched cultures suggest that NGF promotes survival and growth of sensory ganglionic neurons of neural crest origin but not of placodal origin. The data from explant cultures suggest that NGF promotes neurite outgrowth from placodal neurons of the geniculate, petrosal, and nodose ganglia early in their ontogeny. However, we argue that this fibre outgrowth emanates not from the placodal neurons but from neural crest-derived cells which normally give rise only to satellite cells of these ganglia.     

The early development of cranial sensory ganglia and the potentialities of their component cells studied in quail-chick chimeras

The quail-chick marker system has been used to study the early developmental stages of the ganglia located along cranial nerves VII, IX, and X. The streams of neural crest cells arising from the rhombencephalic-vagal neural crest were followed from the onset of their migration up to the localization of crest cells in the trunk and root ganglia of these nerves. It was shown that two different populations of crest cells are segregated early as a result of morphogenetic movements in the hypobranchial region. The dorsal population gives rise to the root ganglia of nerves IX and X located close to the encephalic vesicles, where the crest cells differentiate both into neurons and into glia. In contrast, the ventral stream of neural crest cells contributes together with cells from epibranchial placodes to the trunk ganglia (geniculate, petrous, and nodose ganglia) of cranial nerves VII, IX, and X. The successive steps of the invasion of the placodal anlage by crest cells can be followed owing to the selective labeling of the neural crest cells. It appears that the latter give rise to the satellite cells of the geniculate, petrous, and nodose ganglia while the large sensory neurons originate from the placodes. The nodose ganglion has been the subject of further studies aimed to investigate whether neuronal potentialities can be elicited in the neural crest-derived cells that it contains. The ability to label selectively either the neurons or the glia by the quail nuclear marker made this investigation possible in the particular case of the nodose ganglion whose neurons and satellite cells have a different embryonic origin. By the technique already described (N. M. Le Douarin, M. A. Teillet, C. Ziller, and J. Smith, 1978, Proc. Nat. Acad. Sci. USA75, 2030–2034) of back-transplantation into the neural crest migration pathway of a younger host, it was shown that the presumptive glial cells of the nodose ganglion are able to remigrate when transplanted into a 2-day chick host and to differentiate into autonomic structures (sympathetic ganglion cells, adrenomedullary cells, and enteric ganglia). It is proposed as a working hypothesis that neuronal potentialities contained in the neural crest cells which invade the placodal primordium of the nodose ganglion are repressed through cell-cell interactions occurring between placodal and crest cells.     

Identification and characterization of a calcium channel gamma subunit expressed in differentiating neurons and myoblasts

Transient elevations of intracellular calcium (calcium transients) play critical roles in many developmental processes, including differentiation. Although the factors that regulate calcium transients are not clearly defined, calcium influx may be controlled by molecules interacting with calcium channels, including channel regulatory subunits. Here, we describe the chick gamma4 regulatory subunit (CACNG4), the first such subunit to be characterized in early development. CACNG4 is expressed early in the cranial neural plate, and later in the cranial and dorsal root ganglia; importantly, the timing of this later expression correlates precisely with the onset of neuronal differentiation. CACNG4 expression is also observed in nonneuronal tissues undergoing differentiation, specifically the myotome and a subpopulation of differentiating myoblasts in the limb bud. Finally, within the distal cranial ganglia, we show that CACNG4 is expressed in placode-derived cells (prospective neurons), but also, surprisingly, in neural crest-derived cells, previously shown to form only glia in this location; contrary to these previous results, we find that neural crest cells can form neurons in the distal ganglia. Given the proposed role of CACNG4 in modulating calcium channels and its expression in differentiating cells, we suggest that CACNG4 may promote differentiation via regulation of intracellular calcium levels.     

Restriction of neurogenic ability during neural crest cell differentiation

Multipotent neural crest cells undergo developmental restrictions during embryogenesis and eventually give rise to the neurons and glia of the peripheral nervous system, melanocytes, and pheochromocytes. To understand how neuronal potential is restricted to a subpopulation of crest-derived cells, we have utilized sensitive markers of early neuronal differentiation to assess neurogenesis in crest-derived cell populations subjected to defined experimental conditions in vitro and in vivo. We describe environmental conditions that either (a) result in the irreversible loss of neurogenic potential over a characteristic time course or (b) maintain neurogenic potential among neural crest cells. © 1993 John Wiley & Sons, Inc.     

Changes in the migratory properties of neural crest and early crest-derived cells in vivo following treatment with a phorbol ester drug

In previous work, we found that the phorbol ester drug 12-O-tetradecanoyl phorbol acetate (TPA) reversed the developmental restriction of melanogenesis that normally occurs in neural crest-derived Schwann cell precursors around embryonic Day 5 of quail development. That is, TPA treatment of dorsal root ganglia (DRG) from 7-day quail embryos caused Schwann cell precursors to regain the ability to give rise to melanocytes. In this paper, we examine other long-term effects of TPA on the differentiative and migratory properties of neural crest and crest-derived DRG cells, using heterospecific grafting methods. We report that TPA treatment in culture increased the extent of cell migration following grafting into host embryos, including some ectopic migration into the central nervous system and other locations. TPA did not, however, seem to change the fate of these crest-derived cells, except that some DRG cells underwent pigmentation, as had been observed previously. Interestingly, graft cells associated with peripheral nerves were found to be exclusively unpigmented, whereas graft cells found in all other locations, including the central nervous system, were both pigmented and unpigmented. This suggests that peripheral nerves may act in a fashion antagonistic to the effects of TPA. These findings are consistent with the notion that TPA treatment causes early crest-derived cells to regain developmental properties lost with developmental age.     

Analysis of high PSA N-CAM expression during mammalian spinal cord and peripheral nervous system development.

Using a monoclonal antibody that recognizes specifically a high polysialylated form of N-CAM (high PSA N-CAM), the temporal and spatial expression of this molecule was studied in developing spinal cord and neural crest derivatives of mouse truncal region. Temporal expression was analyzed on immunoblots of spinal cord and dorsal root ganglia (DRGs) extracts microdissected at different developmental stages. Analysis of the ratio of high PSA N-CAM to total N-CAM indicated that sialylation and desialylation are independently regulated from the expression of polypeptide chains of N-CAM. Motoneurons, dorsal root ganglia cells and commissural neurons present a homogeneous distribution of high PSA N-CAMs on both their cell bodies and their neurites. Sialylation of N-CAM can occur in neurons after their aggregation in peripheral ganglia as demonstrated for dorsal root ganglia at E12. Furthermore, peripheral ganglia express different levels of high PSA N-CAM. With in vitro models using mouse neural crest cells, we found that expression of high PSA N-CAM was restricted to cells presenting an early neuronal phenotype, suggesting a common regulation for the expression of high PSA N-CAM molecules, neurofilament proteins and sodium channels. Using perturbation experiments with endoneuraminidase, we confirmed that high PSA N-CAM molecules are involved in fasciculation and neuritic growth when neurons derived from neural crest grow on collagen substrata. However, we demonstrated that these two parameters do not appear to depend on high PSA N-CAM molecules when cells were grown on a fibronectin substratum, indicating the existence of a hierarchy among adhesion molecules.     

Sacral neural crest cells colonise aganglionic hindgut in vivo but fail to compensate for lack of enteric ganglia

The vagal neural crest is the origin of majority of neurons and glia that constitute the enteric nervous system, the intrinsic innervation of the gut. We have recently confirmed that a second region of the neuraxis, the sacral neural crest, also contributes to the enteric neuronal and glial populations of both the myenteric and the submucosal plexuses in the chick, caudal to the level of the umbilicus. Results from this previous study showed that sacral neural crest-derived precursors colonised the gut in significant numbers only 4 days after vagal-derived cells had completed their migration along the entire length of the gut. This observation suggested that in order to migrate into the hindgut and differentiate into enteric neurons and glia, sacral neural crest cells may require an interaction with vagal-derived cells or with factors or signalling molecules released by them or their progeny. This interdependence may also explain the inability of sacral neural crest cells to compensate for the lack of ganglia in the terminal hindgut of Hirschsprung's disease in humans or aganglionic megacolon in animals. To investigate the possible interrelationship between sacral and vagal-derived neural crest cells within the hindgut, we mapped the contribution of various vagal neural crest regions to the gut and then ablated appropriate sections of chick vagal neural crest to interrupt the migration of enteric nervous system precursor cells and thus create an aganglionic hindgut model in vivo. In these same ablated animals, the sacral level neural axis was removed and replaced with the equivalent tissue from quail embryos, thus enabling us to document, using cell-specific antibodies, the migration and differentiation of sacral crest-derived cells. Results showed that the vagal neural crest contributed precursors to the enteric nervous system in a regionalised manner. When quail-chick grafts of the neural tube adjacent to somites 1-2 were performed, neural crest cells were found in enteric ganglia throughout the preumbilical gut. These cells were most numerous in the esophagus, sparse in the preumbilical intestine, and absent in the postumbilical gut. When similar grafts adjacent to somites 3-5 or 3-6 were carried out, crest cells were found within enteric ganglia along the entire gut, from the proximal esophagus to the distal colon. Vagal neural crest grafts adjacent to somites 6-7 showed that crest cells from this region were distributed along a caudal-rostral gradient, being most numerous in the hindgut, less so in the intestine, and absent in the proximal foregut. In order to generate aneural hindgut in vivo, it was necessary to ablate the vagal neural crest adjacent to somites 3-6, prior to the 13-somite stage of development. When such ablations were performed, the hindgut, and in some cases also the cecal region, lacked enteric ganglionated plexuses. Sacral neural crest grafting in these vagal neural crest ablated chicks showed that sacral cells migrated along normal, previously described hindgut pathways and formed isolated ganglia containing neurons and glia at the levels of the presumptive myenteric and submucosal plexuses. Comparison between vagal neural crest-ablated and nonablated control animals demonstrated that sacral-derived cells migrated into the gut and differentiated into neurons in higher numbers in the ablated animals than in controls. However, the increase in numbers of sacral neural crest-derived neurons within the hindgut did not appear to be sufficiently high to compensate for the lack of vagal-derived enteric plexuses, as ganglia containing sacral neural crest-derived neurons and glia were small and infrequent. Our findings suggest that the neuronal fate of a relatively fixed subpopulation of sacral neural crest cells may be predetermined as these cells neither require the presence of vagal-derived enteric precursors in order to colonise the hindgut, nor are capable of dramatically altering their proliferation or d     

Altered neuronal lineages in the facial ganglia of Hoxa2 mutant mice

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

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

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