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

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

In vivo calcium dynamics during neural crest cell migration and patterning using GCaMP3

Examining calcium dynamics within the neural crest (NC) has the potential to shed light on mechanisms that regulate complex cell migration and patterning events during embryogenesis. Unfortunately, typical calcium indicators are added to culture media or have low signal to noise after microinjection into tissue that severely limit analyses to cultured cells or superficial events. Here, we studied in vivo calcium dynamics during NC cell migration and patterning, using a genetically encoded calcium sensor, GCaMP3. We discovered that trunk NC cells displayed significantly more spontaneous calcium transients than cranial NC cells, and during cell aggregation versus cell migration events. Spontaneous calcium transients were more prevalent during NC cell aggregation into discrete sympathetic ganglia (SG). Blocking of N-cadherin activity in trunk NC cells near the presumptive SG led to a dramatic decrease in the frequency of spontaneous calcium transients. Detailed analysis and mathematical modeling of cell behaviors during SG formation showed NC cells aggregated into clusters after displaying a spontaneous calcium transient. This approach highlights the novel application of a genetically encoded calcium indicator to study subsets of cells during ventral events in embryogenesis.     

Quail neural crest cells cannot read positional values in the dorsal trunk feathers of the chicken embryo

Summary If quail neural crest cells are grafted to the chick, they migrate into the feathers of the host and produce melanin pigment. In one study, the dorsal trunk feathers of the chimaera were found to have quail-like pigment patterns. This was interpreted in terms of a positional information model. By contrast, in another study it was found that pigment patterns in the wing plumage of the chimaera bore little or no resemblance to the quail, showing instead a rather uniform, dark pigmentation. This was interpreted in terms of a prepattern in the ectoderm. This striking difference in results could be because the wing and trunk plumages have their pigment patterns specified in different ways. We have examined this possibility by making detailed maps of the dorsal trunk plumage of the normal quail and the quail-chick chimaera. Using this novel technique, we can accurately record the secondary pigment patterns in the embryonic down plumage. In the quail there are well-defined, longitudinal stripes running down the back, whereas the chimaera shows rather uniform, dark pigment in this area. There is little or no indication of stripes and some chimaerae develop asymmetric, mottled patterns. Grafts to the cephalic region also produce uniform pigmentation with no quail-like patterning. These findings indicate that neural crest cells cannot read positional values in the feathers of another species.     

Environmental factors affecting neural crest differentiation: Melanocyte differentiation by crest cells exposed to cell-free (deoxycholate-extracted) dermal mesenchyme matrix

Summary Deoxycholate-extracted, cell-free matrices were prepared from primary expiants or dispersed cell cultures of embryonic avian dermis, ectoderm, gut mesenchyme, endoderm, pharynx, or umbilical artery. Neural crest cells in association with matrices from dermal expiants or monolayers formed melanocytes after six days. Crest cells in association with matrices from all other tissues or grown on plastic did not form melanocytes. It is concluded that a deoxycholate-resistant structural component of the dermal extracellular matrix induces melanocyte differentiation.Abbreviations used ECM extracellular matrix - GAG glycosaminoglycan - HANKS Hank's balanced salt solution - FCS fetal calf serum - DME Dulbecco's modified Eagle's medium - DOC deoxycholate - PMSF phenyl methyl sulfonyl fluoride     

Fate map and morphogenesis of presumptive neural crest and dorsal neural tube

In contrast to the classical assumption that neural crest cells are induced in chick as the neural folds elevate, recent data suggest that they are already specified during gastrulation. This prompted us to map the origin of the neural crest and dorsal neural tube in the early avian embryo. Using a combination of focal dye injections and time-lapse imaging, we find that neural crest and dorsal neural tube precursors are present in a broad, crescent-shaped region of the gastrula. Surprisingly, static fate maps together with dynamic confocal imaging reveal that the neural plate border is considerably broader and extends more caudally than expected. Interestingly, we find that the position of the presumptive neural crest broadly correlates with the BMP4 expression domain from gastrula to neurula stages. Some degree of rostrocaudal patterning, albeit incomplete, is already evident in the gastrula. Time-lapse imaging studies show that the neural crest and dorsal neural tube precursors undergo choreographed movements that follow a spatiotemporal progression and include convergence and extension, reorientation, cell intermixing, and motility deep within the embryo. Through these rearrangement and reorganization movements, the neural crest and dorsal neural tube precursors become regionally segregated, coming to occupy predictable rostrocaudal positions along the embryonic axis. This regionalization occurs progressively and appears to be complete in the neurula by stage 7 at levels rostral to Hensen's node.     

A role for RhoA in the two-phase migratory pattern of post-otic neural crest cells

Neural crest (NC) cells have been elegantly traced to follow stereotypical migratory pathways throughout the vertebrate embryo, yet we still lack complete information on individual cell migratory behaviors and how molecular mechanisms direct NC cell guidance. Here, we analyze the spatio-temporal migratory pattern of post-otic NC and the in vivo role of the small Rho GTPase, RhoA, using fluorescent cell labeling, molecular perturbation, and intravital 4D (3D+ time) confocal imaging in the intact chick embryo. We find that the post-otic NC cell migratory pattern is established in two phases with distinct cell migratory behaviors. An initial wide front of lateral-directed NC cells, led by NC from rhombomere 7 (r7), move as a distinct subpopulation. This is followed in time by fewer NC cells that migrate collectively from r7 to r8 in a follow-the-leader manner with extensive cellular extensions between cells. We show that post-otic migratory NC cells express RhoA, using RT-PCR on isolated, flow cytometry sorted NC cells and in neural tube culture explants. When RhoA function is altered by expression of a dominant negative or constitutively active form, or injection of C3, there are two major consequences. RhoA constitutively active expressing NC cells are less directional, slower and form fewer follow-the-leader chain assemblies. NC cells expressing RhoA-DN are less affective in retracting filopodia, migrate slower and also form fewer follow-the-leader chain assemblies. Together, these alterations to NC cell intrinsic signaling and cell-cell contact disrupt the precise spatio-temporal post-otic NC cell migratory pattern.     

In vivo analysis reveals a critical role for neuropilin-1 in cranial neural crest cell migration in chick

The neural crest provides an excellent model system to study invasive cell migration, however it is still unclear how molecular mechanisms direct cells to precise targets in a programmed manner. We investigate the role of a potential guidance factor, neuropilin-1, and use functional knockdown assays, tissue transplantation and in vivo confocal time-lapse imaging to analyze changes in chick cranial neural crest cell migratory patterns. When neuropilin-1 function is knocked down in ovo, neural crest cells fail to fully invade the branchial arches, especially the 2nd branchial arch. Time-lapse imaging shows that neuropilin-1 siRNA transfected neural crest cells stop and collapse filopodia at the 2nd branchial arch entrances, but do not die. This phenotype is cell autonomous. To test the influence of population pressure and local environmental cues in driving neural crest cells to the branchial arches, we isochronically transplanted small subpopulations of DiI-labeled neural crest cells into host embryos ablated of neighboring, premigratory neural crest cells. Time-lapse confocal analysis reveals that the transplanted cells migrate in narrow, directed streams. Interestingly, with the reduction of neuropilin-1 function, neural crest cells still form segmental migratory streams, suggesting that initial neural crest cell migration and invasion of the branchial arches are separable processes.     

Differentiation of avian neural crest cells in vitro: Absence of a developmental bias toward melanogenesis

Summary Neural crest cells from quail embryos grown in standard culture dishes differentiate almost entirely into melanocytes within 4 or 5 days when chick embryo extract (CEE) or occasional lots of fetal calf serum (FCS) are included in the medium. Gel fractionation showed that the pigment inducing factor(s) present in these media is of high molecular weight (> 400 K daltons). In the absence of CEE, the neural tube can also stimulate melanocyte differentiation. Culture medium supplemented by selected lots of FCS permits crest cell proliferation but little overt differentiation after up to 2 weeks in culture if the neural tube is removed within 18 h of explantation in vitro. Subsequent addition of CEE to such cultures promotes complete melanocyte differentiation. Crest cells from White leghorn chick embryos also differentiate into melanocytes in the presence of CEE, but do not survive well in its absence. Melanocyte differentiation of crest cells from both quail and chick embryos can by suppressed by culturing under a dialysis membrane, even in the presence of the neural tube and CEE, but neuronal differentiation appears greatly enhanced.     

Increase in the cholinergic cardiac plexus in sympathetically aneural chick hearts

Summary Embryonic chick hearts were made sympathetically aneural by removal of premigratory neural crest over somites 10–20. The cholinergic cardiac plexus was assessed at 12 to 15 days of incubation using morphological and biochemical techniques. The cholinergic innervation to the heart was increased by 50 to 100% due to both hypertrophy and hyperplasia of the ganglion cells as well as their terminals. The additional cells were an expansion of the normal population of cholinergic neurons in the heart rather than from some extra source. The expanded population of neurons did not express an adrenergic phenotype in response to the absence of adrenergic cardiac innervation.     

Morphogenesis of sclerotome and neural crest in avian embryos

Summary The distribution of sclerotome and neural crest cells of avian embryos was studied by light and electron microscopy. Sclerotome cells radiated from the somites towards the notochord, to occupy the perichordal space. Neural crest cells, at least initially, also entered cell-free spaces. At the cranial somitic levels they moved chiefly dorsal to the somites, favouring the rostral part of each somite. These cells did not approach the perichordal space. More caudally (i.e. trunk levels), neural crest cells initially moved ventrally between the somites and neural tube. Adjacent to the caudal half of each somite, these cells penetrated no further than the myosclerotomal border, but opposite the rostral somite half, they were found next to the sclerotome almost as far ventrally as the notochord. However, they did not appear to enter the perichordal space, in contrast to sclerotome cells.When tested in vitro, sclerotome cells migrated towards notochords co-cultured on fibronectin-rich extracellular material, and on collagen gels. In contrast, neural crest cells avoided co-cultured notochords. This avoidance was abolished by inclusion of testicular hyaluronidase and chondroitinase ABC in the culture medium, but not by hyaluronidase from Streptomyces hyalurolyticus. The results suggest that sclerotome and neural crest mesenchyme cells have a different distribution with respect to the notochord, and that differential responses to notochordal extracellular material, possibly chondroitin sulphate proteoglycan, may be responsible for this.     

Wise promotes coalescence of cells of neural crest and placode origins in the trigeminal region during head development

While most cranial ganglia contain neurons of either neural crest or placodal origin, neurons of the trigeminal ganglion derive from both populations. The Wnt signaling pathway is known to be required for the development of neural crest cells and for trigeminal ganglion formation, however, migrating neural crest cells do not express any known Wnt ligands. Here we demonstrate that Wise, a Wnt modulator expressed in the surface ectoderm overlying the trigeminal ganglion, play a role in promoting the assembly of placodal and neural crest cells. When overexpressed in chick, Wise causes delamination of ectodermal cells and attracts migrating neural crest cells. Overexpression of Wise is thus sufficient to ectopically induce ganglion-like structures consisting of both origins. The function of Wise is likely synergized with Wnt6, expressed in an overlapping manner with Wise in the surface ectoderm. Electroporation of morpholino antisense oligonucleotides against Wise and Wnt6 causes decrease in the contact of neural crest cells with the delaminated placode-derived cells. In addition, targeted deletion of Wise in mouse causes phenotypes that can be explained by a decrease in the contribution of neural crest cells to the ophthalmic lobe of the trigeminal ganglion. These data suggest that Wise is able to function cell non-autonomously on neural crest cells and promote trigeminal ganglion formation.     

PTEN基因对早期胚胎神经嵴细胞迁移的作用研究

目的 初步探讨PTEN基因在早期神经嵴细胞迁移中的作用.方法 首先胚胎整体的原位杂交和免疫荧光方法检测鸡胚胎内源性的PTEN基因及蛋白水平的表达情况;其次,利用鸡胚胎体内半侧神经管转染的方法,使神经管一侧PTEN基因过表达,对侧神经管为正常对照侧;最后,通过Pax7的整体胚胎免疫荧光表达观察PTEN基因对其标记的部分神经嵴细胞迁移的影响.结果 内源性PTEN基因在mRNA和蛋白水平表达显示,其在早期胚胎HH4期的神经板即开始明显的表达;通过半侧过表达PTEN基因后观察到过表达PTEN基因侧的头部神经嵴细胞迁移与对照侧相比明显受到抑制,但对躯干部的影响并不明显.结论 PTEN基因可能抑制早期胚胎头部神经嵴细胞的迁移.     

The development and distribution of the cranial neural crest in the rat embryo

Summary The head region of rat embryos was investigated by scanning electron microscopy after removal of the surface ectoderm with adhesive tape. Observations were made in embryos from 6-somite to 11-somite stages of development, in order to determine: (1) the sequence of emigration of neural crest cells from the different regions of the future brain; (2) the appearance of crest cells before, during, and after their conversion from an epithelial to a mesenchymal form; (3) the migration pathways.Emigration occurs first from the midbrain, and next from the rostral hindbrain; crest cells from these two regions migrate into the first visceral arch. Subsequently cells emigrate from the caudal hindbrain, but not in a rostrocaudal sequence. At the time of crest cell emigration, the neural fold morphology varies from a slightly convex, widely open plate (midbrain) to a closed tube (caudal hindbrain). Thus the timing of emigration is related neither to age (as reflected in rostrocaudal levels) nor to morphology of the neural epithelium.     

Temporal restriction of migratory and lineage potential in rhombomere 1 and 2 neural crest

Migratory cranial neural crest cells differentiate into a wide range of cell types, such as ectomesenchymal tissue (bone and connective tissues) ventrally in the branchial arches and neural tissue (neurons and glia) dorsally. We investigated spatial and temporal changes of migration and differentiation potential in neural crest populations derived from caudal midbrain and rhombomeres 1 and 2 by back-transplanting cells destined for the first branchial arch and trigeminal ganglion from HH8-HH19 quail into HH7-HH11 chicks. Branchial arch cells differentiated down ectomesenchymal lineages but largely lost both the ability to localize to the trigeminal position and neurogenic differentiation capacity by HH12-HH13, even before the arch is visible, and lost long distance migratory ability around HH17. In contrast, neural crest-derived cells from trigeminal ganglia lost ectomesechymal differentiation potential by HH17. Despite this, they retain the ability to migrate into the branchial arches until at least HH19. However, many of the neural crest-derived trigeminal ganglia cells in the branchial arch localized to the non-neural crest core of the arch from HH13 and older donors. These results suggest that long distance migration ability, finer scale localization, and lineage restriction may not be coordinately regulated in the cranial neural crest population.     

Expression of a complex developmental antigen in precise morphogenetic processes during chick embryogenesis

Summary In order to identify transitory molecules involved in specific events during development, monoclonal antibodies were raised against various structures of the chick embryo at stages exhibiting important tissue reorganization. A7H2 is a monoclonal antibody reacting with an epitope suddenly expressed in select embryonic tissues during precise morphogenetic processes. Splanchnomesoderm and most mesothelia exhibited a strong immunoreactivity during organogenesis whereas non-mesodermal A7H2-activities were usually confined to invaginating or folding epithelia. Most embryonic reactivities were transient but the amnion demonstrated a strong and persistent reactivity and therefore was selected as a source of material for A7H2-antigen characterization. The antigenic determinant was shown to be on a huge molecular complex having a pI of 5. Immunoblots obtained after SDS-PAGE demonstrated a highly disperse pattern in the high MW region of the gel that could be altered or abolished by proteolytic treatments. Fingerprint analysis of the immunoreactive peptide bands demonstrated a clear relationship between them. Using different fixation and permeabilization procedures on amnion cultured cells, we have observed that A7H2-antigen was associated with the cytoplasmic face of the plasma membrane and was resistant to treatments removing most cellular components and producing substratum-attached ventral membranes. We suggest that this macromolecular complex plays a role in specific subsets of cells involved in precise morphogenetic processes, possibly as a link with the external milieu or as a membrane associated structure.     

Abnormalities in neural crest cell migration in laminin alpha5 mutant mice

Although numerous in vitro experiments suggest that extracellular matrix molecules like laminin can influence neural crest migration, little is known about their function in the embryo. Here, we show that laminin alpha5, a gene up-regulated during neural crest induction, is localized in regions of newly formed cranial and trunk neural folds and adjacent neural crest migratory pathways in a manner largely conserved between chick and mouse. In laminin alpha5 mutant mice, neural crest migratory streams appear expanded in width compared to wild type. Conversely, neural folds exposed to laminin alpha5 in vitro show a reduction by half in the number of migratory neural crest cells. During gangliogenesis, laminin alpha5 mutants exhibit defects in condensing cranial sensory and trunk sympathetic ganglia. However, ganglia apparently recover at later stages. These data suggest that the laminin alpha5 subunit functions as a cue that restricts neural crest cells, focusing their migratory pathways and condensation into ganglia. Thus, it is required for proper migration and timely differentiation of some neural crest populations.     

Division of labor during trunk neural crest development

Neural crest cells, the migratory precursors of numerous cell types including the vertebrate peripheral nervous system, arise in the dorsal neural tube and follow prescribed routes into the embryonic periphery. While the timing and location of neural crest migratory pathways has been well documented in the trunk, a comprehensive collection of signals that guides neural crest migration along these paths has only recently been established. In this review, we outline the molecular cascade of events during trunk neural crest development. After describing the sequential routes taken by trunk neural crest cells, we consider the guidance cues that pattern these neural crest trajectories. We pay particular attention to segmental neural crest development and the steps and signals that generate a metameric peripheral nervous system, attempting to reconcile conflicting observations in chick and mouse. Finally, we compare cranial and trunk neural crest development in order to highlight common themes.