Environmental factors unveil dormant developmental capacities in multipotent progenitors of the trunk neural crest

The neural crest (NC), an ectoderm-derived structure of the vertebrate embryo, gives rise to the melanocytes, most of the peripheral nervous system and the craniofacial mesenchymal tissues (i.e., connective, bone, cartilage and fat cells). In the trunk of Amniotes, no mesenchymal tissues are derived from the NC. In certain in vitro conditions however, avian and murine trunk NC cells (TNCCs) displayed a limited mesenchymal differentiation capacity. Whether this capacity originates from committed precursors or from multipotent TNCCs was unknown. Here, we further investigated the potential of TNCCs to develop into mesenchymal cell types in vitro. We found that, in fact, quail TNCCs exhibit a high ability to differentiate into myofibroblasts, chondrocytes, lipid-laden adipocytes and mineralizing osteoblasts. In single cell cultures, both mesenchymal and neural cell types coexisted in TNCC clonal progeny: 78% of single cells yielded osteoblasts together with glial cells and neurons; moreover, TNCCs generated heterogenous clones with adipocytes, myofibroblasts, melanocytes and/or glial cells. Therefore, alike cephalic NCCs, early migratory TNCCs comprised multipotent progenitors able to generate both mesenchymal and melanocytic/neural derivatives, suggesting a continuum in NC developmental potentials along the neural axis. The skeletogenic capacity of the TNC, which was present in the exoskeletal armor of the extinct basal forms of Vertebrates and which persisted in the distal fin rays of extant teleost fish, thus did not totally disappear during vertebrate evolution. Mesenchymal potentials of the TNC, although not fulfilled during development, are still present in a dormant state in Amniotes and can be disclosed in in vitro culture. Whether these potentials are not expressed in vivo due to the presence of inhibitory cues or to the lack of permissive factors in the trunk environment remains to be understood.     

Different downstream pathways for Notch signaling are required for gliogenic and chondrogenic specification of mouse mesencephalic neural crest cells

We examined the roles of Notch signaling and fibroblast growth factors (FGFs) in the gliogenesis of mouse mesencephalic neural crest cells. The present study demonstrated that Notch activation or FGF treatment promotes the differentiation of glia expressing glial fibrillary acidic protein. Notch activation or FGF2 exposure during the first 48 h in culture was critical for glial differentiation. The promotion of gliogenesis by FGF2 was significantly suppressed by the inhibition of Notch signaling using Notch-1 siRNA. These data suggest that FGFs activate Notch signaling and that this activation promotes the gliogenic specification of mouse mesencephalic neural crest cells. Notch activation and FGF treatment have been shown to participate in the chondrogenic specification of these cells [Nakanishi, K., Chan, Y.S., Ito, K., 2007. Notch signaling is required for the chondrogenic specification of mouse mesencephalic neural crest cells. Mech. Dev. 124, 190–203]. Therefore, we analyzed whether or not there were differences between gliogenic and chondrogenic specifications in the downstream pathway of the Notch receptor. Whereas the activation of only the Deltex-mediated pathway was sufficient to promote glial specification, the activation of both RBP-J- and Deltex-dependent pathways was required for chondrogenic specification. These results suggest that the different downstream pathways of the Notch receptor participate in the gliogenic and chondrogenic specification of mouse mesencephalic neural crest cells.     

Plexin-A3 and plexin-A4 restrict the migration of sympathetic neurons but not their neural crest precursors

During development, the semaphorin family of guidance molecules is required for proper formation of the sympathetic nervous system. Plexins are receptors that mediate semaphorin signaling, but how plexins function during sympathetic development is not fully understood. Using phenotypic analyses of mutant mice in vivo, expression pattern studies, and in vitro assays, we show that plexin-A3 and plexin-A4 are essential for normal sympathetic development. This study confirms our previous in vitro findings that the two plexins differentially regulate the guidance of sympathetic axons. In addition, we find that semaphorin signaling through plexin-A3 and plexin-A4 restricts the migration of sympathetic neurons, but these two plexins function redundantly since migration defects are only observed in plexin-A3/-A4 double mutants. Surprisingly, our analysis also indicates that plexin-A3 and plexin-A4 are not required for guiding neural crest precursors prior to reaching the sympathetic anlagen. Immunoprecipitation studies suggest that these two plexins independently mediate secreted semaphorin signaling. Thus, plexin-A3 and plexin-A4 are expressed in newly-differentiated sympathetic neurons, but not their neural crest precursors. They function cooperatively to regulate the migration of sympathetic neurons and then differentially to guide the sympathetic axons.     

Matrix stiffness modulates the differentiation of neural crest stem cells in vivo

Stem cells are often transplanted with scaffolds for tissue regeneration; however, how the mechanical property of a scaffold modulates stem cell fate in vivo is not well understood. Here we investigated how matrix stiffness modulates stem cell differentiation in a model of vascular graft transplantation. Multipotent neural crest stem cells (NCSCs) were differentiated from induced pluripotent stem cells, embedded in the hydrogel on the outer surface of nanofibrous polymer grafts, and implanted into rat carotid arteries by anastomosis. After 3 months, NCSCs differentiated into smooth muscle cells (SMCs) near the outer surface of the polymer grafts; in contrast, NCSCs differentiated into glial cells in the most part of the hydrogel. Atomic force microscopy demonstrated a stiffer matrix near the polymer surface but much lower stiffness away from the polymer graft. Consistently, in vitro studies confirmed that stiff surface induced SMC genes whereas soft surface induced glial genes. These results suggest that the scaffold’s mechanical properties play an important role in directing stem cell differentiation in vivo, which has important implications in biomaterials design for stem cell delivery and tissue engineering.     

The effects of various nutritional supplements on the growth,migration and differentiation ofxenopus laevis neural crest cells in vitro

Summary This study investigates the nutritional requirements ofXenopus laevis neural crest cells and melanophores developing in vitro. A comparison is made between the growth and differentiation of cells in serum-containing medium and a chemically defined, serum-free medium that we have designed. Our chemically defined medium is more efficient than serum-supplemented medium in promoting proliferation of these cells. Several supplements are required to enhance culture development. These include insulin, α-melanocyte stimulating hormone, somatotropin, luteotrophic hormone, linoleic acid, uridine, and putrescine. In addition, collagen and fibronectin provide the most conductive environment tested for cell migration and adhesion. This work was supported by establishment and major equipment grants from the Alberta Heritage Foundation for Medical Research to N. C. M. Nadine C. Milos is a Heritage Medical Research Scholar of the Alberta Heritage Foundation for Medical Research.     

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

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

The avian embryo as a model to study the development of the neural crest: a long and still ongoing story

The aim of this review is to evoke briefly the progress that has been made in our knowledge about the contribution of the neural crest to the vertebrate body since it was discovered by Wilhelm His in 1868. Although first studied essentially in amphibian embryos, a large amount of what is known on this very special structure was gained by experimental work carried out on the avian embryo. The making of chimeras between quail and chick has permitted not only to analyse the normal course of neural crest cell migration and differentiation but also to reveal some of the cellular interactions that regulate these events. Looking to the future, we can foresee that the novel methods, which now allow to manipulate gene activities in definite groups of cells and at elected times in the developing embryo, will make the avian model even more instrumental than ever to approach the developmental problems raised by neural crest cell differentiation.     

Targeting of endothelin receptor-B to the neural crest

Endothelin receptor B (Ednrb) plays a critical role in the development of melanocytes and neurons and glia of the enteric nervous system. These distinct neural crest-derived cell types express Ednrb and share the property of intercalating into tissues, such as the intestine whose muscle precursor cells also express Ednrb. Such widespread Ednrb expression has been a significant obstacle in establishing precise roles for Ednrb in development. We describe here the production of an Ednrb allele floxed at exon 3 and its use in excising the receptor from mouse neural crest cells by use of Cre-recombinase driven by the Wnt1 promoter. Mice born with neural crest-specific excision of Ednrb possess aganglionic colon, lack trunk pigmentation, and die within 5 weeks due to megacolon. Ednrb receptor expression in these animals is absent only in the neural crest but present in surrounding smooth muscle cells. The absence of Ednrb from crest cells also results in a compensatory upregulation of Ednrb expression in other cells within the gut. We conclude that Ednrb loss only in neural crest cells is sufficient to produce the Hirschsprungs disease phenotype observed with genomic Ednrb mutations.     

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.     

Repulsive and attractive semaphorins cooperate to direct the navigation of cardiac neural crest cells

The cardiac neural crest, a subpopulation of the neural crest, contributes to the cardiac outflow tract formation during development. However, how it follows the defined long-range migratory pathway remains unclear. We show here that the migrating cardiac neural crest cells (NCCs) express Plexin-A2, Plexin-D1 and Neuropilin. The membrane-bound ligands for Plexin-A2, Semaphorin (Sema)6A and Sema6B, are expressed in the dorsal neural tube and the lateral pharyngeal arch mesenchyme (the NCC “routes”). Sema3C, a ligand for Plexin-D1/neuropilin-1, is expressed in the cardiac outflow tract (the NCC “target”). Sema6A and Sema6B repel neural crest cells, while Sema3C attracts neural crest cells. Sema6A and Sema6B repulsion and Sema3C attraction are diminished either when Plexin-A2 and Neuropilin-1, or when Plexin-D1, respectively, are knocked down in NCCs. When RNAi knockdown diminishes each receptor in NCCs, the NCCs fail to migrate into the cardiac outflow tract in the developing chick embryo. Furthermore, Plexin-A2-deficient mice exhibit defects of cardiac outflow tract formation. We therefore conclude that the coordination of repulsive cues provided by Sema6A/Sema6B through Plexin-A2 paired with the attractive cue by Sema3C through Plexin-D1 is required for the precise navigation of migrating cardiac NCCs.     

Smad4 is required to regulate the fate of cranial neural crest cells

Smad4 is the central mediator for TGF-β/BMP signals, which are involved in regulating cranial neural crest (CNC) cell formation, migration, proliferation and fate determination. It is unclear whether TGF-β/BMP signals utilize Smad-dependent or -independent pathways to control the development of CNC cells. To investigate the functional significance of Smad4 in regulating CNC cells, we generated mice with neural crest specific inactivation of the Smad4 gene. Our study shows that Smad4 is not required for the migration of CNC cells, but is required in neural crest cells for the development of the cardiac outflow tract. Smad4 is essential in mediating BMP signaling in the CNC-derived ectomesenchyme during early stages of tooth development because conditional inactivation of Smad4 in neural crest derived cells results in incisor and molar development arrested at the dental lamina stage. Furthermore, Smad-mediated TGF-β/BMP signaling controls the homeobox gene patterning of oral/aboral and proximal/distal domains within the first branchial arch. At the cellular level, a Smad4-mediated downstream target gene(s) is required for the survival of CNC cells in the proximal domain of the first branchial arch. Smad4 mutant mice show underdevelopment of the first branchial arch and midline fusion defects. Taken together, our data show that TGF-β/BMP signals rely on Smad-dependent pathways in the ectomesenchyme to mediate epithelial-mesenchymal interactions that control craniofacial organogenesis.     

Multivalent binding of PWWP2A to H2A.Z regulates mitosis and neural crest differentiation

Replacement of canonical histones with specialized histone variants promotes altering of chromatin structure and function. The essential histone variant H2A.Z affects various DNA‐based processes via poorly understood mechanisms. Here, we determine the comprehensive interactome of H2A.Z and identify PWWP2A as a novel H2A.Z‐nucleosome binder. PWWP2A is a functionally uncharacterized, vertebrate‐specific protein that binds very tightly to chromatin through a concerted multivalent binding mode. Two internal protein regions mediate H2A.Z‐specificity and nucleosome interaction, whereas the PWWP domain exhibits direct DNA binding. Genome‐wide mapping reveals that PWWP2A binds selectively to H2A.Z‐containing nucleosomes with strong preference for promoters of highly transcribed genes. In human cells, its depletion affects gene expression and impairs proliferation via a mitotic delay. While PWWP2A does not influence H2A.Z occupancy, the C‐terminal tail of H2A.Z is one important mediator to recruit PWWP2A to chromatin. Knockdown of PWWP2A in Xenopus results in severe cranial facial defects, arising from neural crest cell differentiation and migration problems. Thus, PWWP2A is a novel H2A.Z‐specific multivalent chromatin binder providing a surprising link between H2A.Z, chromosome segregation, and organ development.     

Early regulative ability of the neuroepithelium to form cardiac neural crest

The cardiac neural crest (arising from the level of hindbrain rhombomeres 6–8) contributes to the septation of the cardiac outflow tract and the formation of aortic arches. Removal of this population after neural tube closure results in severe septation defects in the chick, reminiscent of human birth defects. Because neural crest cells from other axial levels have regenerative capacity, we asked whether the cardiac neural crest might also regenerate at early stages in a manner that declines with time. Accordingly, we find that ablation of presumptive cardiac crest at stage 7, as the neural folds elevate, results in reformation of migrating cardiac neural crest by stage 13. Fate mapping reveals that the new population derives largely from the neuroepithelium ventral and rostral to the ablation. The stage of ablation dictates the competence of residual tissue to regulate and regenerate, as this capacity is lost by stage 9, consistent with previous reports. These findings suggest that there is a temporal window during which the presumptive cardiac neural crest has the capacity to regulate and regenerate, but this regenerative ability is lost earlier than in other neural crest populations.     

Twist function is required for the morphogenesis of the cephalic neural tube and the differentiation of the cranial neural crest cells in the mouse embryo

Loss of Twist function in the cranial mesenchyme of the mouse embryo causes failure of closure of the cephalic neural tube and malformation of the branchial arches. In the Twist(-/-) embryo, the expression of molecular markers that signify dorsal forebrain tissues is either absent or reduced, but those associated with ventral tissues display expanded domains of expression. Dorsoventral organization of the mid- and hindbrain and the anterior-posterior pattern of the neural tube are not affected. In the Twist(-/-) embryo, neural crest cells stray from the subectodermal migratory path and the late-migrating subpopulation invades the cell-free zone separating streams of cells going to the first and second branchial arches. Cell transplantation studies reveal that Twist activity is required in the cranial mesenchyme for directing the migration of the neural crest cells, as well as in the neural crest cells within the first branchial arch to achieve correct localization. Twist is also required for the proper differentiation of the first arch tissues into bone, muscle, and teeth.     

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.     

神经嵴发育异常导致综合征型耳聋的机制

综合征型耳聋(Syndromic hearing loss, SHL)现已报道400多种,大多数发病率低,临床常见的有Waardenburg综合征(WS)、先天性小耳畸形综合征、前庭导水管扩大综合征等。因SHL具有极强的临床和遗传异质性,所以对其遗传基础及发病机制的研究变得十分困难。以SOX10和PAX3为中心的基因作用网络引起的神经嵴细胞功能异常与WS、小耳畸形及前庭导水管扩大等表型相关。本课题组前期研究也证实该基因网络参与WS的发病机制。文章针对神经嵴发育异常导致相关综合征型耳聋的发病机制的研究进展进行了系统的阐述,分析并归纳了与综合征型耳聋发病相关的神经嵴发育异常基因互作网络,以期为系统地研究常见综合征型耳聋致病基因的定位克隆以及发病机制提供研究思路和理论基础。     

J. P. Hill and Katherine Watson's studies of the neural crest in marsupials

In the early part of the 20th century, J. P. Hill and K. P. Watson embarked on a comprehensive study of the development of the brain in Australian marsupials. Their work included series from three major groups: dasyurids, peramelids, and diprotodonts, covering early primitive streak through brain closure and folding stages. While the major part of the work was on the development of the brain, in the course of this work they documented that cellular proliferations from the neural plate provided much of the mesenchyme of the branchial arches. These proliferations are now known to be the neural crest. However, except for a very brief note, published shortly after Hill's death, this work was never published. In this study, I present Hill and Watson's work on the development of the early neural plate and the neural crest in marsupials. I compare their findings with published work on the South American marsupial, Monodelphis domestica and demonstrate that patterns reported in Monodelphis are general for marsupials. Further, using their data I demonstrate that in dasyurids, which are ultra-altricial at birth, the neural crest migrates early and in massive quantities, even relative to other marsupials. Finally, I discuss the historical context and speculate on reasons for why this work was unpublished. I find little support for ideas that Hill blocked publication because of loyalty to the germ layer theory. Instead, it appears primarily to have been a very large project that was simply orphaned as Watson and Hill pursued other activities.