scholarly journals Cancer-associated HIF-2α impacts trunk neural crest stemness

2020 ◽  
Author(s):  
Sofie Mohlin ◽  
Camilla U. Persson ◽  
Elina Fredlund ◽  
Emanuela Monni ◽  
Jessica M. Lindvall ◽  
...  
Keyword(s):  
Neural Crest ◽  
Normal Development ◽  
Hypoxia Inducible Factor ◽  
Neural Crest Cells ◽  
Sympathetic Ganglia ◽  
Stem Cell Population ◽  
Neural Crest Development ◽  
Trunk Neural Crest

AbstractThe neural crest is a stem cell population that gives rise to sympathetic ganglia, the cell type of origin of neuroblastoma. Hypoxia Inducible Factor (HIF)-2α is associated with high risk neuroblastoma, however, little is known about its role in normal neural crest development. To address this important question, here we show that HIF-2α is expressed in trunk neural crest cells of human, murine and avian embryos. Modulating HIF-2α in vivo not only causes developmental delays but also induces proliferation and stemness of neural crest cells while altering the number of cells migrating ventrally to sympathoadrenal sites. Transcriptome changes after loss of HIF-2α reflect the in vivo phenotype. The results suggest that expression levels of HIF-2α must be strictly controlled and abnormal levels increase stemness and may promote metastasis. Our findings help elucidate the role of HIF-2α during normal development with implications also in tumor initiation at the onset of neuroblastoma.

scholarly journals Lineage-specific requirements of β-catenin in neural crest development

2002 ◽  
Vol 159 (5) ◽  
pp. 867-880 ◽  
Author(s):  
Lisette Hari ◽  
Véronique Brault ◽  
Maurice Kléber ◽  
Hye-Youn Lee ◽  
Fabian Ille ◽  
...  
Keyword(s):  
Transcription Factor ◽  
Neural Crest ◽  
Neural Crest Cells ◽  
Neural Crest Stem Cells ◽  
Downstream Signaling ◽  
Neural Crest Development ◽  
Sensory Neurogenesis

β-Catenin plays a pivotal role in cadherin-mediated cell adhesion. Moreover, it is a downstream signaling component of Wnt that controls multiple developmental processes such as cell proliferation, apoptosis, and fate decisions. To study the role of β-catenin in neural crest development, we used the Cre/loxP system to ablate β-catenin specifically in neural crest stem cells. Although several neural crest–derived structures develop normally, mutant animals lack melanocytes and dorsal root ganglia (DRG). In vivo and in vitro analyses revealed that mutant neural crest cells emigrate but fail to generate an early wave of sensory neurogenesis that is normally marked by the transcription factor neurogenin (ngn) 2. This indicates a role of β-catenin in premigratory or early migratory neural crest and points to heterogeneity of neural crest cells at the earliest stages of crest development. In addition, migratory neural crest cells lateral to the neural tube do not aggregate to form DRG and are unable to produce a later wave of sensory neurogenesis usually marked by the transcription factor ngn1. We propose that the requirement of β-catenin for the specification of melanocytes and sensory neuronal lineages reflects roles of β-catenin both in Wnt signaling and in mediating cell–cell interactions.

The winged-helix transcription factor FoxD3 is important for establishing the neural crest lineage and repressing melanogenesis in avian embryos

Development ◽  
2001 ◽  
Vol 128 (8) ◽  
pp. 1467-1479 ◽  
Author(s):  
R. Kos ◽  
M.V. Reedy ◽  
R.L. Johnson ◽  
C.A. Erickson
Keyword(s):  
Transcription Factors ◽  
Neural Crest ◽  
Antisense Oligonucleotides ◽  
Neural Crest Cells ◽  
Winged Helix ◽  
Dorsal Neural Tube ◽  
Neural Crest Development ◽  
Mesenchymal Transformation ◽  
Winged Helix Transcription Factor

The winged-helix or forkhead class of transcription factors has been shown to play important roles in cell specification and lineage segregation. We have cloned the chicken homolog of FoxD3, a member of the winged-helix class of transcription factors, and analyzed its expression. Based on its expression in the dorsal neural tube and in all neural crest lineages except the late-emigrating melanoblasts, we predicted that FoxD3 might be important in the segregation of the neural crest lineage from the neural epithelium, and for repressing melanogenesis in early-migrating neural crest cells. Misexpression of FoxD3 by electroporation in the lateral neural epithelium early in neural crest development produced an expansion of HNK1 immunoreactivity throughout the neural epithelium, although these cells did not undergo an epithelial/mesenchymal transformation. To test whether FoxD3 represses melanogenesis in early migrating neural crest cells, we knocked down expression in cultured neural crest with antisense oligonucleotides and in vivo by treatment with morpholino antisense oligonucleotides. Both experimental approaches resulted in an expansion of the melanoblast lineage, probably at the expense of neuronal and glial lineages. Conversely, persistent expression of FoxD3 in late-migrating neural crest cells using RCAS viruses resulted in the failure of melanoblasts to develop. We suggest that FoxD3 plays two important roles in neural crest development. First, it is involved in the segregation of the neural crest lineage from the neuroepithelium. Second, it represses melanogenesis, thereby allowing other neural crest derivatives to differentiate during the early stages of neural crest patterning.

scholarly journals Migrating neural crest cells in the trunk of the avian embryo are multipotent

Development ◽  
1991 ◽  
Vol 112 (4) ◽  
pp. 913-920 ◽  
Author(s):  
S.E. Fraser ◽  
M. Bronner-Fraser
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Sympathetic Neurons ◽  
Morphological Characteristics ◽  
Neural Crest Cells ◽  
Cell Types ◽  
Sympathetic Ganglia ◽  
Avian Embryo ◽  
Developmental Potential ◽  
Trunk Neural Crest

Trunk neural crest cells migrate extensively and give rise to diverse cell types, including cells of the sensory and autonomic nervous systems. Previously, we demonstrated that many premigratory trunk neural crest cells give rise to descendants with distinct phenotypes in multiple neural crest derivatives. The results are consistent with the idea that neural crest cells are multipotent prior to their emigration from the neural tube and become restricted in phenotype after leaving the neural tube either during their migration or at their sites of localization. Here, we test the developmental potential of migrating trunk neural crest cells by microinjecting a vital dye, lysinated rhodamine dextran (LRD), into individual cells as they migrate through the somite. By two days after injection, the LRD-labelled clones contained from 2 to 67 cells, which were distributed unilaterally in all embryos. Most clones were confined to a single segment, though a few contributed to sympathetic ganglia over two segments. A majority of the clones gave rise to cells in multiple neural crest derivatives. Individual migrating neural crest cells gave rise to both sensory and sympathetic neurons (neurofilament-positive), as well as cells with the morphological characteristics of Schwann cells, and other non-neuronal cells (both neurofilament-negative). Even those clones contributing to only one neural crest derivative often contained both neurofilament-positive and neurofilament-negative cells. Our data demonstrate that migrating trunk neural crest cells can be multipotent, giving rise to cells in multiple neural crest derivatives, and contributing to both neuronal and non-neuronal elements within a given derivative.(ABSTRACT TRUNCATED AT 250 WORDS)

Avian neural crest cells can migrate in the dorsolateral path only if they are specified as melanocytes

Development ◽  
1995 ◽  
Vol 121 (3) ◽  
pp. 915-924 ◽  
Author(s):  
C.A. Erickson ◽  
T.L. Goins
Keyword(s):  
Neural Crest ◽  
Normal Development ◽  
Neural Crest Cells ◽  
Pigment Cells ◽  
Environmental Cues ◽  
Avian Embryo ◽  
Thoracic Level ◽  
Branchial Arches ◽  
Trunk Neural Crest ◽  
Migratory Pathway

Neural crest cells are conventionally believed to migrate arbitrarily into various pathways and to differentiate according to the environmental cues that they encounter. We present data consistent with the notion that melanocytes are directed, by virtue of their phenotype, into the dorsolateral path, whereas other neural crest derivatives are excluded. In the avian embryo, trunk neural crest cells that migrate ventrally differentiate largely into neurons and glial cells of the peripheral nervous system. Neural crest cells that migrate into the dorsolateral path become melanocytes, the pigment cells of the skin. Neural crest cells destined for the dorsolateral path are delayed in their migration until at least 24 hours after migration commences ventrally. Previous studies have suggested that invasion into the dorsolateral path is dependent upon a change in the migratory environment. A complementary possibility is that as neural crest cells differentiate into melanocytes they acquire the ability to take this pathway. When quail neural crest cells that have been grown in culture for 12 hours are labeled with Fluoro-gold and then grafted into the early migratory pathway at the thoracic level, they migrate only ventrally and are coincident with the host neural crest. When fully differentiated melanocytes (96 hours old) are back-grafted under identical conditions, however, they enter the dorsolateral path and invade the ectoderm at least one day prior to the host neural crest. Likewise, neural crest cells that have been cultured for at least 20 hours and are enriched in melanoblasts immediately migrate in the dorsolateral path, in addition to the ventral path, when back-grafted into the thoracic level. A population of neural crest cells depleted of melanoblasts--crest cells derived from the branchial arches--are not able to invade the dorsolateral path, suggesting that only pigment cells or their precursors are able to take this migratory route. These results suggest that as neural crest cells differentiate into melanocytes they can exploit the dorsolateral path immediately. Even when 12-hour crest cells are grafted into stage 19–21 embryos at an axial level where host crest are invading the dorsolateral path, these young neural crest cells do not migrate dorsolaterally. Conversely, melanoblasts or melanocytes grafted under the same circumstances are found in the ectoderm. These latter results suggest that during normal development neural crest cells must be specified, if not already beginning to differentiate, as melanocytes in order to take this path.(ABSTRACT TRUNCATED AT 400 WORDS)

scholarly journals Supracellular contraction at the rear of neural crest cell groups drives collective chemotaxis

Science ◽  
2018 ◽  
Vol 362 (6412) ◽  
pp. 339-343 ◽  
Author(s):  
Adam Shellard ◽  
András Szabó ◽  
Xavier Trepat ◽  
Roberto Mayor
Keyword(s):  
Neural Crest ◽  
Ex Vivo ◽  
Embryonic Stem ◽  
Neural Crest Cell ◽  
Neural Crest Cells ◽  
Stem Cell Population ◽  
Cell Group ◽  
Cell Groups ◽  
Cell Chemotaxis

Collective cell chemotaxis, the directed migration of cell groups along gradients of soluble chemical cues, underlies various developmental and pathological processes. We use neural crest cells, a migratory embryonic stem cell population whose behavior has been likened to malignant invasion, to study collective chemotaxis in vivo. StudyingXenopusand zebrafish, we have shown that the neural crest exhibits a tensile actomyosin ring at the edge of the migratory cell group that contracts in a supracellular fashion. This contractility is polarized during collective cell chemotaxis: It is inhibited at the front but persists at the rear of the cell cluster. The differential contractility drives directed collective cell migration ex vivo and in vivo through the intercalation of rear cells. Thus, in neural crest cells, collective chemotaxis works by rear-wheel drive.

The role of the non-canonical Wnt–planar cell polarity pathway in neural crest migration

2013 ◽  
Vol 457 (1) ◽  
pp. 19-26 ◽  
Author(s):  
Roberto Mayor ◽  
Eric Theveneau
Keyword(s):  
Neural Crest ◽  
Cell Polarity ◽  
Planar Cell Polarity ◽  
Neural Crest Cells ◽  
Contact Inhibition ◽  
Stem Cell Population ◽  
Planar Cell Polarity Pathway ◽  
Canonical Wnt ◽  
Neural Crest Migration

The neural crest is an embryonic stem cell population whose migratory behaviour has been likened to malignant invasion. The neural crest, as does cancer, undergoes an epithelial-to-mesenchymal transition and migrates to colonize almost all the tissues of the embryo. Neural crest cells exhibit collective cell migration, moving in streams of high directionality. The migratory neural crest streams are kept in shape by the presence of negative signals in their vicinity. The directionality of the migrating neural crest is achieved by contact-dependent cell polarization, in a phenomenon called contact inhibition of locomotion. Two cells experiencing contact inhibition of locomotion move away from each other after collision. However, if the cell density is high only cells exposed to a free edge can migrate away from the cluster leading to the directional migration of the whole group. Recent work performed in chicks, zebrafish and frogs has shown that the non-canonical Wnt–PCP (planar cell polarity) pathway plays a major role in neural crest migration. PCP signalling controls contact inhibition of locomotion between neural crest cells by localizing different PCP proteins at the site of cell contact during collision and locally regulating the activity of Rho GTPases. Upon collision RhoA (ras homologue family member A) is activated, whereas Rac1 is inhibited at the contact between two migrating neural crest cells, leading to the collapse of protrusions and the migration of cells away from one another. The present review summarizes the mechanisms that control neural crest migration and focuses on the role of non-canonical Wnt or PCP signalling in this process.

Delta signaling mediates segregation of neural crest and spinal sensory neurons from zebrafish lateral neural plate

Development ◽  
2000 ◽  
Vol 127 (13) ◽  
pp. 2873-2882 ◽  
Author(s):  
R.A. Cornell ◽  
J.S. Eisen
Keyword(s):  
Neural Crest ◽  
Point Mutation ◽  
Sensory Neurons ◽  
Genetic Difference ◽  
Neural Plate ◽  
Cranial Neural Crest ◽  
Neural Crest Development ◽  
Neural Crest Derivative ◽  
Trunk Neural Crest

We examined the role of Delta signaling in specification of two derivatives in zebrafish neural plate: Rohon-Beard spinal sensory neurons and neural crest. deltaA-expressing Rohon-Beard neurons are intermingled with premigratory neural crest cells in the trunk lateral neural plate. Embryos homozygous for a point mutation in deltaA, or with experimentally reduced delta signalling, have supernumerary Rohon-Beard neurons, reduced trunk-level expression of neural crest markers and lack trunk neural crest derivatives. Fin mesenchyme, a putative trunk neural crest derivative, is present in deltaA mutants, suggesting it segregates from other neural crest derivatives as early as the neural plate stage. Cranial neural crest derivatives are also present in deltaA mutants, revealing a genetic difference in regulation of trunk and cranial neural crest development.

scholarly journals In vivo transplantation of mammalian neural crest cells into chick hosts reveals a new autonomic sublineage restriction

Development ◽  
1999 ◽  
Vol 126 (19) ◽  
pp. 4351-4363 ◽  
Author(s):  
P.M. White ◽  
D.J. Anderson
Keyword(s):  
Neural Crest ◽  
Neural Crest Cells ◽  
Parasympathetic Ganglia ◽  
Neuronal Markers ◽  
Neural Crest Development ◽  
Parasympathetic Neurons ◽  
Neuronal Subtype ◽  
Transplantation System ◽  
Satellite Glia

The study of mammalian neural crest development has been limited by the lack of an accessible system for in vivo transplantation of these cells. We have developed a novel transplantation system to study lineage restriction in the rodent neural crest. Migratory rat neural crest cells (NCCs), transplanted into chicken embryos, can differentiate into sensory, sympathetic, and parasympathetic neurons, as shown by the expression of neuronal subtype-specific and pan-neuronal markers, as well as into Schwann cells and satellite glia. In contrast, an immunopurified population of enteric neural precursors (ENPs) from the fetal gut can also generate neurons in all of these ganglia, but only expresses appropriate neuronal subtype markers in Remak's and associated pelvic parasympathetic ganglia. ENPs also appear restricted in the kinds of glia they can generate in comparison to NCCs. Thus ENPs have parasympathetic and presumably enteric capacities, but not sympathetic or sensory capacities. These results identify a new autonomic lineage restriction in the neural crest, and suggest that this restriction preceeds the choice between neuronal and glial fates.

scholarly journals Hypoxia inducible factor‐2α importance for migration, proliferation, and self‐renewal of trunk neural crest cells

2020 ◽  
Author(s):  
Camilla U. Niklasson ◽  
Elina Fredlund ◽  
Emanuela Monni ◽  
Jessica M. Lindvall ◽  
Zaal Kokaia ◽  
...  
Keyword(s):  
Neural Crest ◽  
Hypoxia Inducible Factor ◽  
Neural Crest Cells ◽  
Self Renewal ◽  
Trunk Neural Crest

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

2003 ◽  
Vol 162 (2) ◽  
pp. 269-279 ◽  
Author(s):  
Maria Elena De Bellard ◽  
Yi Rao ◽  
Marianne Bronner-Fraser
Keyword(s):  
Neural Crest ◽  
Neural Crest Cells ◽  
Dual Function ◽  
In Vitro Experiments ◽  
Enteric Ganglia ◽  
Robo Receptors ◽  
Trunk Neural Crest ◽  
Differential Ability

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.

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