fbpx
Wikipedia

Neural crest

January 01, 1970

Neural crest cells are a temporary group of cells that arise from the embryonic ectoderm germ layer, and in turn give rise to a diverse cell lineage—including melanocytes, craniofacial cartilage and bone, smooth muscle, peripheral and enteric neurons and glia.[1][2]

Neural crest
The formation of neural crest during the process of neurulation. Neural crest is first induced in the region of the neural plate border. After neural tube closure, neural crest delaminates from the region between the dorsal neural tube and overlying ectoderm and migrates out towards the periphery.
Identifiers
MeSHD009432
TEcrest_by_E5.0.2.1.0.0.2 E5.0.2.1.0.0.2
FMA86666
Anatomical terminology
[edit on Wikidata]

After gastrulation, neural crest cells are specified at the border of the neural plate and the non-neural ectoderm. During neurulation, the borders of the neural plate, also known as the neural folds, converge at the dorsal midline to form the neural tube.[3] Subsequently, neural crest cells from the roof plate of the neural tube undergo an epithelial to mesenchymal transition, delaminating from the neuroepithelium and migrating through the periphery where they differentiate into varied cell types.[1] The emergence of neural crest was important in vertebrate evolution because many of its structural derivatives are defining features of the vertebrate clade.[4]

Underlying the development of neural crest is a gene regulatory network, described as a set of interacting signals, transcription factors, and downstream effector genes that confer cell characteristics such as multipotency and migratory capabilities.[5] Understanding the molecular mechanisms of neural crest formation is important for our knowledge of human disease because of its contributions to multiple cell lineages. Abnormalities in neural crest development cause neurocristopathies, which include conditions such as frontonasal dysplasia, Waardenburg–Shah syndrome, and DiGeorge syndrome.[1]

Therefore, defining the mechanisms of neural crest development may reveal key insights into vertebrate evolution and neurocristopathies.

History edit

Neural crest was first described in the chick embryo by Wilhelm His Sr. in 1868 as "the cord in between" (Zwischenstrang) because of its origin between the neural plate and non-neural ectoderm.[1] He named the tissue ganglionic crest since its final destination was each lateral side of the neural tube where it differentiated into spinal ganglia.[6] During the first half of the 20th century, the majority of research on neural crest was done using amphibian embryos which was reviewed by Hörstadius (1950) in a well known monograph.[7]

Cell labeling techniques advanced the field of neural crest because they allowed researchers to visualize the migration of the tissue throughout the developing embryos. In the 1960s, Weston and Chibon utilized radioisotopic labeling of the nucleus with tritiated thymidine in chick and amphibian embryo respectively. However, this method suffers from drawbacks of stability, since every time the labeled cell divides the signal is diluted. Modern cell labeling techniques such as rhodamine-lysinated dextran and the vital dye diI have also been developed to transiently mark neural crest lineages.[6]

The quail-chick marking system, devised by Nicole Le Douarin in 1969, was another instrumental technique used to track neural crest cells.[8][9] Chimeras, generated through transplantation, enabled researchers to distinguish neural crest cells of one species from the surrounding tissue of another species. With this technique, generations of scientists were able to reliably mark and study the ontogeny of neural crest cells.

Induction edit

A molecular cascade of events is involved in establishing the migratory and multipotent characteristics of neural crest cells. This gene regulatory network can be subdivided into the following four sub-networks described below.

Inductive signals edit

First, extracellular signaling molecules, secreted from the adjacent epidermis and underlying mesoderm such as Wnts, BMPs and Fgfs separate the non-neural ectoderm (epidermis) from the neural plate during neural induction.[1][4]

Wnt signaling has been demonstrated in neural crest induction in several species through gain-of-function and loss-of-function experiments. In coherence with this observation, the promoter region of slug (a neural crest specific gene) contains a binding site for transcription factors involved in the activation of Wnt-dependent target genes, suggestive of a direct role of Wnt signaling in neural crest specification.[10]

The current role of BMP in neural crest formation is associated with the induction of the neural plate. BMP antagonists diffusing from the ectoderm generates a gradient of BMP activity. In this manner, the neural crest lineage forms from intermediate levels of BMP signaling required for the development of the neural plate (low BMP) and epidermis (high BMP).[1]

Fgf from the paraxial mesoderm has been suggested as a source of neural crest inductive signal. Researchers have demonstrated that the expression of dominate-negative Fgf receptor in ectoderm explants blocks neural crest induction when recombined with paraxial mesoderm.[11] The understanding of the role of BMP, Wnt, and Fgf pathways on neural crest specifier expression remains incomplete.

Neural plate border specifiers edit

Signaling events that establish the neural plate border lead to the expression of a set of transcription factors delineated here as neural plate border specifiers. These molecules include Zic factors, Pax3/7, Dlx5, Msx1/2 which may mediate the influence of Wnts, BMPs, and Fgfs. These genes are expressed broadly at the neural plate border region and precede the expression of bona fide neural crest markers.[4]

Experimental evidence places these transcription factors upstream of neural crest specifiers. For example, in Xenopus Msx1 is necessary and sufficient for the expression of Slug, Snail, and FoxD3.[12] Furthermore, Pax3 is essential for FoxD3 expression in mouse embryos.[13]

Neural crest specifiers edit

Following the expression of neural plate border specifiers is a collection of genes including Slug/Snail, FoxD3, Sox10, Sox9, AP-2 and c-Myc. This suite of genes, designated here as neural crest specifiers, are activated in emergent neural crest cells. At least in Xenopus, every neural crest specifier is necessary and/or sufficient for the expression of all other specifiers, demonstrating the existence of extensive cross-regulation.[4] Moreover, this model organism was instrumental in the elucidation of the role of the Hedgehog signaling pathway in the specification of the neural crest, with the transcription factor Gli2 playing a key role.[14]

Outside of the tightly regulated network of neural crest specifiers are two other transcription factors Twist and Id. Twist, a bHLH transcription factor, is required for mesenchyme differentiation of the pharyngeal arch structures.[15] Id is a direct target of c-Myc and is known to be important for the maintenance of neural crest stem cells.[16]

Neural crest effector genes edit

Finally, neural crest specifiers turn on the expression of effector genes, which confer certain properties such as migration and multipotency. Two neural crest effectors, Rho GTPases and cadherins, function in delamination by regulating cell morphology and adhesive properties. Sox9 and Sox10 regulate neural crest differentiation by activating many cell-type-specific effectors including Mitf, P0, Cx32, Trp and cKit.[4]

 
Putative neural crest gene-regulatory network functioning at the neural plate border in vertebrates. Red arrows represent proven direct regulatory interactions. Black arrows show genetic interactions based on loss-of-function and gain-of-functions studies. Gray lines denote repression. Adapted from Bronner-Fraser 2004

Migration edit

Further information: Collective cell migration
 
Delamination of neural crest cells during development. Downregulation of CAMs and tight junction proteins is followed by secretion of MMPs and subsequent delamination.

The migration of neural crest cells involves a highly coordinated cascade of events that begins with closure of the dorsal neural tube.

Delamination edit

After fusion of the neural fold to create the neural tube, cells originally located in the neural plate border become neural crest cells.[17] For migration to begin, neural crest cells must undergo a process called delamination that involves a full or partial epithelial-mesenchymal transition (EMT).[18] Delamination is defined as the separation of tissue into different populations, in this case neural crest cells separating from the surrounding tissue.[19] Conversely, EMT is a series of events coordinating a change from an epithelial to mesenchymal phenotype.[18] For example, delamination in chick embryos is triggered by a BMP/Wnt cascade that induces the expression of EMT promoting transcription factors such as SNAI2 and FoxD3.[19] Although all neural crest cells undergo EMT, the timing of delamination occurs at different stages in different organisms: in Xenopus laevis embryos there is a massive delamination that occurs when the neural plate is not entirely fused, whereas delamination in the chick embryo occurs during fusion of the neural fold.[19]

Prior to delamination, presumptive neural crest cells are initially anchored to neighboring cells by tight junction proteins such as occludin and cell adhesion molecules such as NCAM and N-Cadherin.[20] Dorsally expressed BMPs initiate delamination by inducing the expression of the zinc finger protein transcription factors snail, slug, and twist.[17] These factors play a direct role in inducing the epithelial-mesenchymal transition by reducing expression of occludin and N-Cadherin in addition to promoting modification of NCAMs with polysialic acid residues to decrease adhesiveness.[17][21] Neural crest cells also begin expressing proteases capable of degrading cadherins such as ADAM10[22] and secreting matrix metalloproteinases (MMPs) that degrade the overlying basal lamina of the neural tube to allow neural crest cells to escape.[20] Additionally, neural crest cells begin expressing integrins that associate with extracellular matrix proteins, including collagen, fibronectin, and laminin, during migration.[23] Once the basal lamina becomes permeable the neural crest cells can begin migrating throughout the embryo.

Migration edit

 
Migration of neural crest cells during development. Grey arrows indicate the direction of the paths crest cells migrate. (R=Rostral, C=Caudal)

Neural crest cell migration occurs in a rostral to caudal direction without the need of a neuronal scaffold such as along a radial glial cell. For this reason the crest cell migration process is termed "free migration". Instead of scaffolding on progenitor cells, neural crest migration is the result of repulsive guidance via EphB/EphrinB and semaphorin/neuropilin signaling, interactions with the extracellular matrix, and contact inhibition with one another.[17] While Ephrin and Eph proteins have the capacity to undergo bi-directional signaling, neural crest cell repulsion employs predominantly forward signaling to initiate a response within the receptor bearing neural crest cell.[23] Burgeoning neural crest cells express EphB, a receptor tyrosine kinase, which binds the EphrinB transmembrane ligand expressed in the caudal half of each somite. When these two domains interact it causes receptor tyrosine phosphorylation, activation of rhoGTPases, and eventual cytoskeletal rearrangements within the crest cells inducing them to repel. This phenomenon allows neural crest cells to funnel through the rostral portion of each somite.[17]

Semaphorin-neuropilin repulsive signaling works synergistically with EphB signaling to guide neural crest cells down the rostral half of somites in mice. In chick embryos, semaphorin acts in the cephalic region to guide neural crest cells through the pharyngeal arches. On top of repulsive repulsive signaling, neural crest cells express β1and α4 integrins which allows for binding and guided interaction with collagen, laminin, and fibronectin of the extracellular matrix as they travel. Additionally, crest cells have intrinsic contact inhibition with one another while freely invading tissues of different origin such as mesoderm.[17] Neural crest cells that migrate through the rostral half of somites differentiate into sensory and sympathetic neurons of the peripheral nervous system. The other main route neural crest cells take is dorsolaterally between the epidermis and the dermamyotome. Cells migrating through this path differentiate into pigment cells of the dermis. Further neural crest cell differentiation and specification into their final cell type is biased by their spatiotemporal subjection to morphogenic cues such as BMP, Wnt, FGF, Hox, and Notch.[20]

Clinical significance edit

Neurocristopathies result from the abnormal specification, migration, differentiation or death of neural crest cells throughout embryonic development.[24][25] This group of diseases comprises a wide spectrum of congenital malformations affecting many newborns. Additionally, they arise because of genetic defects affecting the formation of neural crest and because of the action of Teratogens [26]

Waardenburg's syndrome edit

Waardenburg's syndrome is a neurocristopathy that results from defective neural crest cell migration. The condition's main characteristics include piebaldism and congenital deafness. In the case of piebaldism, the colorless skin areas are caused by a total absence of neural crest-derived pigment-producing melanocytes.[27] There are four different types of Waardenburg's syndrome, each with distinct genetic and physiological features. Types I and II are distinguished based on whether or not family members of the affected individual have dystopia canthorum.[28] Type III gives rise to upper limb abnormalities. Lastly, type IV is also known as Waardenburg-Shah syndrome, and afflicted individuals display both Waardenburg's syndrome and Hirschsprung's disease.[29] Types I and III are inherited in an autosomal dominant fashion,[27] while II and IV exhibit an autosomal recessive pattern of inheritance. Overall, Waardenburg's syndrome is rare, with an incidence of ~ 2/100,000 people in the United States. All races and sexes are equally affected.[27] There is no current cure or treatment for Waardenburg's syndrome.

Hirschsprung's Disease edit

Also implicated in defects related to neural crest cell development and migration is Hirschsprung's disease (HD or HSCR), characterized by a lack of innervation in regions of the intestine. This lack of innervation can lead to further physiological abnormalities like an enlarged colon (megacolon), obstruction of the bowels, or even slowed growth. In healthy development, neural crest cells migrate into the gut and form the enteric ganglia. Genes playing a role in the healthy migration of these neural crest cells to the gut include RET, GDNF, GFRα, EDN3, and EDNRB. RET, a receptor tyrosine kinase (RTK), forms a complex with GDNF and GFRα. EDN3 and EDNRB are then implicated in the same signaling network. When this signaling is disrupted in mice, aganglionosis, or the lack of these enteric ganglia occurs.[30]

Fetal Alcohol Spectrum Disorder edit

Prenatal alcohol exposure (PAE) is among the most common causes of developmental defects.[31] Depending on the extent of the exposure and the severity of the resulting abnormalities, patients are diagnosed within a continuum of disorders broadly labeled Fetal Alcohol Spectrum Disorder (FASD). Severe FASD can impair neural crest migration, as evidenced by characteristic craniofacial abnormalities including short palpebral fissures, an elongated upper lip, and a smoothened philtrum. However, due to the promiscuous nature of ethanol binding, the mechanisms by which these abnormalities arise is still unclear. Cell culture explants of neural crest cells as well as in vivo developing zebrafish embryos exposed to ethanol show a decreased number of migratory cells and decreased distances travelled by migrating neural crest cells. The mechanisms behind these changes are not well understood, but evidence suggests PAE can increase apoptosis due to increased cytosolic calcium levels caused by IP3-mediated release of calcium from intracellular stores. It has also been proposed that the decreased viability of ethanol-exposed neural crest cells is caused by increased oxidative stress. Despite these, and other advances much remains to be discovered about how ethanol affects neural crest development. For example, it appears that ethanol differentially affects certain neural crest cells over others; that is, while craniofacial abnormalities are common in PAE, neural crest-derived pigment cells appear to be minimally affected.[32]

DiGeorge syndrome edit

DiGeorge syndrome is associated with deletions or translocations of a small segment in the human chromosome 22. This deletion may disrupt rostral neural crest cell migration or development. Some defects observed are linked to the pharyngeal pouch system, which receives contribution from rostral migratory crest cells. The symptoms of DiGeorge syndrome include congenital heart defects, facial defects, and some neurological and learning disabilities. Patients with 22q11 deletions have also been reported to have higher incidence of schizophrenia and bipolar disorder.[33]

Treacher Collins Syndrome edit

Treacher Collins Syndrome (TCS) results from the compromised development of the first and second pharyngeal arches during the early embryonic stage, which ultimately leads to mid and lower face abnormalities. TCS is caused by the missense mutation of the TCOF1 gene, which causes neural crest cells to undergo apoptosis during embryogenesis. Although mutations of the TCOF1 gene are among the best characterized in their role in TCS, mutations in POLR1C and POLR1D genes have also been linked to the pathogenesis of TCS.[34]

Cell lineages edit

Neural crest cells originating from different positions along the anterior-posterior axis develop into various tissues. These regions of neural crest can be divided into four main functional domains, which include the cranial neural crest, trunk neural crest, vagal and sacral neural crest, and cardiac neural crest.

Cranial neural crest edit

Main article: cranial neural crest

Cranial neural crest migrates dorsolaterally to form the craniofacial mesenchyme that differentiates into various cranial ganglia and craniofacial cartilages and bones.[21] These cells enter the pharyngeal pouches and arches where they contribute to the thymus, bones of the middle ear and jaw and the odontoblasts of the tooth primordia.[35]

Trunk neural crest edit

Main article: trunk neural crest

Trunk neural crest gives rise two populations of cells.[36] One group of cells fated to become melanocytes migrates dorsolaterally into the ectoderm towards the ventral midline. A second group of cells migrates ventrolaterally through the anterior portion of each sclerotome. The cells that stay in the sclerotome form the dorsal root ganglia, whereas those that continue more ventrally form the sympathetic ganglia, adrenal medulla, and the nerves surrounding the aorta.[35]

Vagal and sacral neural crest edit

The vagal and sacral neural crest cells develop into the ganglia of the enteric nervous system and the parasympathetic ganglia.[35]

Cardiac neural crest edit

Main article: cardiac neural crest

Cardiac neural crest develops into melanocytes, cartilage, connective tissue and neurons of some pharyngeal arches. Also, this domain gives rise to regions of the heart such as the musculo-connective tissue of the large arteries, and part of the septum, which divides the pulmonary circulation from the aorta.[35] The semilunar valves of the heart are associated with neural crest cells according to new research.[37]

Evolution edit

Several structures that distinguish the vertebrates from other chordates are formed from the derivatives of neural crest cells. In their "New head" theory, Gans and Northcut argue that the presence of neural crest was the basis for vertebrate specific features, such as sensory ganglia and cranial skeleton. Furthermore, the appearance of these features was pivotal in vertebrate evolution because it enabled a predatory lifestyle.[38][39]

However, considering the neural crest a vertebrate innovation does not mean that it arose de novo. Instead, new structures often arise through modification of existing developmental regulatory programs. For example, regulatory programs may be changed by the co-option of new upstream regulators or by the employment of new downstream gene targets, thus placing existing networks in a novel context.[40][41] This idea is supported by in situ hybridization data that shows the conservation of the neural plate border specifiers in protochordates, which suggest that part of the neural crest precursor network was present in a common ancestor to the chordates.[5] In some non-vertebrate chordates such as tunicates a lineage of cells (melanocytes) has been identified, which are similar to neural crest cells in vertebrates. This implies that a rudimentary neural crest existed in a common ancestor of vertebrates and tunicates.[42]

Neural crest derivatives edit

Ectomesenchyme (also known as mesectoderm):[43] odontoblasts, dental papillae, the chondrocranium (nasal capsule, Meckel's cartilage, scleral ossicles, quadrate, articular, hyoid and columella), tracheal and laryngeal cartilage, the dermatocranium (membranous bones), dorsal fins and the turtle plastron (lower vertebrates), pericytes and smooth muscle of branchial arteries and veins, tendons of ocular and masticatory muscles, connective tissue of head and neck glands (pituitary, salivary, lachrymal, thymus, thyroid) dermis and adipose tissue of calvaria, ventral neck and face

Endocrine cells: chromaffin cells of the adrenal medulla, glomus cells type I/II.

Peripheral nervous system: Sensory neurons and glia of the dorsal root ganglia, cephalic ganglia (VII and in part, V, IX, and X), Rohon-Beard cells, some Merkel cells in the whisker,[44][45] Satellite glial cells of all autonomic and sensory ganglia, Schwann cells of all peripheral nerves.

Enteric cells: Enterochromaffin cells.[46]

Melanocytes, iris muscle and pigment cells, and even associated with some tumors (such as melanotic neuroectodermal tumor of infancy).

See also edit

References edit

  1. ^ a b c d e f Huang, X.; Saint-Jeannet, J.P. (2004). "Induction of the neural crest and the opportunities of life on the edge". Dev. Biol. 275 (1): 1–11. doi:10.1016/j.ydbio.2004.07.033. PMID 15464568.
  2. ^ Shakhova, Olga; Sommer, Lukas (2008). "Neural crest-derived stem cells". StemBook. Harvard Stem Cell Institute. doi:10.3824/stembook.1.51.1. PMID 20614636. Retrieved 27 December 2019.
  3. ^ Brooker, R.J. 2014, Biology, 3rd edn, McGraw-Hill, New York, NY, 1084
  4. ^ a b c d e Meulemans, D.; Bronner-Fraser, M. (2004). "Gene-regulatory interactions in neural crest evolution and development". Dev Cell. 7 (3): 291–9. doi:10.1016/j.devcel.2004.08.007. PMID 15363405.
  5. ^ a b Sauka-Spengler, T.; Meulemans, D.; Jones, M.; Bronner-Fraser, M. (2007). "Ancient evolutionary origin of the neural crest gene regulatory network". Dev Cell. 13 (3): 405–20. doi:10.1016/j.devcel.2007.08.005. PMID 17765683.
  6. ^ a b Le Douarin, N.M. (2004). "The avian embryo as a model to study the development of the neural crest: a long and still ongoing story". Mech. Dev. 121 (9): 1089–102. doi:10.1016/j.mod.2004.06.003. PMID 15296974.
  7. ^ Hörstadius, S. (1950). The Neural Crest: Its Properties and Derivatives in the Light of Experimental Research. Oxford University Press, London, 111 p.
  8. ^ Le Douarin, N.M. (1969). "Particularités du noyau interphasique chez la Caille japonaise (Coturnix coturnix japonica). Utilisation de ces particularités comme "marquage biologique" dans les recherches sur les interactions tissulaires et les migrations cellulaires au cours de l'ontogenèse"". Bull Biol Fr Belg. 103 (3): 435–52. PMID 4191116.
  9. ^ Le Douarin, N.M. (1973). "A biological cell labeling technique and its use in experimental embryology". Dev Biol. 30 (1): 217–22. doi:10.1016/0012-1606(73)90061-4. PMID 4121410.
  10. ^ Vallin, J.; et al. (2001). "Cloning and characterization of the three Xenopus slug promoters reveal direct regulation by Lef/beta-catenin signaling". J Biol Chem. 276 (32): 30350–8. doi:10.1074/jbc.M103167200. PMID 11402039.
  11. ^ Mayor, R.; Guerrero, N.; Martinez, C. (1997). "Role of FGF and noggin in neural crest induction". Dev Biol. 189 (1): 1–12. doi:10.1006/dbio.1997.8634. PMID 9281332.
  12. ^ Tribulo, C.; et al. (2003). "Regulation of Msx genes by Bmp gradient is essential for neural crest specification". Development. 130 (26): 6441–52. doi:10.1242/dev.00878. hdl:11336/95313. PMID 14627721.
  13. ^ Dottori, M.; Gross, M.K.; Labosky, P.; Goulding, M. (2001). "The winged-helix transcription factor Foxd3 suppresses interneuron differentiation and promotes neural crest cell fate". Development. 128 (21): 4127–4138. doi:10.1242/dev.128.21.4127. PMID 11684651.
  14. ^ Cerrizuela, Santiago; Vega-López, Guillermo A.; Palacio, María Belén; Tríbulo, Celeste; Aybar, Manuel J. (2018-12-01). "Gli2 is required for the induction and migration of Xenopus laevis neural crest". Mechanisms of Development. 154: 219–239. doi:10.1016/j.mod.2018.07.010. hdl:11336/101714. ISSN 0925-4773. PMID 30086335.
  15. ^ Vincentz, J.W.; et al. (2008). "An absence of Twist1 results in aberrant cardiac neural crest morphogenesis". Dev Biol. 320 (1): 131–9. doi:10.1016/j.ydbio.2008.04.037. PMC 2572997. PMID 18539270.
  16. ^ Light, W.; et al. (2005). "Xenopus Id3 is required downstream of Myc for the formation of multipotent neural crest progenitor cells". Development. 132 (8): 1831–41. doi:10.1242/dev.01734. PMID 15772131.
  17. ^ a b c d e f Sanes, Dan (2012). Development of the Nervous System, 3rd ed. Oxford: ELSEVIER INC. pp. 70–72. ISBN 978-0123745392.
  18. ^ a b Lamouille, Samy (2014). "Molecular mechanisms of epithelial–mesenchymal transition". Nature Reviews Molecular Cell Biology. 15 (3): 178–196. doi:10.1038/nrm3758. PMC 4240281. PMID 24556840.
  19. ^ a b c Theveneau, Eric (2012). "Neural crest delamination and migration: From epithelium-to-mesenchyme transition to collective cell migration" (PDF). Developmental Biology. 366 (1): 34–54. doi:10.1016/j.ydbio.2011.12.041. PMID 22261150.
  20. ^ a b c Kandel, Eric (2013). Principles of Neural Science. New York: The McGraw-Hill Companies, Inc. pp. 1197–1199. ISBN 978-0-07-139011-8.
  21. ^ a b Taneyhill, L.A. (2008). "To adhere or not to adhere: the role of Cadherins in neural crest development". Cell Adh Migr. 2, 223–30.
  22. ^ Mayor, Roberto (2013). "The Neural Crest". Development. 140 (11): 2247–2251. doi:10.1242/dev.091751. PMID 23674598.
  23. ^ a b Sakuka-Spengler, Tatjana (2008). "A gene regulatory network orchestrates neural crest formation". Nature Reviews Molecular Cell Biology. 9 (7): 557–568. doi:10.1038/nrm2428. PMID 18523435. S2CID 10746234.
  24. ^ Vega-Lopez, Guillermo A.; Cerrizuela, Santiago; Tribulo, Celeste; Aybar, Manuel J. (2018-12-01). "Neurocristopathies: New insights 150 years after the neural crest discovery". Developmental Biology. The Neural Crest: 150 years after His' discovery. 444: S110–S143. doi:10.1016/j.ydbio.2018.05.013. ISSN 0012-1606. PMID 29802835.
  25. ^ Bolande, Robert P. (1974-07-01). "The neurocristopathies: A unifying concept of disease arising in neural crest maldevelopment". Human Pathology. 5 (4): 409–429. doi:10.1016/S0046-8177(74)80021-3. ISSN 0046-8177.
  26. ^ Cerrizuela, Santiago; Vega‐Lopez, Guillermo A.; Aybar, Manuel J. (2020-01-11). "The role of teratogens in neural crest development". Birth Defects Research. 112 (8): 584–632. doi:10.1002/bdr2.1644. ISSN 2472-1727. PMID 31926062. S2CID 210151171.
  27. ^ a b c Mallory, S.B.; Wiener, E; Nordlund, J.J. (1986). "Waardenburg's Syndrome with Hirschprung's Disease: A Neural Crest Defect". Pediatric Dermatology. 3 (2): 119–124. doi:10.1111/j.1525-1470.1986.tb00501.x. PMID 3952027. S2CID 23858201.
  28. ^ Arias, S (1971). "Genetic heterogeneity in the Waardenburg's syndrome". Birth Defects B. 07 (4): 87–101. PMID 5006208.
  29. ^ "Waardenburg syndrome". Genetics Home Reference. October 2012.
  30. ^ Rogers, J. M. (2016). "Search for the missing lncs: gene regulatory networks in neural crest development and long non-coding RNA biomarkers of Hirschsprung's disease". Neurogastroenterol Motil. 28 (2): 161–166. doi:10.1111/nmo.12776. PMID 26806097. S2CID 12394126.
  31. ^ Sampson, P. D.; Streissguth, A. P.; Bookstein, F. L.; Little, R. E.; Clarren, S. K.; Dehaene, P.; Graham, J. M. Jr (1997). "The incidence of fetal alcohol syndrome and prevalence of the alcohol-related neurodevelopmental disorder". Teratology. 56 (5): 317–326. doi:10.1002/(SICI)1096-9926(199711)56:5<317::AID-TERA5>3.0.CO;2-U. PMID 9451756.
  32. ^ Smith, S. M.; Garic, A.; Flentke, G. R.; Berres, M. E. (2014). "Neural crest development in fetal alcohol syndrome". Birth Defects Research Part C: Embryo Today: Reviews. 102 (3): 210–220. doi:10.1002/bdrc.21078. PMC 4827602. PMID 25219761.
  33. ^ Scambler, Peter J. (2000). "The 22q11 deletion syndromes". Human Molecular Genetics. 9 (16): 2421–2426. doi:10.1093/hmg/9.16.2421. PMID 11005797.
  34. ^ Ahmed, M.; Ye, X.; Taub, P. (2016). "Review of the Genetic Basis of Jaw Malformations". Journal of Pediatric Genetics. 05 (4): 209–219. doi:10.1055/s-0036-1593505. PMC 5123890. PMID 27895973.
  35. ^ a b c d Gilbert, Scott F. (2000). The Neural Crest. Sinauer Associates.
  36. ^ Vega-Lopez, Guillermo A.; Cerrizuela, Santiago; Aybar, Manuel J. (2017). "Trunk neural crest cells: formation, migration and beyond". The International Journal of Developmental Biology. 61 (1–2): 5–15. doi:10.1387/ijdb.160408gv. hdl:11336/53692. ISSN 0214-6282. PMID 28287247.
  37. ^ Takamura, Kazushi; Okishima, Takahiro; Ohdo, Shozo; Hayakawa, Kunio (1990). "Association of cephalic neural crest cells with cardiovascular development, particularly that of the semilunar valves". Anatomy and Embryology. 182 (3): 263–72. doi:10.1007/BF00185519. PMID 2268069. S2CID 32986727.
  38. ^ Gans, C.; Northcutt, R. G. (1983). "Neural crest and the origin of vertebrates: A new head". Science. 220 (4594): 268–274. Bibcode:1983Sci...220..268G. doi:10.1126/science.220.4594.268. PMID 17732898. S2CID 39290007.
  39. ^ Northcutt, Glenn (2005). "The new head hypothesis revisited". Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. 304B (4): 274–297. doi:10.1002/jez.b.21063. PMID 16003768.
  40. ^ Sauka-Spengler, T.; Bronner-Fraser, M. (2006). "Development and evolution of the migratory neural crest: a gene regulatory perspective". Curr Opin Genet Dev. 13 (4): 360–6. doi:10.1016/j.gde.2006.06.006. PMID 16793256.
  41. ^ Donoghue, P.C.; Graham, A.; Kelsh, R.N. (2008). "The origin and evolution of the neural crest". BioEssays. 30 (6): 530–41. doi:10.1002/bies.20767. PMC 2692079. PMID 18478530.
  42. ^ Abitua, P. B.; Wagner, E.; Navarrete, I. A.; Levine, M. (2012). "Identification of a rudimentary neural crest in a non-vertebrate chordate". Nature. 492 (7427): 104–107. Bibcode:2012Natur.492..104A. doi:10.1038/nature11589. PMC 4257486. PMID 23135395.
  43. ^ Kalcheim, C. and Le Douarin, N. M. (1998). The Neural Crest (2nd ed.). Cambridge, U. K.: Cambridge University Press.
  44. ^ Van Keymeulen, A; Mascre, G; Youseff, KK; et al. (October 2009). "Epidermal progenitors give rise to Merkel cells during embryonic development and adult homeostasis". J. Cell Biol. 187 (1): 91–100. doi:10.1083/jcb.200907080. PMC 2762088. PMID 19786578.
  45. ^ Szeder, V; Grim, M; Halata, Z; Sieber-Blum, M (January 2003). "Neural crest origin of mammalian Merkel cells". Dev. Biol. 253 (2): 258–63. doi:10.1016/s0012-1606(02)00015-5. PMID 12645929.
  46. ^ Lake, JI; Heuckeroth, RO (1 July 2013). "Enteric nervous system development: migration, differentiation, and disease". American Journal of Physiology. Gastrointestinal and Liver Physiology. 305 (1): G1–24. doi:10.1152/ajpgi.00452.2012. PMC 3725693. PMID 23639815.

External links edit

January 01, 1970
neural, crest, cells, temporary, group, cells, that, arise, from, embryonic, ectoderm, germ, layer, turn, give, rise, diverse, cell, lineage, including, melanocytes, craniofacial, cartilage, bone, smooth, muscle, peripheral, enteric, neurons, glia, formation, . Neural crest cells are a temporary group of cells that arise from the embryonic ectoderm germ layer and in turn give rise to a diverse cell lineage including melanocytes craniofacial cartilage and bone smooth muscle peripheral and enteric neurons and glia 1 2 Neural crestThe formation of neural crest during the process of neurulation Neural crest is first induced in the region of the neural plate border After neural tube closure neural crest delaminates from the region between the dorsal neural tube and overlying ectoderm and migrates out towards the periphery IdentifiersMeSHD009432TEcrest by E5 0 2 1 0 0 2 E5 0 2 1 0 0 2FMA86666Anatomical terminology edit on Wikidata After gastrulation neural crest cells are specified at the border of the neural plate and the non neural ectoderm During neurulation the borders of the neural plate also known as the neural folds converge at the dorsal midline to form the neural tube 3 Subsequently neural crest cells from the roof plate of the neural tube undergo an epithelial to mesenchymal transition delaminating from the neuroepithelium and migrating through the periphery where they differentiate into varied cell types 1 The emergence of neural crest was important in vertebrate evolution because many of its structural derivatives are defining features of the vertebrate clade 4 Underlying the development of neural crest is a gene regulatory network described as a set of interacting signals transcription factors and downstream effector genes that confer cell characteristics such as multipotency and migratory capabilities 5 Understanding the molecular mechanisms of neural crest formation is important for our knowledge of human disease because of its contributions to multiple cell lineages Abnormalities in neural crest development cause neurocristopathies which include conditions such as frontonasal dysplasia Waardenburg Shah syndrome and DiGeorge syndrome 1 Therefore defining the mechanisms of neural crest development may reveal key insights into vertebrate evolution and neurocristopathies Contents 1 History 2 Induction 2 1 Inductive signals 2 2 Neural plate border specifiers 2 3 Neural crest specifiers 2 4 Neural crest effector genes 3 Migration 3 1 Delamination 3 2 Migration 4 Clinical significance 4 1 Waardenburg s syndrome 4 2 Hirschsprung s Disease 4 3 Fetal Alcohol Spectrum Disorder 4 4 DiGeorge syndrome 4 5 Treacher Collins Syndrome 5 Cell lineages 5 1 Cranial neural crest 5 2 Trunk neural crest 5 3 Vagal and sacral neural crest 5 4 Cardiac neural crest 6 Evolution 7 Neural crest derivatives 8 See also 9 References 10 External linksHistory editNeural crest was first described in the chick embryo by Wilhelm His Sr in 1868 as the cord in between Zwischenstrang because of its origin between the neural plate and non neural ectoderm 1 He named the tissue ganglionic crest since its final destination was each lateral side of the neural tube where it differentiated into spinal ganglia 6 During the first half of the 20th century the majority of research on neural crest was done using amphibian embryos which was reviewed by Horstadius 1950 in a well known monograph 7 Cell labeling techniques advanced the field of neural crest because they allowed researchers to visualize the migration of the tissue throughout the developing embryos In the 1960s Weston and Chibon utilized radioisotopic labeling of the nucleus with tritiated thymidine in chick and amphibian embryo respectively However this method suffers from drawbacks of stability since every time the labeled cell divides the signal is diluted Modern cell labeling techniques such as rhodamine lysinated dextran and the vital dye diI have also been developed to transiently mark neural crest lineages 6 The quail chick marking system devised by Nicole Le Douarin in 1969 was another instrumental technique used to track neural crest cells 8 9 Chimeras generated through transplantation enabled researchers to distinguish neural crest cells of one species from the surrounding tissue of another species With this technique generations of scientists were able to reliably mark and study the ontogeny of neural crest cells Induction editA molecular cascade of events is involved in establishing the migratory and multipotent characteristics of neural crest cells This gene regulatory network can be subdivided into the following four sub networks described below Inductive signals edit First extracellular signaling molecules secreted from the adjacent epidermis and underlying mesoderm such as Wnts BMPs and Fgfs separate the non neural ectoderm epidermis from the neural plate during neural induction 1 4 Wnt signaling has been demonstrated in neural crest induction in several species through gain of function and loss of function experiments In coherence with this observation the promoter region of slug a neural crest specific gene contains a binding site for transcription factors involved in the activation of Wnt dependent target genes suggestive of a direct role of Wnt signaling in neural crest specification 10 The current role of BMP in neural crest formation is associated with the induction of the neural plate BMP antagonists diffusing from the ectoderm generates a gradient of BMP activity In this manner the neural crest lineage forms from intermediate levels of BMP signaling required for the development of the neural plate low BMP and epidermis high BMP 1 Fgf from the paraxial mesoderm has been suggested as a source of neural crest inductive signal Researchers have demonstrated that the expression of dominate negative Fgf receptor in ectoderm explants blocks neural crest induction when recombined with paraxial mesoderm 11 The understanding of the role of BMP Wnt and Fgf pathways on neural crest specifier expression remains incomplete Neural plate border specifiers edit Signaling events that establish the neural plate border lead to the expression of a set of transcription factors delineated here as neural plate border specifiers These molecules include Zic factors Pax3 7 Dlx5 Msx1 2 which may mediate the influence of Wnts BMPs and Fgfs These genes are expressed broadly at the neural plate border region and precede the expression of bona fide neural crest markers 4 Experimental evidence places these transcription factors upstream of neural crest specifiers For example in Xenopus Msx1 is necessary and sufficient for the expression of Slug Snail and FoxD3 12 Furthermore Pax3 is essential for FoxD3 expression in mouse embryos 13 Neural crest specifiers edit Following the expression of neural plate border specifiers is a collection of genes including Slug Snail FoxD3 Sox10 Sox9 AP 2 and c Myc This suite of genes designated here as neural crest specifiers are activated in emergent neural crest cells At least in Xenopus every neural crest specifier is necessary and or sufficient for the expression of all other specifiers demonstrating the existence of extensive cross regulation 4 Moreover this model organism was instrumental in the elucidation of the role of the Hedgehog signaling pathway in the specification of the neural crest with the transcription factor Gli2 playing a key role 14 Outside of the tightly regulated network of neural crest specifiers are two other transcription factors Twist and Id Twist a bHLH transcription factor is required for mesenchyme differentiation of the pharyngeal arch structures 15 Id is a direct target of c Myc and is known to be important for the maintenance of neural crest stem cells 16 Neural crest effector genes edit Finally neural crest specifiers turn on the expression of effector genes which confer certain properties such as migration and multipotency Two neural crest effectors Rho GTPases and cadherins function in delamination by regulating cell morphology and adhesive properties Sox9 and Sox10 regulate neural crest differentiation by activating many cell type specific effectors including Mitf P0 Cx32 Trp and cKit 4 nbsp Putative neural crest gene regulatory network functioning at the neural plate border in vertebrates Red arrows represent proven direct regulatory interactions Black arrows show genetic interactions based on loss of function and gain of functions studies Gray lines denote repression Adapted from Bronner Fraser 2004Migration editFurther information Collective cell migration nbsp Delamination of neural crest cells during development Downregulation of CAMs and tight junction proteins is followed by secretion of MMPs and subsequent delamination The migration of neural crest cells involves a highly coordinated cascade of events that begins with closure of the dorsal neural tube Delamination edit After fusion of the neural fold to create the neural tube cells originally located in the neural plate border become neural crest cells 17 For migration to begin neural crest cells must undergo a process called delamination that involves a full or partial epithelial mesenchymal transition EMT 18 Delamination is defined as the separation of tissue into different populations in this case neural crest cells separating from the surrounding tissue 19 Conversely EMT is a series of events coordinating a change from an epithelial to mesenchymal phenotype 18 For example delamination in chick embryos is triggered by a BMP Wnt cascade that induces the expression of EMT promoting transcription factors such as SNAI2 and FoxD3 19 Although all neural crest cells undergo EMT the timing of delamination occurs at different stages in different organisms in Xenopus laevis embryos there is a massive delamination that occurs when the neural plate is not entirely fused whereas delamination in the chick embryo occurs during fusion of the neural fold 19 Prior to delamination presumptive neural crest cells are initially anchored to neighboring cells by tight junction proteins such as occludin and cell adhesion molecules such as NCAM and N Cadherin 20 Dorsally expressed BMPs initiate delamination by inducing the expression of the zinc finger protein transcription factors snail slug and twist 17 These factors play a direct role in inducing the epithelial mesenchymal transition by reducing expression of occludin and N Cadherin in addition to promoting modification of NCAMs with polysialic acid residues to decrease adhesiveness 17 21 Neural crest cells also begin expressing proteases capable of degrading cadherins such as ADAM10 22 and secreting matrix metalloproteinases MMPs that degrade the overlying basal lamina of the neural tube to allow neural crest cells to escape 20 Additionally neural crest cells begin expressing integrins that associate with extracellular matrix proteins including collagen fibronectin and laminin during migration 23 Once the basal lamina becomes permeable the neural crest cells can begin migrating throughout the embryo Migration edit nbsp Migration of neural crest cells during development Grey arrows indicate the direction of the paths crest cells migrate R Rostral C Caudal Neural crest cell migration occurs in a rostral to caudal direction without the need of a neuronal scaffold such as along a radial glial cell For this reason the crest cell migration process is termed free migration Instead of scaffolding on progenitor cells neural crest migration is the result of repulsive guidance via EphB EphrinB and semaphorin neuropilin signaling interactions with the extracellular matrix and contact inhibition with one another 17 While Ephrin and Eph proteins have the capacity to undergo bi directional signaling neural crest cell repulsion employs predominantly forward signaling to initiate a response within the receptor bearing neural crest cell 23 Burgeoning neural crest cells express EphB a receptor tyrosine kinase which binds the EphrinB transmembrane ligand expressed in the caudal half of each somite When these two domains interact it causes receptor tyrosine phosphorylation activation of rhoGTPases and eventual cytoskeletal rearrangements within the crest cells inducing them to repel This phenomenon allows neural crest cells to funnel through the rostral portion of each somite 17 Semaphorin neuropilin repulsive signaling works synergistically with EphB signaling to guide neural crest cells down the rostral half of somites in mice In chick embryos semaphorin acts in the cephalic region to guide neural crest cells through the pharyngeal arches On top of repulsive repulsive signaling neural crest cells express b1and a4 integrins which allows for binding and guided interaction with collagen laminin and fibronectin of the extracellular matrix as they travel Additionally crest cells have intrinsic contact inhibition with one another while freely invading tissues of different origin such as mesoderm 17 Neural crest cells that migrate through the rostral half of somites differentiate into sensory and sympathetic neurons of the peripheral nervous system The other main route neural crest cells take is dorsolaterally between the epidermis and the dermamyotome Cells migrating through this path differentiate into pigment cells of the dermis Further neural crest cell differentiation and specification into their final cell type is biased by their spatiotemporal subjection to morphogenic cues such as BMP Wnt FGF Hox and Notch 20 Clinical significance editNeurocristopathies result from the abnormal specification migration differentiation or death of neural crest cells throughout embryonic development 24 25 This group of diseases comprises a wide spectrum of congenital malformations affecting many newborns Additionally they arise because of genetic defects affecting the formation of neural crest and because of the action of Teratogens 26 Waardenburg s syndrome edit Waardenburg s syndrome is a neurocristopathy that results from defective neural crest cell migration The condition s main characteristics include piebaldism and congenital deafness In the case of piebaldism the colorless skin areas are caused by a total absence of neural crest derived pigment producing melanocytes 27 There are four different types of Waardenburg s syndrome each with distinct genetic and physiological features Types I and II are distinguished based on whether or not family members of the affected individual have dystopia canthorum 28 Type III gives rise to upper limb abnormalities Lastly type IV is also known as Waardenburg Shah syndrome and afflicted individuals display both Waardenburg s syndrome and Hirschsprung s disease 29 Types I and III are inherited in an autosomal dominant fashion 27 while II and IV exhibit an autosomal recessive pattern of inheritance Overall Waardenburg s syndrome is rare with an incidence of 2 100 000 people in the United States All races and sexes are equally affected 27 There is no current cure or treatment for Waardenburg s syndrome Hirschsprung s Disease edit Also implicated in defects related to neural crest cell development and migration is Hirschsprung s disease HD or HSCR characterized by a lack of innervation in regions of the intestine This lack of innervation can lead to further physiological abnormalities like an enlarged colon megacolon obstruction of the bowels or even slowed growth In healthy development neural crest cells migrate into the gut and form the enteric ganglia Genes playing a role in the healthy migration of these neural crest cells to the gut include RET GDNF GFRa EDN3 and EDNRB RET a receptor tyrosine kinase RTK forms a complex with GDNF and GFRa EDN3 and EDNRB are then implicated in the same signaling network When this signaling is disrupted in mice aganglionosis or the lack of these enteric ganglia occurs 30 Fetal Alcohol Spectrum Disorder edit Prenatal alcohol exposure PAE is among the most common causes of developmental defects 31 Depending on the extent of the exposure and the severity of the resulting abnormalities patients are diagnosed within a continuum of disorders broadly labeled Fetal Alcohol Spectrum Disorder FASD Severe FASD can impair neural crest migration as evidenced by characteristic craniofacial abnormalities including short palpebral fissures an elongated upper lip and a smoothened philtrum However due to the promiscuous nature of ethanol binding the mechanisms by which these abnormalities arise is still unclear Cell culture explants of neural crest cells as well as in vivo developing zebrafish embryos exposed to ethanol show a decreased number of migratory cells and decreased distances travelled by migrating neural crest cells The mechanisms behind these changes are not well understood but evidence suggests PAE can increase apoptosis due to increased cytosolic calcium levels caused by IP3 mediated release of calcium from intracellular stores It has also been proposed that the decreased viability of ethanol exposed neural crest cells is caused by increased oxidative stress Despite these and other advances much remains to be discovered about how ethanol affects neural crest development For example it appears that ethanol differentially affects certain neural crest cells over others that is while craniofacial abnormalities are common in PAE neural crest derived pigment cells appear to be minimally affected 32 DiGeorge syndrome edit DiGeorge syndrome is associated with deletions or translocations of a small segment in the human chromosome 22 This deletion may disrupt rostral neural crest cell migration or development Some defects observed are linked to the pharyngeal pouch system which receives contribution from rostral migratory crest cells The symptoms of DiGeorge syndrome include congenital heart defects facial defects and some neurological and learning disabilities Patients with 22q11 deletions have also been reported to have higher incidence of schizophrenia and bipolar disorder 33 Treacher Collins Syndrome edit Treacher Collins Syndrome TCS results from the compromised development of the first and second pharyngeal arches during the early embryonic stage which ultimately leads to mid and lower face abnormalities TCS is caused by the missense mutation of the TCOF1 gene which causes neural crest cells to undergo apoptosis during embryogenesis Although mutations of the TCOF1 gene are among the best characterized in their role in TCS mutations in POLR1C and POLR1D genes have also been linked to the pathogenesis of TCS 34 Cell lineages editNeural crest cells originating from different positions along the anterior posterior axis develop into various tissues These regions of neural crest can be divided into four main functional domains which include the cranial neural crest trunk neural crest vagal and sacral neural crest and cardiac neural crest Cranial neural crest edit Main article cranial neural crest Cranial neural crest migrates dorsolaterally to form the craniofacial mesenchyme that differentiates into various cranial ganglia and craniofacial cartilages and bones 21 These cells enter the pharyngeal pouches and arches where they contribute to the thymus bones of the middle ear and jaw and the odontoblasts of the tooth primordia 35 Trunk neural crest edit Main article trunk neural crest Trunk neural crest gives rise two populations of cells 36 One group of cells fated to become melanocytes migrates dorsolaterally into the ectoderm towards the ventral midline A second group of cells migrates ventrolaterally through the anterior portion of each sclerotome The cells that stay in the sclerotome form the dorsal root ganglia whereas those that continue more ventrally form the sympathetic ganglia adrenal medulla and the nerves surrounding the aorta 35 Vagal and sacral neural crest edit The vagal and sacral neural crest cells develop into the ganglia of the enteric nervous system and the parasympathetic ganglia 35 Cardiac neural crest edit Main article cardiac neural crest Cardiac neural crest develops into melanocytes cartilage connective tissue and neurons of some pharyngeal arches Also this domain gives rise to regions of the heart such as the musculo connective tissue of the large arteries and part of the septum which divides the pulmonary circulation from the aorta 35 The semilunar valves of the heart are associated with neural crest cells according to new research 37 Evolution editSeveral structures that distinguish the vertebrates from other chordates are formed from the derivatives of neural crest cells In their New head theory Gans and Northcut argue that the presence of neural crest was the basis for vertebrate specific features such as sensory ganglia and cranial skeleton Furthermore the appearance of these features was pivotal in vertebrate evolution because it enabled a predatory lifestyle 38 39 However considering the neural crest a vertebrate innovation does not mean that it arose de novo Instead new structures often arise through modification of existing developmental regulatory programs For example regulatory programs may be changed by the co option of new upstream regulators or by the employment of new downstream gene targets thus placing existing networks in a novel context 40 41 This idea is supported by in situ hybridization data that shows the conservation of the neural plate border specifiers in protochordates which suggest that part of the neural crest precursor network was present in a common ancestor to the chordates 5 In some non vertebrate chordates such as tunicates a lineage of cells melanocytes has been identified which are similar to neural crest cells in vertebrates This implies that a rudimentary neural crest existed in a common ancestor of vertebrates and tunicates 42 Neural crest derivatives editEctomesenchyme also known as mesectoderm 43 odontoblasts dental papillae the chondrocranium nasal capsule Meckel s cartilage scleral ossicles quadrate articular hyoid and columella tracheal and laryngeal cartilage the dermatocranium membranous bones dorsal fins and the turtle plastron lower vertebrates pericytes and smooth muscle of branchial arteries and veins tendons of ocular and masticatory muscles connective tissue of head and neck glands pituitary salivary lachrymal thymus thyroid dermis and adipose tissue of calvaria ventral neck and faceEndocrine cells chromaffin cells of the adrenal medulla glomus cells type I II Peripheral nervous system Sensory neurons and glia of the dorsal root ganglia cephalic ganglia VII and in part V IX and X Rohon Beard cells some Merkel cells in the whisker 44 45 Satellite glial cells of all autonomic and sensory ganglia Schwann cells of all peripheral nerves Enteric cells Enterochromaffin cells 46 Melanocytes iris muscle and pigment cells and even associated with some tumors such as melanotic neuroectodermal tumor of infancy See also editFirst arch syndrome DGCR2 may control neural crest cell migration List of human cell types derived from the germ layersReferences edit a b c d e f Huang X Saint Jeannet J P 2004 Induction of the neural crest and the opportunities of life on the edge Dev Biol 275 1 1 11 doi 10 1016 j ydbio 2004 07 033 PMID 15464568 Shakhova Olga Sommer Lukas 2008 Neural crest derived stem cells StemBook Harvard Stem Cell Institute doi 10 3824 stembook 1 51 1 PMID 20614636 Retrieved 27 December 2019 Brooker R J 2014 Biology 3rd edn McGraw Hill New York NY 1084 a b c d e Meulemans D Bronner Fraser M 2004 Gene regulatory interactions in neural crest evolution and development Dev Cell 7 3 291 9 doi 10 1016 j devcel 2004 08 007 PMID 15363405 a b Sauka Spengler T Meulemans D Jones M Bronner Fraser M 2007 Ancient evolutionary origin of the neural crest gene regulatory network Dev Cell 13 3 405 20 doi 10 1016 j devcel 2007 08 005 PMID 17765683 a b Le Douarin N M 2004 The avian embryo as a model to study the development of the neural crest a long and still ongoing story Mech Dev 121 9 1089 102 doi 10 1016 j mod 2004 06 003 PMID 15296974 Horstadius S 1950 The Neural Crest Its Properties and Derivatives in the Light of Experimental Research Oxford University Press London 111 p Le Douarin N M 1969 Particularites du noyau interphasique chez la Caille japonaise Coturnix coturnix japonica Utilisation de ces particularites comme marquage biologique dans les recherches sur les interactions tissulaires et les migrations cellulaires au cours de l ontogenese Bull Biol Fr Belg 103 3 435 52 PMID 4191116 Le Douarin N M 1973 A biological cell labeling technique and its use in experimental embryology Dev Biol 30 1 217 22 doi 10 1016 0012 1606 73 90061 4 PMID 4121410 Vallin J et al 2001 Cloning and characterization of the three Xenopus slug promoters reveal direct regulation by Lef beta catenin signaling J Biol Chem 276 32 30350 8 doi 10 1074 jbc M103167200 PMID 11402039 Mayor R Guerrero N Martinez C 1997 Role of FGF and noggin in neural crest induction Dev Biol 189 1 1 12 doi 10 1006 dbio 1997 8634 PMID 9281332 Tribulo C et al 2003 Regulation of Msx genes by Bmp gradient is essential for neural crest specification Development 130 26 6441 52 doi 10 1242 dev 00878 hdl 11336 95313 PMID 14627721 Dottori M Gross M K Labosky P Goulding M 2001 The winged helix transcription factor Foxd3 suppresses interneuron differentiation and promotes neural crest cell fate Development 128 21 4127 4138 doi 10 1242 dev 128 21 4127 PMID 11684651 Cerrizuela Santiago Vega Lopez Guillermo A Palacio Maria Belen Tribulo Celeste Aybar Manuel J 2018 12 01 Gli2 is required for the induction and migration of Xenopus laevis neural crest Mechanisms of Development 154 219 239 doi 10 1016 j mod 2018 07 010 hdl 11336 101714 ISSN 0925 4773 PMID 30086335 Vincentz J W et al 2008 An absence of Twist1 results in aberrant cardiac neural crest morphogenesis Dev Biol 320 1 131 9 doi 10 1016 j ydbio 2008 04 037 PMC 2572997 PMID 18539270 Light W et al 2005 Xenopus Id3 is required downstream of Myc for the formation of multipotent neural crest progenitor cells Development 132 8 1831 41 doi 10 1242 dev 01734 PMID 15772131 a b c d e f Sanes Dan 2012 Development of the Nervous System 3rd ed Oxford ELSEVIER INC pp 70 72 ISBN 978 0123745392 a b Lamouille Samy 2014 Molecular mechanisms of epithelial mesenchymal transition Nature Reviews Molecular Cell Biology 15 3 178 196 doi 10 1038 nrm3758 PMC 4240281 PMID 24556840 a b c Theveneau Eric 2012 Neural crest delamination and migration From epithelium to mesenchyme transition to collective cell migration PDF Developmental Biology 366 1 34 54 doi 10 1016 j ydbio 2011 12 041 PMID 22261150 a b c Kandel Eric 2013 Principles of Neural Science New York The McGraw Hill Companies Inc pp 1197 1199 ISBN 978 0 07 139011 8 a b Taneyhill L A 2008 To adhere or not to adhere the role of Cadherins in neural crest development Cell Adh Migr 2 223 30 Mayor Roberto 2013 The Neural Crest Development 140 11 2247 2251 doi 10 1242 dev 091751 PMID 23674598 a b Sakuka Spengler Tatjana 2008 A gene regulatory network orchestrates neural crest formation Nature Reviews Molecular Cell Biology 9 7 557 568 doi 10 1038 nrm2428 PMID 18523435 S2CID 10746234 Vega Lopez Guillermo A Cerrizuela Santiago Tribulo Celeste Aybar Manuel J 2018 12 01 Neurocristopathies New insights 150 years after the neural crest discovery Developmental Biology The Neural Crest 150 years after His discovery 444 S110 S143 doi 10 1016 j ydbio 2018 05 013 ISSN 0012 1606 PMID 29802835 Bolande Robert P 1974 07 01 The neurocristopathies A unifying concept of disease arising in neural crest maldevelopment Human Pathology 5 4 409 429 doi 10 1016 S0046 8177 74 80021 3 ISSN 0046 8177 Cerrizuela Santiago Vega Lopez Guillermo A Aybar Manuel J 2020 01 11 The role of teratogens in neural crest development Birth Defects Research 112 8 584 632 doi 10 1002 bdr2 1644 ISSN 2472 1727 PMID 31926062 S2CID 210151171 a b c Mallory S B Wiener E Nordlund J J 1986 Waardenburg s Syndrome with Hirschprung s Disease A Neural Crest Defect Pediatric Dermatology 3 2 119 124 doi 10 1111 j 1525 1470 1986 tb00501 x PMID 3952027 S2CID 23858201 Arias S 1971 Genetic heterogeneity in the Waardenburg s syndrome Birth Defects B 07 4 87 101 PMID 5006208 Waardenburg syndrome Genetics Home Reference October 2012 Rogers J M 2016 Search for the missing lncs gene regulatory networks in neural crest development and long non coding RNA biomarkers of Hirschsprung s disease Neurogastroenterol Motil 28 2 161 166 doi 10 1111 nmo 12776 PMID 26806097 S2CID 12394126 Sampson P D Streissguth A P Bookstein F L Little R E Clarren S K Dehaene P Graham J M Jr 1997 The incidence of fetal alcohol syndrome and prevalence of the alcohol related neurodevelopmental disorder Teratology 56 5 317 326 doi 10 1002 SICI 1096 9926 199711 56 5 lt 317 AID TERA5 gt 3 0 CO 2 U PMID 9451756 Smith S M Garic A Flentke G R Berres M E 2014 Neural crest development in fetal alcohol syndrome Birth Defects Research Part C Embryo Today Reviews 102 3 210 220 doi 10 1002 bdrc 21078 PMC 4827602 PMID 25219761 Scambler Peter J 2000 The 22q11 deletion syndromes Human Molecular Genetics 9 16 2421 2426 doi 10 1093 hmg 9 16 2421 PMID 11005797 Ahmed M Ye X Taub P 2016 Review of the Genetic Basis of Jaw Malformations Journal of Pediatric Genetics 05 4 209 219 doi 10 1055 s 0036 1593505 PMC 5123890 PMID 27895973 a b c d Gilbert Scott F 2000 The Neural Crest Sinauer Associates Vega Lopez Guillermo A Cerrizuela Santiago Aybar Manuel J 2017 Trunk neural crest cells formation migration and beyond The International Journal of Developmental Biology 61 1 2 5 15 doi 10 1387 ijdb 160408gv hdl 11336 53692 ISSN 0214 6282 PMID 28287247 Takamura Kazushi Okishima Takahiro Ohdo Shozo Hayakawa Kunio 1990 Association of cephalic neural crest cells with cardiovascular development particularly that of the semilunar valves Anatomy and Embryology 182 3 263 72 doi 10 1007 BF00185519 PMID 2268069 S2CID 32986727 Gans C Northcutt R G 1983 Neural crest and the origin of vertebrates A new head Science 220 4594 268 274 Bibcode 1983Sci 220 268G doi 10 1126 science 220 4594 268 PMID 17732898 S2CID 39290007 Northcutt Glenn 2005 The new head hypothesis revisited Journal of Experimental Zoology Part B Molecular and Developmental Evolution 304B 4 274 297 doi 10 1002 jez b 21063 PMID 16003768 Sauka Spengler T Bronner Fraser M 2006 Development and evolution of the migratory neural crest a gene regulatory perspective Curr Opin Genet Dev 13 4 360 6 doi 10 1016 j gde 2006 06 006 PMID 16793256 Donoghue P C Graham A Kelsh R N 2008 The origin and evolution of the neural crest BioEssays 30 6 530 41 doi 10 1002 bies 20767 PMC 2692079 PMID 18478530 Abitua P B Wagner E Navarrete I A Levine M 2012 Identification of a rudimentary neural crest in a non vertebrate chordate Nature 492 7427 104 107 Bibcode 2012Natur 492 104A doi 10 1038 nature11589 PMC 4257486 PMID 23135395 Kalcheim C and Le Douarin N M 1998 The Neural Crest 2nd ed Cambridge U K Cambridge University Press Van Keymeulen A Mascre G Youseff KK et al October 2009 Epidermal progenitors give rise to Merkel cells during embryonic development and adult homeostasis J Cell Biol 187 1 91 100 doi 10 1083 jcb 200907080 PMC 2762088 PMID 19786578 Szeder V Grim M Halata Z Sieber Blum M January 2003 Neural crest origin of mammalian Merkel cells Dev Biol 253 2 258 63 doi 10 1016 s0012 1606 02 00015 5 PMID 12645929 Lake JI Heuckeroth RO 1 July 2013 Enteric nervous system development migration differentiation and disease American Journal of Physiology Gastrointestinal and Liver Physiology 305 1 G1 24 doi 10 1152 ajpgi 00452 2012 PMC 3725693 PMID 23639815 External links editEmbryology at UNSW Notes ncrest ancil 445 at NeuroNames Diagram at University of Michigan Hox domains in chicks Retrieved from https en wikipedia org w index php title Neural crest amp oldid 1210017068, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.