Early- and late-migrating cranial neural crest cell populations have equivalent developmental potential in vivo

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JOURNAL ARTICLES

Early- and late-migrating cranial neural crest cell populations have equivalent developmental potential in vivo

CV Baker, M Bronner-Fraser, NM Le Douarin and MA Teillet
Division of Biology, Beckman Institute 139-74, California Institute of Technology, Pasadena 91125, USA.

We present the first in vivo study of the long-term fate and potential of early-migrating and late-migrating mesencephalic neural crest cell populations, by performing isochronic and heterochronic quail-to-chick grafts. Both early- and late-migrating populations form melanocytes, neurons, glia, cartilage and bone in isochronic, isotopic chimeras, showing that neither population is lineage-restricted. The early-migrating population distributes both dorsally and ventrally during normal development, while the late-migrating population is confined dorsally and forms much less cartilage and bone. When the late-migrating population is substituted heterochronically for the early-migrating population, it contributes extensively to ventral derivatives such as jaw cartilage and bone. Conversely, when the early-migrating population is substituted heterochronically for the late-migrating population, it no longer contributes to the jaw skeleton and only forms dorsal derivatives. When the late-migrating population is grafted into a late-stage host whose neural crest had previously been ablated, it migrates ventrally into the jaws. Thus, the dorsal fate restriction of the late-migrating mesencephalic neural crest cell population in normal development is due to the presence of earlier-migrating neural crest cells, rather than to any change in the environment or to any intrinsic difference in migratory ability or potential between early- and late-migrating cell populations. These results highlight the plasticity of the neural crest and show that its fate is determined primarily by the environment.

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				X. Xu, R. Francis, C. J. Wei, K. L. Linask, and C. W. Lo Connexin 43-mediated modulation of polarized cell movement and the directional migration of cardiac neural crest cells Development, September 15, 2006; 133(18): 3629 - 3639. [Abstract] [Full Text] [PDF]

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				A. L. Wilkie, S. A. Jordan, and I. J. Jackson Neural crest progenitors of the melanocyte lineage: coat colour patterns revisited Development, March 9, 2003; 129(14): 3349 - 3357. [Abstract] [Full Text] [PDF]

				J. Charite, D. G. McFadden, G. Merlo, G. Levi, D. E. Clouthier, M. Yanagisawa, J. A. Richardson, and E. N. Olson Role of Dlx6 in regulation of an endothelin-1-dependent, dHAND branchial arch enhancer Genes & Dev., November 15, 2001; 15(22): 3039 - 3049. [Abstract] [Full Text] [PDF]

				J. Begbie and A. Graham Integration Between the Epibranchial Placodes and the Hindbrain Science, October 19, 2001; 294(5542): 595 - 598. [Abstract] [Full Text] [PDF]

				R Kos, M. Reedy, R. Johnson, and C. Erickson The winged-helix transcription factor FoxD3 is important for establishing the neural crest lineage and repressing melanogenesis in avian embryos Development, January 4, 2001; 128(8): 1467 - 1479. [Abstract] [PDF]

				M. J. Belliveau, T. L. Young, and C. L. Cepko Late Retinal Progenitor Cells Show Intrinsic Limitations in the Production of Cell Types and the Kinetics of Opsin Synthesis J. Neurosci., March 15, 2000; 20(6): 2247 - 2254. [Abstract] [Full Text] [PDF]

				K. Artinger, A. Chitnis, M Mercola, and W Driever Zebrafish narrowminded suggests a genetic link between formation of neural crest and primary sensory neurons Development, January 9, 1999; 126(18): 3969 - 3979. [Abstract] [PDF]

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				C. Baker, M. Stark, C Marcelle, and M Bronner-Fraser Competence, specification and induction of Pax-3 in the trigeminal placode Development, January 1, 1999; 126(1): 147 - 156. [Abstract] [PDF]