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Science 6 May 1994:
Vol. 264. no. 5160, pp. 835 - 839
DOI: 10.1126/science.7513443
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Articles

Science, Vol 264, Issue 5160, 835-839
Copyright © 1994 by American Association for the Advancement of Science

articles

Control of cell behavior during vertebrate development by Slug, a zinc finger gene

MA Nieto, MG Sargent, DG Wilkinson, and J Cooke

Instituto Cajal, Madrid, Spain.

Slug, a vertebrate gene encoding a zinc finger protein of the Snail family, is expressed in the neural crest and in mesodermal cells emigrating from the primitive streak. Early chick embryos were incubated with antisense oligonucleotides to chick Slug. These oligonucleotides specifically inhibit the normal change in cell behavior that occurs at the two sites in the emerging body plan in which the gene is expressed. This change, which is the transition from epithelial to mesenchymal character, occurs at the formation of mesoderm during gastrulation and on emigration of the neutral crest from the neural tube.


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M. Dottori, M. K. Gross, P. Labosky, and M. Goulding (2001)
Development 128, 4127-4138
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Conotruncal myocardium arises from a secondary heart field.
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Development 128, 3179-3188
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Development 128, 2509-2515
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Requirement of FoxD3-class signaling for neural crest determination in Xenopus.
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Development 128, 2525-2536
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Human Slug Is a Repressor That Localizes to Sites of Active Transcription.
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A novel Snail-related transcription factor Smuc regulates basic helix-loop-helix transcription factor activities via specific E-box motifs.
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PNAS 96, 13264-13269
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Defining subregions of Hensen's node essential for caudalward movement, midline development and cell survival.
J. Charrier, M. Teillet, F Lapointe, and N. Le Douarin (1999)
Development 126, 4771-4783
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Zebrafish narrowminded suggests a genetic link between formation of neural crest and primary sensory neurons.
K. Artinger, A. Chitnis, M Mercola, and W Driever (1999)
Development 126, 3969-3979
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Xenopus GDF6, a new antagonist of noggin and a partner of BMPs.
C Chang and A Hemmati-Brivanlou (1999)
Development 126, 3347-3357
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Axial mesendoderm refines rostrocaudal pattern in the chick nervous system.
A. Rowan, C. Stern, and K. Storey (1999)
Development 126, 2921-2934
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Induction of the epibranchial placodes.
J Begbie, J. Brunet, J. Rubenstein, and A Graham (1999)
Development 126, 895-902
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Effects of Shh and Noggin on neural crest formation demonstrate that BMP is required in the neural tube but not ectoderm.
M. Selleck, M. Garcia-Castro, K. Artinger, and M Bronner-Fraser (1998)
Development 125, 4919-4930
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A role for rhoB in the delamination of neural crest cells from the dorsal neural tube.
J. Liu and T. Jessell (1998)
Development 125, 5055-5067
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Neural crest emigration from the neural tube depends on regulated cadherin expression.
S Nakagawa and M Takeichi (1998)
Development 125, 2963-2971
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Conserved and divergent roles for members of the Snail family of transcription factors in the chick and mouse embryo.
M Sefton, S Sanchez, and M. Nieto (1998)
Development 125, 3111-3121
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Neural crest induction in Xenopus: evidence for a two-signal model.
C LaBonne and M Bronner-Fraser (1998)
Development 125, 2403-2414
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Control of somite patterning by Sonic hedgehog and its downstream signal response genes.
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Development 125, 777-790
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The Zinc-Finger Protein Slug Causes Desmosome Dissociation, an Initial and Necessary Step for Growth Factor-induced Epithelial-Mesenchymal Transition.
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A forkhead gene related to HNF-3beta is required for gastrulation and axis formation in the ascidian embryo.
C. Olsen and W. Jeffery (1997)
Development 124, 3609-3619
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Dorsoventral patterning of the vertebrate neural tube is conserved in a protochordate.
J. Corbo, A Erives, A Di Gregorio, A Chang, and M Levine (1997)
Development 124, 2335-2344
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Slug, a zinc finger gene previously implicated in the early patterning of the mesoderm and the neural crest, is also involved in chick limb development.
M. Ros, M Sefton, and M. Nieto (1997)
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Expression of Pax-3 is initiated in the early neural plate by posteriorizing signals produced by the organizer and by posterior non-axial mesoderm.
A. Bang, N Papalopulu, C Kintner, and M. Goulding (1997)
Development 124, 2075-2085
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Heart and neural tube defects in transgenic mice overexpressing the Cx43 gap junction gene.
J. Ewart, M. Cohen, R. Meyer, G. Huang, A Wessels, R. Gourdie, A. Chin, S. Park, B. Lazatin, S Villabon, et al. (1997)
Development 124, 1281-1292
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Sequence and developmental expression of AmphiDll, an amphioxus Distal-less gene transcribed in the ectoderm, epidermis and nervous system: insights into evolution of craniate forebrain and neural crest.
N. Holland, G Panganiban, E. Henyey, and L. Holland (1996)
Development 122, 2911-2920
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A Subclass of bHLH Proteins Required for Cardiac Morphogenesis.
D. Srivastava, P. Cserjesi, and E. N. Olson (1995)
Science 270, 1995-1999
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scratch, a pan-neural gene encoding a zinc finger protein related to snail, promotes neuronal development..
M Roark, M A Sturtevant, J Emery, H Vaessin, E Grell, and E Bier (1995)
Genes & Dev. 9, 2384-2398
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twist is required in head mesenchyme for cranial neural tube morphogenesis..
Z F Chen and R R Behringer (1995)
Genes & Dev. 9, 686-699
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Regulative response of the cranial neural tube after neural fold ablation: spatiotemporal nature of neural crest regeneration and up-regulation of Slug.
J Sechrist, M. Nieto, R. Zamanian, and M Bronner-Fraser (1995)
Development 121, 4103-4115
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Induction of avian cardiac myogenesis by anterior endoderm.
T. Schultheiss, S Xydas, and A. Lassar (1995)
Development 121, 4203-4214
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Dorsalization of the neural tube by the non-neural ectoderm.
M. Dickinson, M. Selleck, A. McMahon, and M Bronner-Fraser (1995)
Development 121, 2099-2106
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Multiple roles for FGF-3 during cranial neural development in the chicken.
R Mahmood, P Kiefer, S Guthrie, C Dickson, and I Mason (1995)
Development 121, 1399-1410
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Induction of the prospective neural crest of Xenopus.
R Mayor, R Morgan, and M. Sargent (1995)
Development 121, 767-777
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Origins of the avian neural crest: the role of neural plate-epidermal interactions.
M. Selleck and M Bronner-Fraser (1995)
Development 121, 525-538
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Short-range repression permits multiple enhancers to function autonomously within a complex promoter..
S Gray, P Szymanski, and M Levine (1994)
Genes & Dev. 8, 1829-1838
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Cloning and Characterization of Three Xenopus Slug Promoters Reveal Direct Regulation by Lef/beta -Catenin Signaling.
J. Vallin, R. Thuret, E. Giacomello, M. M. Faraldo, J. P. Thiery, and F. Broders (2001)
J. Biol. Chem. 276, 30350-30358
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Mammalian Scratch: A neural-specific Snail family transcriptional repressor.
E. K. Nakakura, D. N. Watkins, K. E. Schuebel, V. Sriuranpong, M. W. Borges, B. D. Nelkin, and D. W. Ball (2001)
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