Literature DB >> 25922521

Animal models for studying neural crest development: is the mouse different?

Elias H Barriga1, Paul A Trainor2, Marianne Bronner3, Roberto Mayor4.   

Abstract

The neural crest is a uniquely vertebrate cell type and has been well studied in a number of model systems. Zebrafish, Xenopus and chick embryos largely show consistent requirements for specific genes in early steps of neural crest development. By contrast, knockouts of homologous genes in the mouse often do not exhibit comparable early neural crest phenotypes. In this Spotlight article, we discuss these species-specific differences, suggest possible explanations for the divergent phenotypes in mouse and urge the community to consider these issues and the need for further research in complementary systems.
© 2015. Published by The Company of Biologists Ltd.

Entities:  

Keywords:  Chicken; Gene knockout; Mouse; Neural crest; Xenopus; Zebrafish

Mesh:

Year:  2015        PMID: 25922521      PMCID: PMC6514397          DOI: 10.1242/dev.121590

Source DB:  PubMed          Journal:  Development        ISSN: 0950-1991            Impact factor:   6.868


  110 in total

1.  Snail-related transcriptional repressors are required in Xenopus for both the induction of the neural crest and its subsequent migration.

Authors:  C LaBonne; M Bronner-Fraser
Journal:  Dev Biol       Date:  2000-05-01       Impact factor: 3.582

2.  Posteriorization by FGF, Wnt, and retinoic acid is required for neural crest induction.

Authors:  Sandra Villanueva; Alvaro Glavic; Pablo Ruiz; Roberto Mayor
Journal:  Dev Biol       Date:  2002-01-15       Impact factor: 3.582

3.  Idiopathic weight reduction in mice deficient in the high-mobility-group transcription factor Sox8.

Authors:  E Sock; K Schmidt; I Hermanns-Borgmeyer; M R Bösl; M Wegner
Journal:  Mol Cell Biol       Date:  2001-10       Impact factor: 4.272

4.  Wnt-3a is required for somite specification along the anteroposterior axis of the mouse embryo and for regulation of cdx-1 expression.

Authors:  M Ikeya; S Takada
Journal:  Mech Dev       Date:  2001-05       Impact factor: 1.882

5.  Zebrafish pea3 and erm are general targets of FGF8 signaling.

Authors:  H Roehl; C Nüsslein-Volhard
Journal:  Curr Biol       Date:  2001-04-03       Impact factor: 10.834

6.  Overexpression of the transcriptional repressor FoxD3 prevents neural crest formation in Xenopus embryos.

Authors:  B S Pohl; W Knöchel
Journal:  Mech Dev       Date:  2001-05       Impact factor: 1.882

7.  Delayed wound repair and impaired angiogenesis in mice lacking syndecan-4.

Authors:  F Echtermeyer; M Streit; S Wilcox-Adelman; S Saoncella; F Denhez; M Detmar; P Goetinck
Journal:  J Clin Invest       Date:  2001-01       Impact factor: 14.808

8.  A local Wnt-3a signal is required for development of the mammalian hippocampus.

Authors:  S M Lee; S Tole; E Grove; A P McMahon
Journal:  Development       Date:  2000-02       Impact factor: 6.868

9.  Requirement of FoxD3-class signaling for neural crest determination in Xenopus.

Authors:  N Sasai; K Mizuseki; Y Sasai
Journal:  Development       Date:  2001-07       Impact factor: 6.868

10.  The transcription factor Sox9 is required for cranial neural crest development in Xenopus.

Authors:  Rebecca F Spokony; Yoichiro Aoki; Natasha Saint-Germain; Emily Magner-Fink; Jean-Pierre Saint-Jeannet
Journal:  Development       Date:  2002-01       Impact factor: 6.868
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  25 in total

1.  WNT/β-catenin signaling mediates human neural crest induction via a pre-neural border intermediate.

Authors:  Alan W Leung; Barbara Murdoch; Ahmed F Salem; Maneeshi S Prasad; Gustavo A Gomez; Martín I García-Castro
Journal:  Development       Date:  2016-02-01       Impact factor: 6.868

2.  AP-2α and AP-2β cooperatively orchestrate homeobox gene expression during branchial arch patterning.

Authors:  Eric Van Otterloo; Hong Li; Kenneth L Jones; Trevor Williams
Journal:  Development       Date:  2018-01-25       Impact factor: 6.868

3.  Specific and spatial labeling of P0-Cre versus Wnt1-Cre in cranial neural crest in early mouse embryos.

Authors:  Guiqian Chen; Mohamed Ishan; Jingwen Yang; Satoshi Kishigami; Tomokazu Fukuda; Greg Scott; Manas K Ray; Chenming Sun; Shi-You Chen; Yoshihiro Komatsu; Yuji Mishina; Hong-Xiang Liu
Journal:  Genesis       Date:  2017-04-18       Impact factor: 2.487

4.  A collagen VI-dependent pathogenic mechanism for Hirschsprung's disease.

Authors:  Rodolphe Soret; Mathilde Mennetrey; Karl F Bergeron; Anne Dariel; Michel Neunlist; Franziska Grunder; Christophe Faure; David W Silversides; Nicolas Pilon
Journal:  J Clin Invest       Date:  2015-11-16       Impact factor: 14.808

Review 5.  MAPK and PI3K signaling: At the crossroads of neural crest development.

Authors:  Colin J Dinsmore; Philippe Soriano
Journal:  Dev Biol       Date:  2018-02-14       Impact factor: 3.582

Review 6.  Evolvability of the vertebrate craniofacial skeleton.

Authors:  Jennifer L Fish
Journal:  Semin Cell Dev Biol       Date:  2017-12-13       Impact factor: 7.727

7.  Early specification and development of rabbit neural crest cells.

Authors:  Erin Betters; Rebekah M Charney; Martín I Garcia-Castro
Journal:  Dev Biol       Date:  2018-06-20       Impact factor: 3.582

8.  Physiological electric fields induce directional migration of mammalian cranial neural crest cells.

Authors:  Abijeet Singh Mehta; Pin Ha; Kan Zhu; ShiYu Li; Kang Ting; Chia Soo; Xinli Zhang; Min Zhao
Journal:  Dev Biol       Date:  2020-12-24       Impact factor: 3.148

Review 9.  Diabetes, Oxidative Stress, and DNA Damage Modulate Cranial Neural Crest Cell Development and the Phenotype Variability of Craniofacial Disorders.

Authors:  Sharien Fitriasari; Paul A Trainor
Journal:  Front Cell Dev Biol       Date:  2021-05-20

Review 10.  Non-human Primate Models to Investigate Mechanisms of Infection-Associated Fetal and Pediatric Injury, Teratogenesis and Stillbirth.

Authors:  Miranda Li; Alyssa Brokaw; Anna M Furuta; Brahm Coler; Veronica Obregon-Perko; Ann Chahroudi; Hsuan-Yuan Wang; Sallie R Permar; Charlotte E Hotchkiss; Thaddeus G Golos; Lakshmi Rajagopal; Kristina M Adams Waldorf
Journal:  Front Genet       Date:  2021-07-05       Impact factor: 4.599
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