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Summary Anatomy Item Literature (5836) Expression Attributions Wiki
XB-ANAT-2

Papers associated with ectoderm (and mafb)

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Znf703, a novel target of Pax3 and Zic1, regulates hindbrain and neural crest development in Xenopus., Hong CS., Genesis. December 1, 2017; 55 (12):                               

Generation of animal form by the Chordin/Tolloid/BMP gradient: 100 years after D'Arcy Thompson., De Robertis EM., Dev Growth Differ. September 1, 2017; 59 (7): 580-592.            

no privacy, a Xenopus tropicalis mutant, is a model of human Hermansky-Pudlak Syndrome and allows visualization of internal organogenesis during tadpole development., Nakayama T., Dev Biol. June 15, 2017; 426 (2): 472-486.                          

A novel function for Egr4 in posterior hindbrain development., Bae CJ., Sci Rep. January 12, 2015; 5 7750.                              

Spalt-like 4 promotes posterior neural fates via repression of pou5f3 family members in Xenopus., Young JJ., Development. April 1, 2014; 141 (8): 1683-93.                                                                

The Prdm13 histone methyltransferase encoding gene is a Ptf1a-Rbpj downstream target that suppresses glutamatergic and promotes GABAergic neuronal fate in the dorsal neural tube., Hanotel J., Dev Biol. February 15, 2014; 386 (2): 340-57.                                                                    

Pax3 and Zic1 trigger the early neural crest gene regulatory network by the direct activation of multiple key neural crest specifiers., Plouhinec JL., Dev Biol. February 15, 2014; 386 (2): 461-72.                                            

Defining progressive stages in the commitment process leading to embryonic lens formation., Jin H., Genesis. October 1, 2012; 50 (10): 728-40.              

Transcription factors involved in lens development from the preplacodal ectoderm., Ogino H., Dev Biol. March 15, 2012; 363 (2): 333-47.      

Microarray identification of novel downstream targets of FoxD4L1/D5, a critical component of the neural ectodermal transcriptional network., Yan B., Dev Dyn. December 1, 2010; 239 (12): 3467-80.                  

Evolution of axis specification mechanisms in jawed vertebrates: insights from a chondrichthyan., Coolen M., PLoS One. April 18, 2007; 2 (4): e374.              

Phylogenomic analysis and expression patterns of large Maf genes in Xenopus tropicalis provide new insights into the functional evolution of the gene family in osteichthyans., Coolen M., Dev Genes Evol. July 1, 2005; 215 (7): 327-39.

The 5'-AT-rich half-site of Maf recognition element: a functional target for bZIP transcription factor Maf., Yoshida T., Nucleic Acids Res. June 21, 2005; 33 (11): 3465-78.                  

Functional role of a novel ternary complex comprising SRF and CREB in expression of Krox-20 in early embryos of Xenopus laevis., Watanabe T., Dev Biol. January 15, 2005; 277 (2): 508-21.                

FGF2 triggers iris-derived lens regeneration in newt eye., Hayashi T., Mech Dev. June 1, 2004; 121 (6): 519-26.

Characterizing gene expression during lens formation in Xenopus laevis: evaluating the model for embryonic lens induction., Henry JJ., Dev Dyn. June 1, 2002; 224 (2): 168-85.        

Distinct roles of maf genes during Xenopus lens development., Ishibashi S., Mech Dev. March 1, 2001; 101 (1-2): 155-66.          

Isolation, characterization, and expression analysis of zebrafish large Mafs., Kajihara M., J Biochem. January 1, 2001; 129 (1): 139-46.

Regulation of lens fiber cell differentiation by transcription factor c-Maf., Kawauchi S., J Biol Chem. July 2, 1999; 274 (27): 19254-60.

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