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Summary Expression Phenotypes Gene Literature (26) GO Terms (13) Nucleotides (60) Proteins (37) Interactants (202) Wiki
XB-GENEPAGE-480591

Papers associated with foxe3



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A novel fork head gene mediates early steps during Xenopus lens formation., Kenyon KL, Moody SA, Jamrich M., Development. November 1, 1999; 126 (22): 5107-16.            

Sequential activation of transcription factors in lens induction., Ogino H, Yasuda K., Dev Growth Differ. October 1, 2000; 42 (5): 437-48.

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

Characterizing gene expression during lens formation in Xenopus laevis: evaluating the model for embryonic lens induction., Henry JJ, Carinato ME, Schaefer JJ, Wolfe AD, Walter BE, Perry KJ, Elbl TN., Dev Dyn. June 1, 2002; 224 (2): 168-85.        

Xenopus laevis FoxE1 is primarily expressed in the developing pituitary and thyroid., El-Hodiri HM, Seufert DW, Nekkalapudi S, Prescott NL, Kelly LE, Jamrich M., Int J Dev Biol. January 1, 2005; 49 (7): 881-4.            

Of Fox and Frogs: Fox (fork head/winged helix) transcription factors in Xenopus development., Pohl BS, Knöchel W., Gene. January 3, 2005; 344 21-32.      

Zebrafish foxe3: roles in ocular lens morphogenesis through interaction with pitx3., Shi X, Luo Y, Howley S, Dzialo A, Foley S, Hyde DR, Vihtelic TS., Mech Dev. October 1, 2006; 123 (10): 761-82.    

Foxe view of lens development and disease., Medina-Martinez O, Jamrich M., Development. April 1, 2007; 134 (8): 1455-63.    

Convergence of a head-field selector Otx2 and Notch signaling: a mechanism for lens specification., Ogino H, Fisher M, Grainger RM., Development. January 1, 2008; 135 (2): 249-58.          

Xhairy2 functions in Xenopus lens development by regulating p27(xic1) expression., Murato Y, Hashimoto C., Dev Dyn. September 1, 2009; 238 (9): 2179-92.              

Retinoic acid is a key regulatory switch determining the difference between lung and thyroid fates in Xenopus laevis., Wang JH, Deimling SJ, D'Alessandro NE, Zhao L, Possmayer F, Drysdale TA., BMC Dev Biol. January 26, 2011; 11 75.                            

Xenopus laevis insulin receptor substrate IRS-1 is important for eye development., Bugner V, Aurhammer T, Kühl M., Dev Dyn. July 1, 2011; 240 (7): 1705-15.            

Genomic targets of Brachyury (T) in differentiating mouse embryonic stem cells., Evans AL, Faial T, Gilchrist MJ, Down T, Vallier L, Pedersen RA, Wardle FC, Smith JC., PLoS One. January 1, 2012; 7 (3): e33346.              

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

Mutual repression between Gbx2 and Otx2 in sensory placodes reveals a general mechanism for ectodermal patterning., Steventon B, Mayor R, Streit A., Dev Biol. July 1, 2012; 367 (1): 55-65.                

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

The Xenopus doublesex-related gene Dmrt5 is required for olfactory placode neurogenesis., Parlier D, Moers V, Van Campenhout C, Preillon J, Leclère L, Saulnier A, Sirakov M, Busengdal H, Kricha S, Marine JC, Rentzsch F, Bellefroid EJ., Dev Biol. January 1, 2013; 373 (1): 39-52.                              

sox4 and sox11 function during Xenopus laevis eye development., Cizelsky W, Hempel A, Metzig M, Tao S, Hollemann T, Kühl M, Kühl SJ., PLoS One. July 1, 2013; 8 (7): e69372.              

Role of the hypoxia response pathway in lens formation during embryonic development of Xenopus laevis., Baba K, Muraguchi T, Imaoka S., FEBS Open Bio. October 23, 2013; 3 490-5.        

Dissection of a Ciona regulatory element reveals complexity of cross-species enhancer activity., Chen WC, Pauls S, Bacha J, Elgar G, Loose M, Shimeld SM., Dev Biol. June 15, 2014; 390 (2): 261-72.          

Early stages of induction of anterior head ectodermal properties in Xenopus embryos are mediated by transcriptional cofactor ldb1., Plautz CZ, Zirkle BE, Deshotel MJ, Grainger RM., Dev Dyn. December 1, 2014; 243 (12): 1606-18.              

Functional Cloning Using a Xenopus Oocyte Expression System., Plautz CZ, Williams HC, Grainger RM., J Vis Exp. January 30, 2016; (107): e53518.

Bioelectric signalling via potassium channels: a mechanism for craniofacial dysmorphogenesis in KCNJ2-associated Andersen-Tawil Syndrome., Adams DS, Uzel SG, Akagi J, Wlodkowic D, Andreeva V, Yelick PC, Devitt-Lee A, Pare JF, Levin M., J Physiol. June 15, 2016; 594 (12): 3245-70.                              

Anosmin-1 is essential for neural crest and cranial placodes formation in Xenopus., Bae CJ, Hong CS, Saint-Jeannet JP., Biochem Biophys Res Commun. January 15, 2018; 495 (3): 2257-2263.        

Function of chromatin modifier Hmgn1 during neural crest and craniofacial development., Ihewulezi C, Saint-Jeannet JP., Genesis. October 1, 2021; 59 (10): e23447.              

In vitro modeling of cranial placode differentiation: Recent advances, challenges, and perspectives., Griffin C, Saint-Jeannet JP., Dev Biol. February 1, 2024; 506 20-30.

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