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Information integration during bioelectric regulation of morphogenesis of the embryonic frog brain. , Manicka S., iScience. December 15, 2023; 26 (12): 108398.
Rspo2 inhibits TCF3 phosphorylation to antagonize Wnt signaling during vertebrate anteroposterior axis specification. , Reis AH., Sci Rep. June 28, 2021; 11 (1): 13433.
Modeling Bainbridge-Ropers Syndrome in Xenopus laevis Embryos. , Lichtig H., Front Physiol. January 1, 2020; 11 75.
HCN2 Channel-Induced Rescue of Brain Teratogenesis via Local and Long-Range Bioelectric Repair. , Pai VP ., Front Cell Neurosci. January 1, 2020; 14 136.
Bioinformatics Screening of Genes Specific for Well-Regenerating Vertebrates Reveals c-answer, a Regulator of Brain Development and Regeneration. , Korotkova DD., Cell Rep. October 22, 2019; 29 (4): 1027-1040.e6.
Head formation requires Dishevelled degradation that is mediated by March2 in concert with Dapper1. , Lee H , Lee H ., Development. April 10, 2018; 145 (7):
Gene expression of the two developmentally regulated dermatan sulfate epimerases in the Xenopus embryo. , Gouignard N ., PLoS One. January 18, 2018; 13 (1): e0191751.
Tbx2 regulates anterior neural specification by repressing FGF signaling pathway. , Cho GS., Dev Biol. January 15, 2017; 421 (2): 183-193.
Tbx3 represses bmp4 expression and, with Pax6, is required and sufficient for retina formation. , Motahari Z., Development. October 1, 2016; 143 (19): 3560-3572.
Noggin4 is a long-range inhibitor of Wnt8 signalling that regulates head development in Xenopus laevis. , Eroshkin FM., Sci Rep. January 22, 2016; 6 23049.
G protein-coupled receptors Flop1 and Flop2 inhibit Wnt/ β-catenin signaling and are essential for head formation in Xenopus. , Miyagi A., Dev Biol. November 1, 2015; 407 (1): 131-44.
The small leucine-rich repeat secreted protein Asporin induces eyes in Xenopus embryos through the IGF signalling pathway. , Luehders K., Development. October 1, 2015; 142 (19): 3351-61.
The serpin PN1 is a feedback regulator of FGF signaling in germ layer and primary axis formation. , Acosta H., Development. March 15, 2015; 142 (6): 1146-58.
Endogenous gradients of resting potential instructively pattern embryonic neural tissue via Notch signaling and regulation of proliferation. , Pai VP ., J Neurosci. March 11, 2015; 35 (10): 4366-85.
Insulin-like factor regulates neural induction through an IGF1 receptor-independent mechanism. , Haramoto Y ., Sci Rep. January 12, 2015; 5 11603.
Xenopus laevis FGF receptor substrate 3 (XFrs3) is important for eye development and mediates Pax6 expression in lens placode through its Shp2-binding sites. , Kim YJ., Dev Biol. January 1, 2015; 397 (1): 129-39.
Xenopus mutant reveals necessity of rax for specifying the eye field which otherwise forms tissue with telencephalic and diencephalic character. , Fish MB., Dev Biol. November 15, 2014; 395 (2): 317-330.
Custos controls β-catenin to regulate head development during vertebrate embryogenesis. , Komiya Y., Proc Natl Acad Sci U S A. September 9, 2014; 111 (36): 13099-104.
Ras-dva1 small GTPase regulates telencephalon development in Xenopus laevis embryos by controlling Fgf8 and Agr signaling at the anterior border of the neural plate. , Tereshina MB., Biol Open. March 15, 2014; 3 (3): 192-203.
An essential role for LPA signalling in telencephalon development. , Geach TJ ., Development. February 1, 2014; 141 (4): 940-9.
Role of Sp5 as an essential early regulator of neural crest specification in xenopus. , Park DS., Dev Dyn. December 1, 2013; 242 (12): 1382-94.
BMP signal attenuates FGF pathway in anteroposterior neural patterning. , Cho GS., Biochem Biophys Res Commun. May 10, 2013; 434 (3): 509-15.
Tiki1 is required for head formation via Wnt cleavage-oxidation and inactivation. , Zhang X., Cell. June 22, 2012; 149 (7): 1565-77.
The dual regulator Sufu integrates Hedgehog and Wnt signals in the early Xenopus embryo. , Min TH., Dev Biol. October 1, 2011; 358 (1): 262-76.
Barhl2 limits growth of the diencephalic primordium through Caspase3 inhibition of beta-catenin activation. , Juraver-Geslin HA ., Proc Natl Acad Sci U S A. February 8, 2011; 108 (6): 2288-93.
Anterior neural development requires Del1, a matrix-associated protein that attenuates canonical Wnt signaling via the Ror2 pathway. , Takai A., Development. October 1, 2010; 137 (19): 3293-302.
Cell cycle control of wnt receptor activation. , Davidson G., Dev Cell. December 1, 2009; 17 (6): 788-99.
Retinol dehydrogenase 10 is a feedback regulator of retinoic acid signalling during axis formation and patterning of the central nervous system. , Strate I., Development. February 1, 2009; 136 (3): 461-72.
Neural crests are actively precluded from the anterior neural fold by a novel inhibitory mechanism dependent on Dickkopf1 secreted by the prechordal mesoderm. , Carmona-Fontaine C., Dev Biol. September 15, 2007; 309 (2): 208-21.
The secreted serine protease xHtrA1 stimulates long-range FGF signaling in the early Xenopus embryo. , Hou S., Dev Cell. August 1, 2007; 13 (2): 226-41.
Cell cycling and differentiation do not require the retinoblastoma protein during early Xenopus development. , Cosgrove RA., Dev Biol. March 1, 2007; 303 (1): 311-24.
FoxI1e activates ectoderm formation and controls cell position in the Xenopus blastula. , Mir A., Development. February 1, 2007; 134 (4): 779-88.
Neural induction in Xenopus requires inhibition of Wnt-beta-catenin signaling. , Heeg-Truesdell E., Dev Biol. October 1, 2006; 298 (1): 71-86.
Hex acts with beta-catenin to regulate anteroposterior patterning via a Groucho-related co-repressor and Nodal. , Zamparini AL., Development. September 1, 2006; 133 (18): 3709-22.
Kermit 2/ XGIPC, an IGF1 receptor interacting protein, is required for IGF signaling in Xenopus eye development. , Wu J ., Development. September 1, 2006; 133 (18): 3651-60.
The MRH protein Erlectin is a member of the endoplasmic reticulum synexpression group and functions in N-glycan recognition. , Cruciat CM., J Biol Chem. May 5, 2006; 281 (18): 12986-93.
Tes regulates neural crest migration and axial elongation in Xenopus. , Dingwell KS., Dev Biol. May 1, 2006; 293 (1): 252-67.
The doublesex-related gene, XDmrt4, is required for neurogenesis in the olfactory system. , Huang X ., Proc Natl Acad Sci U S A. August 9, 2005; 102 (32): 11349-54.
Xenopus aristaless-related homeobox ( xARX) gene product functions as both a transcriptional activator and repressor in forebrain development. , Seufert DW ., Dev Dyn. February 1, 2005; 232 (2): 313-24.
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.
Autoregulation of canonical Wnt signaling controls midbrain development. , Kunz M., Dev Biol. September 15, 2004; 273 (2): 390-401.
Xenopus XsalF: anterior neuroectodermal specification by attenuating cellular responsiveness to Wnt signaling. , Onai T., Dev Cell. July 1, 2004; 7 (1): 95-106.
Xantivin suppresses the activity of EGF- CFC genes to regulate nodal signaling. , Tanegashima K ., Int J Dev Biol. June 1, 2004; 48 (4): 275-83.
Glypican 4 modulates FGF signalling and regulates dorsoventral forebrain patterning in Xenopus embryos. , Galli A., Development. October 1, 2003; 130 (20): 4919-29.
The IGF pathway regulates head formation by inhibiting Wnt signaling in Xenopus. , Richard-Parpaillon L ., Dev Biol. April 15, 2002; 244 (2): 407-17.
The Wnt/beta-catenin pathway posteriorizes neural tissue in Xenopus by an indirect mechanism requiring FGF signalling. , Domingos PM ., Dev Biol. November 1, 2001; 239 (1): 148-60.
A morphogen gradient of Wnt/beta-catenin signalling regulates anteroposterior neural patterning in Xenopus. , Kiecker C., Development. November 1, 2001; 128 (21): 4189-201.
Active repression of RAR signaling is required for head formation. , Koide T., Genes Dev. August 15, 2001; 15 (16): 2111-21.
Distinct effects of XBF-1 in regulating the cell cycle inhibitor p27( XIC1) and imparting a neural fate. , Hardcastle Z., Development. March 1, 2000; 127 (6): 1303-14.
FGF signaling and the anterior neural induction in Xenopus. , Hongo I., Dev Biol. December 15, 1999; 216 (2): 561-81.