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The sulfotransferase XB5850668.L is required to apportion embryonic ectodermal domains. , Marchak A., Dev Dyn. December 1, 2023; 252 (12): 1407-1427.
Hybridization led to a rewired pluripotency network in the allotetraploid Xenopus laevis. , Phelps WA., Elife. October 3, 2023; 12
Normal Table of Xenopus development: a new graphical resource. , Zahn N ., Development. July 15, 2022; 149 (14):
Lysosomes are required for early dorsal signaling in the Xenopus embryo. , Tejeda-Muñoz N., Proc Natl Acad Sci U S A. April 26, 2022; 119 (17): e2201008119.
Wnt-inducible Lrp6- APEX2 interacting proteins identify ESCRT machinery and Trk-fused gene as components of the Wnt signaling pathway. , Colozza G ., Sci Rep. December 9, 2020; 10 (1): 21555.
Long-term association of a transcription factor with its chromatin binding site can stabilize gene expression and cell fate commitment. , Gurdon JB ., Proc Natl Acad Sci U S A. June 30, 2020; 117 (26): 15075-15084.
Xenopus slc7a5 is essential for notochord function and eye development. , Katada T., Mech Dev. February 1, 2019; 155 48-59.
Broad applicability of a streamlined ethyl cinnamate-based clearing procedure. , Masselink W., Development. February 1, 2019; 146 (3):
Six1 and Irx1 have reciprocal interactions during cranial placode and otic vesicle formation. , Sullivan CH., Dev Biol. February 1, 2019; 446 (1): 68-79.
Wbp2nl has a developmental role in establishing neural and non-neural ectodermal fates. , Marchak A., Dev Biol. September 1, 2017; 429 (1): 213-224.
Developmentally regulated long non-coding RNAs in Xenopus tropicalis. , Forouzmand E., Dev Biol. June 15, 2017; 426 (2): 401-408.
Gene Resistance to Transcriptional Reprogramming following Nuclear Transfer Is Directly Mediated by Multiple Chromatin-Repressive Pathways. , Jullien J ., Mol Cell. March 2, 2017; 65 (5): 873-884.e8.
Pa2G4 is a novel Six1 co-factor that is required for neural crest and otic development. , Neilson KM ., Dev Biol. January 15, 2017; 421 (2): 171-182.
The Role of microRNAs in Animal Cell Reprogramming. , Cruz-Santos MC., Stem Cells Dev. July 15, 2016; 25 (14): 1035-49.
Neural transcription factors bias cleavage stage blastomeres to give rise to neural ectoderm. , Gaur S., Genesis. June 1, 2016; 54 (6): 334-49.
A novel role for Ascl1 in the regulation of mesendoderm formation via HDAC-dependent antagonism of VegT. , Gao L., Development. February 1, 2016; 143 (3): 492-503.
Hierarchical molecular events driven by oocyte-specific factors lead to rapid and extensive reprogramming. , Jullien J ., Mol Cell. August 21, 2014; 55 (4): 524-36.
Maternal syntabulin is required for dorsal axis formation and is a germ plasm component in Xenopus. , Colozza G ., Differentiation. July 1, 2014; 88 (1): 17-26.
Regulation of neurogenesis by Fgf8a requires Cdc42 signaling and a novel Cdc42 effector protein. , Hulstrand AM., Dev Biol. October 15, 2013; 382 (2): 385-99.
Par6b regulates the dynamics of apicobasal polarity during development of the stratified Xenopus epidermis. , Wang S., PLoS One. October 8, 2013; 8 (10): e76854.
MRAS GTPase is a novel stemness marker that impacts mouse embryonic stem cell plasticity and Xenopus embryonic cell fate. , Mathieu ME., Development. August 1, 2013; 140 (16): 3311-22.
A developmental requirement for HIRA-dependent H3.3 deposition revealed at gastrulation in Xenopus. , Szenker E., Cell Rep. June 28, 2012; 1 (6): 730-40.
Plasma membrane cholesterol depletion disrupts prechordal plate and affects early forebrain patterning. , Reis AH., Dev Biol. May 15, 2012; 365 (2): 350-62.
Specific domains of FoxD4/5 activate and repress neural transcription factor genes to control the progression of immature neural ectoderm to differentiating neural plate. , Neilson KM ., Dev Biol. May 15, 2012; 365 (2): 363-75.
Dynamic in vivo binding of transcription factors to cis-regulatory modules of cer and gsc in the stepwise formation of the Spemann-Mangold organizer. , Sudou N ., Development. May 1, 2012; 139 (9): 1651-61.
Maternal xNorrin, a canonical Wnt signaling agonist and TGF-β antagonist, controls early neuroectoderm specification in Xenopus. , Xu S., PLoS Biol. January 1, 2012; 10 (3): e1001286.
Foxi2 is an animally localized maternal mRNA in Xenopus, and an activator of the zygotic ectoderm activator Foxi1e. , Cha SW ., PLoS One. January 1, 2012; 7 (7): e41782.
Histone variant macroH2A confers resistance to nuclear reprogramming. , Pasque V., EMBO J. May 6, 2011; 30 (12): 2373-87.
Interaction of Sox1, Sox2, Sox3 and Oct4 during primary neurogenesis. , Archer TC., Dev Biol. February 15, 2011; 350 (2): 429-40.
SNW1 is a critical regulator of spatial BMP activity, neural plate border formation, and neural crest specification in vertebrate embryos. , Wu MY., PLoS Biol. February 15, 2011; 9 (2): e1000593.
Mammalian nuclear transplantation to Germinal Vesicle stage Xenopus oocytes - a method for quantitative transcriptional reprogramming. , Halley-Stott RP., Methods. May 1, 2010; 51 (1): 56-65.
Xenopus RCOR2 (REST corepressor 2) interacts with ZMYND8, which is involved in neural differentiation. , Zeng W., Biochem Biophys Res Commun. April 16, 2010; 394 (4): 1024-9.
Nectin-2 and N-cadherin interact through extracellular domains and induce apical accumulation of F-actin in apical constriction of Xenopus neural tube morphogenesis. , Morita H., Development. April 1, 2010; 137 (8): 1315-25.
Characterization of somatic cell nuclear reprogramming by oocytes in which a linker histone is required for pluripotency gene reactivation. , Jullien J ., Proc Natl Acad Sci U S A. March 23, 2010; 107 (12): 5483-8.
Histone H3 lysine 4 methylation is associated with the transcriptional reprogramming efficiency of somatic nuclei by oocytes. , Murata K., Epigenetics Chromatin. February 4, 2010; 3 (1): 4.
Bone morphogenetic protein 15 ( BMP15) acts as a BMP and Wnt inhibitor during early embryogenesis. , Di Pasquale E., J Biol Chem. September 18, 2009; 284 (38): 26127-36.
Mad is required for wingless signaling in wing development and segment patterning in Drosophila. , Eivers E., PLoS One. August 6, 2009; 4 (8): e6543.
FGF-activated calcium channels control neural gene expression in Xenopus. , Lee KW., Biochim Biophys Acta. June 1, 2009; 1793 (6): 1033-40.
In vitro organogenesis from undifferentiated cells in Xenopus. , Asashima M ., Dev Dyn. June 1, 2009; 238 (6): 1309-20.
Expression cloning of Xenopus zygote arrest 2 ( Xzar2) as a novel epidermalization-promoting factor in early embryos of Xenopus laevis. , Nakajima Y., Genes Cells. May 1, 2009; 14 (5): 583-95.
Maternal Interferon Regulatory Factor 6 is required for the differentiation of primary superficial epithelia in Danio and Xenopus embryos. , Sabel JL., Dev Biol. January 1, 2009; 325 (1): 249-62.
Reversible membrane permeabilization of mammalian cells treated with digitonin and its use for inducing nuclear reprogramming by Xenopus egg extracts. , Miyamoto K ., Cloning Stem Cells. December 1, 2008; 10 (4): 535-42.
Crossveinless-2 Is a BMP feedback inhibitor that binds Chordin/BMP to regulate Xenopus embryonic patterning. , Ambrosio AL., Dev Cell. August 1, 2008; 15 (2): 248-60.
FoxM1-driven cell division is required for neuronal differentiation in early Xenopus embryos. , Ueno H., Development. June 1, 2008; 135 (11): 2023-30.
Ectodermal factor restricts mesoderm differentiation by inhibiting p53. , Sasai N., Cell. May 30, 2008; 133 (5): 878-90.
Vertebrate CASTOR is required for differentiation of cardiac precursor cells at the ventral midline. , Christine KS ., Dev Cell. April 1, 2008; 14 (4): 616-23.
Sox3 expression is maintained by FGF signaling and restricted to the neural plate by Vent proteins in the Xenopus embryo. , Rogers CD., Dev Biol. January 1, 2008; 313 (1): 307-19.
Cloning and developmental expression of the soxB2 genes, sox14 and sox21, during Xenopus laevis embryogenesis. , Cunningham DD ., Int J Dev Biol. January 1, 2008; 52 (7): 999-1004.
Reprogramming events of mammalian somatic cells induced by Xenopus laevis egg extracts. , Miyamoto K ., Mol Reprod Dev. October 1, 2007; 74 (10): 1268-77.
Vertebrate Ctr1 coordinates morphogenesis and progenitor cell fate and regulates embryonic stem cell differentiation. , Haremaki T ., Proc Natl Acad Sci U S A. July 17, 2007; 104 (29): 12029-34.