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The early dorsal signal in vertebrate embryos requires endolysosomal membrane trafficking. , Azbazdar Y., Bioessays. January 1, 2024; 46 (1): e2300179.
Membrane potential drives the exit from pluripotency and cell fate commitment via calcium and mTOR. , Sempou E., Nat Commun. November 5, 2022; 13 (1): 6681.
Quantitative analysis of transcriptome dynamics provides novel insights into developmental state transitions. , Johnson K., BMC Genomics. October 23, 2022; 23 (1): 723.
Myocyte enhancer factor 2D regulates ectoderm specification and adhesion properties of animal cap cells in the early Xenopus embryo. , Katz Imberman S., FEBS J. August 1, 2015; 282 (15): 2930-47.
In vivo T-box transcription factor profiling reveals joint regulation of embryonic neuromesodermal bipotency. , Gentsch GE ., Cell Rep. September 26, 2013; 4 (6): 1185-96.
The roles of maternal Vangl2 and aPKC in Xenopus oocyte and embryo patterning. , Cha SW ., Development. September 1, 2011; 138 (18): 3989-4000.
Programming pluripotent precursor cells derived from Xenopus embryos to generate specific tissues and organs. , Borchers A ., Genes (Basel). November 18, 2010; 1 (3): 413-26.
Long- and short-range signals control the dynamic expression of an animal hemisphere-specific gene in Xenopus. , Mir A., Dev Biol. March 1, 2008; 315 (1): 161-72.
The role of FoxC1 in early Xenopus development. , Cha JY., Dev Dyn. October 1, 2007; 236 (10): 2731-41.
FoxI1e activates ectoderm formation and controls cell position in the Xenopus blastula. , Mir A., Development. February 1, 2007; 134 (4): 779-88.
Germ-layer specification and control of cell growth by Ectodermin, a Smad4 ubiquitin ligase. , Dupont S., Cell. April 8, 2005; 121 (1): 87-99.
Microarray-based identification of VegT targets in Xenopus. , Taverner NV., Mech Dev. March 1, 2005; 122 (3): 333-54.
Neural induction in Xenopus requires early FGF signalling in addition to BMP inhibition. , Delaune E., Development. January 1, 2005; 132 (2): 299-310.
Cytoplasmic and molecular reconstruction of Xenopus embryos: synergy of dorsalizing and endo-mesodermalizing determinants drives early axial patterning. , Katsumoto K., Development. March 1, 2004; 131 (5): 1135-44.
Evolution of Brachyury proteins: identification of a novel regulatory domain conserved within Bilateria. , Marcellini S ., Dev Biol. August 15, 2003; 260 (2): 352-61.
The Xenopus LIM-homeodomain protein Xlim5 regulates the differential adhesion properties of early ectoderm cells. , Houston DW ., Development. June 1, 2003; 130 (12): 2695-704.
From intestine to muscle: nuclear reprogramming through defective cloned embryos. , Byrne JA., Proc Natl Acad Sci U S A. April 30, 2002; 99 (9): 6059-63.
The Xenopus homologue of Bicaudal-C is a localized maternal mRNA that can induce endoderm formation. , Wessely O ., Development. May 1, 2000; 127 (10): 2053-62.
Endodermal Nodal-related signals and mesoderm induction in Xenopus. , Agius E ., Development. March 1, 2000; 127 (6): 1173-83.
The role of maternal VegT in establishing the primary germ layers in Xenopus embryos. , Zhang J., Cell. August 21, 1998; 94 (4): 515-24.
A vegetally localized T-box transcription factor in Xenopus eggs specifies mesoderm and endoderm and is essential for embryonic mesoderm formation. , Horb ME ., Development. May 1, 1997; 124 (9): 1689-98.
The Xenopus T-box gene, Antipodean, encodes a vegetally localised maternal mRNA and can trigger mesoderm formation. , Stennard F ., Development. December 1, 1996; 122 (12): 4179-88.
Xenopus VegT RNA is localized to the vegetal cortex during oogenesis and encodes a novel T-box transcription factor involved in mesodermal patterning. , Zhang J., Development. December 1, 1996; 122 (12): 4119-29.