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Time-resolved quantitative proteomic analysis of the developing Xenopus otic vesicle reveals putative congenital hearing loss candidates. , Baxi AB., iScience. September 15, 2023; 26 (9): 107665.
Using an aquatic model, Xenopus laevis, to uncover the role of chromodomain 1 in craniofacial disorders. , Wyatt BH., Genesis. February 1, 2021; 59 (1-2): e23394.
Predation threats for a 24-h period activated the extension of axons in the brains of Xenopus tadpoles. , Mori T ., Sci Rep. July 16, 2020; 10 (1): 11737.
Role of the visual experience-dependent nascent proteome in neuronal plasticity. , Liu HH ., Elife. February 7, 2018; 7
Heart regeneration in adult Xenopus tropicalis after apical resection. , Liao S., Cell Biosci. December 13, 2017; 7 70.
PFKFB4 control of AKT signaling is essential for premigratory and migratory neural crest formation. , Figueiredo AL., Development. November 15, 2017; 144 (22): 4183-4194.
A Tissue-Mapped Axolotl De Novo Transcriptome Enables Identification of Limb Regeneration Factors. , Bryant DM., Cell Rep. January 17, 2017; 18 (3): 762-776.
RNA-Seq and microarray analysis of the Xenopus inner ear transcriptome discloses orthologous OMIM(®) genes for hereditary disorders of hearing and balance. , Ramírez-Gordillo D., BMC Res Notes. November 18, 2015; 8 691.
Essential role of the zinc finger transcription factor Casz1 for mammalian cardiac morphogenesis and development. , Liu Z., J Biol Chem. October 24, 2014; 289 (43): 29801-16.
Occupancy of tissue-specific cis-regulatory modules by Otx2 and TLE/Groucho for embryonic head specification. , Yasuoka Y ., Nat Commun. July 9, 2014; 5 4322.
Cadherin-dependent differential cell adhesion in Xenopus causes cell sorting in vitro but not in the embryo. , Ninomiya H., J Cell Sci. April 15, 2012; 125 (Pt 8): 1877-83.
EBF proteins participate in transcriptional regulation of Xenopus muscle development. , Green YS., Dev Biol. October 1, 2011; 358 (1): 240-50.
The nephrogenic potential of the transcription factors osr1, osr2, hnf1b, lhx1 and pax8 assessed in Xenopus animal caps. , Drews C., BMC Dev Biol. January 31, 2011; 11 5.
N- and E-cadherins in Xenopus are specifically required in the neural and non- neural ectoderm, respectively, for F-actin assembly and morphogenetic movements. , Nandadasa S., Development. April 1, 2009; 136 (8): 1327-38.
Changing a limb muscle growth program into a resorption program. , Cai L., Dev Biol. April 1, 2007; 304 (1): 260-71.
DRAGON, a bone morphogenetic protein co-receptor. , Samad TA., J Biol Chem. April 8, 2005; 280 (14): 14122-9.
Xenopus Id3 is required downstream of Myc for the formation of multipotent neural crest progenitor cells. , Light W., Development. April 1, 2005; 132 (8): 1831-41.
Nuclear translocation of Xenopus laevis paxillin. , Ogawa M., Biochem Biophys Res Commun. May 16, 2003; 304 (4): 676-83.
Functional characterization of human NBC4 as an electrogenic Na+-HCO cotransporter (NBCe2). , Virkki LV., Am J Physiol Cell Physiol. June 1, 2002; 282 (6): C1278-89.
Interactions of the novel antimicrobial peptide buforin 2 with lipid bilayers: proline as a translocation promoting factor. , Kobayashi S., Biochemistry. July 25, 2000; 39 (29): 8648-54.
Chemical modification and inactivation of rat liver arginase by N-bromosuccinimide: reaction with His141. , Daghigh F., Arch Biochem Biophys. March 1, 1996; 327 (1): 107-12.
Developmental expression and differential regulation by retinoic acid of Xenopus COUP- TF-A and COUP- TF-B. , van der Wees J ., Mech Dev. February 1, 1996; 54 (2): 173-84.
Xenopus Distal-less related homeobox genes are expressed in the developing forebrain and are induced by planar signals. , Papalopulu N ., Development. March 1, 1993; 117 (3): 961-75.
Differential expression of the Ca2+-binding protein parvalbumin during myogenesis in Xenopus laevis. , Schwartz LM., Dev Biol. August 1, 1988; 128 (2): 441-52.
Characterization of cloned complementary DNA covering more than 6000 nucleotides (97%) of avian vitellogenin mRNA. , Cozens PJ., Eur J Biochem. December 1, 1980; 112 (3): 443-50.