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Xenopus Ssbp2 is required for embryonic pronephros morphogenesis and terminal differentiation. , Cervino AS., Sci Rep. October 4, 2023; 13 (1): 16671.
An efficient miRNA knockout approach using CRISPR-Cas9 in Xenopus. , Godden AM., Dev Biol. March 1, 2022; 483 66-75.
Eya1 protein distribution during embryonic development of Xenopus laevis. , Almasoudi SH., Gene Expr Patterns. December 1, 2021; 42 119213.
Analysis of pallial/cortical interneurons in key vertebrate models of Testudines, Anurans and Polypteriform fishes. , Jiménez S., Brain Struct Funct. September 1, 2020; 225 (7): 2239-2269.
Nucleotide receptor P2RY4 is required for head formation via induction and maintenance of head organizer in Xenopus laevis. , Harata A., Dev Growth Differ. February 1, 2019; 61 (2): 186-197.
The Frog Xenopus as a Model to Study Joubert Syndrome: The Case of a Human Patient With Compound Heterozygous Variants in PIBF1. , Ott T., Front Physiol. January 1, 2019; 10 134.
Patterns of hypothalamic regionalization in amphibians and reptiles: common traits revealed by a genoarchitectonic approach. , Domínguez L., Front Neuroanat. February 3, 2015; 9 3.
Characterization of the hypothalamus of Xenopus laevis during development. II. The basal regions. , Domínguez L., J Comp Neurol. April 1, 2014; 522 (5): 1102-31.
c- Jun N-terminal kinase phosphorylation of heterogeneous nuclear ribonucleoprotein K regulates vertebrate axon outgrowth via a posttranscriptional mechanism. , Hutchins EJ ., J Neurosci. September 11, 2013; 33 (37): 14666-80.
The Xenopus Tgfbi is required for embryogenesis through regulation of canonical Wnt signalling. , Wang F., Dev Biol. July 1, 2013; 379 (1): 16-27.
The hypoxia factor Hif-1α controls neural crest chemotaxis and epithelial to mesenchymal transition. , Barriga EH., J Cell Biol. May 27, 2013; 201 (5): 759-76.
Characterization of the hypothalamus of Xenopus laevis during development. I. The alar regions. , Domínguez L., J Comp Neurol. March 1, 2013; 521 (4): 725-59.
Lin28 proteins are required for germ layer specification in Xenopus. , Faas L., Development. March 1, 2013; 140 (5): 976-86.
Characterization of the neuropeptide Y system in the frog Silurana tropicalis (Pipidae): three peptides and six receptor subtypes. , Sundström G., Gen Comp Endocrinol. July 1, 2012; 177 (3): 322-31.
Ontogenetic distribution of the transcription factor nkx2.2 in the developing forebrain of Xenopus laevis. , Domínguez L., Front Neuroanat. March 2, 2011; 5 11.
Functional analysis of Rfx6 and mutant variants associated with neonatal diabetes. , Pearl EJ ., Dev Biol. March 1, 2011; 351 (1): 135-45.
Paralysis and delayed Z-disc formation in the Xenopus tropicalis unc45b mutant dicky ticker. , Geach TJ ., BMC Dev Biol. January 22, 2010; 10 75.
Identification of a novel uromodulin-like gene related to predator-induced bulgy morph in anuran tadpoles by functional microarray analysis. , Mori T ., PLoS One. June 16, 2009; 4 (6): e5936.
The shroom family proteins play broad roles in the morphogenesis of thickened epithelial sheets. , Lee C , Lee C , Lee C ., Dev Dyn. June 1, 2009; 238 (6): 1480-91.
Interaction of brain somatostatin receptors with the PDZ domains of PSD-95. , Christenn M., FEBS Lett. November 13, 2007; 581 (27): 5173-7.
Differential ability of Ptf1a and Ptf1a-VP16 to convert stomach, duodenum and liver to pancreas. , Jarikji ZH ., Dev Biol. April 15, 2007; 304 (2): 786-99.
Evi1 is specifically expressed in the distal tubule and duct of the Xenopus pronephros and plays a role in its formation. , Van Campenhout C., Dev Biol. June 1, 2006; 294 (1): 203-19.
Development of the pancreas in Xenopus laevis. , Kelly OG., Dev Dyn. August 1, 2000; 218 (4): 615-27.
Primary neuronal differentiation in Xenopus embryos is linked to the beta(3) subunit of the sodium pump. , Messenger NJ., Dev Biol. April 15, 2000; 220 (2): 168-82.
Identification of melanin concentrating hormone ( MCH) as the natural ligand for the orphan somatostatin-like receptor 1 (SLC-1). , Bächner D., FEBS Lett. September 3, 1999; 457 (3): 522-4.
Periodic repression of Notch pathway genes governs the segmentation of Xenopus embryos. , Jen WC., Genes Dev. June 1, 1999; 13 (11): 1486-99.
Elucidating the origins of the vascular system: a fate map of the vascular endothelial and red blood cell lineages in Xenopus laevis. , Mills KR ., Dev Biol. May 15, 1999; 209 (2): 352-68.
A new secreted protein that binds to Wnt proteins and inhibits their activities. , Hsieh JC., Nature. April 1, 1999; 398 (6726): 431-6.
Discovery of three novel orphan G-protein-coupled receptors. , Marchese A., Genomics. February 15, 1999; 56 (1): 12-21.
Expression pattern of the winged helix factor XFD-11 during Xenopus embryogenesis. , Köster M ., Mech Dev. August 1, 1998; 76 (1-2): 169-73.
Basal ganglia organization in amphibians: chemoarchitecture. , Marín O., J Comp Neurol. March 16, 1998; 392 (3): 285-312.
Inwardly rectifying potassium channels: their molecular heterogeneity and function. , Isomoto S., Jpn J Physiol. February 1, 1997; 47 (1): 11-39.
Neural induction and patterning in embryos deficient in FGF signaling. , Godsave SF., Int J Dev Biol. February 1, 1997; 41 (1): 57-65.
Expression of a new G protein-coupled receptor X- msr is associated with an endothelial lineage in Xenopus laevis. , Devic E., Mech Dev. October 1, 1996; 59 (2): 129-40.
Primary sequence and developmental expression pattern of mRNAs and protein for an alpha1 subunit of the sodium pump cloned from the neural plate of Xenopus laevis. , Davies CS., Dev Biol. March 15, 1996; 174 (2): 431-47.
The Xenopus homologue of Otx2 is a maternal homeobox gene that demarcates and specifies anterior body regions. , Pannese M., Development. March 1, 1995; 121 (3): 707-20.
Immunohistochemical studies on the development of the hypothalamo-hypophysial system in Xenopus laevis. , Ogawa K., Anat Rec. February 1, 1995; 241 (2): 244-54.
Xenopus axis formation: induction of goosecoid by injected Xwnt-8 and activin mRNAs. , Steinbeisser H ., Development. June 1, 1993; 118 (2): 499-507.
Expression of functional pituitary somatostatin receptors in Xenopus oocytes. , White MM., Proc Natl Acad Sci U S A. January 1, 1990; 87 (1): 133-6.
Functional expression of brain cholecystokinin and bombesin receptors in Xenopus oocytes. , Moriarty TM., Dev Biol. August 1, 1988; 464 (1): 75-9.
Immunocytochemical analysis of proenkephalin-derived peptides in the amphibian hypothalamus and optic tectum. , Merchenthaler I., Dev Biol. July 28, 1987; 416 (2): 219-27.
Immunocytochemical localization and spatial relation to the adenohypophysis of a somatostatin-like and a corticotropin-releasing factor-like peptide in the brain of four amphibian species. , Olivereau M., Cell Tissue Res. February 1, 1987; 247 (2): 317-24.
Differentiating effects of murine nerve growth factor in the peripheral and central nervous systems of Xenopus laevis tadpoles. , Levi-Montalcini R., Proc Natl Acad Sci U S A. October 1, 1985; 82 (20): 7111-5.
Effects of synthetic mammalian thyrotrophin releasing hormone, somatostatin and dopamine on the secretion of prolactin and growth hormone from amphibian and reptilian pituitary glands incubated in vitro. , Hall TR., J Endocrinol. August 1, 1984; 102 (2): 175-80.
Cerebrospinal fluid-contacting neurons and other somatostatin-immunoreactive perikarya in brains of tadpoles of Xenopus laevis. , Blähser S., Cell Tissue Res. January 1, 1982; 224 (3): 693-7.
Tissue distribution of immunoreactive somatostatin in the South African clawed toad (Xenopus laevis). , Shapiro B., J Endocrinol. March 1, 1979; 80 (3): 407-8.