Papers associated with brain (and sst.1)

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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.

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