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Impaired negative feedback and death following acute stress in glucocorticoid receptor knockout Xenopus tropicalis tadpoles. , Paul B ., Gen Comp Endocrinol. September 15, 2022; 326 114072.
Angiogenesis in the intermediate lobe of the pituitary gland alters its structure and function. , Tanaka S., Gen Comp Endocrinol. May 1, 2013; 185 10-8.
Plasticity of melanotrope cell regulations in Xenopus laevis. , Roubos EW ., Eur J Neurosci. December 1, 2010; 32 (12): 2082-6.
Ultrastructural and neurochemical architecture of the pituitary neural lobe of Xenopus laevis. , van Wijk DC., Gen Comp Endocrinol. September 1, 2010; 168 (2): 293-301.
Light modulates the melanophore response to alpha-MSH in Xenopus laevis: an analysis of the signal transduction crosstalk mechanisms involved. , Isoldi MC., Gen Comp Endocrinol. January 1, 2010; 165 (1): 104-10.
Accessory subunit Ac45 controls the V-ATPase in the regulated secretory pathway. , Jansen EJ., Biochim Biophys Acta. December 1, 2008; 1783 (12): 2301-10.
Brain distribution and evidence for both central and neurohormonal actions of cocaine- and amphetamine-regulated transcript peptide in Xenopus laevis. , Roubos EW ., J Comp Neurol. April 1, 2008; 507 (4): 1622-38.
Evidence for the role of adenosine 5'-triphosphate-binding cassette (ABC)-A1 in the externalization of annexin 1 from pituitary folliculostellate cells and ABCA1-transfected cell models. , Omer S., Endocrinology. July 1, 2006; 147 (7): 3219-27.
Widespread tissue distribution and diverse functions of corticotropin-releasing factor and related peptides. , Boorse GC., Gen Comp Endocrinol. March 1, 2006; 146 (1): 9-18.
Urocortins of the South African clawed frog, Xenopus laevis: conservation of structure and function in tetrapod evolution. , Boorse GC., Endocrinology. November 1, 2005; 146 (11): 4851-60.
Neuronal, neurohormonal, and autocrine control of Xenopus melanotrope cell activity. , Roubos EW ., Ann N Y Acad Sci. April 1, 2005; 1040 172-83.
Xenopus laevis FoxE1 is primarily expressed in the developing pituitary and thyroid. , El-Hodiri HM ., Int J Dev Biol. January 1, 2005; 49 (7): 881-4.
Expression and characterization of the extracellular Ca(2+)-sensing receptor in melanotrope cells of Xenopus laevis. , van den Hurk MJ., Endocrinology. June 1, 2003; 144 (6): 2524-33.
Characterization and functional expression of cDNAs encoding thyrotropin-releasing hormone receptor from Xenopus laevis. , Bidaud I., Eur J Biochem. September 1, 2002; 269 (18): 4566-76.
Multiple control and dynamic response of the Xenopus melanotrope cell. , Kolk SM., Comp Biochem Physiol B Biochem Mol Biol. May 1, 2002; 132 (1): 257-68.
Characterization of three corticotropin-releasing factor receptors in catfish: a novel third receptor is predominantly expressed in pituitary and urophysis. , Arai M., Endocrinology. January 1, 2001; 142 (1): 446-54.
Identification of two corticotropin-releasing factor receptors from Xenopus laevis with high ligand selectivity: unusual pharmacology of the type 1 receptor. , Dautzenberg FM., J Neurochem. October 1, 1997; 69 (4): 1640-9.
The secretion of alpha-MSH from xenopus melanotropes involves calcium influx through omega-conotoxin-sensitive voltage-operated calcium channels. , Scheenen WJ., J Neuroendocrinol. August 1, 1994; 6 (4): 457-64.
Evidence of direct estrogenic regulation of human corticotropin-releasing hormone gene expression. Potential implications for the sexual dimophism of the stress response and immune/inflammatory reaction. , Vamvakopoulos NC., J Clin Invest. October 1, 1993; 92 (4): 1896-902.
Control of melanoblast differentiation in amphibia by alpha- melanocyte stimulating hormone, a serum melanization factor, and a melanization inhibiting factor. , Fukuzawa T ., Pigment Cell Res. January 1, 1989; 2 (3): 171-81.