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	Single-cell atlas comparison across vertebrates reveals auditory cell evolution and mechanisms for hair cell regeneration., Wang Y, Wang H, Zhang P, Zhu B, Li W, Zhao X, Yan M, Song X, Lai F, Dong J, Cui J, Guo X, Wu HJ, Li J., Commun Biol. December 19, 2024; 7 (1): 1648.
	Temporal and spatial transcriptomic dynamics across brain development in Xenopus laevis tadpoles., Ta AC, Huang LC, McKeown CR, Bestman JE, Van Keuren-Jensen K, Cline HT., G3 (Bethesda). January 4, 2022; 12 (1):
	Xenopus pitx3 target genes lhx1 and xnr5 are identified using a novel three-fluor flow cytometry-based analysis of promoter activation and repression., Hooker LN, Smoczer C, Abbott S, Fakhereddin M, Hudson JW, Crawford MJ., Dev Dyn. September 1, 2017; 246 (9): 657-669.
	Comparative analysis of monoaminergic cerebrospinal fluid-contacting cells in Osteichthyes (bony vertebrates)., Xavier AL, Fontaine R, Bloch S, Affaticati P, Jenett A, Demarque M, Vernier P, Yamamoto K., J Comp Neurol. June 15, 2017; 525 (9): 2265-2283.
	Gene expression analysis of developing cell groups in the pretectal region of Xenopus laevis., Morona R, Ferran JL, Puelles L, González A., J Comp Neurol. March 1, 2017; 525 (4): 715-752.
	Deep-brain photoreception links luminance detection to motor output in Xenopus frog tadpoles., Currie SP, Doherty GH, Sillar KT., Proc Natl Acad Sci U S A. May 24, 2016; 113 (21): 6053-8.
	ACT-PRESTO: Rapid and consistent tissue clearing and labeling method for 3-dimensional (3D) imaging., Lee E, Choi J, Jo Y, Kim JY, Jang YJ, Lee HM, Kim SY, Lee HJ, Cho K, Jung N, Hur EM, Jeong SJ, Moon C, Choe Y, Rhyu IJ, Kim H, Sun W., Sci Rep. January 11, 2016; 6 18631.
	Spatiotemporal Development of the Orexinergic (Hypocretinergic) System in the Central Nervous System of Xenopus laevis., López JM, Morales L, González A., Brain Behav Evol. January 1, 2016; 88 (2): 127-146.
	Ascl1 phospho-status regulates neuronal differentiation in a Xenopus developmental model of neuroblastoma., Wylie LA, Hardwick LJ, Papkovskaia TD, Thiele CJ, Philpott A., Dis Model Mech. May 1, 2015; 8 (5): 429-41.
	Dopamine: a parallel pathway for the modulation of spinal locomotor networks., Sharples SA, Koblinger K, Humphreys JM, Whelan PJ., Front Neural Circuits. June 16, 2014; 8 55.
	Ascl1 as a novel player in the Ptf1a transcriptional network for GABAergic cell specification in the retina., Mazurier N, Parain K, Parlier D, Pretto S, Hamdache J, Vernier P, Locker M, Bellefroid E, Perron M., PLoS One. March 18, 2014; 9 (3): e92113.
	Wiring the retinal circuits activated by light during early development., Bertolesi GE, Hehr CL, McFarlane S., Neural Dev. February 13, 2014; 9 3.
	Angiogenesis in the intermediate lobe of the pituitary gland alters its structure and function., Tanaka S, Nakakura T, Jansen EJ, Unno K, Okada R, Suzuki M, Martens GJ, Kikuyama S., Gen Comp Endocrinol. May 1, 2013; 185 10-8.
	Pax3 and Zic1 drive induction and differentiation of multipotent, migratory, and functional neural crest in Xenopus embryos., Milet C, Maczkowiak F, Roche DD, Monsoro-Burq AH., Proc Natl Acad Sci U S A. April 2, 2013; 110 (14): 5528-33.
	Pattern of calbindin-D28k and calretinin immunoreactivity in the brain of Xenopus laevis during embryonic and larval development., Morona R, González A., J Comp Neurol. January 1, 2013; 521 (1): 79-108.
	Okadaic acid-sensitive phosphatase is related to MII/G1 transition in mouse oocytes., Moride N, Kuwahara A, Sutoh A, Tanaka Y, Mukai Y, Yamashita M, Matsuzaki T, Yasui T, Irahara M., Zygote. May 1, 2012; 20 (2): 193-8.
	Contexts for dopamine specification by calcium spike activity in the CNS., Velázquez-Ulloa NA, Spitzer NC, Dulcis D., J Neurosci. January 5, 2011; 31 (1): 78-88.
	Immunohistochemical localization of DARPP-32 in the brain and spinal cord of anuran amphibians and its relation with the catecholaminergic system., López JM, Morona R, González A., J Chem Neuroanat. December 1, 2010; 40 (4): 325-38.
	Sonic hedgehog expression during Xenopus laevis forebrain development., Domínguez L, González A, Moreno N., Dev Biol. August 6, 2010; 1347 19-32.
	Identification of the gene encoding alkylglycerol monooxygenase defines a third class of tetrahydrobiopterin-dependent enzymes., Watschinger K, Keller MA, Golderer G, Hermann M, Maglione M, Sarg B, Lindner HH, Hermetter A, Werner-Felmayer G, Konrat R, Hulo N, Werner ER., Proc Natl Acad Sci U S A. August 3, 2010; 107 (31): 13672-7.
	Immunohistochemical localization of calbindin-D28k and calretinin in the brainstem of anuran and urodele amphibians., Morona R, González A., J Comp Neurol. August 10, 2009; 515 (5): 503-37.
	Generation of functional eyes from pluripotent cells., Viczian AS, Solessio EC, Lyou Y, Zuber ME., PLoS Biol. August 1, 2009; 7 (8): e1000174.
	Mediolateral and rostrocaudal topographic organization of the sympathetic preganglionic cell pool in the spinal cord of Xenopus laevis., Nakano M, Goris RC, Atobe Y, Kadota T, Funakoshi K., J Comp Neurol. March 20, 2009; 513 (3): 292-314.
	Spatio-temporal expression of Pax6 in Xenopus forebrain., Moreno N, Rétaux S, González A., Brain Res. November 6, 2008; 1239 92-9.
	Simvastatin inhibits catecholamine secretion and synthesis induced by acetylcholine via blocking Na+ and Ca2+ influx in bovine adrenal medullary cells., Matsuda T, Toyohira Y, Ueno S, Tsutsui M, Yanagihara N., J Pharmacol Exp Ther. October 1, 2008; 327 (1): 130-6.
	Xenopus zinc finger transcription factor IA1 (Insm1) expression marks anteroventral noradrenergic neuron progenitors in Xenopus embryos., Parlier D, Ariza A, Christulia F, Genco F, Vanhomwegen J, Kricha S, Souopgui J, Bellefroid EJ., Dev Dyn. August 1, 2008; 237 (8): 2147-57.
	Islet1 as a marker of subdivisions and cell types in the developing forebrain of Xenopus., Moreno N, Domínguez L, Rétaux S, González A., Neuroscience. July 17, 2008; 154 (4): 1423-39.
	Anuran olfactory bulb organization: embryology, neurochemistry and hodology., Moreno N, Morona R, López JM, Dominguez L, Muñoz M, González A., Brain Res Bull. March 18, 2008; 75 (2-4): 241-5.
	Ptf1a triggers GABAergic neuronal cell fates in the retina., Dullin JP, Locker M, Robach M, Henningfeld KA, Parain K, Afelik S, Pieler T, Perron M., BMC Dev Biol. May 31, 2007; 7 110.
	Timing the generation of distinct retinal cells by homeobox proteins., Decembrini S, Andreazzoli M, Vignali R, Barsacchi G, Cremisi F., PLoS Biol. September 1, 2006; 4 (9): e272.
	Colocalization of nitric oxide synthase and monoamines in neurons of the amphibian brain., López JM, Moreno N, Morona R, Muñoz M, González A., Brain Res Bull. September 15, 2005; 66 (4-6): 555-9.
	Central amygdala in anuran amphibians: neurochemical organization and connectivity., Moreno N, González A., J Comp Neurol. August 15, 2005; 489 (1): 69-91.
	Localization of Mel1b melatonin receptor-like immunoreactivity in ocular tissues of Xenopus laevis., Wiechmann AF, Udin SB, Summers Rada JA., Exp Eye Res. October 1, 2004; 79 (4): 585-94.
	Establishment of a ventral cell fate in the spinal cord., Moghadam KS, Chen A, Heathcote RD., Dev Dyn. August 1, 2003; 227 (4): 552-62.
	Differential distribution of Mel(1a) and Mel(1c) melatonin receptors in Xenopus laevis retina., Wiechmann AF., Exp Eye Res. January 1, 2003; 76 (1): 99-106.
	Tyrosine hydroxylase-immunoreactive interneurons in the olfactory bulb of the frogs Rana pipiens and Xenopus laevis., Boyd JD, Delaney KR., J Comp Neurol. December 2, 2002; 454 (1): 42-57.
	Reduction in cell size during development of the spinal cord., Chen A, Ekman JM, Heathcote RD., J Comp Neurol. July 12, 1999; 409 (4): 592-602.
	Identification of suprachiasmatic melanotrope-inhibiting neurons in Xenopus laevis: a confocal laser-scanning microscopy study., Ubink R, Tuinhof R, Roubos EW., J Comp Neurol. July 20, 1998; 397 (1): 60-8.
	Basal ganglia organization in amphibians: chemoarchitecture., Marín O, Smeets WJ, González A., J Comp Neurol. March 16, 1998; 392 (3): 285-312.
	Stage-dependent changes in adrenal steroids and catecholamines during development in Xenopus laevis., Kloas W, Reinecke M, Hanke W., Gen Comp Endocrinol. December 1, 1997; 108 (3): 416-26.
	Brain-derived neurotrophic factor/neurotrophin-4 receptor TrkB is localized on ganglion cells and dopaminergic amacrine cells in the vertebrate retina., Cellerino A, Kohler K., J Comp Neurol. September 15, 1997; 386 (1): 149-60.
	Development of catecholamine systems in the central nervous system of the newt Pleurodeles waltlii as revealed by tyrosine hydroxylase immunohistochemistry., González A, Marín O, Smeets WJ., J Comp Neurol. September 11, 1995; 360 (1): 33-48.
	Ontogeny of catecholamine systems in the central nervous system of anuran amphibians: an immunohistochemical study with antibodies against tyrosine hydroxylase and dopamine., González A, Marín O, Tuinhof R, Smeets WJ., J Comp Neurol. August 1, 1994; 346 (1): 63-79.
	Effects of localized application of retinoic acid on Xenopus laevis development., Drysdale TA, Crawford MJ., Dev Biol. April 1, 1994; 162 (2): 394-401.
	Morphogenesis of catecholaminergic interneurons in the frog spinal cord., Heathcote RD, Chen A., J Comp Neurol. April 1, 1994; 342 (1): 57-68.
	A nonrandom interneuronal pattern in the developing frog spinal cord., Heathcote RD, Chen A., J Comp Neurol. February 15, 1993; 328 (3): 437-48.
	Distribution of tyrosine hydroxylase and dopamine immunoreactivities in the brain of the South African clawed frog Xenopus laevis., González A, Tuinhof R, Smeets WJ., Anat Embryol (Berl). February 1, 1993; 187 (2): 193-201.
	Does lineage determine the dopamine phenotype in the tadpole hypothalamus?: A quantitative analysis., Huang S, Moody SA., J Neurosci. April 1, 1992; 12 (4): 1351-62.
	Phosphorylation of human recombinant tyrosine hydroxylase isoforms 1 and 2: an additional phosphorylated residue in isoform 2, generated through alternative splicing., Le Bourdellès B, Horellou P, Le Caer JP, Denèfle P, Latta M, Haavik J, Guibert B, Mayaux JF, Mallet J., J Biol Chem. September 15, 1991; 266 (26): 17124-30.
	Development of the Xenopus laevis hatching gland and its relationship to surface ectoderm patterning., Drysdale TA, Elinson RP., Development. February 1, 1991; 111 (2): 469-78.

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