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Using Xenopus to discover new candidate genes involved in BOR and other congenital hearing loss syndromes. , Neal SJ, Rajasekaran A, Jusić N, Taylor L , Read M, Alfandari D , Alfandari D , Pignoni F, Moody SA ., J Exp Zool B Mol Dev Evol. October 13, 2023;
Cellular and molecular profiles of larval and adult Xenopus corneal epithelia resolved at the single-cell level. , Sonam S, Bangru S, Perry KJ, Chembazhi UV, Kalsotra A, Henry JJ ., Dev Biol. November 1, 2022; 491 13-30.
Tissue disaggregation and isolation of specific cell types from transgenic Xenopus appendages for transcriptional analysis by FACS. , Kakebeen AD, Chitsazan AD, Wills AE ., Dev Dyn. September 1, 2021; 250 (9): 1381-1392.
Otic Neurogenesis in Xenopus laevis: Proliferation, Differentiation, and the Role of Eya1. , Almasoudi SH, Schlosser G ., Front Neuroanat. January 1, 2021; 15 722374.
Fzd3 Expression Within Inner Ear Afferent Neurons Is Necessary for Central Pathfinding. , Stoner ZA, Ketchum EM, Sheltz-Kempf S, Blinkiewicz PV, Elliott KL, Duncan JS., Front Neurosci. January 1, 2021; 15 779871.
A Critical E-box in Barhl1 3' Enhancer Is Essential for Auditory Hair Cell Differentiation. , Hou K, Jiang H, Karim MR, Zhong C, Xu Z, Liu L, Guan M, Shao J, Huang X ., Cells. May 15, 2019; 8 (5):
Insights into electrosensory organ development, physiology and evolution from a lateral line-enriched transcriptome. , Modrell MS, Lyne M, Carr AR, Zakon HH , Buckley D, Campbell AS, Davis MC, Micklem G, Baker CV ., Elife. March 27, 2017; 6
Dissecting the pre-placodal transcriptome to reveal presumptive direct targets of Six1 and Eya1 in cranial placodes. , Riddiford N, Schlosser G ., Elife. August 31, 2016; 5
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, Powers TR , van Velkinburgh JC, Trujillo-Provencio C, Schilkey F, Serrano EE ., BMC Res Notes. November 18, 2015; 8 691.
Opportunities and limits of the one gene approach: the ability of Atoh1 to differentiate and maintain hair cells depends on the molecular context. , Jahan I, Pan N, Fritzsch B ., Front Cell Neurosci. February 5, 2015; 9 26.
Transit amplification in the amniote cerebellum evolved via a heterochronic shift in NeuroD1 expression. , Butts T, Hanzel M, Wingate RJ., Development. July 1, 2014; 141 (14): 2791-5.
Sponge genes provide new insight into the evolutionary origin of the neurogenic circuit. , Richards GS, Simionato E, Perron M , Adamska M, Vervoort M, Degnan BM., Curr Biol. August 5, 2008; 18 (15): 1156-61.
The α1 subunit of nicotinic acetylcholine receptors in the inner ear: transcriptional regulation by ATOH1 and co-expression with the γ subunit in hair cells. , Scheffer D, Sage C, Plazas PV, Huang M, Wedemeyer C, Zhang DS, Chen ZY, Elgoyhen AB, Corey DP, Pingault V., J Neurochem. December 1, 2007; 103 (6): 2651-64.
Differential transcription of Barhl1 homeobox gene in restricted functional domains of the central nervous system suggests a role in brain patterning. , Rachidi M, Lopes C., Int J Dev Neurosci. February 1, 2006; 24 (1): 35-44.
Evolution of neural precursor selection: functional divergence of proneural proteins. , Quan XJ, Denayer T, Yan J, Jafar-Nejad H, Philippi A, Lichtarge O, Vleminckx K , Vleminckx K , Hassan BA., Development. April 1, 2004; 131 (8): 1679-89.
The activity of neurogenin1 is controlled by local cues in the zebrafish embryo. , Blader P, Fischer N, Gradwohl G, Guillemot F , Strähle U., Development. November 1, 1997; 124 (22): 4557-69.
XATH-1, a vertebrate homolog of Drosophila atonal, induces a neuronal differentiation within ectodermal progenitors. , Kim P, Helms AW, Johnson JE, Zimmerman K., Dev Biol. July 1, 1997; 187 (1): 1-12.
Identification of neurogenin, a vertebrate neuronal determination gene. , Ma Q, Kintner C , Anderson DJ., Cell. October 4, 1996; 87 (1): 43-52.