Papers associated with krt12.5

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	Stage-specific keratins in Xenopus laevis embryos and tadpoles: the XK81 gene family., Miyatani S, Winkles JA, Sargent TD, Dawid IB., J Cell Biol. November 1, 1986; 103 (5): 1957-65.
	A set of novel tadpole specific genes expressed only in the epidermis are down-regulated by thyroid hormone during Xenopus laevis metamorphosis., Furlow JD, Berry DL, Wang Z, Brown DD., Dev Biol. February 15, 1997; 182 (2): 284-98.
	Gene expression screening in Xenopus identifies molecular pathways, predicts gene function and provides a global view of embryonic patterning., Gawantka V, Pollet N, Delius H, Vingron M, Pfister R, Nitsch R, Blumenstock C, Niehrs C., Mech Dev. October 1, 1998; 77 (2): 95-141.
	Lineage of anuran epidermal basal cells and their differentiation potential in relation to metamorphic skin remodeling., Suzuki K, Utoh R, Kotani K, Obara M, Yoshizato K., Dev Growth Differ. June 1, 2002; 44 (3): 225-38.
	An essential role of Xenopus Foxi1a for ventral specification of the cephalic ectoderm during gastrulation., Matsuo-Takasaki M, Matsumura M, Sasai Y., Development. September 1, 2005; 132 (17): 3885-94.
	Tsukushi controls ectodermal patterning and neural crest specification in Xenopus by direct regulation of BMP4 and X-delta-1 activity., Kuriyama S, Lupo G, Ohta K, Ohnuma S, Harris WA, Tanaka H., Development. January 1, 2006; 133 (1): 75-88.
	A novel Xenopus laevis larval keratin gene, xlk2: its gene structure and expression during regeneration and metamorphosis of limb and tail., Tazawa I, Shimizu-Nishikawa K, Yoshizato K., Biochim Biophys Acta. May 1, 2006; 1759 (5): 216-24.
	Molecular features of thyroid hormone-regulated skin remodeling in Xenopus laevis during metamorphosis., Suzuki K, Machiyama F, Nishino S, Watanabe Y, Kashiwagi K, Kashiwagi A, Yoshizato K., Dev Growth Differ. May 1, 2009; 51 (4): 411-27.
	Characterization of a novel type I keratin gene and generation of transgenic lines with fluorescent reporter genes driven by its promoter/enhancer in Xenopus laevis., Suzuki KT, Kashiwagi K, Ujihara M, Marukane T, Tazaki A, Watanabe K, Mizuno N, Ueda Y, Kondoh H, Kashiwagi A, Mochii M., Dev Dyn. December 1, 2010; 239 (12): 3172-81.
	Mapping gene expression in two Xenopus species: evolutionary constraints and developmental flexibility., Yanai I, Peshkin L, Jorgensen P, Kirschner MW., Dev Cell. April 19, 2011; 20 (4): 483-96.
	Proteomic analysis of fibroblastema formation in regenerating hind limbs of Xenopus laevis froglets and comparison to axolotl., Rao N, Song F, Jhamb D, Wang M, Milner DJ, Price NM, Belecky-Adams TL, Palakal MJ, Cameron JA, Li B, Chen X, Stocum DL., BMC Dev Biol. July 25, 2014; 14 32.
	Spemann organizer transcriptome induction by early beta-catenin, Wnt, Nodal, and Siamois signals in Xenopus laevis., Ding Y, Ploper D, Sosa EA, Colozza G, Moriyama Y, Benitez MD, Zhang K, Merkurjev D, De Robertis EM., Proc Natl Acad Sci U S A. April 11, 2017; 114 (15): E3081-E3090.
	Clustered Xenopus keratin genes: A genomic, transcriptomic, and proteomic analysis., Suzuki KT, Suzuki M, Suzuki M, Shigeta M, Fortriede JD, Takahashi S, Mawaribuchi S, Yamamoto T, Taira M, Fukui A., Dev Biol. June 15, 2017; 426 (2): 384-392.
	KDM3A-mediated demethylation of histone H3 lysine 9 facilitates the chromatin binding of Neurog2 during neurogenesis., Lin H, Zhu X, Chen G, Song L, Gao L, Khand AA, Chen Y, Lin G, Tao Q, Tao Q., Development. October 15, 2017; 144 (20): 3674-3685.
	Reactivation of larval keratin gene (krt62.L) in blastema epithelium during Xenopus froglet limb regeneration., Satoh A, Mitogawa K, Saito N, Suzuki M, Suzuki M, Suzuki KT, Ochi H, Makanae A., Dev Biol. December 15, 2017; 432 (2): 265-272.
	Morphological and transcriptomic analyses reveal three discrete primary stages of postembryonic development in the common fire salamander, Salamandra salamandra., Sanchez E, Küpfer E, Goedbloed DJ, Nolte AW, Lüddecke T, Schulz S, Vences M, Steinfartz S., J Exp Zool B Mol Dev Evol. March 1, 2018; 330 (2): 96-108.
	Tissue mechanics drives regeneration of a mucociliated epidermis on the surface of Xenopus embryonic aggregates., Kim HY, Kim HY, Jackson TR, Stuckenholz C, Davidson LA, Davidson LA., Nat Commun. January 31, 2020; 11 (1): 665.
	Rspo2 inhibits TCF3 phosphorylation to antagonize Wnt signaling during vertebrate anteroposterior axis specification., Reis AH, Sokol SY., Sci Rep. June 28, 2021; 11 (1): 13433.
	Sobp modulates the transcriptional activation of Six1 target genes and is required during craniofacial development., Tavares ALP, Jourdeuil K, Neilson KM, Majumdar HD, Moody SA., Development. September 1, 2021; 148 (17):
	Systematic mapping of rRNA 2'-O methylation during frog development and involvement of the methyltransferase Fibrillarin in eye and craniofacial development in Xenopus laevis., Delhermite J, Tafforeau L, Sharma S, Marchand V, Wacheul L, Lattuca R, Desiderio S, Motorin Y, Bellefroid E, Lafontaine DLJ., PLoS Genet. January 18, 2022; 18 (1): e1010012.
	Xenopus Dusp6 modulates FGF signaling to precisely pattern pre-placodal ectoderm., Tsukano K, Yamamoto T, Watanabe T, Michiue T., Dev Biol. August 1, 2022; 488 81-90.
	The heparan sulfate modification enzyme, Hs6st1, governs Xenopus neuroectodermal patterning by regulating distributions of Fgf and Noggin., Yamamoto T, Kaneshima T, Tsukano K, Michiue T., Dev Biol. April 1, 2023; 496 87-94.
	Ndst1, a heparan sulfate modification enzyme, regulates neuroectodermal patterning by enhancing Wnt signaling in Xenopus., Yamamoto T, Kambayashi Y, Tsukano K, Michiue T., Dev Growth Differ. April 1, 2023; 65 (3): 153-160.
	Enhancement of neural crest formation by mechanical force in Xenopus development., Kaneshima T, Ogawa M, Yamamoto T, Tsuboyama Y, Miyata Y, Kotani T, Okajima T, Michiue T., Int J Dev Biol. January 1, 2024; 68 (1): 25-37.

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