ZFIN Morpholino: MO2-foxi1

Target Location

Genome Build: GRCz11Chromosome: 12

Genomic Features

No data available

Expression

Gene expression in Wild Types + MO2-foxi1

Expressed Gene	Anatomy	Figures
bmper	whole organism	Fig. 7 from Yao et al., 2014
cdh6	(not) otic vesicle neuroblast (sensu Vertebrata)	Fig. 4 from Hans et al., 2013
cxcr4b	olfactory placode	Fig. 6 from Yao et al., 2014
dlx3b	dorsolateral placode whole organism	Fig. 6 , Fig. 7 from Yao et al., 2014
foxe3	otic vesicle	Fig. 6 from Yao et al., 2014

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Phenotype

Phenotype resulting from MO2-foxi1

Phenotype	Fish	Figures
adenohypophyseal placode increased size, abnormal	x24Tg + MO2-foxi1 + MO2-gata3	Fig. 4 from Bhat et al., 2013
dorsolateral placode hmx3a expression decreased distribution, abnormal	TU + MO2-foxi1	Fig. 6 from Yao et al., 2014
dorsolateral placode dlx3b expression decreased distribution, abnormal	TU + MO2-foxi1	Fig. 6 from Yao et al., 2014
embryonic viscerocranium morphogenesis disrupted, abnormal	WT + MO2-foxi1	Fig. 1 from Solomon et al., 2003
epibranchial field sox3 expression absent, abnormal	WT + MO2-foxi1	Fig. 7 from Sun et al., 2007

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Phenotype of all Fish created by or utilizing MO2-foxi1

Phenotype	Fish	Conditions	Figures
pharyngeal endoderm apoptotic, abnormal	AB + MO2-foxi1	heat shock	Fig. 9 from Edlund et al., 2014
pharyngeal endoderm apoptotic, abnormal	AB + MO2-foxi1	standard conditions	Fig. 9 from Edlund et al., 2014
dorsolateral placode hmx3a expression decreased distribution, abnormal	TU + MO2-foxi1	control	Fig. 6 from Yao et al., 2014
epibranchial field sox3 expression decreased distribution, abnormal	TU + MO2-foxi1	control	Fig. 6 from Yao et al., 2014
otic placode pax2a expression decreased distribution, abnormal	TU + MO2-foxi1	control	Fig. 6 from Yao et al., 2014

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Citations

Include unpublished citations

McCarthy, N., Sidik, A., Bertrand, J.Y., Eberhart, J.K. (2016) An Fgf-Shh signaling hierarchy regulates early specification of the zebrafish skull. Developmental Biology. 415(2):261-77
Long, L., Guo, H., Yao, D., Xiong, K., Li, Y., Liu, P., Zhu, Z., Liu, D. (2015) Regulation of transcriptionally active genes via the catalytically inactive Cas9 in C. elegans and D. rerio. Cell Research. 25:638-41
Edlund, R.K., Ohyama, T., Kantarci, H., Riley, B.B., Groves, A.K. (2014) Foxi transcription factors promote pharyngeal arch development by regulating formation of FGF signaling centers. Developmental Biology. 390:1-13
Yao, D., Zhao, F., Wu, Y., Wang, J., Wei, D., Zhao, J., Zhu, Z., Liu, D. (2014) Dissecting the differentiation process of the pre-placodal ectoderm in zebrafish. Developmental Dynamics : an official publication of the American Association of Anatomists. 243(10):1338-51
Bhat, N., Kwon, H.J., and Riley, B.B. (2013) A gene network that coordinates preplacodal competence and neural crest specification in zebrafish. Developmental Biology. 373(1):107-117
Hans, S., Irmscher, A., and Brand, M. (2013) Zebrafish Foxi1 provides a neuronal ground state during inner ear induction preceding the Dlx3b/4b-regulated sensory lineage. Development (Cambridge, England). 140(9):1936-1945
Padanad, M.S., Bhat, N., Guo, B., and Riley, B.B. (2012) Conditions that influence the response to Fgf during otic placode induction. Developmental Biology. 364(1):1-10
Kwon, H.J., Bhat, N., Sweet, E.M., Cornell, R.A., and Riley, B.B. (2010) Identification of early requirements for preplacodal ectoderm and sensory organ development. PLoS Genetics. 6(9):pii: e1001133
Hans, S., and Westerfield, M. (2007) Changes in retinoic acid signaling alter otic patterning. Development (Cambridge, England). 134(13):2449-2458
Hans, S., Christison, J., Liu, D., and Westerfield, M. (2007) Fgf-dependent otic induction requires competence provided by Foxi1 and Dlx3b. BMC Developmental Biology. 7(1):5

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