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Search Criteria

Gene/Clone	Species	Stage	Anatomy Item	Experimenter
pax2	xenopus		hindbrain [+] cerebellum,fourth ventricle,medulla oblongata,rhombomere,rhombic lip,dorsal column nucleus,granule cell,granule cell layer of the cerebellum,locus coeruleus,raphe nucleus,solitary tract,Mauthner cell,nucleus of the solitary tract,nucleus reticularis medialis,nucleus reticularis superior,nucleus reticularis inferior

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Expression summary for pax2

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Experiment	Species	Images	Stages	Anatomy	Assay
Vize Lab Assay Vize Lab	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
Cartry J et al. (2006) Assay Paper	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
Schlosser G and Ahrens K (2004) Assay Paper	laevis	1 image	NF stage 32 to NF stage 33 and 34	hindbrain	in situ hybridization
Lupo G et al. (2005) Assay Paper	xenopus	4 images	NF stage 29 and 30 to NF stage 33 and 34	hindbrain	in situ hybridization
Carroll T et al. (1999) Assay Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
Colas A et al. (2008) Assay Paper	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
Harland Lab Assay Harland Lab	tropicalis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
En2, Pax2/5 and Tcf-4 transcription factors cooperate in patterning the Xenopus brain. Paper	laevis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Negative regulation of Hedgehog signaling by the cholesterogenic enzyme 7-dehydrocholesterol reductase. Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
Lef1 plays a role in patterning the mesoderm and ectoderm in Xenopus tropicalis. Paper	tropicalis	1 image	NF stage 37 and 38	hindbrain, rhombomere	in situ hybridization
Retinoic acid is a key regulatory switch determining the difference between lung and thyroid fates in Xenopus laevis. Paper	laevis	1 image	NF stage 29 and 30 to NF stage 40	hindbrain	in situ hybridization
Retinoic acid is a key regulatory switch determining the difference between lung and thyroid fates in Xenopus laevis. Paper	laevis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Retinoic acid is a key regulatory switch determining the difference between lung and thyroid fates in Xenopus laevis. Paper	laevis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Saulnier DM et al. (2002) Assay Paper	laevis	1 image	NF stage 32	hindbrain	in situ hybridization
Williams Syndrome Transcription Factor is critical for neural crest cell function in Xenopus laevis. Paper	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
HNF1B controls proximal-intermediate nephron segment identity in vertebrates by regulating Notch signalling components and I... Paper	laevis	1 image	NF stage 33 and 34 to NF stage 35 and 36	hindbrain	in situ hybridization
Li L et al. (2012) Assay Paper	laevis	2 images	NF stage 35 and 36 to NF stage 37 and 38	hindbrain	in situ hybridization
Lhx1 is required for specification of the renal progenitor cell field. Paper	laevis	1 image	NF stage 32	hindbrain	in situ hybridization
Li DH et al. (2005) Assay Paper	laevis	1 image	NF stage 29 and 30 to NF stage 31	hindbrain	in situ hybridization
Reggiani L et al. (2007) Assay Paper	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
Buisson I et al. (2014) Assay Paper	laevis	2 images	NF stage 33 and 34 to NF stage 35 and 36	hindbrain	in situ hybridization
Griffin JN et al. (2015) Assay Paper	tropicalis	2 images	NF stage 28 to NF stage 33 and 34	hindbrain	in situ hybridization
Komiya Y et al. (2014) Assay Paper	laevis	1 image	NF stage 26	hindbrain	in situ hybridization
Cho GS et al. (2011) Assay Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
del Viso F et al. (2012) Assay Paper	tropicalis	3 images	NF stage 35 and 36 to NF stage 37 and 38	hindbrain	in situ hybridization
Hanotel J et al. (2014) Assay Paper	laevis	1 image	NF stage 32	hindbrain	in situ hybridization
Hspa9 is required for pronephros specification and formation in Xenopus laevis. Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
CRISPR/Cas9: An inexpensive, efficient loss of function tool to screen human disease genes in Xenopus. Paper	tropicalis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Carroll TJ and Vize PD (1999) Assay Paper	laevis	1 image	NF stage 35 and 36	hindbrain	in situ hybridization
Hspa9 is required for pronephros specification and formation in Xenopus laevis. Paper	laevis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Hspa9 is required for pronephros specification and formation in Xenopus laevis. Paper	laevis	1 image	NF stage 32	hindbrain	in situ hybridization
Hspa9 is required for pronephros specification and formation in Xenopus laevis. Paper	laevis	1 image	NF stage 32	hindbrain	in situ hybridization
Pa2G4 is a novel Six1 co-factor that is required for neural crest and otic development. Paper	laevis	1 image	NF stage 28	hindbrain	in situ hybridization
A homeobox gene, vax2, controls the patterning of the eye dorsoventral axis. Paper	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
Hedgehog-dependent E3-ligase Midline1 regulates ubiquitin-mediated proteasomal degradation of Pax6 during visual system deve... Paper	laevis	1 image	NF stage 33 and 34	hindbrain	in situ hybridization
Griffin JN et al. (2018) Assay Paper	tropicalis	1 image	NF stage 37 and 38	hindbrain	in situ hybridization
Cervino AS et al. (2023) Assay Paper	laevis	1 image	NF stage 32	hindbrain	in situ hybridization

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