ZFIN ID: ZDB-FISH-150901-17600
Fish name: w34Tg
Genotype: w34Tg
Targeting Reagent: none
HUMAN DISEASE MODELED by w34Tg
No data available
GENE EXPRESSION
Gene expression in w34Tg
RNA expression
Expressed Gene Structure Conditions Figures
axin2 control Fig. S3 with image from Felber et al., 2015
heat shock Fig. S3 with image from Felber et al., 2015
ccnd1 heat shock Fig. 5 with image from Goessling et al., 2008
col1a2 heat shock Fig. 3 with imageFig. S2 with image from Felber et al., 2015
col10a1a heat shock Fig. 3 with image from Felber et al., 2015
col12a1a perforation: spinal cord, heat shock Fig. 4 with image from Wehner et al., 2017
col12a1b perforation: spinal cord, heat shock Fig. 4 with image from Wehner et al., 2017
fabp10a heat shock Fig. 5 with image from Goessling et al., 2008
fgf3 heat shock Fig. 6 with image from Felber et al., 2015
foxa3 heat shock Fig. 5 with image from Goessling et al., 2008
gsc heat shock Fig. 3 with image from Kagermeier-Schenk et al., 2011
hhex heat shock Fig. 5 with imageFig. S4b with image from Goessling et al., 2008
il17rd heat shock Fig. 6 with image from Felber et al., 2015
myca heat shock Fig. 5 with image from Lancman et al., 2013
Fig. 5 with image from Goessling et al., 2008
nkx2.5 control Fig. 11 with image from Novikov et al., 2013
heat shock Fig. 11 with image from Novikov et al., 2013
pdx1 heat shock Fig. 5 with imageFig. S4b with image from Goessling et al., 2008
prox1a heat shock Fig. 5 with image from Goessling et al., 2008
runx2a heat shock Fig. 4 with image from Felber et al., 2015
runx2b heat shock Fig. 4 with image from Felber et al., 2015
sp7 chemical treatment by environment: SU5402 Fig. 6 with image from Felber et al., 2015
heat shock Fig. 4 with imageFig. 6 with image from Felber et al., 2015
spry1 heat shock Fig. 6 with image from Felber et al., 2015
tbxta control Fig. 11 with image from Novikov et al., 2013
heat shock Fig. 11 with image from Novikov et al., 2013
wif1 control Fig. S3 with image from Felber et al., 2015
heat shock Fig. S3 with image from Felber et al., 2015
Protein expression
Antibody Antigen Genes Structure Conditions Figures
Ab3-prox1 heat shock Fig. 5 with image from Lancman et al., 2013
Fig. 1 with image from So et al., 2013
Ab3-prox1 control Fig. 1 with image from So et al., 2013
Reporter gene expression
Expressed Gene Structure Conditions Figures
GFP heat shock Fig. 4 from Kumaradevan et al., 2018
PHENOTYPE
Phenotype in w34Tg
Phenotype Conditions Figures
canonical Wnt signaling pathway increased process quality, abnormal heat shock Fig. 11 with image from Novikov et al., 2013
cardioblast cell fate specification process quality, normal heat shock Fig. 11 with image from Novikov et al., 2013
cell proliferation in forebrain increased occurrence, abnormal heat shock Fig. 3 with image from Wang et al., 2012
ceratobranchial 5 tooth ossification increased occurrence, abnormal heat shock Fig. 3 with image from Felber et al., 2015
endoderm hepatoblast distended, abnormal heat shock Fig. 1 with image from So et al., 2013
eye absent, abnormal heat shock Fig. 4 from Kumaradevan et al., 2018
eye aplastic, abnormal heat shock Fig. 2 with image from Özhan et al., 2013
eye decreased size, abnormal heat shock Fig. 4 from Kumaradevan et al., 2018
hyomandibula ossification increased occurrence, abnormal heat shock Fig. 3 with image from Felber et al., 2015
hypothalamus has extra parts of type neuronal stem cell, abnormal heat shock Fig. 3 with image from Wang et al., 2012
hypothalamus has fewer parts of type radial glial cell, abnormal heat shock Fig. 3 with image from Wang et al., 2012
hypothalamus has fewer parts of type serotonergic neuron, abnormal heat shock Fig. 3 with image from Wang et al., 2012
hypothalamus has fewer parts of type GABAergic neuron, abnormal heat shock Fig. 3 with image from Wang et al., 2012
hypothalamus increased size, abnormal heat shock Fig. S4 with image from Wang et al., 2012
myocardial precursor physical object quality, normal heat shock Fig. 11 with image from Novikov et al., 2013
neural precursor cell proliferation increased occurrence, abnormal heat shock Fig. 3 with image from Wang et al., 2012
neurogenesis disrupted, abnormal heat shock Fig. 3 with image from Wang et al., 2012
neuronal stem cell undifferentiated, abnormal heat shock Fig. 3 with image from Wang et al., 2012
opercle sp7 expression absent, abnormal chemical treatment by environment: SU5402 Fig. 6 with image from Felber et al., 2015
opercle col1a2 expression increased amount, abnormal heat shock Fig. 3 with image from Felber et al., 2015
opercle col10a1a expression increased amount, abnormal heat shock Fig. 3 with image from Felber et al., 2015
opercle sp7 expression increased amount, abnormal heat shock Fig. 6 with image from Felber et al., 2015
opercle ossification increased occurrence, abnormal heat shock Fig. 3 with image from Felber et al., 2015
ossification increased occurrence, abnormal heat shock Fig. 3 with image from Felber et al., 2015
pharyngeal arch 3-7 il17rd expression increased amount, abnormal heat shock Fig. 6 with image from Felber et al., 2015
pharyngeal arch 3-7 fgf3 expression increased amount, abnormal heat shock Fig. 6 with image from Felber et al., 2015
pharyngeal arch 3-7 axin2 expression increased amount, abnormal heat shock Fig. S3 with image from Felber et al., 2015
pharyngeal arch 3-7 spry1 expression increased amount, abnormal heat shock Fig. 6 with image from Felber et al., 2015
pharyngeal arch 3-7 wif1 expression increased amount, abnormal heat shock Fig. S3 with image from Felber et al., 2015
protein kinase B signaling increased process quality, abnormal heat shock Fig. 6 from Lee et al., 2014
trunk curved, abnormal heat shock Fig. 4 from Kumaradevan et al., 2018
trunk regenerating tissue col12a1b expression increased amount, abnormal perforation: spinal cord, heat shock Fig. 4 with image from Wehner et al., 2017
trunk regenerating tissue col12a1a expression increased amount, abnormal perforation: spinal cord, heat shock Fig. 4 with image from Wehner et al., 2017
whole organism dorsalized, abnormal heat shock Fig. 4 from Kumaradevan et al., 2018
Wnt signaling pathway increased process quality, abnormal heat shock Fig. 6 from Lee et al., 2014

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