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Search results 6501 to 6600 out of 6883 for Pax6

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Type Details Score
Genotype
Genotype
Symbol: Foxp1/Foxp1 Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: C57BL/6 * FVB
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Celf1/Celf1 Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S2/SvPas * FVB
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Tg(Pax6-cre,GFP)2Pgr/? Zeb2/Zeb2
Background: involves: 129S1/Sv * 129X1/SvJ * C57BL/6J
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Rint1/Rint1 Tg(Pax6-cre,GFP)2Pgr/? Trp53/Trp53
Background: involves: 129P2/OlaHsd
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Bmpr1a/Bmpr1a Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S7/SvEvBrd * C57BL/6 * FVB
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Six3/Six3 Six6/Six6 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Six3/Six3<+> Six6/Six6<+> Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Protein Coding Gene
MGI:1913993 | Rnf220
Type: protein_coding_gene
Organism: mouse, laboratory
Publication
12213201 | J:78916
First Author: Xu ZP
Year: 2002
Journal: Genomics
Title: Functional and structural characterization of the human gene BHLHB5, encoding a basic helix-loop-helix transcription factor.
Volume: 80
Issue: 3
Pages: 311-8
Publication
16443760 | J:106430
First Author: Artner I
Year: 2006
Journal: Diabetes
Title: MafB: an activator of the glucagon gene expressed in developing islet alpha- and beta-cells.
Volume: 55
Issue: 2
Pages: 297-304
Publication
11287190 | J:69276
First Author: Davis RJ
Year: 2001
Journal: Mech Dev
Title: Characterization of mouse Dach2, a homologue of Drosophila dachshund.
Volume: 102
Issue: 1-2
Pages: 169-79
Publication
11861467 | J:74573
First Author: Inoue T
Year: 2002
Journal: Development
Title: Math3 and NeuroD regulate amacrine cell fate specification in the retina.
Volume: 129
Issue: 4
Pages: 831-42
Publication
27436347 | J:249003
 
First Author: Li F
Year: 2016
Journal: Mol Cell Endocrinol
Title: Sleeve gastrectomy activates the GLP-1 pathway in pancreatic β cells and promotes GLP-1-expressing cells differentiation in the intestinal tract.
Volume: 436
Pages: 33-40
Publication
10704382 | J:60832
First Author: Pattyn A
Year: 2000
Journal: Development
Title: Control of hindbrain motor neuron differentiation by the homeobox gene Phox2b.
Volume: 127
Issue: 7
Pages: 1349-58
Publication
37275527 | J:358354
First Author: Ding L
Year: 2023
Journal: iScience
Title: Zhx2 maintains islet β-cell mass and function by transcriptionally regulating Pax6.
Volume: 26
Issue: 6
Pages: 106871
Publication
25471260 | J:218750
First Author: Su LD
Year: 2015
Journal: Cerebellum
Title: LGI1 is involved in the development of mouse brain.
Volume: 14
Issue: 1
Pages: 12-4
Publication
24449271 | J:207488
First Author: Aloia L
Year: 2014
Journal: Genes Dev
Title: Zrf1 is required to establish and maintain neural progenitor identity.
Volume: 28
Issue: 2
Pages: 182-97
Publication
15057935 | J:91189
First Author: Cvekl A
Year: 2004
Journal: Bioessays
Title: Anterior eye development and ocular mesenchyme: new insights from mouse models and human diseases.
Volume: 26
Issue: 4
Pages: 374-86
Protein Domain
IPR001523 | Paired_dom
Type: Domain
Description: The paired domain is an approximately 126 amino acid DNA-binding domain, which is found in eukaryotic transcription regulatory proteins involved in embryogenesis. The domain was originally described as the 'paired box' in the Drosophila protein paired (prd) [, ]. The paired domain is generally located in the N-terminal part. An octapeptide []and/or a homeodomain can occur C-terminal to the paired domain, as well as a Pro-Ser-Thr-rich C terminus.Paired domain proteins can function as transcription repressors or activators. The paired domain contains three subdomains, which show functional differences in DNA-binding. The crystal structures of prd and Pax proteins show that the DNA-bound paired domain is bipartite, consisting of an N-terminal subdomain (PAI or NTD) and a C-terminal subdomain (RED or CTD), connected by a linker. PAI and RED each form a three-helical fold, with the most C-terminal helices comprising a helix-turn-helix (HTH) motif that binds the DNA major groove. In addition, the PAI subdomain encompasses an N-terminal β-turn andβ-hairpin, also named 'wing', participating in DNA-binding. The linker canbind into the DNA minor groove. Different Pax proteins and their alternativelyspliced isoforms use different (sub)domains for DNA-binding to mediate thespecificity of sequence recognition [, ].Some proteins known to contain a paired domain:Drosophila paired (prd), a segmentation pair-rule class protein.Drosophila gooseberry proximal (gsb-p) and gooseberry distal (gsb-d),segmentation polarity class proteins.Drosophila Pox-meso and Pox-neuro proteins.The Pax proteins:Mammalian protein Pax1, which may play a role in the formation of segmented structures in the embryo. In mouse, mutations in Pax1 produce the undulated phenotype, characterised by vertebral malformations along the entire rostro-caudal axis.Mammalian protein Pax2, a probable transcription factor that may have arole in kidney cell differentiation.Mammalian protein Pax3. Pax3 is expressed during early neurogenesis. In humans, defects in Pax3 are the cause of Waardenburg's syndrome (WS), anautosomal dominant combination of deafness and pigmentary disturbance.Mammalian protein Pax4 pays an important role in the differentiation and development of pancreatic islet beta cells. It binds to a common element in the glucagon, insulin and somatostatin promoters. In humans, it has been related to the rare, familial, clinically and genetically heterogeneous form of diabetes MODY (maturity-onset diabetes of the young).Mammalian protein Pax5, also known as B-cell specific transcription factor(BSAP). Pax5 is involved in the regulation of the CD19 gene. It plays animportant role in B-cell differentiation as well as neural development andspermatogenesis.Mammalian protein Pax6 (oculorhombin). Pax6 is a transcription factor withimportant functions in eye and nasal development. In Man, defects in Pax6are the cause of aniridia type II (AN2), an autosomal dominant disordercharacterised by complete or partial absence of the iris.Mammalian protein Pax7 is involved in the regulation of muscle stem cells proliferation, playing a role in myogenesis and muscle regeneration.Mammalian protein Pax8, required in thyroid development.Mammalian protein Pax9, required for normal development of thymus, parathyroid glands, ultimobranchial bodies, teeth, skeletal elements of skull and larynx as well as distal limbs. In man, defects in Pax9 cause oligodontia.Zebrafish protein Paired box protein Pax-2a, involved in the development of the midbrain/hindbrain boundary organizer and specification of neuronal cell fates.Xenopus laevis protein Paired box protein Pax-3-A, which promotes both hatching gland and neural crest cell fates, two of the cell populations that arise from the neural plate border.
Publication
19668192 | J:154336
First Author: Albuquerque RJ
Year: 2009
Journal: Nat Med
Title: Alternatively spliced vascular endothelial growth factor receptor-2 is an essential endogenous inhibitor of lymphatic vessel growth.
Volume: 15
Issue: 9
Pages: 1023-30
Publication
22031541 | J:178697
First Author: Plageman TF Jr
Year: 2011
Journal: Development
Title: A Trio-RhoA-Shroom3 pathway is required for apical constriction and epithelial invagination.
Volume: 138
Issue: 23
Pages: 5177-88
Publication
16126193 | J:103528
First Author: Dean CH
Year: 2005
Journal: Dev Biol
Title: Canonical Wnt signaling negatively regulates branching morphogenesis of the lung and lacrimal gland.
Volume: 286
Issue: 1
Pages: 270-86
Publication
22509096 | J:191619
 
First Author: Ha A
Year: 2012
Journal: Mol Vis
Title: Identification of Wnt/β-catenin modulated genes in the developing retina.
Volume: 18
Pages: 645-56
Publication
34518365 | J:312458
 
First Author: Kisseleff E
Year: 2021
Journal: eNeuro
Title: Glycogen Synthase Kinase 3 Regulates the Genesis of Displaced Retinal Ganglion Cells3.
Volume: 8
Issue: 5
Publication
15207851 | J:90895
First Author: Ozawa Y
Year: 2004
Journal: Mol Cell Neurosci
Title: Downregulation of STAT3 activation is required for presumptive rod photoreceptor cells to differentiate in the postnatal retina.
Volume: 26
Issue: 2
Pages: 258-70
Publication
21357686 | J:185788
First Author: Qu X
Year: 2011
Journal: J Biol Chem
Title: Lacrimal gland development and Fgf10-Fgfr2b signaling are controlled by 2-O- and 6-O-sulfated heparan sulfate.
Volume: 286
Issue: 16
Pages: 14435-44
Publication
28763805 | J:258463
First Author: Wang Y
Year: 2017
Journal: Invest Ophthalmol Vis Sci
Title: β1-Integrin Deletion From the Lens Activates Cellular Stress Responses Leading to Apoptosis and Fibrosis.
Volume: 58
Issue: 10
Pages: 3896-3922
Publication
28118981 | J:240406
First Author: Zhang Y
Year: 2017
Journal: Dev Biol
Title: Monitoring p53 by MDM2 and MDMX is required for endocrine pancreas development and function in a spatio-temporal manner.
Volume: 423
Issue: 1
Pages: 34-45
Publication
16510501 | J:144139
First Author: Yaron O
Year: 2006
Journal: Development
Title: Notch1 functions to suppress cone-photoreceptor fate specification in the developing mouse retina.
Volume: 133
Issue: 7
Pages: 1367-78
Publication
14978477 | J:88422
 
First Author: Ebong S
Year: 2004
Journal: Mol Vis
Title: Characterization of the roles of STAT1 and STAT3 signal transduction pathways in mammalian lens development.
Volume: 10
Pages: 122-31
Publication
20817091 | J:280184
First Author: Lange C
Year: 2011
Journal: Neurobiol Dis
Title: Retina-specific activation of a sustained hypoxia-like response leads to severe retinal degeneration and loss of vision.
Volume: 41
Issue: 1
Pages: 119-30
Publication
19838301 | J:154049
First Author: Fischer MD
Year: 2009
Journal: PLoS One
Title: Noninvasive, in vivo assessment of mouse retinal structure using optical coherence tomography.
Volume: 4
Issue: 10
Pages: e7507
Publication
15558476 | J:134146
First Author: Beebe D
Year: 2004
Journal: Int J Dev Biol
Title: Contributions by members of the TGFbeta superfamily to lens development.
Volume: 48
Issue: 8-9
Pages: 845-56
Publication
26407529 | J:227069
First Author: Huang J
Year: 2015
Journal: Dev Biol
Title: Negative and positive auto-regulation of BMP expression in early eye development.
Volume: 407
Issue: 2
Pages: 256-64
Publication
19168903 | J:151035
First Author: Calera MR
Year: 2009
Journal: Invest Ophthalmol Vis Sci
Title: Depression of intraocular pressure following inactivation of connexin43 in the nonpigmented epithelium of the ciliary body.
Volume: 50
Issue: 5
Pages: 2185-93
Publication
36078116 | J:329001
 
First Author: Sellitto C
Year: 2022
Journal: Cells
Title: Double Deletion of PI3K and PTEN Modifies Lens Postnatal Growth and Homeostasis.
Volume: 11
Issue: 17
Publication
24270425 | J:207830
First Author: Sellitto C
Year: 2013
Journal: J Clin Invest
Title: AKT activation promotes PTEN hamartoma tumor syndrome-associated cataract development.
Volume: 123
Issue: 12
Pages: 5401-9
Publication
23986258 | J:201574
First Author: Braunger BM
Year: 2013
Journal: J Neurosci
Title: TGF-β signaling protects retinal neurons from programmed cell death during the development of the mammalian eye.
Volume: 33
Issue: 35
Pages: 14246-58
Publication
33389129 | J:319410
First Author: Ali M
Year: 2021
Journal: Hum Genet
Title: A missense allele of PEX5 is responsible for the defective import of PTS2 cargo proteins into peroxisomes.
Volume: 140
Issue: 4
Pages: 649-666
Publication
18566469 | J:141762
First Author: Rajagopal R
Year: 2008
Journal: Invest Ophthalmol Vis Sci
Title: Functions of the type 1 BMP receptor Acvr1 (Alk2) in lens development: cell proliferation, terminal differentiation, and survival.
Volume: 49
Issue: 11
Pages: 4953-60
Publication
18586877 | J:141905
First Author: Shui YB
Year: 2008
Journal: Invest Ophthalmol Vis Sci
Title: HIF-1: an age-dependent regulator of lens cell proliferation.
Volume: 49
Issue: 11
Pages: 4961-70
Publication
17404619 | J:121231
First Author: Collombat P
Year: 2007
Journal: J Clin Invest
Title: Embryonic endocrine pancreas and mature beta cells acquire alpha and PP cell phenotypes upon Arx misexpression.
Volume: 117
Issue: 4
Pages: 961-70
Publication
32173580 | J:298034
 
First Author: Shihan MH
Year: 2020
Journal: Matrix Biol
Title: Fibronectin has multifunctional roles in posterior capsular opacification (PCO).
Volume: 90
Pages: 79-108
Publication
22021442 | J:180120
First Author: Chauhan BK
Year: 2011
Journal: Proc Natl Acad Sci U S A
Title: Balanced Rac1 and RhoA activities regulate cell shape and drive invagination morphogenesis in epithelia.
Volume: 108
Issue: 45
Pages: 18289-94
Publication
27304846 | J:257615
First Author: Sellitto C
Year: 2016
Journal: Invest Ophthalmol Vis Sci
Title: The Phosphoinosotide 3-Kinase Catalytic Subunit p110α is Required for Normal Lens Growth.
Volume: 57
Issue: 7
Pages: 3145-51
Publication
28951044 | J:287904
 
First Author: Whitson JA
Year: 2017
Journal: Free Radic Biol Med
Title: Proteomic analysis of the glutathione-deficient LEGSKO mouse lens reveals activation of EMT signaling, loss of lens specific markers, and changes in stress response proteins.
Volume: 113
Pages: 84-96
Publication
28525556 | J:242122
First Author: Whitson JA
Year: 2017
Journal: Invest Ophthalmol Vis Sci
Title: Transcriptome of the GSH-Depleted Lens Reveals Changes in Detoxification and EMT Signaling Genes, Transport Systems, and Lipid Homeostasis.
Volume: 58
Issue: 5
Pages: 2666-2684
Publication
28827139 | J:250101
First Author: Wei Z
Year: 2017
Journal: Am J Pathol
Title: Reduced Glutathione Level Promotes Epithelial-Mesenchymal Transition in Lens Epithelial Cells via a Wnt/β-Catenin-Mediated Pathway: Relevance for Cataract Therapy.
Volume: 187
Issue: 11
Pages: 2399-2412
Publication
24142921 | J:218363
First Author: Wolf L
Year: 2013
Journal: G3 (Bethesda)
Title: Identification and characterization of FGF2-dependent mRNA: microRNA networks during lens fiber cell differentiation.
Volume: 3
Issue: 12
Pages: 2239-55
Publication
27472077 | J:286662
First Author: Whitson JA
Year: 2016
Journal: Invest Ophthalmol Vis Sci
Title: Evidence of Dual Mechanisms of Glutathione Uptake in the Rodent Lens: A Novel Role for Vitreous Humor in Lens Glutathione Homeostasis.
Volume: 57
Issue: 8
Pages: 3914-25
Publication
38391903 | J:345586
 
First Author: Wazin F
Year: 2024
Journal: Cells
Title: Conditional Ablation of Spred1 and Spred2 in the Eye Lens Negatively Impacts Its Development and Growth.
Volume: 13
Issue: 4
Publication
26021489 | J:225920
First Author: Spaeth JM
Year: 2015
Journal: Diabetologia
Title: The FOXP1, FOXP2 and FOXP4 transcription factors are required for islet alpha cell proliferation and function in mice.
Volume: 58
Issue: 8
Pages: 1836-44
Publication
28384713 | J:254701
First Author: Suzuki-Kerr H
Year: 2017
Journal: Invest Ophthalmol Vis Sci
Title: Forkhead Box Protein P1 Is Dispensable for Retina but Essential for Lens Development.
Volume: 58
Issue: 4
Pages: 1916-1929
Publication
31177529 | J:289294
First Author: Muhammad F
Year: 2019
Journal: Eur J Immunol
Title: Tissue-specific production of MicroRNA-155 inhibits melanocortin 5 receptor-dependent suppressor macrophages to promote experimental autoimmune uveitis.
Volume: 49
Issue: 11
Pages: 2074-2082
Publication
33896079 | J:312372
First Author: Karnam S
Year: 2021
Journal: Dev Dyn
Title: Drebrin, an actin-binding protein, is required for lens morphogenesis and growth.
Volume: 250
Issue: 11
Pages: 1600-1617
Publication
31847788 | J:331971
First Author: Martynova E
Year: 2019
Journal: Open Biol
Title: Transcriptomic analysis and novel insights into lens fibre cell differentiation regulated by Gata3.
Volume: 9
Issue: 12
Pages: 190220
Publication
19389370 | J:149462
First Author: Le TT
Year: 2009
Journal: Dev Biol
Title: Jagged 1 is necessary for normal mouse lens formation.
Volume: 328
Issue: 1
Pages: 118-26
Publication
23733098 | J:226225
 
First Author: Maiorano NA
Year: 2013
Journal: Nat Commun
Title: Restricted perinatal retinal degeneration induces retina reshaping and correlated structural rearrangement of the retinotopic map.
Volume: 4
Pages: 1938
Publication
26674965 | J:309577
First Author: Noh H
Year: 2016
Journal: Mol Cells
Title: Over-Expression of Ephrin-A5 in Mice Results in Decreasing the Size of Progenitor Pool through Inducing Apoptosis.
Volume: 39
Issue: 2
Pages: 136-40
Genotype
Genotype
Symbol: Pax6/Pax6 Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ * FVB * NMRI
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Rb1/Rb1 Rbl1/Rbl1 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S2/SvPas * 129S4/SvJae * 129X1/SvJ * C57BL/6 * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: E2f2/E2f2 Rbl1/Rbl1 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129 * C57BL/6 * FVB/N * NMRI
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: E2f1/E2f1<+> Rbl1/Rbl1 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129 * C57BL/6 * FVB/N * NMRI
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: E2f1/E2f1 Rbl1/Rbl1 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129 * C57BL/6 * FVB/N * NMRI
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: E2f3/E2f3 Rbl1/Rbl1 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129 * C57BL/6 * FVB/N * NMRI
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gt(ROSA)26Sor/Gt(ROSA)26Sor<+> Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ctnnb1/Ctnnb1 Tg(Cryaa-cre)10Mlr/?
Background: involves: 129P2/OlaHsd * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Pax6/Pax6<+> Tg(CAG-EGFP,-Pax6,-lacZ)1Stoy/? Tg(Dct-cre)1Apdn/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ctnnb1/Ctnnb1 Tg(Cryaa-cre)10Mlr/?
Background: involves: 129X1/SvJ * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Sox2/Sox2 Tg(Cryaa-cre)10Mlr/?
Background: involves: C57BL/6 * FVB/N * SJL
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Pax6/Pax6 Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S1/Sv * 129X1/SvJ * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ahi1/Ahi1 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129 * C57BL/6 * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ahi1/Ahi1 Nphp1/Nphp1<+> Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129 * C57BL/6 * FVB/N * NMRI
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Pax6/Pax6<+> Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ncoa6/Ncoa6 Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S6/SvEvTac * C57BL/6 * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ugdh/Ugdh H2az2/H2az2<+> Tg(Pax6-HRAS*G12V)2044Ove/?
Background: involves: 129S4/SvJaeSor * 129S6/SvEvTac * C57BL/6 * CBA/J * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gclc/Gclc<+> Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S4/SvJaeSor * C57BL/6N * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gclc/Gclc Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S4/SvJaeSor * C57BL/6N * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Igs1/Igs1<+> Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ * C57BL/6
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Pax6/Pax6 Tg(Rax-cre)1Zkoz/?
Background: involves: 102/El * C3H/Rl
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Kdr/Kdr Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Kdr/Kdr Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Dnm1/Dnm1 Dnm2/Dnm2 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/SvImJ * C57BL/6
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Kdr/Kdr Vegfa/Vegfa Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Vhl/Vhl Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S4/SvJae
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Pcdhg/Pcdhg Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S7/SvEvBrd * C57BL/6J
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Atrip/Atrip Tg(Pax6-cre,GFP)2Pgr/? Trp53/Trp53
Background: involves: 129P2/OlaHsd * 129S2/SvPas * C57BL/6
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Rap1a/Rap1a Rap1b/Rap1b Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S/SvEv * C57BL/6 * FVB
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Apc/Apc Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S4/SvJae * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Pax6/Pax6 Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Rac1/Rac1 Rhoa/Rhoa Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S4/SvJae * FVB
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Ctnnb1/Ctnnb1 Rax/Rax Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129P2/OlaHsd * 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Fgfr2/Fgfr2 Fgfr3/Fgfr3 Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S6/SvEvTac * 129X1/SvJ * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Fgfr1/Fgfr1 Fgfr2/Fgfr2 Tg(Cryaa-cre)10Mlr/?
Background: involves: 129S1/Sv * 129X1/SvJ * FVB/N
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gt(ROSA)26Sor/Gt(ROSA)26Sor<+> Rax/Rax<+> Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129S4/SvJaeSor
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Tg(CAG-Bgeo/ALPP)1Lbe/? Tg(Pax6-cre,GFP)2Pgr/?
Background: involves: 129S1/Sv * 129X1/SvJ
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gt(ROSA)26Sor/Gt(ROSA)26Sor<+> Tg(Pax6-cre,GFP)1Pgr/?
Background: involves: 129S4/SvJaeSor * FVB
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gt(ROSA)26Sor/Gt(ROSA)26Sor<+> Tg(Pax6-cre)1Rilm/?
Background: involves: 129S4/SvJaeSor * C57BL/6
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gt(ROSA)26Sor/Gt(ROSA)26Sor<+> Tg(Pax6-cre)1Knd/?
Background: involves: 129S4/SvJaeSor * C3H * C57BL/6
Zygosity: cn
Has Mutant Allele: true
Genotype
Genotype
Symbol: Gt(ROSA)26Sor/Gt(ROSA)26Sor<+> Tg(Pax6-cre)1Zkoz/?
Background: involves: 129S4/SvJaeSor * FVB/N
Zygosity: cn
Has Mutant Allele: true




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