Strain Information | |
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Image | |
BRC No. | RBRC02290 |
Type | Transgene |
Species | Mus musculus |
Strain name | STOCK Tg(Nanog-GFP,Puro)1Yam |
Former Common name | |
H-2 Haplotype | |
ES Cell line | RF8 [129S4/SvJae] |
Background strain | |
Appearance | |
Strain development | RF8(129S4/SvJae由来)ES細胞をC57BL/6JJclのblastocystにインジェクションして作製。C57BL/6Jに数回戻し交配をした後、DBA/2JJclと1回交配を行い、その後、兄妹交配にて維持。 |
Strain description | iPS細胞 (誘導性多能性幹細胞 induced pluripotent stem cell) 作製系統 (Nanog-GFPレポーター系統) 。Tgホモ/ヘミマウスともに生存性、繁殖性あり。性差の偏り (雄の偏り) あり (詳細不明) 。 |
Colony maintenance | Carrier x Carrier (Homozygote x Homozygote) |
References | Generation of germline-competent induced pluripotent stem cells. Okita K, Ichisaka T, Yamanaka S Nature, 448, 313-317 (2007) 17554338 |
Health Report | |
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Examination Date / Room / Rack |
Gene | |||||||
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Gene Symbol | Gene Name | Chr. | Allele Symbol | Allele Name | Common Names | Promoter | Diseases Related to This Gene |
Frt | yeast FRT (flippase recombination target) site | UN | Frt | ||||
GFP | Green Fluorescent Protein (Aequorea victoria) | UN | Nanog promoter | ||||
GH | Growth hormone polyA (Bovine) | UN | GH | ||||
IRES | internal ribosomal entry site (EMCV) | UN | |||||
puro | puromycin acyltransferase (Streptomyces alboniger) | UN | puro |
Phenotype | |
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Annotation by Mammalian phenotyhpe ontology | |
Detailed phenotype data |
Ordering Information | |
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供与核酸 | Jellyfish EGFP cDNA, Encephalomyocarditis virus (EMCV) internal ribosomal entry site (IRES), S. alboniger puromycin resistance gene, bovine growth hormone polyadenylation signal, yeast FRT (flipase recombination target) site, mouse genomic DNA from RP23-117GFPNF |
Research application | Cell Biology Research Developmental Biology Research FLP/frt system Fluorescent Proteins/lacZ System |
提供条件 | |
Depositor | 山中 伸弥(国立大学法人京都大学) |
Strain Status | 凍結胚 凍結精子 |
Strain Availability | 凍結胚より作出したマウスを2~4ヶ月以内に提供可能 凍結精子を1ヶ月以内に提供可能 凍結胚を1ヶ月以内に提供可能 |
Additional Info. | Necessary documents for ordering:
Genotyping protocol -PCR- Mouse of the Month Dec 2007 Mouse of the Month Oct 2012 |
BRC mice in Publications |
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Nagamatsu G, Kosaka T, Saito S, Takubo K, Akiyama H, Sudo T, Horimoto K, Oya M, Suda T. Tracing the conversion process from primordial germ cells to pluripotent stem cells in mice. Biol Reprod 86(6) 182(2012) 22423052 |
Shinagawa T, Takagi T, Tsukamoto D, Tomaru C, Huynh LM, Sivaraman P, Kumarevel T, Inoue K, Nakato R, Katou Y, Sado T, Takahashi S, Ogura A, Shirahige K, Ishii S. Histone variants enriched in oocytes enhance reprogramming to induced pluripotent stem cells. Cell Stem Cell 14(2) 217-27(2014) 24506885 |
Nukaya D, Minami K, Hoshikawa R, Yokoi N, Seino S. Preferential gene expression and epigenetic memory of induced pluripotent stem cells derived from mouse pancreas. Genes Cells 20(5) 367-81(2015) 25727848 |
Nagamatsu G, Kosaka T, Kawasumi M, Kinoshita T, Takubo K, Akiyama H, Sudo T, Kobayashi T, Oya M, Suda T. A germ cell-specific gene, Prmt5, works in somatic cell reprogramming. J Biol Chem 286(12) 10641-8(2011) 21270127 |
Jincho Y, Araki R, Hoki Y, Tamura C, Nakamura M, Ando S, Kasama Y, Abe M. Generation of genome integration-free induced pluripotent stem cells from fibroblasts of C57BL/6 mice without c-Myc transduction. J Biol Chem 285(34) 26384-9(2010) 20554535 |
Araki R, Suga T, Hoki Y, Imadome K, Sunayama M, Kamimura S, Fujita M, Abe M. iPS cell generation-associated point mutations include many C > T substitutions via different cytosine modification mechanisms. Nat Commun 15(1) 4946(2024) 38862540 |
Araki R, Hoki Y, Suga T, Obara C, Sunayama M, Imadome K, Fujita M, Kamimura S, Nakamura M, Wakayama S, Nagy A, Wakayama T, Abe M. Genetic aberrations in iPSCs are introduced by a transient G1/S cell cycle checkpoint deficiency. Nat Commun 11(1) 197(2020) 31924765 |
Koga M, Matsuda M, Kawamura T, Sogo T, Shigeno A, Nishida E, Ebisuya M. Foxd1 is a mediator and indicator of the cell reprogramming process. Nat Commun 5 3197(2014) 24496101 |
Okita K, Hong H, Takahashi K, Yamanaka S. Generation of mouse-induced pluripotent stem cells with plasmid vectors. Nat Protoc 5(3) 418-28(2010) 20203661 |
Cavallari C, Fonsato V, Herrera MB, Bruno S, Tetta C, Camussi G. Role of Lefty in the anti tumor activity of human adult liver stem cells. Oncogene 32(7) 819-26(2013) 22469982 |
Iseki H, Nakachi Y, Hishida T, Yamashita-Sugahara Y, Hirasaki M, Ueda A, Tanimoto Y, Iijima S, Sugiyama F, Yagami K, Takahashi S, Okuda A, Okazaki Y. Combined Overexpression of JARID2, PRDM14, ESRRB, and SALL4A Dramatically Improves Efficiency and Kinetics of Reprogramming to Induced Pluripotent Stem Cells. Stem Cells 34(2) 322-33(2016) 26523946 |
Araki R, Hoki Y, Uda M, Nakamura M, Jincho Y, Tamura C, Sunayama M, Ando S, Sugiura M, Yoshida MA, Kasama Y, Abe M. Crucial role of c-Myc in the generation of induced pluripotent stem cells. Stem Cells 29(9) 1362-70(2011) 21732496 |
Araki R, Jincho Y, Hoki Y, Nakamura M, Tamura C, Ando S, Kasama Y, Abe M. Conversion of ancestral fibroblasts to induced pluripotent stem cells. Stem Cells 28(2) 213-20(2010) 20020427 |
Swistowski A, Peng J, Liu Q, Mali P, Rao MS, Cheng L, Zeng X. Efficient generation of functional dopaminergic neurons from human induced pluripotent stem cells under defined conditions. Stem Cells 28(10) 1893-904(2010) 20715183 |
Borisova E, Nishimura K, An Y, Takami M, Li J, Song D, Matsuo-Takasaki M, Luijkx D, Aizawa S, Kuno A, Sugihara E, Sato TA, Yumoto F, Terada T, Hisatake K, Hayashi Y. Structurally-discovered KLF4 variants accelerate and stabilize reprogramming to pluripotency. iScience 25(1) 103525(2022) 35106457 |