Pluripotency in the embryo and in culture - Wikidata - wikimedia - TriplyDB

Pluripotency in the embryo and in culture

Pluripotency in the embryo and in culture

http://www.wikidata.org/entity/Q36119496

about

Intercellular interactions, position, and polarity in establishing blastocyst cell lineages and embryonic axes From pluripotency to forebrain patterning: an in vitro journey astride embryonic stem cells The ability of inner-cell-mass cells to self-renew as embryonic stem cells is acquired following epiblast specification A gonogenic stimulated transition of mouse embryonic stem cells with enhanced control of diverse differentiation pathways Heterogeneities in Nanog Expression Drive Stable Commitment to Pluripotency in the Mouse Blastocyst Evaluating Cell Processes, Quality, and Biomarkers in Pluripotent Stem Cells Using Video Bioinformatics Activation of Wnt/ß-catenin signaling in ESC promotes rostral forebrain differentiation in vitro.Describing the Stem Cell Potency: The Various Methods of Functional Assessment and In silico Diagnostics Molecular basis of embryonic stem cell self-renewal: from signaling pathways to pluripotency network Genetic exploration of the exit from self-renewal using haploid embryonic stem cells Exit from pluripotency is gated by intracellular redistribution of the bHLH transcription factor Tfe3 Characterization of the finch embryo supports evolutionary conservation of the naive stage of development in amniotes MEK inhibitor PD0325901 and vitamin C synergistically induce hypomethylation of mouse embryonic stem cells Esrrb is a pivotal target of the Gsk3/Tcf3 axis regulating embryonic stem cell self-renewal Forced expression of Nanog or Esrrb preserves the ESC status in the absence of nucleostemin expression Generation of organized germ layers from a single mouse embryonic stem cell.Tracking the embryonic stem cell transition from ground state pluripotency.The many faces of Pluripotency: in vitro adaptations of a continuum of in vivo states.Otx2 and Oct4 drive early enhancer activation during embryonic stem cell transition from naive pluripotency.Stable methylation at promoters distinguishes epiblast stem cells from embryonic stem cells and the in vivo epiblasts.INO80 facilitates pluripotency gene activation in embryonic stem cell self-renewal, reprogramming, and blastocyst development.Resetting transcription factor control circuitry toward ground-state pluripotency in human.Germ cell specification and pluripotency in mammals: a perspective from early embryogenesis.Dax1 and Nanog act in parallel to stabilize mouse embryonic stem cells and induced pluripotency Time to reconsider stem cell induction strategies Genome and transcriptome of the regeneration-competent flatworm, Macrostomum lignano.A model-based analysis of culture-dependent phenotypes of mESCs.Application Of Small Molecules Favoring Naïve Pluripotency during Human Embryonic Stem Cell Derivation.Expression of Oct3/4 and Nanog in the head and neck squamous carcinoma cells and its clinical implications for delayed neck metastasis in stage I/II oral tongue squamous cell carcinoma.Hmga2 is necessary for Otx2-dependent exit of embryonic stem cells from the pluripotent ground state The roles of ERAS during cell lineage specification of mouse early embryonic development.Lineage-Specific Profiling Delineates the Emergence and Progression of Naive Pluripotency in Mammalian Embryogenesis Elf5-centered transcription factor hub controls trophoblast stem cell self-renewal and differentiation through stoichiometry-sensitive shifts in target gene networks.Naive pluripotency is associated with global DNA hypomethylation.Nanog, Oct4 and Tet1 interplay in establishing pluripotency A genetic and developmental pathway from STAT3 to the OCT4-NANOG circuit is essential for maintenance of ICM lineages in vivo.Impairment of DNA Methylation Maintenance Is the Main Cause of Global Demethylation in Naive Embryonic Stem Cells.Rebuilding pluripotency from primordial germ cells.Identification of the missing pluripotency mediator downstream of leukaemia inhibitory factor.Comparative Principles of DNA Methylation Reprogramming during Human and Mouse In Vitro Primordial Germ Cell Specification.

P2860

Q27022008-CABFB661-796C-4DF0-82CC-E7C1F1D5547C Q27030826-F704424C-F7EF-4F5B-95FB-8896F1705E56 Q27313398-A3F1E835-855E-43DA-BCF5-B1E145697194 Q27318536-B187D5A2-0450-4013-A329-15267B073A65 Q27321176-5B20EC42-EE13-48EC-A812-BC1C7C82A26E Q27322932-0208C52D-872C-42BE-AB34-8ACA9BD2EAD9 Q27347251-2556B812-9FFE-44DA-A80A-F3FC3E63FC43 Q28080291-CAFB8E1D-E036-40F6-A482-A9714D0C5B7F Q28084007-FB95E5A5-CEAD-4276-BD9A-19B3A624C5CE Q28587174-8C5AF9C4-5A71-456A-B256-F8FCEE42C4AE Q28594750-D9F6EB68-02FA-48D8-A26F-B94374BA0BFF Q28611189-F13C64E1-1543-45BE-88DA-32EA2B4D4258 Q28818258-54E2224C-7036-41FB-8877-A5C1065D59BD Q28910178-51C6D3F8-9C93-4FB6-95B4-36AE2444CB40 Q29465793-D49CE6A8-CD8A-4EBE-AC08-7A82FBC4462D Q30580247-A80D0064-FB2D-4593-BC9E-57E6F6442FD9 Q33588332-90F4ADF8-F50C-4B93-931C-03DF747F503D Q33796203-30543342-B292-4F43-99F2-E392E5EC81BD Q33818368-5EE16F8F-C83F-428C-B954-858EF729F8B6 Q34081966-60A84A80-FE7E-4F77-9F0D-98350EF7B910 Q34131597-CECEF85B-7CB8-4D73-AAB7-2061E8AF6E6D Q34173263-C006CD68-76F8-4FD6-AFB2-DBE9F3376B1B Q34277888-69D2EB3A-485D-4025-B963-BE7818F7CD70 Q34385206-4EEFD040-DD5D-44DA-8C77-24A23E96B7B1 Q34414126-BB22D37D-7A23-45AC-90F3-179AB326D08D Q34495191-5AFCC9CE-9949-4917-B789-2A18ACE632EA Q35124239-4EFBF4B4-DDDE-4F54-8AEC-DA29BB93684C Q35804223-FEFCB588-C378-4F50-9A99-0405F1074E8F Q35813876-DF490310-42C7-422A-9759-153075A6BC50 Q35977066-0AEC67A1-E6AE-47FD-B47C-0CEB2F6C95FA Q36011778-DCDA6629-954B-4F58-AFCF-D5733ED6073E Q36275655-64FAA388-54CF-4271-80AC-A3B3F8479A0D Q36406398-6918BEA3-EB07-458E-8A70-8BF7C80299EF Q36665797-1E942DFF-DDDD-4A55-AA99-D2196DE439B1 Q36870715-6F690EF1-CD5F-490E-8DBD-D202409F0C14 Q36981774-6044C0B9-7F94-4980-8D5B-76E387CDC9D5 Q37023694-88940F24-91D0-4C0A-86E4-69EB6AEFA025 Q37133634-C30ACCF0-ADC1-458F-AE83-D406B65838DE Q37217381-FDA889FD-DEA5-44B2-A2D2-4500F21662FD Q37340541-6D98FB36-C47F-40A1-829B-D376EADC6645

P2860

Pluripotency in the embryo and in culture

http://www.wikidata.org/entity/Q36119496

description

2012 nî lūn-bûn

@nan

2012年の論文

@ja

2012年論文

@yue

2012年論文

@zh-hant

2012年論文

@zh-hk

2012年論文

@zh-mo

2012年論文

@zh-tw

2012年论文

@wuu

2012年论文

@zh

2012年论文

@zh-cn

name

Pluripotency in the embryo and in culture

@ast

Pluripotency in the embryo and in culture

@en

type

label

Pluripotency in the embryo and in culture

@ast

Pluripotency in the embryo and in culture

@en

prefLabel

Pluripotency in the embryo and in culture

@ast

Pluripotency in the embryo and in culture

@en

P1433

Q36119496-C5D04056-0B97-420F-A876-83E9E06CB93B

P1476

Q36119496-69F91211-B4C8-47A1-8D33-6612416905C1

P2093

Q36119496-5D79740B-654F-4C4A-8BF3-D6A011D7B176

Q36119496-C46DA064-0A9B-494D-AD7F-7079E5B08BDE

P2860

Q36119496-0021E306-DEC0-4494-8D72-19024D09B7B1

Q36119496-0427BAE2-8036-45BF-B494-EAC40E7501EE

Q36119496-0464A1C0-EB18-4BAE-8757-34042E885540

Q36119496-046B4074-AF85-4891-AE8C-B4F336970777

Q36119496-0556C7DC-E9D7-41F1-A181-A81B79B2C520

Q36119496-05A6C457-CCBA-43CD-88C2-D53E1967C715

Q36119496-0A4B54DB-B2C9-42B2-908E-5B2919E68904

Q36119496-0A563FCC-87C7-46A1-B113-86C6BE746873

Q36119496-0BB36BDB-0DD1-44A4-8921-A25904C714AF

Q36119496-0E3F5343-1FDF-4B4F-B995-E3CD9AB6E114

P304

Q36119496-CBC8EF11-490B-41D3-A28C-8866A55491D1

P31

Q36119496-BB97786C-DF51-4240-B3BE-8D9F75BB697F

P356

Q36119496-4D6AF6BA-C3F4-49E0-8E92-CBF324D562A6

P433

Q36119496-E7D7D99E-5FB7-4CED-AF05-3C39DAA1F644

P478

Q36119496-407C90F1-64C0-4B2B-9B9A-BF34573658FD

P50

Q36119496-4A330449-D5FF-4833-A64C-9A8C25B805FF

Q36119496-FCDE7C1A-00CC-4EAD-8CCC-26F672DB1184

P577

Q36119496-A8B2ADA6-2F36-4A5C-8BA7-EB3A93762415

P698

Q36119496-017FA748-2442-40B3-9947-01D91BA7F3ED

P932

Q36119496-D3A437D5-C30A-4522-8D1E-A6C809239742

P356

CSHPERSPECT.A008128

P1433

Cold Spring Harbor Perspectives in Biology

P1476

Pluripotency in the embryo and in culture

@en

P2093

Austin Smith

http://www.w3.org/2001/XMLSchema#string

Jennifer Nichols

http://www.w3.org/2001/XMLSchema#string

P2860

Formation of pluripotent stem cells in the mammalian embryo depends on the POU transcription factor Oct4

Core transcriptional regulatory circuitry in human embryonic stem cells

STAT3 activation is sufficient to maintain an undifferentiated state of mouse embryonic stem cells

Self-renewal of pluripotent embryonic stem cells is mediated via activation of STAT3

Isolation of a pluripotent cell line from early mouse embryos cultured in medium conditioned by teratocarcinoma stem cells

Maintaining embryonic stem cell pluripotency with Wnt signaling

The transcriptional foundation of pluripotency

Targeted disruption of the mouse Stat3 gene leads to early embryonic lethality

Establishment in culture of pluripotential cells from mouse embryos

Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors

P304

a008128

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1101/CSHPERSPECT.A008128

http://www.w3.org/2001/XMLSchema#string

P433

8

http://www.w3.org/2001/XMLSchema#string

P478

4

http://www.w3.org/2001/XMLSchema#string

P50

Jennifer Nichols

P577

2012-08-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

22855723

http://www.w3.org/2001/XMLSchema#string

P932

3405859

http://www.w3.org/2001/XMLSchema#string