Checkpoint-apoptosis uncoupling in human and mouse embryonic stem cells: a source of karyotpic instability.
about
Aneuploidy in pluripotent stem cells and implications for cancerous transformationThe architectural organization of human stem cell cycle regulatory machinerySelf-Renewal Signalling in Presenescent Tetraploid IMR90 Cells.Profiling TRA-1-81 antigen distribution on a human embryonic stem cellB-MYB is essential for normal cell cycle progression and chromosomal stability of embryonic stem cells.Somatic polyploidy is associated with the upregulation of c-MYC interacting genes and EMT-like signatureThree steps to the immortality of cancer cells: senescence, polyploidy and self-renewal.Mouse hematopoietic stem cells, unlike human and mouse embryonic stem cells, exhibit checkpoint-apoptosis coupling.Normal human pluripotent stem cell lines exhibit pervasive mosaic aneuploidyThe CENP-O complex requirement varies among different cell types.Hematopoietic stem/progenitor cells, generation of induced pluripotent stem cells, and isolation of endothelial progenitors from 21- to 23.5-year cryopreserved cord blood.Human cytomegalovirus infection interferes with the maintenance and differentiation of trophoblast progenitor cells of the human placentaEnhancing Hematopoietic Stem Cell Transplantation Efficacy by Mitigating Oxygen Shock.Comparison of American mink embryonic stem and induced pluripotent stem cell transcriptomes.Stem cell pluripotency: a cellular trait that depends on transcription factors, chromatin state and a checkpoint deficient cell cycle.Genomic Instability Associated with p53 Knockdown in the Generation of Huntington's Disease Human Induced Pluripotent Stem CellsHuman embryonic stem cell responses to ionizing radiation exposures: current state of knowledge and future challengesImplications of aneuploidy for stem cell biology and brain therapeuticsMouse hematopoietic cell-targeted STAT3 deletion: stem/progenitor cell defects, mitochondrial dysfunction, ROS overproduction, and a rapid aging-like phenotypeCytogenetic analysis and Dlk1-Dio3 locus epigenetic status of mouse embryonic stem cells during early passages.Evidence for cell fusion is absent in vascular lesions associated with pulmonary arterial hypertension.Lessons learned about human stem cell responses to ionizing radiation exposures: a long road still ahead of us.Spontaneously differentiated GATA6-positive human embryonic stem cells represent an important cellular step in human embryonic development; they are not just an artifact of in vitro culture.G1 to S phase cell cycle transition in somatic and embryonic stem cells.Development of insulin-producing cells from primitive biologic precursors.Mouse embryonic stem cells undergo charontosis, a novel programmed cell death pathway dependent upon cathepsins, p53, and EndoG, in response to etoposide treatment.Targeting DOT1L action and interactions in leukemia: the role of DOT1L in transformation and development.Tumorigenicity of pluripotent stem cells: biological insights from molecular imagingThe human cleavage stage embryo is a cradle of chromosomal rearrangements.Aneuploid human embryonic stem cells: origins and potential for modeling chromosomal disorders.Genetic and non-genetic instability in tumor progression: link between the fitness landscape and the epigenetic landscape of cancer cells.Chromosome instability in mouse embryonic stem cells.Mitotic spindle disruption in human preimplantation embryos activates the spindle assembly checkpoint but not apoptosis until Day 5 of development.Trace levels of mitomycin C disrupt genomic integrity and lead to DNA damage response defect in long-term-cultured human embryonic stem cells.Identification of proteins related to epigenetic regulation in the malignant transformation of aberrant karyotypic human embryonic stem cells by quantitative proteomics.Human embryonic stem cells fail to activate CHK1 and commit to apoptosis in response to DNA replication stress.Human embryonic stem cells suffer from centrosomal amplification.Oct-4 is critical for survival/antiapoptosis of murine embryonic stem cells subjected to stress: effects associated with Stat3/survivin.A RHO Small GTPase Regulator ABR Secures Mitotic Fidelity in Human Embryonic Stem CellsIs stem cell chromosomes stability affected by cryopreservation conditions?
P2860
Q27013982-30C81F0E-35CA-4534-AEFD-35AD42947139Q28609122-26338285-1F94-45B3-89C7-3185B04D850DQ30500386-5FFE7FCE-84F9-4D62-BAA2-520FE37853FBQ33322023-958D7109-51FE-4C81-A3EB-C07877609131Q33346222-CDFC7AE0-AC79-4D93-AA8D-3A6120327E97Q33363918-52EF5ED8-6AED-4565-AC53-7A4F26CF56A0Q33590178-FC3B16CC-4DA8-410E-8EB9-23E618DF5C1EQ33640520-24B0A41B-EAEF-4142-99A1-BDE9E16B2FF6Q33999117-A8A33D6C-7DED-4503-ACEF-02D22BF00425Q34030160-ABCABAEF-80DB-4E76-9705-97F5CE1ABE99Q35001593-F3421857-EA98-4C05-A1D6-FD17B737140CQ35488673-D725DDDC-C5BA-4CB5-9320-E52AFB7F723BQ35781096-455B516B-612D-48D3-A5F1-BC3F4A39C739Q35875436-6E333049-D6CC-40DF-9B6B-A3EFD4A992E7Q35889873-A37E6B86-1EEF-4588-BFA3-F565FFAA5FDEQ35959686-8540AE1F-6901-4A5F-AC89-A3B35AA2A72CQ36200201-6C3D3739-6C46-4C5C-B48A-AD0DC1006810Q36208256-2D43E90E-3A00-4BA5-A59B-37BEBEB4B01AQ36286847-1662CB8B-3840-4402-A568-D3923D8DEE1BQ36422051-BCC78D07-6C49-4A60-828D-F6BE5D0E93C1Q37018303-D7BC2671-6706-4272-9BDC-7A06DD0A35A3Q37139081-D36249A9-07A5-4164-BF4F-035A48DCF356Q37208249-009D90DE-A2B4-4409-975E-6D5C7FE6781FQ37220180-6537DB51-1E49-47B5-B457-BEE44AB8080BQ37428593-BA6D1D0A-39AB-44E4-A674-E07E2EB2127BQ37584840-937FED0E-F811-4200-BDC0-E613409B49DAQ37709373-6A3D168C-E735-45C8-B2A9-6618B74AC347Q37794511-F947364C-C8DA-4A69-8E3F-12DEE54188BAQ37839568-7D8C659A-2B5D-4ABF-A2B4-F77DF0637CE7Q37900302-FB05713A-1826-4C34-BA26-74992FEA7695Q38103747-8DAB77B1-8C4E-4EAB-8B20-4A2543300D90Q38420210-0DAFDA9D-BBE6-49CF-973B-FEC532F462A3Q38979868-F13BE7DC-1660-477E-AA3F-F7D96370D674Q38994070-8960E096-1773-4773-B63D-DF399749B9CAQ39030316-E6F3EA66-3619-45C2-B73A-8E53E1519877Q39354618-849EB101-0F7C-416D-8544-F7606480B381Q39641991-15B98BFA-20DC-4220-AF29-D178D8616B48Q40068733-DD9A08E1-DE49-4FCC-83D1-61AD6A5B03DCQ41018816-D5978253-DA62-4E43-8E46-4953F877D2D9Q41335402-D6598A43-F27E-4129-B198-E08BC7BE6C78
P2860
Checkpoint-apoptosis uncoupling in human and mouse embryonic stem cells: a source of karyotpic instability.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@ast
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@en
type
label
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@ast
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@en
prefLabel
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@ast
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@en
P2093
P2860
P1433
P1476
Checkpoint-apoptosis uncouplin ...... urce of karyotpic instability.
@en
P2093
Charlie Mantel
Hal E Broxmeyer
Hirohiko Shibayama
Kye-Seong Kim
Louis M Pelus
Man Ryul Lee
Mervin C Yoder
Min-Kyoung Kim
Myung-Kwan Han
Seiji Fukuda
P2860
P304
P356
10.1182/BLOOD-2006-10-054247
P407
P577
2007-02-08T00:00:00Z