about
Mitochondrial variability as a source of extrinsic cellular noiseAnatomy of a blastocyst: cell behaviors driving cell fate choice and morphogenesis in the early mouse embryoRegulatory gene network circuits underlying T cell development from multipotent progenitorsTranscriptional network control of normal and leukaemic haematopoiesisConcise review: bone marrow autotransplants for liver disease?Intercellular interactions, position, and polarity in establishing blastocyst cell lineages and embryonic axesDynamic heterogeneity of DNA methylation and hydroxymethylation in embryonic stem cell populations captured by single-cell 3D high-content analysisContribution of stochastic partitioning at human embryonic stem cell division to NANOG heterogeneityThe hematopoietic stem cell niche in homeostasis and diseaseModeling the epigenetic attractors landscape: toward a post-genomic mechanistic understanding of developmentA general model for binary cell fate decision gene circuits with degeneracy: indeterminacy and switch behavior in the absence of cooperativityIntrinsic Noise Profoundly Alters the Dynamics and Steady State of Morphogen-Controlled Bistable Genetic SwitchesMicroRNA profiling during cardiomyocyte-specific differentiation of murine embryonic stem cells based on two different miRNA array platformsProteomic indicators of oxidation and hydration state in colorectal cancerFunctional significance of mononuclear phagocyte populations generated through adult hematopoiesisGenetic networks governing heart development.Single cell transcriptional profiling reveals heterogeneity of human induced pluripotent stem cells.M-CSF instructs myeloid lineage fate in single haematopoietic stem cellsTransdifferentiation of pancreatic cells by loss of contact-mediated signalingClassification of transient behaviours in a time-dependent toggle switch modelBifurcation analysis of single-cell gene expression data reveals epigenetic landscapeStochastic variation of transcript abundance in C57BL/6J mice.Systematic search for recipes to generate induced pluripotent stem cellsReshaping the epigenetic landscape during early flower development: induction of attractor transitions by relative differences in gene decay rates.A continuum of cell states spans pluripotency and lineage commitment in human embryonic stem cells.Decomposition of gene expression state space trajectoriesFunctional heterogeneity of embryonic stem cells revealed through translational amplification of an early endodermal transcript.Prepatterning in the stem cell compartment.Analysis of human and mouse reprogramming of somatic cells to induced pluripotent stem cells. What is in the plate?Dynamic equilibrium of heterogeneous and interconvertible multipotent hematopoietic cell subsets.Transcriptional corepressor TLE1 functions with Runx2 in epigenetic repression of ribosomal RNA genes.Chemical composition and the potential for proteomic transformation in cancer, hypoxia, and hyperosmotic stressDeciphering the mesodermal potency of porcine skin-derived progenitors (SKP) by microarray analysis.Predicting pancreas cell fate decisions and reprogramming with a hierarchical multi-attractor model.A deterministic map of Waddington's epigenetic landscape for cell fate specification.Early in vitro differentiation of mouse definitive endoderm is not correlated with progressive maturation of nuclear DNA methylation patterns.Stem cell and tissue engineering in breast reconstructionDiscovering small molecules to control stem cell fate.Inactivation of a single copy of Crebbp selectively alters pre-mRNA processing in mouse hematopoietic stem cells.Spatiotemporal network motif reveals the biological traits of developmental gene regulatory networks in Drosophila melanogaster
P2860
Q21563492-B169444C-5D0B-426B-894D-B867291A778AQ24631741-F188C0F8-C109-45EB-A63A-EB0FB8D3CF31Q26995184-65C27E98-68B2-48D2-A4BE-496380C90903Q27005940-44F22224-F646-4030-94E2-8658AC77229CQ27010009-A31ECBC1-6BFE-414D-BDC5-6F74DF81D89BQ27022008-AE603034-C700-4BF7-834E-6690E37439D3Q27302797-34D7B053-EB76-4DC7-81B6-F37ECC98150CQ27333498-EED3BFD4-0009-46DD-972E-DC999F96D9AEQ28082775-CA426D0D-BB26-4501-B79D-874D710CED5FQ28083970-8E7E1240-216C-4C5A-A796-7D22F5417BBEQ28478193-9A0C432E-18F0-4981-94C6-315FE8BB3BA9Q28552898-34CE2027-BF5C-4C1F-AE6C-CDE13B6C2CF4Q28744335-0660E131-C6C0-4948-8A97-BCFDDC087491Q28829212-6E74213B-8F12-4DC2-BF93-38260844316DQ30366001-ABBA963C-48EB-42F0-9899-2C4D6DF9464EQ30367427-293083B4-D84F-4ABF-8835-746AA12FA1B8Q30498340-DBBEF7D1-7B20-4609-A59D-FB705A0BCE4EQ30540578-D50CC0AD-86D3-4B0F-B73F-8EAF603DDC87Q30543433-63E00513-7D49-4FD5-8361-1D0A4CC7680CQ30584893-98D95D0B-6F27-4F6B-9A23-2827EC8E1E85Q30878726-42E7882A-5013-4400-973B-6C88E459BAC2Q31004622-01446811-5DD3-46DA-983F-720864AD8D7EQ31044390-ACDFAC26-E75A-47F4-9BC7-7FBAB3C79827Q33360682-8F586DB9-D19B-4AA0-B53A-5044AC383092Q33515036-5575AFDF-0B01-4816-94A4-7C3C3821B76DQ33521305-90A6084D-A4E7-460D-9525-E5258CD3410EQ33592981-19C9688E-5770-4C4B-AE5E-D5D9504F3326Q33598286-3486E1AA-74C8-461F-9417-6085FBE125FDQ33700366-7E515577-4011-45CE-BCC5-5FCA762DAACBQ33718926-135BEDEA-B455-4049-992A-1954FB6596A9Q33732988-8B7F4325-0B9E-490B-9451-8EE9D655F29BQ33777591-A4C44D47-D86F-42E7-ACF0-7251035BF8A0Q33813533-A9B41FAB-6B49-4074-A1EA-C2B5186A5BD6Q33851580-FA4D554A-DE7A-4568-AFDD-7141AA1D81EFQ33914359-5F1482F5-759E-4985-8E66-5F10E68B80D0Q33968112-D68FC8AA-5A04-4572-A7A1-E6709386F4E6Q33973210-7F49A97E-5B85-456D-9410-55CFB9D422DBQ34007289-1F5D5C44-277A-4BF0-B415-5E6B27690C21Q34013832-D3BA7B5C-BAEF-42A2-B265-6AF7BF4B18EAQ34252823-DAEF64B8-7937-419E-AC3B-D20B69122E90
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on May 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Stem cell states, fates, and the rules of attraction.
@en
Stem cell states, fates, and the rules of attraction.
@nl
type
label
Stem cell states, fates, and the rules of attraction.
@en
Stem cell states, fates, and the rules of attraction.
@nl
prefLabel
Stem cell states, fates, and the rules of attraction.
@en
Stem cell states, fates, and the rules of attraction.
@nl
P1433
P1476
Stem cell states, fates, and the rules of attraction.
@en
P2093
Carsten Peterson
Peter W Andrews
P304
P356
10.1016/J.STEM.2009.04.011
P407
P577
2009-05-01T00:00:00Z