The radial positioning of chromatin is not inherited through mitosis but is established de novo in early G1.
about
Cell-by-cell dissection of gene expression and chromosomal interactions reveals consequences of nuclear reorganizationTissue-specific spatial organization of genomesUnderstanding Spatial Genome Organization: Methods and InsightsGetting the genome in shape: the formation of loops, domains and compartmentsAn Overview of Genome Organization and How We Got There: from FISH to Hi-CChromosome conformation of human fibroblasts grown in 3-dimensional spheroids.Continued stabilization of the nuclear higher-order structure of post-mitotic neurons in vivoA novel multiplexed, image-based approach to detect phenotypes that underlie chromosome instability in human cellsTwo ways to fold the genome during the cell cycle: insights obtained with chromosome conformation captureCentromere positioning and dynamics in living Arabidopsis plantsChromatin position in human HepG2 cells: although being non-random, significantly changed in daughter cells.Distinct nuclear orientation patterns for mouse chromosome 11 in normal B lymphocytes.Dynamics of relative chromosome position during the cell cycle.Divergence between motoneurons: gene expression profiling provides a molecular characterization of functionally discrete somatic and autonomic motoneurons.Interphase chromosome arrangement in Arabidopsis thaliana is similar in differentiated and meristematic tissues and shows a transient mirror symmetry after nuclear division.Activation of estrogen-responsive genes does not require their nuclear co-localizationGenome-wide dynamics of replication timing revealed by in vitro models of mouse embryogenesis.Domain-wide regulation of DNA replication timing during mammalian developmentChromosome territories.The yin and yang of chromatin spatial organization.Chromatin dynamics.4D chromatin dynamics in cycling cells: Theodor Boveri's hypotheses revisited.Positioning of chromosomes in human spermatozoa is determined by ordered centromere arrangementIdentification of Gene Positioning Factors Using High-Throughput Imaging Mapping.Maintenance of imprinting and nuclear architecture in cycling cellsA genome-wide screen identifies genes that affect somatic homolog pairing in Drosophila.Cell-Cycle Control of Bivalent Epigenetic Domains Regulates the Exit from PluripotencyMobility and immobility of chromatin in transcription and genome stability.Actin-dependent intranuclear repositioning of an active gene locus in vivo.A genetic locus targeted to the nuclear periphery in living cells maintains its transcriptional competence.Epigenetic control of nuclear architectureEpigenetics and chromatin plasticity in embryonic stem cellsThe spatial order of transcription in mammalian cells.Nuclear functions in space and time: gene expression in a dynamic, constrained environment.Porin new light onto chromatin and nuclear organizationChromatin dynamics is correlated with replication timing.Genomic Architecture may Influence Recurrent Chromosomal Translocation Frequency in the Igh Locus.Replication timing and transcriptional control: beyond cause and effect--part II.Sizing up the nucleus: nuclear shape, size and nuclear-envelope assembly.Nuclear architecture as an epigenetic regulator of neural development and function.
P2860
Q24794800-682741DD-BB1A-4D76-89AB-6BA1C452B516Q24805135-884272AC-EEB1-4F5C-B40C-26873B2F0F78Q26766143-47DBF248-C189-4FF3-9E29-CA10FD6055DAQ26800278-C9ABBF11-5310-40CE-9E52-2431032BB70BQ26801741-D1301620-5756-46D1-98C7-CC9543D8C1F9Q27311141-8674D10B-A18B-4FFD-8FE3-EAEA4654E30DQ27334574-D25850C2-3D72-4AF7-8753-CBD52F755B58Q28546578-5D2A8823-AEFD-4968-BD45-E6FEAD07AB65Q29300664-B1F6423A-02A8-4D6A-ABFC-1ACF5CAA29ECQ30476395-AE5605FC-902B-4B92-830B-EFD12E4E7316Q30486603-B41B7F7B-5D6D-43C9-97D4-41AAD08D0E38Q30582493-157EC5AD-E0C0-49C6-AE81-DBBE6784911AQ30854666-58D57293-683F-4FEC-B4A7-E468F04FC91DQ33228148-AA2BC2C9-5181-4A49-89B0-DDB9A3B19DAAQ33343913-D556D8DA-7476-4AA5-B2B2-C9B4C17DF74EQ33565429-3C362774-04B8-4AC4-B526-CFD9327E9BBDQ33618903-9B5495E7-2185-4690-976B-66859F8FDC4EQ33684292-9FBABB20-AA4E-45FC-A0DE-E123E760BA92Q33693822-DF2027FA-7106-4F54-9A8F-3008BD499128Q33829755-4A50BC00-F8A7-4DD7-AE03-2B901606F47BQ33950324-BCCF8C21-3C5A-439E-99E3-8C0616295424Q34165063-E2811BAB-7E30-4BFE-A381-64CDC9E4DCC5Q34541454-1D4A6852-37C6-4806-B609-22428538E034Q35961554-6219E815-128C-4ADC-ADCF-24E4D57D5CE2Q36002526-DEA09153-9411-47ED-8851-88B2D982818FQ36065950-EB6CC7E1-1817-4CD3-8E1B-82668B0DE002Q36200995-6B785A19-5079-4166-8408-FADE8C901395Q36227827-874D7123-6D32-480F-9741-1BFC7D49EE1EQ36274498-16084ED0-94DF-42F9-8C9D-5B3B25450081Q36404918-76E3D771-E0B0-4A81-9AB1-BE0EE569063EQ36707394-375E059B-05B9-4094-B2B1-9116E40D2408Q37096807-7AF6D5E2-5516-4D17-AD78-18B538C9CE1AQ37117106-820812D2-558C-4947-BD43-EAF9B1BF07B0Q37149516-EA7CE733-1AAC-448D-8448-0326E2708E51Q37169825-44367A18-EB8B-49EB-A2E2-AF71372E6DD3Q37257454-061AD92A-34DC-4CB0-8986-AD09ABC47A84Q37417907-8C39504D-9E58-4456-B548-D35DA94F17CFQ37432729-8B343C01-E95B-48BE-B35A-28176EFE2A68Q37472616-ED289969-B5BD-4159-BD48-BE091440ED3EQ38184290-A9BA7267-275E-4D18-89F3-01E83ACFE081
P2860
The radial positioning of chromatin is not inherited through mitosis but is established de novo in early G1.
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
The radial positioning of chro ...... tablished de novo in early G1.
@en
type
label
The radial positioning of chro ...... tablished de novo in early G1.
@en
prefLabel
The radial positioning of chro ...... tablished de novo in early G1.
@en
P2093
P1433
P1476
The radial positioning of chro ...... tablished de novo in early G1.
@en
P2093
Inga Thomson
Jonathan R Chubb
Susan Gilchrist
Wendy A Bickmore
P304
P356
10.1016/J.CUB.2003.12.024
P407
P577
2004-01-01T00:00:00Z