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Chromatin Dynamics in Vivo: A Game of Musical ChairsAn Overview of Genome Organization and How We Got There: from FISH to Hi-CRNA Polymerase II C-Terminal Domain: Tethering Transcription to Transcript and TemplateSpatial organization of RNA polymerase II inside a mammalian cell nucleus revealed by reflected light-sheet superresolution microscopy.Chromatin associations in Arabidopsis interphase nucleiDynamics of the association of heat shock protein HSPA6 (Hsp70B') and HSPA1A (Hsp70-1) with stress-sensitive cytoplasmic and nuclear structures in differentiated human neuronal cellsIntegrating epigenomic data and 3D genomic structure with a new measure of chromatin assortativityVisualization of the spatial arrangement of nuclear organization using three-dimensional fluorescence in situ hybridization in early mouse embryos: A new "EASI-FISH chamber glass" for mammalian embryos.Imaging RNA Polymerase II transcription sites in living cellsRNA polymerase II transcription elongation control.Abundance and distribution of RNA polymerase II in Arabidopsis interphase nuclei.Hi-C Chromatin Interaction Networks Predict Co-expression in the Mouse Cortex.Enhancer Runaway and the Evolution of Diploid Gene ExpressionChromatin structure and transposable elements in organismal aging.In the loop: promoter-enhancer interactions and bioinformatics.A pathway-centric view of spatial proximity in the 3D nucleome across cell lines.Detection and replication of epistasis influencing transcription in humans.Targeting of Heat Shock Protein HSPA6 (HSP70B') to the Periphery of Nuclear Speckles is Disrupted by a Transcription Inhibitor Following Thermal Stress in Human Neuronal Cells.Cajal body function in genome organization and transcriptome diversity.Localization of heat shock protein HSPA6 (HSP70B') to sites of transcription in cultured differentiated human neuronal cells following thermal stress.Clustering of Drosophila housekeeping promoters facilitates their expression.Chromatin proteins and RNA are associated with DNA during all phases of mitosisDifferential Targeting of Hsp70 Heat Shock Proteins HSPA6 and HSPA1A with Components of a Protein Disaggregation/Refolding Machine in Differentiated Human Neuronal Cells following Thermal Stress.Enhancer SINEs Link Pol III to Pol II Transcription in Neurons.Knockdown of Heat Shock Proteins HSPA6 (Hsp70B') and HSPA1A (Hsp70-1) Sensitizes Differentiated Human Neuronal Cells to Cellular Stress.Nucleoporins redistribute inside the nucleus after cell cycle arrest induced by histone deacetylases inhibition.Dynamic Behavior of the RNA Polymerase II and the Ubiquitin Proteasome System During the Neuronal DNA Damage Response to Ionizing Radiation.The Set of Structural DNA-Nuclear Matrix Interactions in Neurons Is Cell-Type Specific and Rather Independent of Functional Constraints.Co-expressed genes prepositioned in spatial neighborhoods stochastically associate with SC35 speckles and RNA polymerase II factories.BAF53 is required for mitotic progressionTranscription-driven genome organization: a model for chromosome structure and the regulation of gene expression tested through simulations
P2860
Q26799305-DAFBCFBA-8A5C-46D6-81B3-362D0CB48C8CQ26801741-55A07B8C-7781-4517-95EF-641E641C22F1Q29540749-8A5916EE-43AD-4069-A8C4-1E7E7855E51BQ30565963-70E5DFA0-3450-4D96-8D78-AB2C84EEBBCBQ30597626-8877732F-DB10-43C9-A976-939154B70056Q30826718-A1AED11F-52CC-4730-A8E5-F4EC14AE9426Q31113419-3EE437EC-3A6A-49BB-BEDC-4442A24F2879Q33593097-4E5A35A9-A7BB-44FE-86A0-F47D30C1FDE7Q34418682-6F9B4766-7715-46F2-B799-EC26BD5C5FB1Q34960186-685D8512-09CE-4994-951A-5DE6A80D77A3Q35170512-556A60DE-38DE-44B4-8494-9E5591F3B62AQ35627802-84E81941-BCFC-4B46-B916-B923C6FA462DQ35839674-5C689DC1-DEAC-4ECF-B0F2-167B9CE2D36EQ37361621-92EFB7EF-644F-4E2E-A506-FFFE9FDAB1ECQ37480563-8A120E15-0609-498D-9BC6-5FF829BD0148Q37504751-58555A6C-751F-493C-87CD-BA488BC84372Q37699035-31072050-1FC3-4AD9-8B96-5CDC212F0967Q38741171-57501B0A-5DA7-4687-B517-50D0C6DE716CQ38808242-D7AC0632-AED2-4C87-9C64-55E974E45F2BQ38947456-D11F25B3-1DD8-4B30-9871-2CA8E4941EFDQ40976777-280D6C77-FBD5-4CD9-9550-3FACEDA85B43Q41568783-7D49D763-93E1-4139-A189-765F9E2136F0Q42290756-778AF20C-439B-4C0B-B47A-4508964BB1D6Q47162405-B1BBBFBD-0956-4D69-99C8-AC6AE8E76C60Q47579639-3027FE3A-CE58-421A-A8CA-EA847AD9433CQ48144118-CE78D1D2-2034-44F6-9525-061299C75F1EQ50434322-D6D10FA9-6A89-4DDF-BF64-C3DA427FE8DDQ51248632-1A86153A-CCBB-4EAE-B9D0-D25D3A942B30Q53090579-18ADC7FD-447F-4E62-815F-E4FB257E777DQ58150411-7BDFEB89-2C7B-439B-9B20-A7F365C566ACQ58721322-BDD02FCB-7AFD-400F-9E0D-F4652E725DA3
P2860
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh
2012年學術文章
@zh-hant
name
Transcription factories
@ast
Transcription factories
@en
type
label
Transcription factories
@ast
Transcription factories
@en
prefLabel
Transcription factories
@ast
Transcription factories
@en
P2093
P2860
P356
P1476
Transcription factories
@en
P2093
Dietmar Rieder
James G McNally
Zlatko Trajanoski
P2860
P356
10.3389/FGENE.2012.00221
P577
2012-10-23T00:00:00Z