about
Imaging Transcription: Past, Present, and FutureMinor Loops in Major Folds: Enhancer-Promoter Looping, Chromatin Restructuring, and Their Association with Transcriptional Regulation and DiseaseActive chromatin and transcription play a key role in chromosome partitioning into topologically associating domains.Structural and functional diversity of Topologically Associating DomainsQuantitative Immunofluorescence Analysis of Nucleolus-Associated ChromatinExplorations to improve the completeness of exome sequencingTwo ways to fold the genome during the cell cycle: insights obtained with chromosome conformation captureA 3D map of the human genome at kilobase resolution reveals principles of chromatin loopingLive cell imaging of low- and non-repetitive chromosome loci using CRISPR-Cas9The detailed 3D multi-loop aggregate/rosette chromatin architecture and functional dynamic organization of the human and mouse genomes.Restraint-based three-dimensional modeling of genomes and genomic domains.Laying a solid foundation for Manhattan--'setting the functional basis for the post-GWAS era'.Influence of oncogenic transcription factors on chromatin conformation and implications in prostate cancer.Nucleolus association of chromosomal domains is largely maintained in cellular senescence despite massive nuclear reorganisation.Depletion of the chromatin looping proteins CTCF and cohesin causes chromatin compaction: insight into chromatin folding by polymer modellingWide-scale alterations in interchromosomal organization in breast cancer cells: defining a network of interacting chromosomes.Architectural proteins: regulators of 3D genome organization in cell fate3D Chromosome Regulatory Landscape of Human Pluripotent Cells.CTCF-Mediated Human 3D Genome Architecture Reveals Chromatin Topology for Transcription.Nuclear position dictates DNA repair pathway choice.Genome-wide mapping and analysis of chromosome architecture.Enhancer variants: evaluating functions in common disease.Epigenetic regulation by heritable RNA.Cell type specific alterations in interchromosomal networks across the cell cycle.diffHic: a Bioconductor package to detect differential genomic interactions in Hi-C data.The Role of Crowding Forces in Juxtaposing β-Globin Gene Domain Remote Regulatory Elements in Mouse Erythroid CellsIdentification of Gene Positioning Factors Using High-Throughput Imaging Mapping.Bipartite structure of the inactive mouse X chromosomeLong range chromatin organization: a new layer in splicing regulation?Genome-wide maps of nuclear lamina interactions in single human cellsChromatin interaction analysis reveals changes in small chromosome and telomere clustering between epithelial and breast cancer cellsThe International Nucleome Consortium.Nanoscale spatial organization of the HoxD gene cluster in distinct transcriptional states.Long-read ChIA-PET for base-pair-resolution mapping of haplotype-specific chromatin interactions.Genetic sequence-based prediction of long-range chromatin interactions suggests a potential role of short tandem repeat sequences in genome organizationLong non-coding RNAs in corticogenesis: deciphering the non-coding code of the brainChromosomes at Work: Organization of Chromosome Territories in the Interphase Nucleus.Spatial Organization of Epigenomes.Large-scale probabilistic 3D organization of human chromosome territories.The 3D Genome as Moderator of Chromosomal Communication.
P2860
Q26772088-2D97CAD5-077D-4330-85B2-7BA50DEDD672Q26775145-FC140897-2BC0-4A7D-8074-44AF89005FFCQ27321750-AE82F0CC-F3C4-4034-8E61-84B35732AF2BQ28088652-3B5EC1B7-E0FB-4198-BE67-BB241D2AD9DEQ28364885-A42C203B-F826-4091-9E58-9418EE5D8C85Q28596922-64D7E7AD-93A0-475F-AA43-F517F5DBA80CQ29300664-169358A4-26D5-4CEF-8087-77781CF2718BQ29615814-42F41BD4-473C-426C-A29C-578732E93140Q30252964-95039CFC-FDB4-4CC2-BFC3-7824E1D96E53Q30833339-08415FE9-61B2-4AB9-A383-214C765D0FD2Q30952722-EF1A8DC5-A3A8-47C0-8194-0B62D5410382Q33631309-C6755377-87AE-4BC7-B156-3A91A202B13BQ33675577-E83153ED-66EB-4081-B60D-B44BED074CBAQ33757972-986645FA-D37B-48DD-AD31-90B1C972F53EQ34314868-C4FE931C-8901-490C-BA48-C2F88AA4F4ACQ34430376-73C16DBD-390C-490E-9AEE-85CA29E31C8EQ34438433-E1736C28-F47F-45FC-9AE1-0EA36525EFF4Q34505845-34D4E36E-346C-4653-B0B0-5A2BAF4BA379Q34505857-627F0009-708B-4CDF-B21E-12FD5ABEA22BQ34518930-FF4434A1-5A18-46B9-B1BE-BD978B261223Q34539078-0DFE80DD-4E97-4C6A-B929-55DED7380D51Q34624842-0A9597CF-1368-4134-AADE-66ABE24F43F7Q35151858-46F15ECF-8764-4F35-94E8-4BADE4EC284CQ35295223-9F145948-5A1C-401C-AB33-572C4A44AD38Q35748418-FF8D02D9-AB9E-4706-B201-0B28CC4409E3Q35799030-73BD9ACB-6810-49ED-BDB4-97F623BA8270Q35961554-B2D00F6F-E5BC-4C8D-93E4-874C14FF71C8Q35964734-352D6ADD-2C6E-43B3-AB26-57F246C761F4Q36072603-9C4D3C55-236B-4ADD-83AB-8C30D4531C49Q36094851-6335A758-A841-4D81-A925-FDAEB92B5C48Q36104763-E8B4555B-504E-47C0-9694-845C6D4AEC34Q36189603-78B66BDD-3BD8-45EF-9937-83CBA4FF1CF3Q36300252-AB094AF5-9856-4672-9CB3-9DA4FB549751Q36327941-292BA2EA-54EE-4F36-8AB7-6C6DBAACE7ABQ36350228-B213BFA2-4A9C-4CE3-94A3-2499017D6EA4Q36394663-2AE1171B-3D03-4981-84D0-F710B8004512Q36470519-11A2ECDD-7F9E-4210-B9EC-65B7FE4DA771Q36491208-D5EDBACD-5211-487B-B5B1-D53213F22453Q36514617-00B3B624-C5EF-48F5-82C7-A06FDE36E144Q36678954-844A45AB-AA13-4797-B3EF-93CE927CA002
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
The spatial organization of the human genome.
@en
type
label
The spatial organization of the human genome.
@en
prefLabel
The spatial organization of the human genome.
@en
P1476
The spatial organization of the human genome.
@en
P356
10.1146/ANNUREV-GENOM-091212-153515
P577
2013-07-15T00:00:00Z