about
Identification and analysis of functional elements in 1% of the human genome by the ENCODE pilot projectResolving the complexity of the human genome using single-molecule sequencingThe accessible chromatin landscape of the human genomeWidespread plasticity in CTCF occupancy linked to DNA methylationComprehensive mapping of long-range interactions reveals folding principles of the human genomeAn expansive human regulatory lexicon encoded in transcription factor footprintsSystematic localization of common disease-associated variation in regulatory DNASequencing newly replicated DNA reveals widespread plasticity in human replication timing.CCCTC-binding factor and the transcription factor T-bet orchestrate T helper 1 cell-specific structure and function at the interferon-gamma locus.Epigenetic regulation by chromatin activation mark H3K4me3 in primate progenitor cells within adult neurogenic nicheMolecular targets of chromatin repressive mark H3K9me3 in primate progenitor cells within adult neurogenic niches.DNase I-hypersensitive exons colocalize with promoters and distal regulatory elements.A comparative encyclopedia of DNA elements in the mouse genomeComprehensive characterization of erythroid-specific enhancers in the genomic regions of human Krüppel-like factors.Comprehensive analysis of the chromatin landscape in Drosophila melanogaster.Genome-wide comparative analysis reveals human-mouse regulatory landscape and evolution.Mouse regulatory DNA landscapes reveal global principles of cis-regulatory evolutionLate-replicating heterochromatin is characterized by decreased cytosine methylation in the human genome.Cell-of-origin chromatin organization shapes the mutational landscape of cancerA genome-wide map of adeno-associated virus-mediated human gene targetingDynamic reprogramming of chromatin accessibility during Drosophila embryo development.Native elongating transcript sequencing reveals human transcriptional activity at nucleotide resolution.Zebrafish globin switching occurs in two developmental stages and is controlled by the LCR.BEDOPS: high-performance genomic feature operations.Large-scale identification of sequence variants influencing human transcription factor occupancy in vivoAn encyclopedia of mouse DNA elements (Mouse ENCODE).Foxp3 exploits a pre-existent enhancer landscape for regulatory T cell lineage specificationGenome Sequencing of Autism-Affected Families Reveals Disruption of Putative Noncoding Regulatory DNA.Probing DNA shape and methylation state on a genomic scale with DNase I.Cross-species Analyses Unravel the Complexity of H3K27me3 and H4K20me3 in the Context of Neural Stem Progenitor Cells.A microbial profiling method for the human microbiota using high-throughput sequencing.Global mapping of protein-DNA interactions in vivo by digital genomic footprinting.Functionally and phenotypically distinct subpopulations of marrow stromal cells are fibroblast in origin and induce different fates in peripheral blood monocytes.The birth of a human-specific neural gene by incomplete duplication and gene fusion.Developmental fate and cellular maturity encoded in human regulatory DNA landscapes.A temporal chromatin signature in human embryonic stem cells identifies regulators of cardiac developmentConservation of trans-acting circuitry during mammalian regulatory evolution.DNase I hypersensitivity analysis of the mouse brain and retina identifies region-specific regulatory elementsCircuitry and dynamics of human transcription factor regulatory networks.Coupling transcription factor occupancy to nucleosome architecture with DNase-FLASH.
P50
Q21061203-34D68A7C-10EE-402F-9EA2-DF2B168613F7Q22122132-16E0AE34-11D5-4C25-9F25-F8FA4BF10B20Q24595581-962A6304-5BCE-4B77-B4EA-BAFE0C7A8E11Q24608987-4AF22489-27CD-4BA3-B1A3-34ED40DF4C10Q28131819-568EE87C-75DE-4F8A-8D00-3613CE936EB5Q28274429-29668000-2352-438D-A069-509B65A3DF07Q29614895-8B1D5DAD-4301-4885-A50D-CA345745A1BFQ33591861-74D04684-858D-47FD-BF0A-BD60E50CE26FQ33606470-C7DA65E7-23A9-4E93-B001-405F70703353Q33781132-E291042F-03A7-483F-BAF4-9CA79903286DQ33972484-A060F5AA-7D83-4331-8B3C-023C06BAC908Q34352768-1A0406EA-20D0-4885-A2CE-45BED287AAC4Q34700119-E0246CC0-96DC-4475-8C7D-5FB2D09D3FC8Q34975754-6C14CF3C-0233-4B9F-AC85-A156870C0877Q35030499-D6F6BDC1-7536-4888-BA9F-B4A66DED0DD9Q35097288-A65F34EF-700F-4354-955B-4962F636897FQ35111710-B0843035-4604-4466-BA2D-78B77B5621F3Q35493825-1E0EBC4D-5CB9-4EA7-9799-624FA5352FA2Q35510462-32DEF3CB-8F02-4C3C-BDCD-44B5E17D5819Q35510498-C0DAF16F-4FFF-48AC-8E82-CD3810966878Q35561152-816B7972-63B4-4C20-B29A-614D6500D8B1Q35927818-B9A5F347-65AA-4977-9318-6E41DC63E302Q36043069-21177697-5985-40C0-81A9-E4F1DFD77373Q36076319-C634DD55-3185-4236-AB41-E36CFD17A6B1Q36338647-70B3ABA7-567C-4F73-A252-FA36A9E0C044Q36377972-DC883863-B15E-4CAE-A3FC-8C3D1967CDCEQ36383859-FA45332B-6665-4C1A-B794-4F59305D38F7Q36473412-8845E3F8-C81F-4581-9F91-39F4A81988F3Q36782127-745BC716-BCE0-4CCA-B36A-12E605E94DF4Q37085475-C804B112-4E79-4422-84EA-66374D78EAF7Q37150587-FB843427-1E31-47C5-88B0-BF45BEC6D0DDQ37157318-D82EC19D-B6BB-4F15-B6F9-71C515EF970CQ37667542-DCDB5192-1691-4E43-BE0B-254A627FF167Q37692482-697B2572-343D-4DFD-9434-D38D70E78282Q38394827-8053CAC5-B747-4775-A80C-A772627F4DA8Q38458441-2F60422F-FF05-4807-ACD4-D92FE6E7D214Q39843784-52429667-0478-477D-BA4A-3A25E2EE261DQ40613576-790DC672-D1B1-49F1-B26E-AF77756F4F22Q42150273-897FEF5D-7048-412A-A842-558DA0AC3DFFQ43560554-F51BD9AA-689E-43E2-A845-F8F475560889
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Richard Sandstrom
@ast
Richard Sandstrom
@en
Richard Sandstrom
@es
Richard Sandstrom
@fr
Richard Sandstrom
@nl
Richard Sandstrom
@sl
type
label
Richard Sandstrom
@ast
Richard Sandstrom
@en
Richard Sandstrom
@es
Richard Sandstrom
@fr
Richard Sandstrom
@nl
Richard Sandstrom
@sl
altLabel
Richard S Sandstrom
@en
prefLabel
Richard Sandstrom
@ast
Richard Sandstrom
@en
Richard Sandstrom
@es
Richard Sandstrom
@fr
Richard Sandstrom
@nl
Richard Sandstrom
@sl
P106
P1153
26637246900
P21
P2798
P31
P496
0000-0002-3356-1547