about
Reconstructing an ancestral mammalian immune supercomplex from a marsupial major histocompatibility complexGenome of the marsupial Monodelphis domestica reveals innovation in non-coding sequencesORegAnno: an open-access community-driven resource for regulatory annotationProtein-DNA binding in high-resolutionGene co-regulation by Fezf2 selects neurotransmitter identity and connectivity of corticospinal neuronsAn integrated model of multiple-condition ChIP-Seq data reveals predeterminants of Cdx2 binding.DNA familial binding profiles made easy: comparison of various motif alignment and clustering strategies.Feed-forward regulation of a cell fate determinant by an RNA-binding protein generates asymmetry in yeastLarge scale comparison of innate responses to viral and bacterial pathogens in mouse and macaque.Discovering homotypic binding events at high spatial resolution.High resolution genome wide binding event finding and motif discovery reveals transcription factor spatial binding constraintsA Multi-step Transcriptional and Chromatin State Cascade Underlies Motor Neuron Programming from Embryonic Stem Cells.Ligand-dependent dynamics of retinoic acid receptor binding during early neurogenesisA multi-parametric flow cytometric assay to analyze DNA-protein interactions.Combined analysis reveals a core set of cycling genesReprogrammed Stomach Tissue as a Renewable Source of Functional β Cells for Blood Glucose Regulation.Synergistic binding of transcription factors to cell-specific enhancers programs motor neuron identity.The Pioneer Transcription Factor FoxA Maintains an Accessible Nucleosome Configuration at Enhancers for Tissue-Specific Gene Activation.Inferring protein-DNA dependencies using motif alignments and mutual information.Saltatory remodeling of Hox chromatin in response to rostrocaudal patterning signals.Genome-Wide Organization of GATA1 and TAL1 Determined at High Resolution.STAMP: a web tool for exploring DNA-binding motif similarities.Global control of motor neuron topography mediated by the repressive actions of a single hox gene.Regulatory conservation of protein coding and microRNA genes in vertebrates: lessons from the opossum genome.miniMDS: 3D structural inference from high-resolution Hi-C data.A Cdx4-Sall4 regulatory module controls the transition from mesoderm formation to embryonic hematopoiesis.Deconvolving sequence features that discriminate between overlapping regulatory annotations.Improved detection of DNA motifs using a self-organized clustering of familial binding profiles.Transcription factor binding site identification using the self-organizing map.Widespread and precise reprogramming of yeast protein-genome interactions in response to heat shock.Self-organizing neural networks to support the discovery of DNA-binding motifs.An integrative view of the regulatory and transcriptional landscapes in mouse hematopoiesisJoint inference and alignment of genome structures enables characterization of compartment-independent reorganization across cell typesDirect prediction of regulatory elements from partial data without imputationCharacterizing protein-DNA binding event subtypes in ChIP-exo dataProneural factors Ascl1 and Neurog2 contribute to neuronal subtype identities by establishing distinct chromatin landscapes
P50
Q21092780-1D6DF138-960A-43A7-8BB9-0B9B11F8434FQ22122236-7763EA0F-E7C3-47F1-8578-702B64BCE5E1Q24648942-9DAD1811-4D66-4824-9915-D4AAEC220B22Q28084330-A28FE678-1EBD-4A3A-9AFD-4FA4CAA928A4Q28591195-CE772808-E1FF-4182-B914-91B7C9DC759AQ30787173-12B4FEA7-FEA1-4ADD-9346-38907E65366DQ33280629-A455B9B6-7ABD-45BC-BF99-00A752EDC346Q33895359-B46E3C35-B585-45EE-B106-EAE328D7B8C2Q33971466-E480BA21-3582-48E0-92FA-AD1CD05373AAQ34368356-05227F2B-A65D-48E0-B782-1E2EB9368D79Q34388423-E68425B5-AC15-464B-9A89-FA29EAFBB104Q34547013-FBABE8FE-C527-49E2-BC31-45E7BE06726BQ34964350-B20CE16C-0206-4DE8-BF12-56EC268AAAC4Q36560070-01B3AE2C-B37B-4B8B-A1DE-A0A1405A9132Q36570663-7058B2CC-8742-4423-A649-B9F5EBFA4160Q36654846-FF913731-EEA5-4431-8F50-5A25E7168DB2Q37288224-26951DC8-CAE2-447E-9FD3-8EE51B18B074Q40002806-2DAD71BE-1273-45F4-A91B-520011A6AF8CQ40190795-DD7E6199-023C-400B-807C-FE5D26102EEDQ41839120-85F8586B-619D-4099-98C4-C3FFFC7DAA3FQ41903956-DF55DBEB-76F6-4BD8-A456-D84282335ECFQ42055929-01FD8C4B-C35D-48D2-BD5D-740B634649D8Q42409696-43B52A00-BE1B-4B45-98FB-BE0000614BC2Q42467145-E8FA396C-5D45-404F-8A01-8B637F0DFAFEQ42697206-757E7E58-4777-4D90-9C04-AD1B02515457Q42867167-3AD68D7B-7825-49CC-82A1-A3587F564CF0Q46075500-DD694231-A873-4CBD-9A7D-A7471B499AC3Q48484765-745BE128-5D5F-448B-838D-E54DAB219A7FQ48504113-2A581457-854D-48FC-9EBC-D6F8D82F4FAAQ51419679-A2C8E239-4872-4FF5-93F9-38009C9D865BQ51937721-32B9A541-6DA5-44F6-9D95-86F24071CCCAQ90050931-213605A4-8965-4E2B-A333-C85AAA0AE01BQ90595510-B126FE14-C7FB-4CE3-89FD-95907CF5CE28Q91089241-05B111F8-A26C-4AEC-BC2C-393F6F53CA93Q91233647-704DA423-D9EE-4A3D-A74D-E2DCFB9F1F6DQ92000787-E187902F-BB59-4208-98A7-34748CD30256
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Shaun Mahony
@ast
Shaun Mahony
@en
Shaun Mahony
@es
Shaun Mahony
@sl
type
label
Shaun Mahony
@ast
Shaun Mahony
@en
Shaun Mahony
@es
Shaun Mahony
@sl
prefLabel
Shaun Mahony
@ast
Shaun Mahony
@en
Shaun Mahony
@es
Shaun Mahony
@sl
P108
P1053
C-5699-2014
P106
P31
P3829
P496
0000-0002-2641-1807