Chromatin inheritance upon Zeste-mediated Brahma recruitment at a minimal cellular memory module
about
Molecular genetic analysis of Suppressor 2 of zeste identifies key functional domainsAn Sp1/KLF binding site is important for the activity of a Polycomb group response element from the Drosophila engrailed gene.Long-range communication between the silencers of HMR.Chromosomal distribution of PcG proteins during Drosophila developmentCorto and DSP1 interact and bind to a maintenance element of the Scr Hox gene: understanding the role of Enhancers of trithorax and Polycomb.The enhancer of trithorax and polycomb corto interacts with cyclin G in Drosophila.Stability and dynamics of polycomb target sites in Drosophila development.Evolutionary plasticity of polycomb/trithorax response elements in Drosophila speciesFunctional anatomy of polycomb and trithorax chromatin landscapes in Drosophila embryosStochastic spatio-temporal dynamic model for gene/protein interaction network in early Drosophila development.Transcriptional regulation by CHIP/LDB complexesTrithorax group proteins: switching genes on and keeping them active.Efficient and specific targeting of Polycomb group proteins requires cooperative interaction between Grainyhead and Pleiohomeotic.Polycomb group-dependent Cyclin A repression in DrosophilaGenetic screens for enhancers of brahma reveal functional interactions between the BRM chromatin-remodeling complex and the delta-notch signal transduction pathway in DrosophilaQuantitative analysis of polycomb response elements (PREs) at identical genomic locations distinguishes contributions of PRE sequence and genomic environment.Genome-wide polycomb target gene prediction in Drosophila melanogaster.Activation of Ftz-F1-Responsive Genes through Ftz/Ftz-F1 Dependent Enhancers.Distinct chromatin configurations regulate the initiation and the maintenance of hGH gene expressionDrosophila ptip is essential for anterior/posterior patterning in development and interacts with the PcG and trxG pathways.Architectural and functional diversity of polycomb group response elements in Drosophila.Mapping polycomb response elements at the Drosophilla melanogaster giant locus.Transcription through enhancers suppresses their activity in Drosophila.Epigenetic regulations in hematopoietic Hox code.High-resolution mapping defines the cooperative architecture of Polycomb response elements.The Mcp element from the bithorax complex contains an insulator that is capable of pairwise interactions and can facilitate enhancer-promoter communication.Molecular structures guide the engineering of chromatin.Analysis of a polycomb group protein defines regions that link repressive activity on nucleosomal templates to in vivo functionRole of Transcriptional Read-Through in PRE Activity in Drosophila melanogasterIntergenic transcription through a polycomb group response element counteracts silencing.Polycomb and Trithorax Group Genes in Drosophila.The bithorax complex iab-7 Polycomb response element has a novel role in the functioning of the Fab-7 chromatin boundary
P2860
Q24649818-69F66C49-D922-4C77-8AF2-166C09EAF88DQ24814416-35AB2280-B2C6-4C96-AB4A-4FA7A5F26564Q27930527-53301ECA-943E-4F75-8459-2FC7AD993A34Q33239849-06509E0C-8790-4BC3-998A-FA1F18C3FE8DQ33239867-9DF68281-A876-45E4-9C11-82987C03B100Q33320548-43EFB235-87F3-4633-AA6C-53D78FDED7ADQ33367118-2D3C5C4F-A25F-4BC9-A553-8C30C9446639Q33380406-3D545AC2-2E2F-4204-9F41-03F8BF0C61D9Q33399874-3DCC9B49-F5EF-490D-AF38-3A2DE68CB1DBQ33552533-826D7803-2A5A-4E00-B3A2-4E75DBF05DA9Q33668708-39649B6B-654A-4B30-B30A-1B89CA635D34Q34235226-4FF34C14-3BE8-4271-B43F-A8CB70A2F9E4Q34353564-48330924-CB23-437E-8EAC-756BC206615BQ34360272-EAA2FEAF-94D9-4E12-BFBF-5FBE95A4DA0CQ34573397-4B14B2AE-3945-41B2-80B2-1DC3F7D5E272Q34761063-8A2C509F-69DD-4393-828E-E49E2573CF81Q36106859-60DF6AEB-06C9-4B6F-8D67-F942046FB68BQ36159460-DC066227-A3B4-4790-BA56-6A7F1A5B9815Q36759681-BA9BC3C6-04B3-4743-AFB8-B4FA1A60C9B7Q37186890-DD906CAF-5B5E-494B-A90E-5343BBF993F1Q37194766-9E4D079A-02DE-4492-B6FC-5FF5973DB5BCQ37366572-FD20A9C4-B74A-47B7-909B-6B5D92675DA4Q37366831-70BD7DD4-157A-4AD3-B338-C6933921F9B5Q37802749-B0033AC6-58D7-4864-9BE8-670FFFE092C3Q39208908-F7B97331-C0EB-479A-A6B1-CC1452359F0FQ40435150-F5692651-6D71-41D9-B1FF-0634CDA74D42Q41510757-66ADA98F-C9F6-46C4-92B7-CA36D67FC126Q42254996-A8D86959-12B5-4C4C-A4A4-5876C042F419Q42288170-54C58DE1-C179-43F4-90BC-232FD74E3B42Q42705685-C654B2A7-5DC6-4FC7-9145-047013CB2948Q46253902-4F729045-4726-4960-AF6A-D03B63EA85AAQ58777038-56DA65E0-B380-4329-B090-9290724F2194
P2860
Chromatin inheritance upon Zeste-mediated Brahma recruitment at a minimal cellular memory module
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 12 February 2004
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Chromatin inheritance upon Zes ...... minimal cellular memory module
@en
Chromatin inheritance upon Zes ...... inimal cellular memory module.
@nl
type
label
Chromatin inheritance upon Zes ...... minimal cellular memory module
@en
Chromatin inheritance upon Zes ...... inimal cellular memory module.
@nl
prefLabel
Chromatin inheritance upon Zes ...... minimal cellular memory module
@en
Chromatin inheritance upon Zes ...... inimal cellular memory module.
@nl
P2860
P356
P1433
P1476
Chromatin inheritance upon Zes ...... minimal cellular memory module
@en
P2093
Jérôme Déjardin
P2860
P304
P356
10.1038/SJ.EMBOJ.7600108
P407
P577
2004-02-12T00:00:00Z