Systematic analysis of essential yeast TAFs in genome-wide transcription and preinitiation complex assembly
about
TAF7: a possible transcription initiation check-point regulatorTAF9b (formerly TAF9L) is a bona fide TAF that has unique and overlapping roles with TAF9Individual CREB-target genes dictate usage of distinct cAMP-responsive coactivation mechanismsDistinct modes of gene regulation by a cell-specific transcriptional activatorTFIID component TAF7 functionally interacts with both TFIIH and P-TEFbTFIID and Spt-Ada-Gcn5-acetyltransferase functions probed by genome-wide synthetic genetic array analysis using a Saccharomyces cerevisiae taf9-ts alleleMinimal components of the RNA polymerase II transcription apparatus determine the consensus TATA boxThe new core promoter element XCPE1 (X Core Promoter Element 1) directs activator-, mediator-, and TATA-binding protein-dependent but TFIID-independent RNA polymerase II transcription from TATA-less promotersTranscriptional activators in yeastConserved region I of human coactivator TAF4 binds to a short hydrophobic motif present in transcriptional regulatorsThe TAF9 C-terminal conserved region domain is required for SAGA and TFIID promoter occupancy to promote transcriptional activation.Yeast TFIID serves as a coactivator for Rap1p by direct protein-protein interactionAlternative splicing targeting the hTAF4-TAFH domain of TAF4 represses proliferation and accelerates chondrogenic differentiation of human mesenchymal stem cellsA role for voltage-dependent anion channel Vdac1 in polyglutamine-mediated neuronal cell death.TAF6delta controls apoptosis and gene expression in the absence of p53.Computational modelling of genome-wide [corrected] transcription assembly networks using a fluidics analogyAssociation of the Mediator complex with enhancers of active genes.Mapping and functional characterization of the TAF11 interaction with TFIIA.Alternative splicing of TAF6: downstream transcriptome impacts and upstream RNA splice control elements.TAF4 inactivation in embryonic fibroblasts activates TGF beta signalling and autocrine growth.Novel functions for TAF7, a regulator of TAF1-independent transcription.Targets of the Gal4 transcription activator in functional transcription complexes.Distinct regulatory mechanisms of eukaryotic transcriptional activation by SAGA and TFIID.TAF4, a subunit of transcription factor II D, directs promoter occupancy of nuclear receptor HNF4A during post-natal hepatocyte differentiation.Control of embryonic stem cell lineage commitment by core promoter factor, TAF3.Transcriptional regulation in Saccharomyces cerevisiae: transcription factor regulation and function, mechanisms of initiation, and roles of activators and coactivators.Structure and mechanism of the RNA polymerase II transcription machinery.Identification of molecular biomarkers for multiple sclerosis.Interaction networks of the molecular machines that decode, replicate, and maintain the integrity of the human genome.The 19S proteasome subcomplex promotes the targeting of NuA4 HAT to the promoters of ribosomal protein genes to facilitate the recruitment of TFIID for transcriptional initiation in vivo.Eaf1p Is Required for Recruitment of NuA4 in Targeting TFIID to the Promoters of the Ribosomal Protein Genes for Transcriptional Initiation In Vivo.The general transcription factor TAF7 is essential for embryonic development but not essential for the survival or differentiation of mature T cells.Phosphorylation-dependent regulation of cyclin D1 and cyclin A gene transcription by TFIID subunits TAF1 and TAF7Combining guilt-by-association and guilt-by-profiling to predict Saccharomyces cerevisiae gene function.TAF7: traffic controller in transcription initiation.Wnt signaling targets ETO coactivation domain of TAF4/TFIID in vivoDirect TFIIA-TFIID protein contacts drive budding yeast ribosomal protein gene transcription.Mechanisms of antisense transcription initiation from the 3' end of the GAL10 coding sequence in vivo.New insights into the function of transcription factor TFIID from recent structural studies.Genome-wide analysis of pre-mRNA splicing: intron features govern the requirement for the second-step factor, Prp17 in Saccharomyces cerevisiae and Schizosaccharomyces pombe.
P2860
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
P248
Q24300763-F117F650-B490-4ECF-B814-1815BF4CCF57Q24302399-1DA3C584-0C1A-4D26-9DF2-927BE5C8AA06Q24306838-4380C665-FBA2-4668-B667-A7A8A872943DQ24316297-E7AD602A-3E7B-4F78-BA53-2AB5B1A8EDE0Q24317617-4D8FCEE8-F5A0-485B-923B-48FD486A7FF0Q24545962-81B9D100-0532-486D-A0F3-2461A8E69A20Q24649912-9E86A530-FCFE-449B-A9CD-ECEB41C99C54Q24681624-5A10B664-485A-4CF3-B9EC-BF3EE2A8D16BQ25257450-4A4D2DDF-C64E-450A-AF0D-B5C5B8D34777Q27644713-0F6426FC-1A28-4393-9958-63BE77BEFA22Q27935406-4D597DDF-94FA-48ED-82B0-55060CF3BF82Q27938360-14FFEE32-0628-4ABD-94A7-904852356F02Q28534001-BB0732F6-00B8-4B70-BD58-C13A2A6D7A71Q33305438-D40E8BA5-8B70-4DEA-9AFB-DF752DA84351Q33351996-3A993509-5F8F-4AED-81D3-7472A018F8B9Q33366428-AEDFC59C-89C8-44E7-A923-672E70989B9CQ33713593-C8E613F3-31E6-4745-B8F9-4DC9AE6605B2Q33713693-E2A7F8BC-10D0-484B-95A4-DEC37CAFCFA1Q33905777-61E6FB8D-488F-41DE-AB48-1178E44D935DQ33910929-4B5656B9-4167-4684-B0FC-02FA6879B266Q34385864-BDEED317-6EFA-4E8F-980B-07FAC30B1E21Q34456105-37514B38-A8F1-4D63-8D54-B20FC2873DB5Q34478777-9A2C9E35-70B0-4E60-B098-B3168792FC47Q35176557-4B29F82B-70C0-4A0F-9226-2177A8F9D673Q35314562-45A4844B-5F0E-4230-987C-8134B423C913Q35542072-5D786C1D-E32D-4F7D-A661-F32936D60BCCQ35758805-78385605-AFB5-4275-A986-EF2457E4D57DQ35789583-2E3428CD-25D1-4501-BABB-EF47C304B081Q35816201-B23224A9-40BE-424E-9B73-CC900E66252DQ35823742-70337DEE-EC33-4B8F-8338-EDD962598703Q35917477-7861912E-D7A8-4B7C-A570-383F541D108BQ35943895-1AAE38CD-AAA9-439B-A33E-2811A0A3795FQ36211051-902F89B2-B472-4E97-BC36-E87E0A60DDDCQ36748881-F82C28A4-753E-4A5A-9876-EE4E13FEE4A3Q36815365-319AC310-FA0E-4688-8C50-E97BAC22CB60Q37068274-FCB97B5F-CCAC-47D3-B930-F1744C67795CQ37095433-91A7CC7A-6A86-4F14-B6DC-C7E514B7C482Q37122772-EE06B4A1-1F1B-457E-85FD-E1A85A65D692Q37855183-BACB7DE7-D7A8-4800-A6A3-4ED751C9D8C5Q38336034-EE78F466-E69E-4C50-A3A5-01E8FD712B8D
P2860
Systematic analysis of essential yeast TAFs in genome-wide transcription and preinitiation complex assembly
description
2003 nî lūn-bûn
@nan
2003 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Systematic analysis of essenti ...... preinitiation complex assembly
@ast
Systematic analysis of essenti ...... preinitiation complex assembly
@en
Systematic analysis of essenti ...... reinitiation complex assembly.
@nl
type
label
Systematic analysis of essenti ...... preinitiation complex assembly
@ast
Systematic analysis of essenti ...... preinitiation complex assembly
@en
Systematic analysis of essenti ...... reinitiation complex assembly.
@nl
prefLabel
Systematic analysis of essenti ...... preinitiation complex assembly
@ast
Systematic analysis of essenti ...... preinitiation complex assembly
@en
Systematic analysis of essenti ...... reinitiation complex assembly.
@nl
P2093
P2860
P356
P1433
P1476
Systematic analysis of essenti ...... preinitiation complex assembly
@en
P2093
Ezra G Jennings
Helen C Causton
Michael R Green
Richard A Young
Sukesh R Bhaumik
Tseng-Hsing Wang
Wu-Cheng Shen
Xiaochun Zhu
P2860
P304
P356
10.1093/EMBOJ/CDG336
P407
P50
P577
2003-07-01T00:00:00Z