about
Human TAF(II)55 interacts with the vitamin D(3) and thyroid hormone receptors and with derivatives of the retinoid X receptor that have altered transactivation propertiesTAFII55 binding to TAFII250 inhibits its acetyltransferase activityTAF9b (formerly TAF9L) is a bona fide TAF that has unique and overlapping roles with TAF9In vivo functional analysis of the histone 3-like TAF9 and a TAF9-related factor, TAF9LThe human TFIID components TAF(II)135 and TAF(II)20 and the yeast SAGA components ADA1 and TAF(II)68 heterodimerize to form histone-like pairsA multiplicity of coactivators is required by Gcn4p at individual promoters in vivoCoordinate regulation of RARgamma2, TBP, and TAFII135 by targeted proteolysis during retinoic acid-induced differentiation of F9 embryonal carcinoma cellsTAF4b is required for mouse spermatogonial stem cell development.SPN1, a conserved gene identified by suppression of a postrecruitment-defective yeast TATA-binding protein mutantProtein-protein interaction map for yeast TFIID.Bromodomain factor 1 corresponds to a missing piece of yeast TFIID.Identification of two novel TAF subunits of the yeast Saccharomyces cerevisiae TFIID complex.Mutations in the histone fold domain of the TAF12 gene show synthetic lethality with the TAF1 gene lacking the TAF N-terminal domain (TAND) by different mechanisms from those in the SPT15 gene encoding the TATA box-binding protein (TBP)ADR1-mediated transcriptional activation requires the presence of an intact TFIID complex.Identification of a yeast transcription factor IID subunit, TSG2/TAF48.Distinct mutations in yeast TAF(II)25 differentially affect the composition of TFIID and SAGA complexes as well as global gene expression patterns.A yeast taf17 mutant requires the Swi6 transcriptional activator for viability and shows defects in cell cycle-regulated transcription.Spn1 regulates the recruitment of Spt6 and the Swi/Snf complex during transcriptional activation by RNA polymerase IIAnalysis of TAF90 mutants displaying allele-specific and broad defects in transcription.The yeast SAS (something about silencing) protein complex contains a MYST-type putative acetyltransferase and functions with chromatin assembly factor ASF1Molecular genetics of the RNA polymerase II general transcriptional machineryTrinucleotide repeats are clustered in regulatory genes in Saccharomyces cerevisiae.The intronless and TATA-less human TAF(II)55 gene contains a functional initiator and a downstream promoter element.Study of a region on yeast chromosome XIII that complements pet G199 mutants (COX7) and carries a new non-essential gene.A TATA-binding protein mutant defective for TFIID complex formation in vivo.Activation and repression mechanisms in yeast.Mapping and functional characterization of the TAF11 interaction with TFIIA.The yeast TAF145 inhibitory domain and TFIIA competitively bind to TATA-binding proteinThe Gcn4p activation domain interacts specifically in vitro with RNA polymerase II holoenzyme, TFIID, and the Adap-Gcn5p coactivator complex.Direct transactivator-transcription factor IID (TFIID) contacts drive yeast ribosomal protein gene transcriptionSp1 and AP2 regulate but do not constitute TATA-less human TAF(II)55 core promoter activity.Distinct regulatory mechanisms of eukaryotic transcriptional activation by SAGA and TFIID.Bicoid functions without its TATA-binding protein-associated factor interaction domains.TFIID-specific yeast TAF40 is essential for the majority of RNA polymerase II-mediated transcription in vivoSpecific variants of general transcription factors regulate germ cell development in diverse organismsIdentification of Genes in Saccharomyces cerevisiae that Are Haploinsufficient for Overcoming Amino Acid Starvation.Molecular genetic dissection of TAF25, an essential yeast gene encoding a subunit shared by TFIID and SAGA multiprotein transcription factorsTranscription elongation factor Spt4 mediates loss of phosphorylated RNA polymerase II transcription in response to DNA damage.A multiplicity of mediators: alternative forms of transcription complexes communicate with transcriptional regulators.A feed forward circuit comprising Spt6, Ctk1 and PAF regulates Pol II CTD phosphorylation and transcription elongation.
P2860
Q22010399-BFD1D6D6-9290-4D20-BE4E-363D3F17C9DCQ24291775-9F8D6146-1ACF-4FE4-B690-683E7E0E24A7Q24302399-5CDA9C44-4782-406D-8B84-49FE3DFA4FD9Q24306731-ABDB93CD-B37D-4D13-95BC-1FEC6771B426Q24554357-C724CAD4-4A03-41DD-950F-3CE496576A11Q24684851-E81B5D3E-E921-45DB-B42D-0434944E1115Q24797549-D4AC3F52-6502-46C6-8276-71C2ED2B6A78Q27329725-F18424BB-3E47-47AA-9C4B-3696045362A1Q27929864-F37B2D4B-B2B0-435C-B1D1-21559233E153Q27930749-C82175AF-7200-4ABF-88A1-C4489F9FB18DQ27931210-78CF618B-6232-4A03-8976-0A3B362158C1Q27931284-786B0E04-70B0-4DA5-B942-D892DFAFD2F3Q27932095-FD7D3209-7050-4D68-9DF0-167374EF3D29Q27935186-09BFD698-1153-40A5-89CB-9DC4A26C6779Q27936204-61E13258-D4E4-44A7-B5EF-BF66D9993877Q27936344-B6C07170-7E16-40A5-AFE6-51B2D3C84A69Q27938450-8517856B-701F-4BA5-90B9-D6E23D59EE84Q27939723-9B7F9B94-16EA-4B9A-8937-AAB5B2E3FC1CQ27939741-005D4505-8B40-4330-9A9A-37691F7D113CQ27940230-08499677-B923-41C4-99C6-82A80533306CQ29620260-6C6B8469-7CD7-457E-BBBC-1BE31608CF9AQ30326652-D53D3A68-9B2A-405E-B908-C86BEF8BB0ACQ30988768-5CC0F3A8-6EAB-4AA5-90C3-B0368BA9BB5CQ32041165-ABA8F293-C960-4C34-9E08-50D235AED98CQ33651485-E08E4810-E716-4914-9F09-D42B0C345967Q33671494-11624B78-E5BB-48FD-A2EA-F1C01C92D59AQ33713693-A9B8B3C3-D8FB-44A6-AB90-2D539E41B308Q33771547-533712EC-C30E-49BC-8A64-E9C4198F7883Q33772811-C1740705-F8A7-408A-9D5D-D9B924CF7BD6Q33832637-F7058AA0-8428-42E2-99D9-B32ECAA35C51Q34460815-B222F3B3-5D8A-4AFA-9980-8699CC9AB358Q34478777-FA0535AD-0F8F-4C8F-9036-0D8ABF911113Q35128380-0A7E48A4-BA1D-49EC-AB9B-39AE82E63BDFQ35207267-84D174C3-03F1-41DF-B0B9-2A1BB156F053Q37202072-28B25176-3C1D-4B46-B6BF-0B78FEEDA232Q37746418-EDB166E9-CFBE-4C0E-B68E-A89F2E242EC6Q39528206-E021C812-844F-4414-980F-1DF920061035Q39676103-01CA86BD-920A-4E5B-9B76-65DB5C303DC1Q39722071-642E74F1-CFF1-4034-AFC7-1C0F1231AEFFQ41892815-2549F1A3-25D6-4086-B7B6-738F1ACB8119
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on December 1996
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Yeast homologues of higher eukaryotic TFIID subunits.
@en
Yeast homologues of higher eukaryotic TFIID subunits.
@nl
type
label
Yeast homologues of higher eukaryotic TFIID subunits.
@en
Yeast homologues of higher eukaryotic TFIID subunits.
@nl
prefLabel
Yeast homologues of higher eukaryotic TFIID subunits.
@en
Yeast homologues of higher eukaryotic TFIID subunits.
@nl
P2093
P2860
P356
P1476
Yeast homologues of higher eukaryotic TFIID subunits.
@en
P2093
S Buratowski
Z Moqtaderi
P2860
P304
14654-14658
P356
10.1073/PNAS.93.25.14654
P407
P577
1996-12-01T00:00:00Z