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Query: UNIPROT:P20226 (
TATA-binding protein
)
1,297
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The transcription factors TFIID and SAGA are multi-subunit complexes involved in transcription by RNA polymerase II. TFIID and SAGA contain common
TATA-binding protein
(
TBP
)-associated factor (
TAF
(II)) subunits and each complex contains a subunit with histone acetyltransferase activity. These observations have raised questions about whether the functions of the two complexes in vivo are unique or overlapping. Here we use genome-wide expression analysis to investigate how expression of the yeast genome depends on both shared and unique subunits of these two complexes. We find that expression of most genes requires one or more of the common
TAF
(II) subunits, indicating that the functions of TFIID and SAGA are widely required for gene expression. Among the subunits shared by TFIID and SAGA are three histone-like
TAF
(II)s, which have been proposed to form a sub-complex and mediate a common function in global transcription. Unexpectedly, we find that the histone-like
TAF
(II)s have distinct roles in expression of the yeast genome. Most importantly, we show that the histone acetylase components of TFIID and SAGA (
TAF
(II)145 and Gcn5) are functionally redundant, indicating that expression of a large fraction of yeast genes can be regulated through the action of either complex.
...
PMID:Redundant roles for the TFIID and SAGA complexes in global transcription. 1086 29
Protein-protein interactions between human heat shock transcription factor 1 (hHSF1) and general transcription factors TFIIA-gamma, TFIIB,
TBP
,
TAF
(II)32, and TAF(II)55 and positive coactivator PC4 were characterized in order to identify potential targets of contact in the transcriptional preinitiation complex. These contacts represent one of the final steps in the signal transfer of heat stress to the transcriptional apparatus.
TATA-binding protein
(
TBP
) and transcription factor IIB (TFIIB) were identified as major targets for HSF1 transcriptional activation domains AD1 and AD2 based on in vitro interaction assays.
TBP
showed affinity for AD2 and a fragment containing AD1, while the core domain of TFIIB interacted primarily with the AD1 fragment. Interactions were also detected between full-length HSF1 and the small subunit (gamma) of TFIIA. PC4 interacted weakly with HSF2 and showed even less affinity for HSF1. Coimmunoprecipitation of transiently expressed
TBP
in HeLa cells demonstrated that HSF1 AD2 and AD1+AD2 are able to bind
TBP
in vivo. Assays based on transcriptional interference confirmed predictions that both
TBP
and TFIIB can interact with HSF1 activation domains in HeLa cells. The negative regulatory region (NR) of HSF1 did not interact with any general factors tested in vitro but did bind TFIID in nuclear extracts through contacts that probably involve TATA associated proteins (TAFs). These results suggest a model for transcriptional regulation by HSF1 that involves a shift between formation of dysfunctional TFIID complexes with the NR and transcriptionally competent complexes with the C-terminal activation domains.
...
PMID:Potential targets for HSF1 within the preinitiation complex. 1100 81
Neuronal intranuclear inclusions have become the neuropathological signature of the CAG repeat diseases, although their cytotoxicity is a matter of controversy. It has been demonstrated that the inclusions in dentatorubral-pallidoluysian atrophy (DRPLA) and Machado-Joseph disease (MJD) were immunopositive for several transcription factors such as
TATA-binding protein
(
TBP
), TBP-associated factor (
TAF
(II)130), Sp1, cAMP-responsive element-binding protein (CREB) and CREB-binding protein, suggesting that neuronal degeneration in polyglutamine diseases may result from nuclear depletion of transcription factors containing the glutamine-rich domain. It was also revealed that, in the DRPLA brain, expanded polyglutamine stretches were diffusely accumulated in neuronal nucleoplasm. This nuclear pathology involved many neurons in various nervous system regions, such as the cerebral cortex, thalamus, substantia nigra, pontine nuclei, reticular formation and inferior olive, in addition to the previously recognized affected regions. The diffuse nuclear labeling was also detected in MJD, Huntington's disease, and spinal and bulbar muscular atrophy, suggesting that this nuclear pathology may be a characteristic feature and may exert certain influence on certain nuclear functions of many neurons in the CAG repeat diseases.
...
PMID:Pathology of CAG repeat diseases. 1121 Oct 58
Preinitiation complex assembly is nucleated by the binding of TFIID to the promoters of protein coding genes transcribed by RNA polymerase II. TFIID is comprised of the
TATA-binding protein
(
TBP
) and
TBP
-associated factors (
TAF
(II)s). We investigated the transcription properties of
TBP
and TFIID on chromatin templates. On naked templates both
TBP
and purified TFIID are able to initiate basal transcription. However, on chromatin templates only
TBP
mediates transcription initiation in a heat-treated extract, whereas TFIID does not. Moreover,
TBP
-mediated chromatin transcription is blocked in a nontreated extract. These observations suggest that a chromatin-targeted repressor is present in crude extracts and that chromatin per se is not refractory to transcription mediated by
TBP
. As
TBP
can function through
TAF
(II)-independent and
TAF
(II)-dependent pathways, the repression of
TBP
-mediated basal transcription may be an additional level to the control of Pol II transcription initiation on chromatin.
...
PMID:Chromatin is permissive to TATA-binding protein (TBP)-mediated transcription initiation. 1127 78
NFATp is one member of a family of transcriptional activators that regulate the expression of cytokine genes. To study mechanisms of NFATp transcriptional activation, we established a reconstituted transcription system consisting of human components that is responsive to activation by full-length NFATp. The TATA-associated factor (
TAF
(II)) subunits of the TFIID complex were required for NFATp-mediated activation in this transcription system, since
TATA-binding protein
(
TBP
) alone was insufficient in supporting activated transcription. In vitro interaction assays revealed that human
TAF
(II)130 (hTAF(II)130) and its Drosophila melanogaster homolog dTAF(II)110 bound specifically and reproducibly to immobilized NFATp. Sequences contained in the C-terminal domain of NFATp (amino acids 688 to 921) were necessary and sufficient for hTAF(II)130 binding. A partial TFIID complex assembled from recombinant hTBP, hTAF(II)250, and hTAF(II)130 supported NFATp-activated transcription, demonstrating the ability of hTAF(II)130 to serve as a coactivator for NFATp in vitro. Overexpression of hTAF(II)130 in Cos-1 cells inhibited NFATp activation of a luciferase reporter. These studies demonstrate that hTAF(II)130 is a coactivator for NFATp and represent the first biochemical characterization of the mechanism of transcriptional activation by the NFAT family of activators.
...
PMID:Human Taf(II)130 is a coactivator for NFATp. 1131 76
c-Jun is an oncoprotein that activates transcription of many genes involved in cell growth and proliferation. We studied the mechanism of transcriptional activation by human c-Jun in a human RNA polymerase II transcription system composed of highly purified recombinant and native transcription factors. Transcriptional activation by c-Jun depends on the
TATA-binding protein
(
TBP
)-associated factor (
TAF
) subunits of transcription factor IID (TFIID). Protein-protein interaction assays revealed that c-Jun binds with high specificity to the largest subunit of human TFIID, TAF(II)250. The region of TAF(II)250 bound by c-Jun lies in the N-terminal 163 amino acids. This same region of TAF(II)250 binds to
TBP
and represses its interaction with TATA boxes, thereby decreasing DNA binding by TFIID. We hypothesized that c-Jun is capable of derepressing the effect of the TAF(II)250 N terminus on TFIID-driven transcription. In support of this hypothesis, we found that c-Jun increased levels of TFIID-driven transcription in vitro when added at high concentrations to a DNA template lacking activator protein 1 (AP-1) sites. Moreover, c-Jun blocked the repression of
TBP
DNA binding caused by the N terminus of TAF(II)250. In addition to revealing a mechanism by which c-Jun activates transcription, our studies provide the first evidence that an activator can bind directly to the N terminus of TAF(II)250 to derepress RNA polymerase II transcription in vitro.
...
PMID:c-Jun binds the N terminus of human TAF(II)250 to derepress RNA polymerase II transcription in vitro. 1131 4
Human transcription factor TFIID contains the
TATA-binding protein
(
TBP
) and several
TBP
-associated factors (
TAF
(II)s). To elucidate the structural organization and function of TFIID, we expressed and characterized the product of a cloned cDNA encoding human TAF(II)135 (hTAF(II)135). Comparative far Western blots have shown that hTAF(II)135 interacts strongly with hTAF(II)20, moderately with hTAF(II)150, and weakly with hTAF(II)43 and hTAF(II)250. Consistent with these observations and with sequence relationships of hTAF(II)20 and hTAF(II)135 to histones H2B and H2A, respectively, TFIID preparations that contain higher levels of hTAF(II)135 also contain higher levels of hTAF(II)20, and the interaction between hTAF(II)20 and hTAF(II)135 is critical for human TFIID assembly in vitro. From a functional standpoint, hTAF(II)135 has been found to interact strongly and directly with hTFIIA and (within a complex that also contains hTBP and hTAF(II)250) to specifically cooperate with TFIIA to relieve TAF(II)250-mediated repression of
TBP
binding and function on core promoters. Finally, we report a functional synergism between
TAF
(II)s and the TRAP/Mediator complex in activated transcription, manifested as hTAF(II)-mediated inhibition of basal transcription and a consequent TRAP requirement for both a high absolute level of activated transcription and a high and more physiological activated/basal transcription ratio. These results suggest a dynamic TFIID structure in which the switch from a basal hTAF(II)-enhanced repression state to an activator-mediated activated state on a promoter may be mediated in part through activator or coactivator interactions with hTAF(II)135.
...
PMID:Positive and negative TAF(II) functions that suggest a dynamic TFIID structure and elicit synergy with traps in activator-induced transcription. 1156 72
Activation of RNA-polymerase-II-dependent transcription involves conversion of signals provided by gene-specific activator proteins into the synthesis of messenger RNA. This conversion requires dynamic structural changes in chromatin and assembly of general transcription factors (GTFs) and RNA polymerase II at core promoter sequence elements surrounding the transcription start site of genes. One hallmark of transcriptional activation is the interaction of DNA-bound activators with coactivators such as the
TATA-box binding protein
(
TBP
)-associated factors (
TAF
(II)s) within the GTF TFIID. TAF(II)250 possesses a variety of activities that are likely to contribute to the initial steps of RNA polymerase II transcription. TAF(II)250 is a scaffold for assembly of other
TAF
(II)s and
TBP
into TFIID, TAF(II)250 binds activators to recruit TFIID to particular promoters, TAF(II)250 regulates binding of
TBP
to DNA, TAF(II)250 binds core promoter initiator elements, TAF(II)250 binds acetylated lysine residues in core histones, and TAF(II)250 possesses protein kinase, ubiquitin-activating/conjugating and acetylase activities that modify histones and GTFs. We speculate that these activities achieve two goals--(1) they aid in positioning and stabilizing TFIID at particular promoters, and (2) they alter chromatin structure at the promoter to allow assembly of GTFs--and we propose a model for how TAF(II)250 converts activation signals into active transcription.
...
PMID:TAF(II)250: a transcription toolbox. 1168 93
Differentiation in vitro of mouse F9 embryonal carcinoma (EC) cells to the parietal endoderm (PE) mimics processes of development of the early mouse embryo. This differentiation is accompanied by a dramatic down-regulation of all genes transcribed by RNA polymerase III (pol III). Complementation of extracts from cells, differentiated for various time periods with purified pol III transcription factors show for the first time that TFIIIC1 can substantially restore this impaired transcription, particularly in the early stages of differentiation. At later stages (day 7) the TBP (
TATA-binding protein
)-
TAF
complex, TFIIIBbeta, may also become limiting, which can contribute to but cannot account for the reduced transcription of type 2 promoters in PE cells. Because TFIIIBbeta is not required for the expression of type 3 promoters, other components must necessarily be involved, and our results show that U6 transcription can significantly be reactivated by TFIIIC1. By employing a variant type 3 promoter construct, which essentially requires a mutant form of TBP (TBP-DR2), we show that TBP is not limiting in PE extracts. The partial purification of pol III transcription factors from PE and EC cells revealed that TFIIIC2 activity could be purified from both cell types, whereas TFIIIC1 activity was dramatically reduced in extracts from PE cells.
...
PMID:The activity of transcription factor IIIC1 is impaired during differentiation of F9 cells. 1174 93
Type I interferon (IFN) stimulates transcription through a heteromeric transcription factor that contains tyrosine-phosphorylated STAT2. We show that STAT2 recruits histone acetyltransferases (HAT) through its transactivation domain, resulting in localized transient acetylation of histones. GCN5, but not p300/CBP or PCAF, is required for STAT2 function. However, GCN5 function is impaired by the transcriptional antagonist, adenovirus E1A oncoprotein. The TFIID component
TAF
(II)130 potentiates STAT2 function, but TAF(II)28 or the HAT activity of TAF(II)250 do not, and transcriptional induction can proceed independently of the
TATA-binding protein
, TBP. Moreover, IFN-stimulated transcription was resistant to poliovirus-targeted degradation by TBP, and continued despite host-cell transcriptional shutoff during poliovirus infection. We conclude that a non-classical transcriptional mechanism combats an anticellular action of poliovirus, through a TBP-free
TAF
-containing complex and GCN5.
...
PMID:IFN-Stimulated transcription through a TBP-free acetyltransferase complex escapes viral shutoff. 1180 63
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