EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Activators of transcription are known to also play an important and direct role in activating DNA replication. However, the mechanism whereby they stimulate replication has remained elusive. One model suggests that, in the context of replication origins, transcriptional activators work by interacting with replication factors. We show that a defined, single interaction between a DNA-bound derivative of the activator Gal4 and Gal11P, a mutant form of the RNA polymerase II holoenzyme component Gal11, suffices for stimulating DNA replication as it does for transcription. Moreover, recruitment of TBP, which can activate transcription from a gene promoter, also stimulates DNA replication from an origin site. These results strongly argue that transcriptional activators may not necessarily need to contact DNA replication factors directly, but can stimulate replication by recruiting the RNA polymerase II transcription complex to DNA.
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PMID:Activation of DNA replication in yeast by recruitment of the RNA polymerase II transcription complex. 1038 58

snRNA gene transcription is activated in part by recruitment of SNAP(c) to the core promoter through protein-protein contacts with the POU domain of the enhancer-binding factor Oct-1. We show that a mini-SNAP(c) consisting of a subset of SNAP(c) subunits is capable of directing both RNA polymerase II (Pol II) and Pol III snRNA gene transcription. Mini-SNAP(c) cannot be recruited by Oct-1, but binds as efficiently to the promoter as SNAP(c) together with Oct-1 and directs activated RNA Pol III transcription. Thus, SNAP(c) represses its own binding to DNA, and repression is relieved by interactions with the Oct-1 POU domain that promote cooperative binding. We have shown previously that TBP also represses its own binding, and in that case repression is relieved by cooperative interactions with SNAP(c). This may represent a general mechanism to ensure that core promoter-binding factors, which have strikingly slow off-rates, are recruited specifically to promoter sequences rather than to cryptic-binding sites in the genome.
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PMID:SNAP(c): a core promoter factor with a built-in DNA-binding damper that is deactivated by the Oct-1 POU domain. 1042 33

Cell-free transcription of archaeal promoters is mediated by two archaeal transcription factors, aTBP and TFB, which are orthologues of the eukaryotic transcription factors TBP and TFIIB. Using the cell-free transcription system described for the hyperthermophilic Archaeon Pyrococcus furiosus by Hethke et al., the temperature limits and template topology requirements of archaeal transcription were investigated. aTBP activity was not affected after incubation for 1 hr at 100 degrees. In contrast, the half-life of RNA polymerase activity was 23 min and that of TFB activity was 3 min. The half-life of a 328-nt RNA product was 10 min at 100 degrees. Best stability of RNA was observed at pH 6, at 400 mm K-glutamate in the absence of Mg(2+) ions. Physiological concentrations of K-glutamate were found to stabilize protein components in addition, indicating that salt is an important extrinsic factor contributing to thermostability. Both RNA and proteins were stabilized by the osmolyte betaine at a concentration of 1 m. The highest activity for RNA synthesis at 95 degrees was obtained in the presence of 1 m betaine and 400 mm K-glutamate. Positively supercoiled DNA, which was found to exist in Pyrococcus cells, can be transcribed in vitro both at 70 degrees and 90 degrees. However, negatively supercoiled DNA was the preferred template at all temperatures tested. Analyses of transcripts from plasmid topoisomers harboring the glutamate dehydrogenase promoter and of transcription reactions conducted in the presence of reverse gyrase indicate that positive supercoiling of DNA inhibits transcription from this promoter.
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PMID:Cell-free transcription at 95 degrees: thermostability of transcriptional components and DNA topology requirements of Pyrococcus transcription. 1043 May 63

TFIID is a general transcription factor required for the assembly of the transcription machinery on most eukaryotic promoters transcribed by RNA polymerase II. Although the TATA-binding subunit (TBP) of TFIID is able to support core promoter and activator-dependent transcription under some circumstances, the roles of TBP-associated factors (TAF(II)s) in TFIID-mediated activation remain unclear. To define the evolutionarily conserved function of TFIID and to elucidate the roles of TAF(II)s in gene activation, we have cloned the mouse TAF(II)55 subunit of TFIID and further isolated mouse TFIID from a murine FM3A-derived cell line that constitutively expresses FLAG-tagged mouse TAF(II)55. Both mouse and human TFIIDs are capable of mediating transcriptional activation by Gal4 fusions containing different activation domains in a highly purified human cell-free transcription system devoid of TFIIA and Mediator. Although TAF(II)-independent activation by Gal4-VP16 can also be observed in this highly purified human transcription system with either mouse or yeast TBP, TAF(II)s are strictly required for estrogen receptor-mediated activation independently of the core promoter sequence. In addition, TAF(II)s are necessary for transcription from a preassembled chromatin template. These findings clearly demonstrate an essential role of TAF(II)s as a transcriptional coactivator for estrogen receptor and in chromatin transcription.
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PMID:Isolation of mouse TFIID and functional characterization of TBP and TFIID in mediating estrogen receptor and chromatin transcription. 1043 27

The CDK9 kinase in association with Cyclin T is a component of the transcription positive-acting complex pTEFb which facilitates the transition from abortive to productive transcription elongation by phosphorylating the carboxyl-terminal domain of RNA polymerase II. The Cyclin T1/CDK9 complex is implicated in Tat transactivation, and it has been suggested that Tat functions by recruiting this complex to RNAPII through cooperative binding to RNA. Here, we demonstrate that targeted recruitment of Cyclin T1/CDK9 kinase complex to specific promoters, through fusion to a DNA-binding domain of either Cyclin T1 or CDK9 kinase, stimulates transcription in vivo. Transcriptional enhancement was dependent on active CDK9, as a catalytically inactive form had no transcriptional effect. We determined that, unlike conventional activators, DNA-bound CDK9 does not activate enhancerless TATA-promoters unless TBP is overexpressed, suggesting that CDK9 acts in vivo at a step subsequent to TFIID recruitment DNA-bound. Finally, we determined that CDK9-mediated transcriptional activation is mediated by preferentially stimulating productive transcription elongation.
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PMID:Transcriptional regulation by targeted recruitment of cyclin-dependent CDK9 kinase in vivo. 1046 4

Basal transcription factor TFIID comprises the TATA-box-binding protein, TBP, and associated factors, the TAF(II)s. Previous studies have implicated TAF(II)250 and TAF(II)150 in core promoter selectivity of RNA polymerase II. Here, we have used a random DNA binding site selection procedure to identify target sequences for these TAFs. Individually, neither TAF(II)250 nor TAF(II)150 singles out a clearly constrained DNA sequence. However, a TAF(II)250-TAF(II)150 complex selects sequences that match the Initiator (Inr) consensus. When in a trimeric complex with TBP, these TAFs select Inr sequences at the appropriate distance from the TATA-box. Point mutations that inhibit binding of the TAF(II)250-TAF(II)150 complex also impair Inr function in reconstituted basal transcription reactions, underscoring the functional relevance of Inr recognition by TAFs. Surprisingly, the precise DNA sequence at the start site of transcription influences transcriptional regulation by the upstream activator Sp1. Finally, we found that TAF(II)150 specifically binds to four-way junction DNA, suggesting that promoter binding by TFIID may involve recognition of DNA structure as well as primary sequence. Taken together, our results establish that TAF(II)250 and TAF(II)150 bind the Inr directly and that Inr recognition can determine the responsiveness of a promoter to an activator.
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PMID:DNA binding site selection by RNA polymerase II TAFs: a TAF(II)250-TAF(II)150 complex recognizes the initiator. 1046 61

Transcription factor (TF) IIIB recruits RNA polymerase (pol) III for specific initiation of transcription. All three subunits of TFIIIB, TBP, Brf (the TFIIB-related subunit) and B", are required for transcription of supercoiled and linear duplex DNA, but we show here that B" is non-essential on a promoter that has been partly pre-opened by unpairing a short segment of the transcription bubble. These findings expose a striking similarity between transcriptional initiation by pol II, pol III and bacterial RNA polymerases: a preformed single-stranded DNA bubble upstream of the transcriptional start removes the dependence of pol II on TFIIE, TFIIH and ATP hydrolysis, and the dependence of pol III on B"; the favored placement of the transcription bubble for B"-independent transcription by pol III overlaps a DNA segment that interacts sequence specifically as single-stranded DNA with the sigma(70 )initiation subunit of Escherichia coli RNA polymerase holoenzyme.
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PMID:A minimal RNA polymerase III transcription system. 1048 56

SWI/SNF is a chromatin remodeling complex that facilitates expression of a number of yeast genes. Here we demonstrate that SWI/SNF can be recruited from yeast nuclear extracts by a transcriptional activator. Recruitment is dependent on an activation domain but not on promoter sequences, TBP, or RNA polymerase II holoenzyme. We also show that acidic activation domains can target SWI/SNF remodeling activity. These results demonstrate that SWI/SNF activity can be targeted by gene-specific activators and that this recruitment can occur independently of Pol II holoenzyme.
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PMID:Recruitment of the SWI/SNF chromatin remodeling complex by transcriptional activators. 1050 94

Recently the definition of the metazoan RNA polymerase II and archaeal core promoters has been expanded to include a region immediately upstream of the TATA box called the B recognition element (BRE), so named because eukaryal transcription factor TFIIB and its archaeal orthologue TFB interact with the element in a sequence-specific manner. Here we present the 2.4-A crystal structure of archaeal TBP and the C-terminal core of TFB (TFB(c)) in a complex with an extended TATA-box-containing promoter that provides a detailed picture of the stereospecific interactions between the BRE and a helix-turn-helix motif in the C-terminal cyclin repeat of TFB(c). This interaction is important in determining the level of basal transcription and explicitly defines the direction of transcription.
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PMID:The structural basis for the oriented assembly of a TBP/TFB/promoter complex. 1057 Jan 30

The SAGA complex of Saccharomyces cerevisiae is required for the transcription of many RNA polymerase II-dependent genes. Previous studies have demonstrated that SAGA possesses histone acetyltransferase activity, catalyzed by the SAGA component Gcn5. However, the transcription of many genes, although SAGA dependent, is Gcn5 independent, suggesting the existence of distinct SAGA activities. We have studied the in vivo role of two other SAGA components, Spt3 and Spt20, at the well-characterized GAL1 promoter. Our results demonstrate that both Spt3 and Spt20 are required for the binding of TATA-binding protein but not of the activator Gal4 and that this role is Gcn5 independent. These results suggest a coactivator role for Spt3 and Spt20 in the recruitment of TBP.
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PMID:The Spt components of SAGA facilitate TBP binding to a promoter at a post-activator-binding step in vivo. 1058 1

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