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)

Malondialdehyde, a genotoxic byproduct of lipid peroxidation, reacts with guanine in DNA to form pyrimido[1,2-alpha]purin-10(3H)one (M(1)dG), the first endogenous DNA lesion found to be a target of nucleotide excision repair enzymes. A subpathway of nucleotide excision repair, transcription-coupled repair, is thought to occur when RNA polymerase (RNAP) is arrested at damage in transcribed DNA strands and might function for efficient removal of M(1)dG in active genes. Results presented here show that M(1)dG and its stable, exocyclic analog 1,N(2)-propanodeoxyguanine (PdG), arrest translocation of T7 RNAP and mammalian RNAPII when located in the transcribed strand of a DNA template. M(1)dG paired with thymine is exocyclic and poses a stronger block to transcription than the acyclic N(2)-(3-oxo-1-propenyl)-dG, formed upon cytosine-catalyzed opening of M(1)dG in duplex DNA. PdG is a complete block to RNAPII regardless of base pairing. The elongation factor TFIIS (SII) induces reversal and RNA transcript cleavage by RNAPII arrested at PdG. Thus, arrested RNAPII complexes may be stable at M(1)dG in cells and may resume transcription once the offending adduct is removed. The conclusion from this work is that malondialdehyde adducts in the transcribed strand of expressed genes are strong blocks to RNAPs and are targets for cellular transcription-coupled repair. If so, then M(1)dG, already known to be highly mutagenic in human cells, also may contribute to apoptosis in the developing tissues of individuals with Cockayne's syndrome, a hereditary disorder characterized by transcription-coupled repair deficiency.
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PMID:Malondialdehyde adducts in DNA arrest transcription by T7 RNA polymerase and mammalian RNA polymerase II. 1512 25

New structural studies of RNA polymerase II (Pol II) complexes mark the beginning of a detailed mechanistic analysis of the eukaryotic mRNA transcription cycle. Crystallographic models of the complete Pol II, together with new biochemical and electron microscopic data, give insights into transcription initiation. The first X-ray analysis of a Pol II complex with a transcription factor, the elongation factor TFIIS, supports the idea that the polymerase has a 'tunable' active site that switches between mRNA synthesis and cleavage. The new studies also show that domains of transcription factors can enter polymerase openings, to modulate function during transcription.
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PMID:RNA polymerase II structure: from core to functional complexes. 1519 70

The mechanism for elongation catalyzed by human RNA polymerase II (RNAP II) has been analyzed using millisecond phase transient state kinetics. Here, we apply a running start, two-bond, double-quench protocol. Quenching the reaction with EDTA indicates NTP loading into the active site followed by rapid isomerization. HCl quenching defines the time of phosphodiester bond formation. Model-independent and global kinetic analyses were applied to simulate the RNAP II mechanism for forward elongation through the synthesis of two specific phosphodiester bonds, modeling rate data collected over a wide range of nucleoside triphosphate concentrations. We report adequate two-bond kinetic simulations for the reaction in the presence of TFIIF alone and in the presence of TFIIF+TFIIS, providing detailed insight into the RNAP II mechanism and into processive RNA synthesis. RNAP II extends an RNA chain through a substrate induced-fit mechanism, termed NTP-driven translocation. After rapid isomerization, chemistry is delayed. At a stall point induced by withholding the next templated NTP, RNAP II fractionates into at least two active and one paused conformation, revealed as different forward rates of elongation. In the presence of TFIIF alone or in the presence of TFIIF+TFIIS, rapid rates are very similar; although, with TFIIF alone the complex is more highly poised for forward synthesis. Based on steady-state analysis, TFIIF was thought to suppress transcriptional pausing, but this view is misleading. TFIIF supports elongation and suppresses pausing by stabilizing the post-translocated elongation complex. When TFIIS is present, RNA cleavage and transcriptional restart pathways are supported, but TFIIS has a role in suppression of transient pausing, which is the most important contribution of TFIIS to elongation from a stall position.
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PMID:Transcription factors IIF and IIS and nucleoside triphosphate substrates as dynamic probes of the human RNA polymerase II mechanism. 1535 37

TFIIS, an elongation factor encoded by DST1 in Saccharomyces cerevisiae, stimulates transcript cleavage in arrested RNA polymerase II. Two components of the RNA polymerase II machinery, Med13 (Srb9) and Spt8, were isolated as two-hybrid partners of the conserved TFIIS N-terminal domain. They belong to the Cdk8 module of the Mediator and to a subform of the SAGA co-activator, respectively. Co-immunoprecipitation experiments showed that TFIIS can bind the Cdk8 module and SAGA in cell-free extracts. spt8Delta and dst1Delta mutants were sensitive to nucleotide-depleting drugs and epistatic to null mutants of the RNA polymerase II subunit Rpb9, suggesting that their elongation defects are mediated by Rpb9. rpb9Delta, spt8Delta and dst1Delta were lethal in cells lacking the Rpb4 subunit. The TFIIS N-terminal domain is also strictly required for viability in rpb4Delta, although it is not needed for binding to RNA polymerase II or for transcript cleavage. It is proposed that TFIIS and the Spt8-containing form of SAGA co-operate to rescue RNA polymerase II from unproductive elongation complexes, and that the Cdk8 module temporarily blocks transcription during transcript cleavage.
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PMID:Members of the SAGA and Mediator complexes are partners of the transcription elongation factor TFIIS. 1535 73

The crystal structure of the complete 12 subunit RNA polymerase (pol) II bound to a transcription bubble and product RNA reveals incoming template and nontemplate DNA, a seven base pair DNA/RNA hybrid, and three nucleotides each of separating DNA and RNA. The complex adopts the posttranslocation state and accommodates a cocrystallized nucleoside triphosphate (NTP) substrate. The NTP binds in the active site pore at a position to interact with a DNA template base. Residues surrounding the NTP are conserved in all cellular RNA polymerases, suggesting a universal mechanism of NTP selection and incorporation. DNA-DNA and DNA-RNA strand separation may be explained by pol II-induced duplex distortions. Four protein loops partition the active center cleft, contribute to embedding the hybrid, prevent strand reassociation, and create an RNA exit tunnel. Binding of the elongation factor TFIIS realigns RNA in the active center, possibly converting the elongation complex to an alternative state less prone to stalling.
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PMID:Complete RNA polymerase II elongation complex structure and its interactions with NTP and TFIIS. 1561 Jul 38

Uninduced heat shock genes are poised for rapid activation, with RNA polymerase II (Pol II) transcriptionally engaged, but paused or stalled, within the promoter-proximal region. Upon heat shock, this Pol II is promptly released from the promoter region and additional Pol II and transcription factors are robustly recruited to the gene. Regulation of the heat shock response relies upon factors that modify the efficiency of elongation through the initially transcribed sequence. Here, we report that Pol II is susceptible to transcription arrest within the promoter-proximal region of Drosophila hsp70 and that transcript cleavage factor TFIIS is essential for rapid induction of hsp70 RNA. Moreover, using a tandem RNAi-ChIP assay, we discovered that TFIIS is not required to establish the stalled Pol II, but that TFIIS is critical for efficient release of Pol II from the hsp70 promoter region and the subsequent recruitment of additional Pol II upon heat induction.
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PMID:Efficient release from promoter-proximal stall sites requires transcript cleavage factor TFIIS. 1562 21

Termination by RNA polymerase III (Pol III) produces RNAs whose 3' oligo(U) termini are bound by La protein, a chaperone that protects RNAs from 3' exonucleases and promotes their maturation. Multiple reports indicate that yeasts use La-dependent and -independent pathways for tRNA maturation, with defective pre-tRNAs being most sensitive to decay and most dependent on La for maturation and function. The Rpc11p subunit of Pol III shows homology with the zinc ribbon of TFIIS and is known to mediate RNA 3' cleavage and to be important for termination. We used a La-dependent opal suppressor, tRNASerUGAM, which suppresses ade6-704 and the accumulation of red pigment, to screen Schizosaccaromyces pombe for rpc11 mutants that increase tRNA-mediated suppression. Analyses of two zinc ribbon mutants indicate that they are deficient in Pol III RNA 3' cleavage activity and produce pre-tRNASerUGAM transcripts with elongated 3'-oligo(U) tracts that are better substrates for La. A substantial fraction of pre-tRNASerUGAM contains too few 3' Us for efficient La binding and appears to decay in wild-type cells but has elongated oligo(U) tracts and matures along the La-dependent pathway in the mutants. The data indicate that Rpc11p limits RNA 3'-U length and that this significantly restricts pre-tRNAs to a La-independent pathway of maturation in fission yeast.
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PMID:Mutations in the RNA polymerase III subunit Rpc11p that decrease RNA 3' cleavage activity increase 3'-terminal oligo(U) length and La-dependent tRNA processing. 1563 64

TFIIS is a transcription elongation factor that has been extensively studied biochemically. Although the in vitro mechanisms by which TFIIS stimulates RNA transcript cleavage and polymerase read-through have been well characterized, its in vivo roles remain unclear. To better understand TFIIS function in vivo, we have examined its role during Gal4-mediated activation of the Saccharomyces cerevisiae GAL1 gene. Surprisingly, TFIIS is strongly associated with the GAL1 upstream activating sequence. In addition, TFIIS recruitment to Gal4-binding sites is dependent on Gal4, SAGA, and Mediator but not on RNA polymerase II (Pol II). The association of TFIIS is also necessary for the optimal recruitment of TATA-binding protein and Pol II to the GAL1 promoter. These results provide strong evidence that TFIIS plays an important role in the initiation of transcription at GAL1 in addition to its well-characterized roles in transcription elongation.
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PMID:Evidence that the elongation factor TFIIS plays a role in transcription initiation at GAL1 in Saccharomyces cerevisiae. 1576 71

A number of proteins and drugs have been implicated in the process of transcriptional elongation by RNA polymerase (Pol) II, but the factors that govern the elongation rate (nucleotide additions per min) and processivity (nucleotide additions per initiation event) in vivo are poorly understood. Here, we show that a mutation in the Rpb2 subunit of Pol II reduces both the elongation rate and processivity in vivo. In contrast, none of the putative elongation factors tested affect the elongation rate, although mutations in the THO complex and in Spt4 significantly reduce processivity. The drugs 6-azauracil and mycophenolic acid reduce both the elongation rate and processivity, and this processivity defect is aggravated by mutations in Spt4, TFIIS, and CTDK-1. Our results suggest that, in vivo, a reduced rate of Pol II elongation leads to premature dissociation along the chromatin template and that Pol II processivity can be uncoupled from elongation rate.
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PMID:Distinction and relationship between elongation rate and processivity of RNA polymerase II in vivo. 1578 Sep 39

In the cell, RNA polymerase II (pol II) efficiently transcribes DNA packaged into nucleosomes, but in vitro encounters with the nucleosomes induce catalytic inactivation (arrest) of the pol II core enzyme. To determine potential mechanisms making nucleosomes transparent to transcription in vivo, we analyzed the nature of the nucleosome-induced arrest. We found that the arrests have been detected mostly at positions of strong intrinsic pause sites of DNA. The transient pausing makes pol II vulnerable to arrest, which involves backtracking of the elongation complex for a considerable distance on DNA. The histone-DNA contacts reestablished in front of pol II stabilize backtracked conformation of the polymerase. In agreement with this mechanism, blocking of backtracking prevents nucleosome-induced arrest. Transcript cleavage factor TFIIS reactivates the backtracked complexes and promotes pol II transcription through the nucleosome. Our findings establish the crucial role of elongation factors that suppress pol II pausing and backtracking for transcription in the context of chromatin.
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PMID:Nature of the nucleosomal barrier to RNA polymerase II. 1580 12

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