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)

We have delineated the amino acid to nucleotide contacts made by two interacting dimers of the replication terminator protein (RTP) of Bacillus subtilis with a novel naturally occurring bipolar replication terminus by converting RTP to a site-directed chemical nuclease and mapping its cleavage sites on the terminus. The data show a relatively symmetrical arrangement of the amino acid to base contacts, and a comparison of the bipolar contacts with that of a normal unipolar terminus suggests that the DNA-protein contacts play an important determinative role in generating polarity from structurally symmetrical RTP dimers. The amino acid to nucleotide contacts provided distance constraints that enabled us to build a three-dimensional model of the protein-DNA complex. The model is consistent with features of the bipolar Ter.RTP complex derived from mutational and cross-linking data. The bipolar terminus arrested Escherichia coli DNA replication and DnaB helicase and T7 RNA polymerase in vitro in both orientations. RTP arrested the unwinding of duplex DNA on the bipolar Ter DNA substrate regardless of the length of the duplex DNA. The latter result suggested further that the terminus arrested authentic DNA unwinding by the helicase rather than just translocation of helicase on DNA.
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PMID:Structural and functional analysis of a bipolar replication terminus. Implications for the origin of polarity of fork arrest. 1127 92

The current models that have been proposed to explain the mechanism of replication termination are (i) passive arrest of a replication fork by the terminus (Ter) DNA-terminator protein complex that impedes the replication fork and the replicative helicase in a polar fashion and (ii) an active barrier model in which the Ter-terminator protein complex arrests a fork not only by DNA-protein interaction but also by mechanistically significant terminator protein-helicase interaction. Despite the existence of some evidence supporting in vitro interaction between the replication terminator protein (RTP) and DnaB helicase, there has been continuing debate in the literature questioning the validity of the protein-protein interaction model. The objective of the present work was two-fold: (i) to reexamine the question of RTP-DnaB interaction by additional techniques and different mutant forms of RTP, and (ii) to investigate if a common domain of RTP is involved in the arrest of both helicase and RNA polymerase. The results validate and confirm the RTP-DnaB interaction in vitro and suggest a critical role for this interaction in replication fork arrest. The results also show that the Tyr(33) residue of RTP plays a critical role both in the arrest of helicase and RNA polymerase.
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PMID:A single domain of the replication termination protein of Bacillus subtilis is involved in arresting both DnaB helicase and RNA polymerase. 1131 34

The p44 subunit plays a crucial role in the overall activity of the transcription/DNA repair factor TFIIH: on the one hand its N-terminal domain interacts with and regulates the XPD helicase (, ); on the other hand, as shown in the present study, it participates with the promoter escape reaction. Mutagenesis along with recombinant technology using the baculovirus/insect cells expression system allowed us to define the function of the two structural motifs of the C-terminal moiety of p44: mutations within the C4 zinc finger motif (residues 291-308) prevent incorporation of the p62 subunit within the core TFIIH. Double mutations in the RING finger motif (residues 345-385) allow the synthesis of the first phosphodiester bond by RNA polymerase II, but prevent its escape from the promoter. This highlights the role of transcription factor IIH in the various steps of the transcription initiation process.
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PMID:A role of the C-terminal part of p44 in the promoter escape activity of transcription factor IIH. 1131 35

A cDNA encoding a novel member of the helicase family, MDDX28, has been cloned from a human testis library. This apparently intronless gene was transcribed in all tissues studied. MDDX28 encodes a protein of 540 amino acids, with approximately 30% homology to other helicases over the core region, containing all the conserved DEAD-box helicase motifs. No homologue is known. MDDX28 has RNA and Mg(2+)-dependent ATPase activity. Subcellular localization studies of MDDX28 using oligoclonal antibodies raised against the protein as well as its enhanced green fluorescence protein (EGFP) demonstrated that the protein is localized in the mitochondria and the nucleus. To our knowledge, MDDX28 is the first member of the RNA helicase described with this dual location. The nuclear localization of MDDX28 depended on active RNA polymerase II transcription, suggesting that the protein could be transported to and from the nucleus. This was confirmed further in an interspecies heterokaryon assay, in which MDDX28 was seen to translocate to the nucleus and mitochondria. The mitochondrial uptake of the MDDX28-EGFP-N1 fusion protein was inhibited by carbonyl cyanide p-(trichloromethoxy)phenylhydrazone. Our results indicate that MDDX28 can be transported between the mitochondria and the nucleus.
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PMID:Cloning and characterization of MDDX28, a putative dead-box helicase with mitochondrial and nuclear localization. 1135 Sep 55

RNA helicase A (RHA) is a member of an ATPase/DNA and RNA helicase family and is a homologue of Drosophila maleless protein (MLE), which regulates X-linked gene expression. RHA is also a component of holo-RNA polymerase II (Pol II) complexes and recruits Pol II to the CREB binding protein (CBP). The ATPase and/or helicase activity of RHA is required for CREB-dependent transcription. To further understand the role of RHA on gene expression, we have identified a 50-amino-acid transactivation domain that interacts with Pol II and termed it the minimal transactivation domain (MTAD). The protein sequence of this region contains six hydrophobic residues and is unique to RHA homologues and well conserved. A mutant with this region deleted from full-length RHA decreased transcriptional activity in CREB-dependent transcription. In addition, mutational analyses revealed that several tryptophan residues in MTAD are important for the interaction with Pol II and transactivation. These mutants had ATP binding and ATPase activities comparable to those of wild-type RHA. A mutant lacking ATP binding activity was still able to interact with Pol II. In CREB-dependent transcription, the transcriptional activity of each of these mutants was less than that of wild-type RHA. The activity of the double mutant lacking both functions was significantly lower than that of each mutant alone, and the double mutant had a dominant negative effect. These results suggest that RHA could independently regulate CREB-dependent transcription either through recruitment of Pol II or by ATP-dependent mechanisms.
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PMID:Dual roles of RNA helicase A in CREB-dependent transcription. 1141 26

Gene 4 of bacteriophage T7 encodes a protein (gp4) that can translocate along single-stranded DNA, couple the unwinding of duplex DNA with the hydrolysis of dTTP, and catalyze the synthesis of short RNA oligoribonucleotides for use as primers by T7 DNA polymerase. Electron microscopic studies have shown that gp4 forms hexameric rings, and X-ray crystal structures of the gp4 helicase domain and of the highly homologous RNA polymerase domain of Escherichia coli DnaG have been determined. Earlier biochemical studies have shown that when single-stranded DNA is bound to the hexameric ring, the primase domain remains accessible to free DNA. Given these results, a model was suggested in which the primase active site in the gp4 hexamer is located on the outside of the hexameric ring. We have used electron microscopy and single-particle image analysis to examine T7 gp4, and have determined that the primase active site is located on the outside of the hexameric ring, and therefore provide direct structural support for this model.
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PMID:The primase active site is on the outside of the hexameric bacteriophage T7 gene 4 helicase-primase ring. 1153 31

RNA replication of all positive-strand RNA viruses is closely associated with intracellular membranes. Brome mosaic virus (BMV) RNA replication occurs on the perinuclear region of the endoplasmic reticulum (ER), both in its natural plant host and in the yeast Saccharomyces cerevisiae. The only viral component in the BMV RNA replication complex that localizes independently to the ER is 1a, a multifunctional protein with an N-terminal RNA capping domain and a C-terminal helicase-like domain. The other viral replication components, the RNA polymerase-like protein 2a and the RNA template, depend on 1a for recruitment to the ER. We show here that, in membrane extracts, 1a is fully susceptible to proteolytic digestion in the absence of detergent and thus, a finding consistent with its roles in RNA replication, is wholly or predominantly on the cytoplasmic face of the ER with no detectable lumenal protrusions. Nevertheless, 1a association with membranes is resistant to high-salt and high-pH treatments that release most peripheral membrane proteins. Membrane flotation gradient analysis of 1a deletion variants and 1a segments fused to green fluorescent protein (GFP) showed that sequences in the N-terminal RNA capping module of 1a mediate membrane association. In particular, a region C-terminal to the core methyltransferase homology was sufficient for high-affinity ER membrane association. Confocal immunofluorescence microscopy showed that even though these determinants mediate ER localization, they fail to localize GFP to the narrow region of the perinuclear ER, where full-length 1a normally resides. Instead, they mediate a more globular or convoluted distribution of ER markers. Thus, additional sequences in 1a that are distinct from the primary membrane association determinants contribute to 1a's normal subcellular distribution, possibly through effects on 1a conformation, orientation, or multimerization on the membrane.
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PMID:Identification of sequences in Brome mosaic virus replicase protein 1a that mediate association with endoplasmic reticulum membranes. 1171 27

Chilo iridescent virus (CIV) is the type species for genus Iridovirus, and belongs to the family Iridoviridae. Members of this family are large, isometric, cytoplasmic DNA viruses. Our laboratory has established that CIV replicates productively in the cotton boll weevil, Anthonomus grandis. Given the economic importance of this host and the dearth of knowledge on this virus, we have initiated host-virus interaction and molecular studies on CIV. This report focuses on regulation of transcription in CIV infections. We carried out northern analyses on total cellular RNA from infections of IPRI-CF-124T cells, using a complete genomic library of CIV and several putative gene-specific probes. Our data show a temporal cascade based on analysis of 137 detectable transcripts comprising 38 immediate-early (IE), 34 delayed-early (DE), and 65 late (L) transcripts. Analysis with gene-specific probes supported the cascade pattern. Both helicase and RNA polymerase were immediate-early; major capsid protein was late. The CIV gene expression cascade appears to operate primarily at the transcriptional level. Temporal classes observed are consistent with earlier studies at the polypeptide level and with transcriptional patterns in frog virus 3, genus Ranavirus in the Iridoviridae. Our results provide an important basis for understanding mechanisms driving the CIV temporal cascade.
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PMID:Transcription and temporal cascade in Chilo iridescent virus infected cells. 1176 18

Eukaryotic transcriptional activators have been proposed to function, for the most part, by promoting the assembly of preinitiation complex through the recruitment of the RNA polymerase II transcriptional machinery to the promoter. Previous studies have shown that transcriptional activation is critically dependent on transcription factor IIH (TFIIH), which functions during promoter opening and promoter escape, the steps following preinitiation complex assembly. Here we have analyzed the role of TFIIH in transcriptional activation and show that the excision repair cross-complementing (ERCC) 3 helicase activity of TFIIH plays a regulatory role to stimulate promoter escape in activated transcription. The stimulatory effect of the ERCC3 helicase is observed until approximately 10-nt RNA is synthesized, and the helicase seems to act throughout the entire course of promoter escape. Analyses of the early phase of transcription show that a majority of the initiated complexes abort transcription and fail to escape the promoter; however, the proportion of productive complexes that escape the promoter apparently increases in response to activation. Our results establish that promoter escape is an important regulatory step stimulated by the ERCC3 helicase activity in response to activation and reveal a possible mechanism of transcriptional synergy.
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PMID:The regulatory role for the ERCC3 helicase of general transcription factor TFIIH during promoter escape in transcriptional activation. 1181 77

We have investigated the mode of action of calicheamicin in living cells by using oligonucleotide microarrays to monitor its effects on gene expression across the entire yeast genome. Transcriptional effects were observed as early as 2 min into drug exposure. Among these effects were the upregulation of two nuclear proteins encoding a Y'-helicase (a subtelomerically encoded protein whose function is to maintain telomeres) and a suppressor of rpc10 and rpb40 mutations (both rpc10 and rpb40 encode RNA polymerase subunits). With longer calicheamicin exposure, genes involved in chromatin arrangement, DNA repair and/or oxidative damage, DNA synthesis and cell cycle checkpoint control as well as other nuclear proteins were all differentially expressed. Additionally, ribosomal proteins and a variety of metabolic, biosynthetic, and stress response genes were also altered in their expression.
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PMID:Transcriptional effects of the potent enediyne anti-cancer agent Calicheamicin gamma(I)(1). 1188 39

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