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)

Cytochrome d has been postulated to be the "respiratory protection" oxidase of Azotobacter vinelandii, allowing this organism to fix nitrogen under aerobic growth conditions. We have previously cloned and characterized the structural genes for the A. vinelandii cytochrome d (cydA and cydB). The cyd genes are co-transcribed, yielding an mRNA of approximately 3.6 kilobase pairs. The level of the cyd message was 2-3-fold higher in cells that were fixing nitrogen, as compared with non-nitrogen-fixing cells. RNase protection analysis was used to determine the transcriptional start site at 275 bases upstream of the initiator ATG of cydA, and this start site was the same for nitrogen-fixing and non-nitrogen-fixing cells. The cyd promoter has sequence similarities to the canonical Escherichia coli promoters, which are transcribed by the major sigma 70 form of RNA polymerase. Plasmid-borne lacZ transcriptional fusions were constructed, using approximately 650 base pairs of 5'-upstream sequences of the cyd structural genes. This region had a strong promoter activity which was further up-regulated 1.5-2.5-fold upon the induction of nitrogen fixation. The cyd-lacZ fusions were characterized in a nifA- as well as an ntrA- background. Mutations in neither of these nif regulatory genes affected the constitutive expression of cyd under non-nitrogen-fixing conditions. However, the up-regulation of this promoter during the induction of nitrogen fixation was abolished only in the ntrA- background. Based on these results, the cytochrome d promoter of A. vinelandii belongs to a new class of nitrogen-regulated promoters which, unlike the authentic nif genes, does not require the ntrA gene product for its expression. The up-regulation of this promoter during nitrogen fixation, however, requires the ntrA gene product.
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PMID:Transcriptional regulation of cytochrome d in nitrogen-fixing Azotobacter vinelandii. Evidence that up-regulation during N2 fixation is independent of nifA but dependent on ntrA. 166 Apr 68

Nuclear runoff transcription studies revealed nearly equivalent sense and antisense transcription across exon 1 of the N-myc locus. Antisense primary transcription initiates at multiple sites in intron 1 and gives rise to stable polyadenylated and nonpolyadenylated transcripts. This pattern of antisense transcription, which is directed by RNA polymerase II, is independent of gene amplification and cell type. The nonpolyadenylated antisense transcripts have 5' ends which are complementary to the 5' ends of the N-myc sense mRNA. We determined, by using an RNase protection technique designed to detect in vivo duplexes, that most of the cytoplasmic nonpolyadenylated antisense RNA exists in an RNA-RNA duplex with approximately 5% of the sense N-myc mRNA. Duplex formation appeared to occur with only a subset of the multiple forms of the N-myc mRNA, with the precise transcriptional initiation site of the RNA playing a role in determining this selectivity. Cloning of each strand of the RNA-RNA duplex revealed that most duplexes included both exon 1 and intron 1 sequences, suggesting that duplex formation could modulate RNA processing by preserving a population of N-myc mRNA which retains intron 1.
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PMID:N-myc mRNA forms an RNA-RNA duplex with endogenous antisense transcripts. 169 23

The variant-specific surface glycoprotein (VSG) gene 221 of Trypanosoma brucei is transcribed as part of a 60 kb expression site (ES). We have identified the promoter controlling this multigene transcription unit by the use of 221 chromosome-enriched DNA libraries and VSG gene 221 expression site specific transcripts. The start of transcription was determined by hybridization and RNase protection analysis of nascent RNA. The 5' ends of the major transcripts coming from the initiation region map at nucleotide sequences that do not strongly resemble rRNA transcriptional starts even though the transcripts are synthesized by an RNA polymerase highly resistant to alpha-amanitin. The cloned VSG gene 221 ES transcription initiation region promotes high CAT gene expression, when reintroduced by electroporation into T. brucei. We show that the activity of this expression site is controlled at or near transcription initiation in bloodstream trypanosomes. The 221 ES is inactivated without any sequence alteration within 1.4 kb of the transcription start site. This excludes mechanisms of promoter inactivation involving DNA rearrangements in the vicinity of the transcription start site, e.g. promoter inversion or conversion.
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PMID:The promoter for a variant surface glycoprotein gene expression site in Trypanosoma brucei. 169 65

It has been reported (Iborra et al. (1979) J. Biol. Chem. 254, 10920-10924) that the third and the fifth largest subunit of yeast RNA polymerase I exhibit ribonuclease H activity. The authors suggested that the third largest subunit is identical with the chromatin-associated ribonuclease H49, the putative yeast equivalent of bovine ribonuclease H IIb. Although the third largest subunit of calf thymus RNA polymerase I and ribonuclease H IIb display nearly identical molecular masses under denaturing conditions, serological analysis reveals that, in contrast to their counterparts in yeast, these mammalian proteins are distinct entities. Interestingly, sera from some patients with mixed connective tissue disease which contain antibodies directed against RNA polymerase I, also react with ribonuclease H IIb epitopes. This observation suggests that a protein displaying ribonuclease H IIb antigenicity could be associated with RNA polymerase I. Additional indications supporting this conclusion are discussed.
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PMID:Class II ribonuclease H comigrates with, but is distinct from, the third largest subunit of calf thymus RNA polymerase I. 169 96

A small-scale plasmid preparation is described that is useful for a variety of procedures from double-stranded sequencing to in vitro transcription. No specialized equipment or reagents are required. The preparation of plasmid DNA does not require the use of RNase; instead the larger RNAs are precipitated with 2.5 M ammonium acetate. The resulting plasmid DNA is used routinely for double-stranded sequencing with the Klenow fragment of DNA polymerase and has been used for generating deletions with exonuclease III. In addition, the plasmid DNA has been used to generate transcripts with T7 RNA polymerase that translate well in reticulocyte lysate.
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PMID:A small-scale plasmid preparation yielding DNA suitable for double-stranded sequencing and in vitro transcription. 170 92

It is generally assumed that the machinery that transcribes genes is composed entirely of polypeptides. However, in vitro transcription by silkworm RNA polymerase III requires a transcription factor that is not a polypeptide. This component, TFIIIR, is distinct from the previously identified transcription components: RNA polymerase III, and the accessory factors TFIIIA, TFIIIB, TFIIIC, and TFIIID. The newly discovered TFIIIR is a macromolecule that appears to be composed of RNA. It is resistant to heat, detergent, phenol, protease, and deoxyribonuclease, but it is sensitive to alkali and ribonuclease.
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PMID:A class III transcription factor composed of RNA. 170 25

We have isolated Escherichia coli transcription complexes, paused in the presence and absence of Nus A, which contain RNA substituted at every UMP residue with a photocrosslinking nucleotide analog. The pause site is immediately downstream from an RNA stem-loop structure, and although pausing occurs in the absence of Nus A, it is substantially enhanced in the presence of Nus A. We have analyzed the secondary structure of this RNA and show that the analog does not interfere with the formation of the normal stem-loop structures. Additionally, the analog substrate does not alter transcriptional pausing, in the presence or absence of Nus A, indicating that Nus A recognition of the transcription complex is not affected by the presence of the crosslinking groups in the RNA. Ribonuclease digestion of the RNA in paused complexes identifies two accessible regions, two nucleotides in the loop and one near the base of the upstream side of the stem-loop. Cleavage at one loop nucleotide is enhanced by Nus A, while the nucleotide near the base of the stem-loop is partially protected. Upon irradiation of the transcription complex, Nus A is not photoaffinity labeled by the RNA, even at a high molar ration to RNA polymerase (250:1). Both the beta and beta' subunits are labeled, however, indicating that the putative stem-loop binding domain on the core polymerase involves both subunits. Because the nucleotide protected from ribonuclease by Nus A is very near two analogs, yet Nus A is not crosslinked to the RNA, it is unlikely that Nus A could be protecting this position through direct contact. Furthermore, analog is substituted at positions in both the loop and at several positions in the stem, and again, no crosslinking to Nus A is observed. We conclude that enhancement of pausing by Nus A probably does not require direct interaction with the bases in the RNA stem-loop.
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PMID:RNA-protein interactions in a Nus A-containing Escherichia coli transcription complex paused at an RNA hairpin. 170 33

Ternary complexes of RNA polymerase II, bearing the nascent RNA transcript, are intermediates in the synthesis of all eukaryotic mRNAs and are implicated as regulatory targets of factors that control RNA chain elongation and termination. Information as to the structure of such complexes is essential in understanding the catalytic and regulatory properties of the RNA polymerase. We have prepared complexes of purified RNA polymerase II halted at defined positions along a DNA template and used RNase footprinting to map interactions of the polymerase with the nascent RNA. Unexpectedly, the transcript is sensitive to cleavage by RNases A and T1 at positions as close as 3 nucleotides from the 3'-terminal growing point. Ternary complexes in which the transcript has been cleaved to give a short fragment can retain that fragment and remain active and able to continue elongation. Since DNA.RNA hybrid structures are completely resistant to cleavage under our reaction conditions, the results suggest that any DNA.RNA hybrid intermediate can extend for no more than 3 base pairs, in dramatic contrast to recent models for transcription elongation. At lower RNase concentrations, the transcript is protected from cleavage out to about 24 nucleotides from the 3' terminus. We interpret this partial protection as due to the presence of an RNA binding site on the polymerase that binds the nascent transcript during elongation, a model proposed earlier by several workers in preference to the hybrid model. The properties of this RNA binding site are likely to play a central role in the process of transcription elongation and termination and in their regulation.
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PMID:Footprinting analysis of mammalian RNA polymerase II along its transcript: an alternative view of transcription elongation. 170 38

We have identified the template-binding polypeptide in the pea chloroplast transcriptional complex by photoaffinity labelling. This polypeptide has an apparent molecular weight of about 150 kDa and binds to both, chloroplast ribosomal (16S rRNA) and messenger (psbA) promoters. The 16S rRNA and psbA promoters were amplified from chloroplast DNA by the polymerase chain reaction and labelled with a photoactive analogue of TTP, 5-bromodeoxy UTP, as well as with alpha-32P-dCTP. Using the filter-binding assay, the conditions for binding of the RNA polymerase complex to chloroplast promoters were optimized. The polypeptide directly interacting with the template was photo-crosslinked to it and resolved by denaturing gel electrophoresis. The photoaffinity labelling of the 150 kDa polypeptide was dependent on photoactivation by UV irradiation, and the presence of chloroplast promoters. Competition experiments showed that the protein formed a strong interaction with the plastid promoters which could not be displaced by lambda-phage DNA or synthetic polynucleotides. The photo-crosslinked and nuclease-treated promoter-polypeptide complex was resistant to further digestion with DNase and RNase, but could be hydrolyzed by Proteinase K. Binding of the promoters by the 150 kDa polypeptide could not be surpressed by transcription inhibitors like rifampicin and alpha-amanitin. However, heparin (0.001%) inhibited the formation of the enzyme-promoter complex, and interfered with the photoaffinity labelling of the 150 kDa polypeptide. The extent of photoaffinity labelling of 150 kDa polypeptide exhibits some degree of correlation to total transcriptional activity under various salt concentrations. The results demonstrate that the 150 kDa polypeptide is a functional template binding polypeptide of the pea chloroplast transcription complex.
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PMID:Identification of the template binding polypeptide in the pea chloroplast transcriptional complex. 173 6

The functional template for transcription of vesicular stomatitis virus (VSV) RNA is a ribonucleoprotein particle (nucleocapsid) consisting of the negative-strand sense genomic RNA completely encapsidated by the viral nucleocapsid (N) protein. As an approach to create nucleocapsids in vitro, we demonstrate here the specific encapsidation by purified N protein of in vitro-synthesized RNA sequences representing the 5' end of both the negative- and positive-strand VSV genome-length RNAs. As few as 19 nucleotides from the 5'-end of positive-strand RNA allowed maximal encapsidation, although the 5' terminal 10 nucleotides would allow partial (50%) encapsidation. Sequences downstream of the binding site can be of any origin. Specific encapsidation of VSV sequences was dependent on the presence of uninfected cell cytoplasmic extracts or poly(A). The synthetic nucleocapsids have the properties of RNase resistance and a buoyant density typical of wild-type VSV nucleocapsids. We have encapsidated a synthetic virionlike RNA species which contained just the terminal sequences of the virion RNA: the N encapsidation signal from the 5' end and the leader gene from the 3' end. This assembled nucleocapsid could function in vitro as a transcription template for the VSV RNA polymerase.
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PMID:Assembly and transcription of synthetic vesicular stomatitis virus nucleocapsids. 185 4

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