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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)

The rna82 mutation of Saccharomyces cerevisiae inactivates an RNA processing activity responsible for maturation of 3'-terminal sequences upon 5 S and 37 S ribosomal RNA precursors. This study describes a difference in the processing of transcripts of an S. cerevisiae dimeric tRNA gene (tRNA(arg)-tRNA(Asp) in RNA polymerase III in vitro transcription extracts prepared from rna82 and wild-type cells. The mutant extract accumulated additional processing intermediates containing tRNA(Arg) sequences as compared to the extract from wild-type cells. The structure of these intermediates revealed a defect in removal of the 10 nucleotides left 3' to the tRNA(Arg) sequence by the RNase P cleavage immediately 5' to tRNA(Asp). This is the first demonstration of a mutational defect affecting maturation of 3' sequences upon a eukaryotic tRNA precursor.
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PMID:Processing of transcripts of a dimeric tRNA gene in yeast uses the nuclease responsible for maturation of the 3' termini upon 5 S and 37 S precursor rRNAs. 266 58

A transfer RNA complete devoid of modified nucleosides was synthesized by in vitro transcription, and some of its properties in aminoacylation and protein synthesis in vitro were studied. For this purpose, a plasmid was constructed which contained a glycine tRNA gene from Mycoplasma mycoides under the promoter of the T7 RNA polymerase, as well as a BstNI restriction site at the 3'-end of the tRNA gene. Cleavage of plasmid DNA with BstNI followed by T7 RNA polymerase transcription in vitro yielded an RNA which was processed with M1 RNA, the catalytic subunit of ribonuclease P, to give a tRNA of mature length. The tRNA synthesized in this manner can be esterified with glycine in vitro, and the rate of aminoacylation is the same as when using the corresponding fully modified glycine tRNA from M. mycoides. Furthermore, in protein synthesis in vitro, the tRNA lacking modified nucleosides was essentially as efficient as the corresponding normal glycine tRNA. However, the Escherichia coli extract used in our protein-synthesizing system introduced one modification, pseudouridine, into the in vitro-synthesized tRNA, and it cannot be excluded that this modification has an essential role in protein synthesis.
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PMID:Properties of a transfer RNA lacking modified nucleosides. 284 31

The seven tRNA genes clustered in the supB-E region of the Escherichia coli chromosome were transcribed in vitro with purified RNA polymerase, using a restriction fragment from lambda psu degrees 2, a transducing phage carrying the chromosome region, as template. A single major transcript was synthesized, which was about 770 nucleotides long and contained all seven tRNA sequences. The terminal sequences of the transcript were determined and mapped on the DNA sequence of the supB-E region previously determined. The transcription start site is seven base pairs downstream from the Pribnow box sequence, as expected from the DNA sequence analysis and consistent with the findings on the trimeric tRNA precursor (pppG--tRNAMETM-tRNALeu-tRNAGln1) which was detected in an RNase P mutant and shown to be coded for by the supB-E region. Cleavage of the restriction fragment at the -35 region with another restriction endonuclease abolished the template activity of the fragment. Transcription of the supB-E tRNA operon was relatively unaffected by the presence of rho factor. Transcription termination occurs within a region of three bases between positions 770 and 772 from the transcription start site. Immediately upstream from the termination sites, there is a region of 26 nucleotides that could form a stem structure, thereby consistent with the general feature of rho-independent termination sites.
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PMID:In vitro transcription of the supB-E tRNA operon of Escherichia coli. Characterization of transcription products. 628 82

In S. typhimurium, the hisR locus is defined by mutations causing reduced levels of the histidine transfer RNA. As a preliminary step in the analysis of the hisR mutants, a 972 bp DNA fragment containing the histidine tRNA gene from wild-type Salmonella was cloned and completely sequenced. This analysis revealed the existence of a tRNA gene cluster which, in addition to the tRNAHis gene, includes the genes for tRNALeu1, tRNAPro1 and a tentative tRNAArgCGG. All four tRNA genes are present as single copies and are separated by spacer sequences ranging from 20 to 53 bp in length. The gene cluster is efficiently transcribed in vitro by E. coli RNA polymerase and yields a transcript, approximately 480 nucleotides long, which contains all four tRNA sequences. This tetrameric precursor can be processed to 4S RNA in vitro with a wild-type Salmonella extract, but not with an extract prepared from a hisU (RNase P) mutant. Using portions of the tRNA gene cluster as specific hybridization probes, various processing intermediates were shown to accumulate in vivo in the hisU mutant. Most of these RNAs are monomeric precursors only a few nucleotides longer than the respective mature tRNA species.
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PMID:The hisR locus of Salmonella: nucleotide sequence and expression. 635 94

We have investigated the subcellular organization of the four human Y RNAs. These RNAs, which are transcribed by RNA polymerase III, are usually found complexed with the Ro autoantigen, a 60-kD protein. We designed 2'-OMe oligoribonucleotides that were complementary to accessible single-stranded regions of Y RNAs within Ro RNPs and used them in fluorescence in situ hybridization. Although all four Y RNAs were primarily cytoplasmic, oligonucleotides directed against three of the RNAs hybridized to discrete structures near the nucleolar rim. We have termed these structures "perinucleolar compartments" (PNCs). Double labeling experiments with appropriate antisera revealed that PNCs are distinct from coiled bodies and fibrillar centers. Co-hybridization with a genomic DNA clone spanning the human Y1 and Y3 genes showed that PNCs are not stably associated with the transcription site for these Y RNAs. Although 5S rDNA was often located near the nucleolar periphery, PNCs are not associated with 5S gene loci. Two additional pol III transcripts, the RNA components of RNase P and RNase MRP, did colocalize within PNCs. Most interestingly, the polypyrimidine tract-binding protein hnRNP I/PTB was also concentrated in this compartment. Possible roles for this novel nuclear subdomain in macromolecular assembly and/or nucleocytoplasmic shuttling of these five pol III transcripts, along with hnRNP I/PTB, are discussed.
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PMID:A perinucleolar compartment contains several RNA polymerase III transcripts as well as the polypyrimidine tract-binding protein, hnRNP I. 753 9

For the first time mosaic nucleic acids composed of 50% RNA and 50% DNA can be obtained as transcripts with T7 RNA polymerase. Two NTPs could be replaced simultaneously in a transcription reaction. This means more than 40 deoxynucleotides were inserted in one transcript. Previously, a maximum of two deoxynucleotides could be incorporated and 2'-O-methyl-NTPs were not substrates at all. We obtained reasonable transcript yields with a maximal level of 99% 2'-O-methyl-NTPs, and the products contained up to 58% 2'-O-methylnucleotides at more than 20 positions. Sequence-specific nucleotide incorporation was monitored by sequence ladders (partial alkali or iodine cleavage). No base misincorporations were detected with 100% dGTP, dCTP and dTTP, and with partial incorporation of dATP alpha S, 2'-O-methyl-GTP alpha S and 2'-O-methyl-CTP alpha S, whereas they were found with dATP, 2'-O-methyl-ATP alpha S and 2'-O-methyl-UTP alpha S. Quantitative data allow predetermined modification levels of partially modified transcripts. Highly modified transcripts can be used for structural and functional studies, in modification interference approaches and for in vitro evolution procedures. Modification interference studies revealed a small number of important phosphate and ribose moieties in RNase P substrates. The conversion of T7 RNA polymerase to a DNA polymerase extends the observation that there is no absolute distinction between RNA and DNA polymerases. Accordingly, an adapted concept of a primordial RNA world is presented.
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PMID:Enzymatic synthesis of 2'-modified nucleic acids: identification of important phosphate and ribose moieties in RNase P substrates. 754 Nov 30

4-Thiouridine (s4U), a photoreactive analog of uridine, was randomly incorporated into tRNA2(fMet) precursor molecules by transcription with T7 RNA polymerase. The s4U-containing transcripts were trimmed at their 5'-ends with RNase P RNA to yield mature tRNA2(fMet). The photoreactive tRNA2(fMet) derivatives were aminoacylated and bound to the P site of 70S ribosomes from Escherichia coli in the presence of a poly(A,G,U) template. Irradiation of the complexes at 300 nm resulted in the covalent cross-linking of tRNA2(fMet) to ribosomal proteins and rRNAs within both the 50S and 30S subunits. The labeled proteins were identified as L1, L27, and S19. 50S-subunit proteins L1 and L27 were attached to nucleotide U17 or U17.1 within the D loop of tRNA2(fMet), whereas 30S-subunit protein S19 was cross-linked to nucleotide U47 in the variable loop. Both of these sites occur in or near the central fold of the tRNA. These results permit us to map the D loop of P site-bound tRNA to the region between the central protuberance and the L1 ridge on the 50S ribosomal subunit, while the variable loop can be placed above the cleft on the head of the 30S subunit.
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PMID:Mapping the central fold of tRNA2(fMet) in the P site of the Escherichia coli ribosome. 825 1

Secondary structure models for yeast nuclear RNase P RNAs were derived by phylogenetic comparative analysis. RNase P RNA genes from six Saccharomyces species were characterized and compared with the published gene sequences of Saccharomyces cerevisiae (RPR1), Schizosaccharomyces pombe, and Schizosaccharomyces octosporus. The general organization of the Saccharomyces genes were similar: all were present in single copy and contained RNA polymerase III-specific regulatory elements, including tRNA gene-like A- and B-box promoters located within 5' leader regions and poly(T) terminators following the mature RNA domain. As observed previously, two RNase P RNAs were present in each of the species: a shorter RNA corresponding to the mature domain and a longer possible precursor RNA that includes the 5' leader sequences. The mature RNA domains of three of these genes were sufficiently divergent from the S. cerevisiae RNA such that compensatory base changes in paired elements were readily identified, yet homologous regions could be aligned. A striking common core of primary and secondary structure emerged for the Saccharomyces RNase P RNAs. Furthermore, the Schizosaccharomyces homologs conformed in large part to the Saccharomyces conserved core and shared with it a distinctive structural domain that has so far only been observed in the yeast nuclear RNase P RNAs. Comparison of the yeast core to a previously published eubacterial conserved core and to the RNA homologs from vertebrates revealed a number of similarities, suggesting that RNase P RNA from diverse sources may share a core of structurally conserved elements.
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PMID:Comparative structural analysis of nuclear RNase P RNAs from yeast. 831 72

The mitochondrial RNase P RNA gene in yeast Saccharomyces cerevisiae is transcribed from a variant mitochondrial promoter (SP). The sequence of this SP promoter [TATAAGAAG (+2)] differs from the conserved mitochondrial promoter sequence [TATAAGTAA (+2)] by-1T-->A and +2A-->G nucleotide substitutions. To determine the effect of these nucleotide alterations in mitochondrial promoter function, an in vitro transcription analysis was carried out. In the presence of high concentrations of rNTPs (i.e., 125 microM), transcription initiation on the wild-type or variant promoter occurred at the conventional 3' adenine nucleotide. However, at low rNTP concentrations (i.e., 5 microM) and in the presence of a complementary dinucleotide primer corresponding to positions -1 + 1, the mitochondrial RNA polymerase started transcription one nucleotide upstream of the conventional start site. Surprisingly, in the presence of some noncomplementary dinucleotides (i.e., GpA or CpA), which do not have perfect Watson-Crick base pairing with the initiator sequence, transcriptional initiation also occurred with the SP promoter but not with the conserved promoter sequence. This finding is the first example of utilization of noncomplementary dinucleotide primer by an RNA polymerase. Further analysis of mitochondrial promoter function by site-directed mutagenesis determined that the guanine nucleotide at position +2 is mainly responsible for this unusual function of the SP promoter.
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PMID:Unusual usage of noncomplementary dinucleotide primers by the yeast mitochondrial RNA polymerase. 914 28

The perinucleolar compartment (PNC) is a unique nuclear structure preferentially localized at the periphery of the nucleolus. Several small RNAs transcribed by RNA polymerase III (e.g., the Y RNAs, MRP RNA, and RNase P H1 RNA) and the polypyrimidine tract binding protein (PTB; hnRNP I) have thus far been identified in the PNC (Ghetti, A., S. PinolRoma, W.M. Michael, C. Morandi, and G. Dreyfuss. 1992. Nucleic Acids Res. 20:3671-3678; Matera, A.G., M.R. Frey, K. Margelot, and S.L. Wolin. 1995. J. Cell Biol. 129:1181-1193; Lee, B., A.G. Matera, D.C. Ward, and J. Craft. 1996. Proc. Natl. Acad. Sci. USA. 93: 11471-11476). In this report, we have further characterized this structure in both fixed and living cells. Detection of the PNC in a large number of human cancer and normal cells showed that PNCs are much more prevalent in cancer cells. Analysis through the cell cycle using immunolabeling with a monoclonal antibody, SH54, specifically recognizing PTB, demonstrated that the PNC dissociates at the beginning of mitosis and reforms at late telophase in the daughter nuclei. To visualize the PNC in living cells, a fusion protein between PTB and green fluorescent protein (GFP) was generated. Time lapse studies revealed that the size and shape of the PNC is dynamic over time. In addition, electron microscopic examination in optimally fixed cells revealed that the PNC is composed of multiple strands, each measuring approximately 80-180 nm diam. Some of the strands are in direct contact with the surface of the nucleolus. Furthermore, analysis of the sequence requirement for targeting PTB to the PNC using a series of deletion mutants of the GFP-PTB fusion protein showed that at least three RRMs at either the COOH or NH2 terminus are required for the fusion protein to be targeted to the PNC. This finding suggests that RNA binding may be necessary for PTB to be localized in the PNC.
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PMID:The dynamic organization of the perinucleolar compartment in the cell nucleus. 916 99

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