Search results for "RNA Polymerase III"

showing 6 items of 6 documents

Eukaryotic RNA Polymerases: The Many Ways to Transcribe a Gene

2021

In eukaryotic cells, three nuclear RNA polymerases (RNA pols) carry out the transcription from DNA to RNA, and they all seem to have evolved from a single enzyme present in the common ancestor with archaea. The multiplicity of eukaryotic RNA pols allows each one to remain specialized in the synthesis of a subset of transcripts, which are different in the function, length, cell abundance, diversity, and promoter organization of the corresponding genes. We hypothesize that this specialization of RNA pols has conditioned the evolution of the regulatory mechanisms used to transcribe each gene subset to cope with environmental changes. We herein present the example of the homeostatic regulation …

0301 basic medicineQH301-705.5Mini ReviewRNA polymerase IIBiochemistry Genetics and Molecular Biology (miscellaneous)BiochemistryRNA polymerase III03 medical and health sciencesRNA pol III0302 clinical medicineTranscription (biology)evolutionRNA polymerase IMolecular BiosciencesRNA pol IBiology (General)Molecular BiologyGenePolymeraseGeneticsMessenger RNAbiologyCèl·lules eucariotesnucleusRNARNA pol II030104 developmental biologybiology.proteinRNAtranscription030217 neurology & neurosurgeryFrontiers in Molecular Biosciences
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The role of cell interactions in the control of RNA synthesis.

1967

CytoplasmChemistryCellular differentiation5.8S ribosomal RNACellRNAPhosphorus IsotopesCell DifferentiationRNA integrity numberNon-coding RNABiochemistry Genetics and Molecular Biology (miscellaneous)RNA polymerase IIICell biologymedicine.anatomical_structureRNA editingmedicineCentrifugation Density GradientAnimalsRNAUltracentrifugationEchinodermataBiochimica et biophysica acta
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A comparative analysis to study editing of small noncoding BC200- and Alu transcripts in brain of prion-inoculated rhesus monkeys (M. Mulatta).

2012

Small retroelements (short interspersed elements, abbreviated SINEs) are abundant in vertebrate genomes. Using RNA isolated from rhesus monkey cerebellum and buffy coat, reverse-transcription polymerase chain reaction (RT PCR) was applied to clone cDNA of BC200 and Alu RNAs. Transcripts containing Alu-SINE sequences may be subjected to extensive RNA editing by ADAR (adenosine deaminases that act on RNA) deamination. Abundance of Alu transcripts was determined with real-time RT PCR and was significantly higher than BC200 (brain cytoplasmic) in cerebellum. BC200 transcripts were absent from buffy coat cells. Availability of the rhesus genome sequence allowed the BC200 transcripts to be mapped…

DNA ComplementaryHealth Toxicology and MutagenesisMolecular Sequence DataRNA-dependent RNA polymeraseBiologyToxicologyReal-Time Polymerase Chain ReactionRNA polymerase IIICreutzfeldt-Jakob SyndromeAlu ElementsComplementary DNACerebellumAnimalsShort Interspersed Nucleotide ElementsGeneticsBase SequenceReverse Transcriptase Polymerase Chain ReactionIntronRNARNA Polymerase IIISequence Analysis DNAMolecular biologyMacaca mulattaReal-time polymerase chain reactionRNA editingADARRNARNA Small UntranslatedRNA EditingJournal of toxicology and environmental health. Part A
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Arthropod 7SK RNA

2008

The 7SK small nuclear RNA (snRNA) is a key player in the regulation of polymerase (pol) II transcription. The 7SK RNA was long believed to be specific to vertebrates where it is highly conserved. Homologs in basal deuterostomes and a few lophotrochozoan species were only recently reported. On longer timescales, 7SK evolves rapidly with only few conserved sequence and structure motifs. Previous attempts to identify the Drosophila homolog thus have remained unsuccessful despite considerable efforts. Here we report on the discovery of arthropod 7SK RNAs using a novel search strategy based on pol III promoters, as well as the subsequent verification of its expression. Our results demonstrate th…

GeneticsbiologyComputational BiologyGene Expression7SK Small Nuclear RNAPrp24RNA polymerase IINon-coding RNARNA polymerase IIIConserved sequenceDrosophila melanogasterEvolutionary biologyRNA Small NuclearSequence Homology Nucleic AcidDatabases GeneticGeneticsbiology.proteinAnimalsNucleic Acid ConformationsnRNPArthropodsMolecular BiologyEcology Evolution Behavior and SystematicsSmall nuclear RNAMolecular Biology and Evolution
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The transcription reinitiation properties of RNA polymerase III in the absence of transcription factors

2007

AbstractTranscription reinitiation by RNA polymerase (Pol) III proceeds through facilitated recycling, a process by which the terminating Pol III, assisted by the transcription factors TFIIIB and TFIIIC, rapidly reloads onto the same transcription unit. To get further insight into the Pol III transcription mechanism, we analyzed the kinetics of transcription initiation and reinitiation of a simplified in vitro transcription system consisting only of Pol III and template DNA. The data indicates that, in the absence of transcription factors, first-round transcription initiation by Pol III proceeds at a normal rate, while facilitated reinitiation during subsequent cycles is compromised.

RNA polymerase IIISaccharomyces cerevisiae ProteinsTranscription GeneticvirusesShort CommunicationMolecular Sequence DataRNA polymerase IISaccharomyces cerevisiaeBiochemistryRNA polymerase IIITranscription Factor TFIIIBTranscription Factors TFIIIGene Expression Regulation FungalMolecular BiologyTFIIIBBase SequencebiologyGeneral transcription factorG-less cassetteCell BiologyMolecular biologyTranscription preinitiation complexbiology.proteinTranscription reinitiationTranscription factor II FTranscription factor II ETranscription factor II DTranscription factor II BCellular and Molecular Biology Letters
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Chromatin-dependent regulation of RNA polymerases II and III activity throughout the transcription cycle

2015

The particular behaviour of eukaryotic RNA polymerases along different gene regions and amongst distinct gene functional groups is not totally understood. To cast light onto the alternative active or backtracking states of RNA polymerase II, we have quantitatively mapped active RNA polymerases at a high resolution following a new biotin-based genomic run-on (BioGRO) technique. Compared with conventional profiling with chromatin immunoprecipitation, the analysis of the BioGRO profiles in Saccharomyces cerevisiae shows that RNA polymerase II has unique activity profiles at both gene ends, which are highly dependent on positioned nucleosomes. This is the first demonstration of the in vivo infl…

Transcription factoriesSaccharomyces cerevisiae ProteinsTranscription Elongation GeneticTranscription GeneticRNA polymerase II28Saccharomyces cerevisiaeBiology03 medical and health scienceschemistry.chemical_compoundTranscripció genèticaRNA polymeraseGeneticsRNA polymerase IRNA polymerase II holoenzyme9030304 developmental biologyGenetics0303 health sciencesGeneral transcription factorGene regulation Chromatin and Epigenetics030302 biochemistry & molecular biologyRNA Polymerase IIIGenomicsNucleosomesCell biologychemistryTranscription Termination Geneticbiology.proteinRNARNA Polymerase IIGenome FungalTranscription factor II DSmall nuclear RNA
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