EC:2.7.7.48 - FACTA Search

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Query: EC:2.7.7.48 (transcriptase)
9,479 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Transcription by the influenza virus RNA-dependent RNA polymerase is dependent on cellular RNA processing activities that are known to be associated with cellular RNA polymerase II (Pol II) transcription, namely, capping and splicing. Therefore, it had been hypothesized that transcription by the viral RNA polymerase and Pol II might be functionally linked. Here, we demonstrate for the first time that the influenza virus RNA polymerase complex interacts with the large subunit of Pol II via its C-terminal domain. The viral polymerase binds hyperphosphorylated forms of Pol II, indicating that it targets actively transcribing Pol II. In addition, immunofluorescence analysis is consistent with a new model showing that influenza virus polymerase accumulates at Pol II transcription sites. The present findings provide a framework for further studies to elucidate the mechanistic principles of transcription by a viral RNA polymerase and have implications for the regulation of Pol II activities in infected cells.
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PMID:Association of the influenza A virus RNA-dependent RNA polymerase with cellular RNA polymerase II. 1582 95

A fecal archive containing 115 sapovirus (SaV) strains detected in samples collected from 15 outbreaks and 98 sporadic cases of gastroenteritis between 1989 and 2004 in the UK were characterized in order to determine the genomic diversity within SaV co-circulating in the human population. Strains were characterized by partial sequencing of the genes encoding the RNA-dependent RNA polymerase (RdRp) region and/or the polymerase/capsid (Pol/Cap) junction of the open reading frame (Orf) 1. Overall, SaV of genogroup I genotype 1 (GI 1) were the predominant strains circulating in the UK in each year between 1989 and 2004. During 2004, GII 1 was the predominant strain. These two SaV types accounted for 89.5% of the sporadic cases and outbreaks in the UK. The remaining cases were caused by six other SaV genotypes. On the basis of partial sequencing of the RdRp and capsid encoding genes of strains, which did not show sufficient homology to any of the currently recognized genotypes, we propose the inclusion of a presumptive fourth genotype within genogroup I (GI 4).
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PMID:Characterization of sapoviruses collected in the United Kingdom from 1989 to 2004. 1655 76

The influenza virus RNA-dependent RNA polymerase interacts with the serine-5 phosphorylated carboxy-terminal domain (CTD) of the large subunit of RNA polymerase II (Pol II). It was proposed that this interaction allows the viral RNA polymerase to gain access to host mRNA-derived capped RNA fragments required as primers for the initiation of viral mRNA synthesis. Here, we show, using a chromatin immunoprecipitation (ChIP) analysis, that similar amounts of Pol II associate with Pol II promoter DNAs in influenza virus-infected and mock-infected cells. However, there is a statistically significant reduction in Pol II densities in the coding region of Pol II genes in infected cells. Thus, influenza virus specifically interferes with Pol II elongation, but not Pol II initiation. We propose that influenza virus RNA polymerase, by binding to the CTD of initiating Pol II and subsequent cleavage of the capped 5' end of the nascent transcript, triggers premature Pol II termination.
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PMID:Influenza virus inhibits RNA polymerase II elongation. 1662 67

Lacking an RNA-dependent RNA polymerase, hepatitis delta virus (HDV), which contains a circular RNA of 1.7 kilobases, is nonetheless able to replicate its RNA by use of cellular transcription machineries. Previously, we have shown that the replications of genomic- and antigenomic-strand HDV RNAs have different sensitivities to alpha-amanitin, suggesting that these two strands are synthesized in different transcription machineries in the cells, but the nature of these transcription machineries is not clear. In this study, we performed metabolic labeling and immunofluorescence staining of newly synthesized HDV RNA with bromouridine after HDV RNA transfection into hepatocytes and confirmed that HDV RNA synthesis had both alpha-amanitin-sensitive and -resistant components. The antigenomic RNA labeling was alpha-amanitin resistant and localized to the nucleolus. The genomic RNA labeling was alpha-amanitin sensitive and more diffusely localized in the nucleoplasm. Most of the genomic RNA labeling appeared to colocalize with the PML nuclear bodies. Furthermore, promyelocytic leukemia protein, RNA polymerase II (Pol II), and the Pol I-associated transcription factor SL1 could be precipitated together with hepatitis delta antigen, suggesting the association of HDV replication complex with the Pol I and Pol II transcription machineries. This conclusion was further confirmed by an in vitro replication assay. These findings provide additional evidence that HDV RNA synthesis occurs in the Pol I and Pol II transcription machineries, thus extending the capability of the cellular DNA-dependent RNA polymerases to utilizing RNA as templates.
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PMID:RNA-templated replication of hepatitis delta virus: genomic and antigenomic RNAs associate with different nuclear bodies. 1677 35

Influenza viruses replicate and transcribe their segmented negative-sense single-stranded RNA genome in the nucleus of the infected host cell. All RNA synthesising activities associated with influenza virus are performed by the virally encoded RNA-dependent RNA polymerase (RdRp) that consists of three subunits, PA, PB1 and PB2. However, viral transcription is critically dependent on on-going cellular transcription, in particular, on activities associated with the cellular DNA-dependent RNA polymerase II (Pol II). Thus, the viral RdRp uses short 5' capped RNA fragments, derived from cellular Pol II transcripts, as primers for viral mRNA synthesis. These capped RNA primers are generated by cleavage of host Pol II transcripts by an endonuclease activity associated with the viral RdRp. Moreover, some viral transcripts require splicing and since influenza virus does not encode splicing machinery, it is dependent on host splicing, an activity also related to Pol II transcription. Despite these functional links between viral and host Pol II transcription, there has been no evidence that a physical association existed between the two transcriptional machineries. However, recently it was reported that there is a physical interaction between the trimeric viral RdRp and cellular Pol II. The viral RdRp was found to interact with the C-terminal domain (CTD) of initiating Pol II, at a stage in the transcription cycle when capping takes place. It was therefore proposed that this interaction may be required for the viral RNA (vRNA) polymerase to gain access to capped RNA substrates for endonucleolytic cleavage. The virus not only relies on cellular factors to support its own RNA synthesis, but also subverts cellular pathways in order to generate an environment optimised for viral multiplication. In this respect, the interaction of the viral NS1 protein with factors involved in cellular pre-mRNA processing is of particular relevance. The virus also alters the distribution of Pol II on cellular genes, leading to a reduction in elongating Pol II thereby contributing to the phenomenon known as host shut-off.
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PMID:Functional association between viral and cellular transcription during influenza virus infection. 1693 65

In metazoans, the mechanisms of transcriptional termination by RNA polymerase II (Pol II) and accelerated decay of messenger RNA (mRNA) following transcription shutdown are linked by sharing the same sequence elements and mRNA elongation, processing and termination factors. This begs the question, how could one process have two opposite outcomes, making or degrading mRNA? An integrated "allosteric-GENEi-torpedo" model that could explain this paradox predicts participation of two novel factors: (1) An allosteric factor, regulated by a physiological repressor, binds to a unique sequence element of a gene near the site of cleavage and polyadenylation, poly(A) site, and acts on the homologous site on the nascent transcript to cause its cleavage. The conformational changes of this factor determine the fate of nascent RNA, either to get cleaved and processed to mature mRNA for directing protein synthesis, or not to get cleaved and become template for double-stranded (ds) RNA synthesis. (2) A general transcription termination factor, recruited by transcribing Pol II at the poly(A) site, allostrically alters and induces Pol II to switch template from DNA to nascent RNA several hundred nucleotides downstream of the poly(A) site. The template switch disengages Pol II from DNA and effectively terminates transcription. The Pol II with newly acquired RNA-dependent RNA polymerase activity retraces its path, back along the nascent RNA, so generating dsRNA. The extent to which it can retrace this path is determined by the factors influencing the cleavage of the pre-mRNA at the site of polyA addition. If cleavage and polyadenylation occur, the retracing is cut short, the 3' RNA is degraded by an exonuclease and the polymerase is liberated to reinitiate transcription. If the cleavage is inhibited, then a full-length dsRNA can be produced. This can then be subject to cleavage by "Dicer", which generates fragments of approximately 22bp that guide degradation of the cognate mRNA via the RNA interference (RNAi) pathway. This model complements the current "allosteric-torpedo" model of transcription termination, and could explain the apparent paradox of the divergent results of a common biological process.
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PMID:Coupling of transcription termination to RNAi. 1715 79

Mitochondrial toxicity is a major adverse effect of the nucleoside reverse-transcriptase inhibitors (NRTIs) used for treatment of human immunodeficiency virus type 1 (HIV-1) infection and can result in life-threatening lactic acidosis. The toxicity is due to inhibition of polymerase gamma (Pol gamma), which is required for replication of mitochondrial DNA (mtDNA). Genetic factors could be involved in this process, given that not all NRTI-treated patients experience the toxicity. In 1 patient with lactic acidosis, a novel homozygous Pol gamma mutation (arginine to cysteine at codon 964 [R964C]) was identified at a site close to polymerase motif B, which is highly conserved among family A polymerases. Recombinant R964C Pol gamma showed only 14% activity, compared with that of wild-type Pol gamma. Culture with stavudine significantly reduced mtDNA levels in patient-derived lymphoblastoid cell lines (LCLs) harboring R964C Pol gamma, compared with those in LCLs harboring wild-type Pol gamma. The novel Pol gamma mutation could be associated with the severe lactic acidosis induced by long-term NRTI use.
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PMID:Novel mutation of human DNA polymerase gamma associated with mitochondrial toxicity induced by anti-HIV treatment. 1743 18

RNA-directed DNA methylation (RdDM) is a nuclear process in which small interfering RNAs (siRNAs) direct the cytosine methylation of DNA sequences that are complementary to the siRNAs. In plants, double stranded-RNAs (dsRNAs) generated by RNA-dependent RNA polymerase 2 (RDR2) serve as precursors for Dicer-like 3 dependent biogenesis of 24-nt siRNAs. Plant specific RNA polymerase IV (Pol IV) is presumed to generate the initial RNA transcripts that are substrates for RDR2. siRNAs are loaded onto an argonaute4-containing RISC (RNA-induced silencing complex) that targets the de novo DNA methyltransferase DRM2 to RdDM target loci. Nascent RNA transcripts from the target loci are generated by another plant-specific RNA polymerase, Pol V, and these transcripts help recruit complementary siRNAs and the associated RdDM effector complex to the target loci in a transcription-coupled DNA methylation process. Small RNA binding proteins such as ROS3 may direct target-specific DNA demethylation by the ROS1 family of DNA demethylases. Chromatin remodeling enzymes and histone modifying enzymes also participate in DNA methylation and possibly demethylation. One of the well studied functions of RdDM is transposon silencing and genome stability. In addition, RdDM is important for paramutation, imprinting, gene regulation, and plant development. Locus-specific DNA methylation and demethylation, and transposon activation under abiotic stresses suggest that RdDM is also important in stress responses of plants. Further studies will help illuminate the functions of RdDM in the dynamic control of epigenomes during development and environmental stress responses.
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PMID:RNA-directed DNA methylation and demethylation in plants. 1938 59

Mutations affecting the maintenance of heritable epigenetic states in maize identify multiple RNA-directed DNA methylation (RdDM) factors including RMR1, a novel member of a plant-specific clade of Snf2-related proteins. Here we show that RMR1 is necessary for the accumulation of a majority of 24 nt small RNAs, including those derived from Long-Terminal Repeat (LTR) retrotransposons, the most common repetitive feature in the maize genome. A genetic analysis of DNA transposon repression indicates that RMR1 acts upstream of the RNA-dependent RNA polymerase, RDR2 (MOP1). Surprisingly, we show that non-polyadenylated transcripts from a sampling of LTR retrotransposons are lost in both rmr1 and rdr2 mutants. In contrast, plants deficient for RNA Polymerase IV (Pol IV) function show an increase in polyadenylated LTR RNA transcripts. These findings support a model in which Pol IV functions independently of the small RNA accumulation facilitated by RMR1 and RDR2 and support that a loss of Pol IV leads to RNA Polymerase II-based transcription. Additionally, the lack of changes in general genome homeostasis in rmr1 mutants, despite the global loss of 24 nt small RNAs, challenges the perceived roles of siRNAs in maintaining functional heterochromatin in the genomes of outcrossing grass species.
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PMID:Production and processing of siRNA precursor transcripts from the highly repetitive maize genome. 1968 Apr 64

Retroviruses express Gag and Pol proteins by translation of unspliced genome-length viral RNA. For some retroviruses, transport of unspliced viral RNA to the cytoplasm is mediated by small regulatory proteins such as human immunodeficiency virus Rev, while other retroviruses contain constitutive transport elements in their RNAs that allow transport without splicing. In this study, we found that the betaretrovirus Jaagsiekte sheep retrovirus (JSRV) encodes within the env gene a trans-acting factor (Rej) necessary for the synthesis of Gag protein from unspliced viral RNA. Deletion of env sequences from a JSRV proviral expression plasmid (pTN3) abolished its ability to produce Gag polyprotein in transfected 293T cells, and Gag synthesis could be restored by cotransfection of an env expression plasmid (DeltaGP). Deletion analysis localized the complementing activity (Rej) to the putative Env signal peptide, and a signal peptide expression construct showed Rej activity. Two other betaretroviruses, mouse mammary tumor virus (MMTV) and human endogenous retrovirus type K, encode analogous factors (Rem and Rec, respectively) that are encoded from doubly spliced env mRNAs. Reverse transcriptase-PCR cloning and sequencing identified alternate internal splicing events in the 5' end of JSRV env that could signify analogous doubly spliced Rej mRNAs, and cDNA clones expressing two of them also showed Rej activity. The predicted Rej proteins contain motifs similar to those found in MMTV Rem and other analogous retroviral regulatory proteins. Interestingly, in most cell lines, JSRV expression plasmids with Rej deleted showed normal transport of unspliced JSRV RNA to the cytoplasm; however, in 293T cells Rej modestly enhanced export of unspliced viral RNA (2.8-fold). Metabolic labeling experiments with [(35)S]methionine indicated that JSRV Rej is required for the synthesis of viral Gag polyprotein. Thus, in most cell lines, the predominant function of Rej is to facilitate translation of unspliced viral mRNA.
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PMID:Jaagsiekte sheep retrovirus encodes a regulatory factor, Rej, required for synthesis of Gag protein. 1977 24

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