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Sample records for plant rna polymerase

  1. RNA-dependent RNA polymerase 1 in potato (Solanum tuberosum) and its relationship to other plant RNA-dependent RNA polymerases.

    Science.gov (United States)

    Hunter, Lydia J R; Brockington, Samuel F; Murphy, Alex M; Pate, Adrienne E; Gruden, Kristina; MacFarlane, Stuart A; Palukaitis, Peter; Carr, John P

    2016-03-16

    Cellular RNA-dependent RNA polymerases (RDRs) catalyze synthesis of double-stranded RNAs that can serve to initiate or amplify RNA silencing. Arabidopsis thaliana has six RDR genes; RDRs 1, 2 and 6 have roles in anti-viral RNA silencing. RDR6 is constitutively expressed but RDR1 expression is elevated following plant treatment with defensive phytohormones. RDR1 also contributes to basal virus resistance. RDR1 has been studied in several species including A. thaliana, tobacco (Nicotiana tabacum), N. benthamiana, N. attenuata and tomato (Solanum lycopersicum) but not to our knowledge in potato (S. tuberosum). StRDR1 was identified and shown to be salicylic acid-responsive. StRDR1 transcript accumulation decreased in transgenic potato plants constitutively expressing a hairpin construct and these plants were challenged with three viruses: potato virus Y, potato virus X, and tobacco mosaic virus. Suppression of StRDR1 gene expression did not increase the susceptibility of potato to these viruses. Phylogenetic analysis of RDR genes present in potato and in a range of other plant species identified a new RDR gene family, not present in potato and found only in Rosids (but apparently lost in the Rosid A. thaliana) for which we propose the name RDR7.

  2. Comparative analysis of RNA silencing suppression activities between viral suppressors and an endogenous plant RNA-dependent RNA polymerase.

    Science.gov (United States)

    Yoon, Ju-Yeon; Han, Kyoung-Sik; Park, Han-Yong; Choi, Seung-Kook

    2012-06-01

    RNA silencing is an evolutionarily conserved system that functions as an antiviral mechanism in eukaryotes, including higher plants. To counteract this, several plant viruses express silencing suppressors that inhibit RNA silencing in host plants. Here, we show that both 2b protein from peanut stunt virus (PSV) and a hairpin construct (designated hp-RDR6) that silences endogenous RNA-dependent RNA polymerase 6 (RDR6) strongly suppress RNA silencing. The Agrobacterium infiltration system was used to demonstrate that both PSV 2b and hp-RDR6 suppressed local RNA silencing as strongly as helper component (HC-Pro) from potato virus Y (PVY) and P19 from tomato bush stunt virus (TBSV). The 2b protein from PSV eliminated the small-interfering RNAs (siRNAs) associated with RNA silencing and prevented systemic silencing, similar to 2b protein from cucumber mosaic virus (CMV). On the other hand, hp-RDR6 suppressed RNA silencing by inhibiting the generation of secondary siRNAs. The small coat protein (SCP) of squash mosaic virus (SqMV) also displayed weak suppression activity of RNA silencing. Agrobacterium-mediated gene transfer was used to investigate whether viral silencing suppressors or hp-RDR6 enhanced accumulations of green fluorescence protein (GFP) and β-glucuronidase (GUS) as markers of expression in leaf tissues of Nicotina benthamiana. Expression of both GFP and GUS was significantly enhanced in the presence of PSV 2b or CMV 2b, compared to no suppression or the weak SqMV SCP suppressor. Co-expression with hp-RDR6 also significantly increased the expression of GFP and GUS to levels similar to those induced by PVY HC-Pro and TBSV P19.

  3. The RNA silencing enzyme RNA polymerase v is required for plant immunity.

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    Ana López

    2011-12-01

    Full Text Available RNA-directed DNA methylation (RdDM is an epigenetic control mechanism driven by small interfering RNAs (siRNAs that influence gene function. In plants, little is known of the involvement of the RdDM pathway in regulating traits related to immune responses. In a genetic screen designed to reveal factors regulating immunity in Arabidopsis thaliana, we identified NRPD2 as the OVEREXPRESSOR OF CATIONIC PEROXIDASE 1 (OCP1. NRPD2 encodes the second largest subunit of the plant-specific RNA Polymerases IV and V (Pol IV and Pol V, which are crucial for the RdDM pathway. The ocp1 and nrpd2 mutants showed increases in disease susceptibility when confronted with the necrotrophic fungal pathogens Botrytis cinerea and Plectosphaerella cucumerina. Studies were extended to other mutants affected in different steps of the RdDM pathway, such as nrpd1, nrpe1, ago4, drd1, rdr2, and drm1drm2 mutants. Our results indicate that all the mutants studied, with the exception of nrpd1, phenocopy the nrpd2 mutants; and they suggest that, while Pol V complex is required for plant immunity, Pol IV appears dispensable. Moreover, Pol V defective mutants, but not Pol IV mutants, show enhanced disease resistance towards the bacterial pathogen Pseudomonas syringae DC3000. Interestingly, salicylic acid (SA-mediated defenses effective against PsDC3000 are enhanced in Pol V defective mutants, whereas jasmonic acid (JA-mediated defenses that protect against fungi are reduced. Chromatin immunoprecipitation analysis revealed that, through differential histone modifications, SA-related defense genes are poised for enhanced activation in Pol V defective mutants and provide clues for understanding the regulation of gene priming during defense. Our results highlight the importance of epigenetic control as an additional layer of complexity in the regulation of plant immunity and point towards multiple components of the RdDM pathway being involved in plant immunity based on genetic evidence

  4. Inhibition of RNA polymerase II allows controlled mobilisation of retrotransposons for plant breeding.

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    Thieme, Michael; Lanciano, Sophie; Balzergue, Sandrine; Daccord, Nicolas; Mirouze, Marie; Bucher, Etienne

    2017-07-07

    Retrotransposons play a central role in plant evolution and could be a powerful endogenous source of genetic and epigenetic variability for crop breeding. To ensure genome integrity several silencing mechanisms have evolved to repress retrotransposon mobility. Even though retrotransposons fully depend on transcriptional activity of the host RNA polymerase II (Pol II) for their mobility, it was so far unclear whether Pol II is directly involved in repressing their activity. Here we show that plants defective in Pol II activity lose DNA methylation at repeat sequences and produce more extrachromosomal retrotransposon DNA upon stress in Arabidopsis and rice. We demonstrate that combined inhibition of both DNA methylation and Pol II activity leads to a strong stress-dependent mobilization of the heat responsive ONSEN retrotransposon in Arabidopsis seedlings. The progenies of these treated plants contain up to 75 new ONSEN insertions in their genome which are stably inherited over three generations of selfing. Repeated application of heat stress in progeny plants containing increased numbers of ONSEN copies does not result in increased activation of this transposon compared to control lines. Progenies with additional ONSEN copies show a broad panel of environment-dependent phenotypic diversity. We demonstrate that Pol II acts at the root of transposon silencing. This is important because it suggests that Pol II can regulate the speed of plant evolution by fine-tuning the amplitude of transposon mobility. Our findings show that it is now possible to study induced transposon bursts in plants and unlock their use to induce epigenetic and genetic diversity for crop breeding.

  5. Isolation and characterization of an RNA-dependent RNA polymerase from Nicotiana clevelandii plants infected with red clover necrotic mosaic dianthovirus.

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    Bates, H J; Farjah, M; Osman, T A; Buck, K W

    1995-06-01

    A template-bound RNA polymerase was isolated from Nicotiana clevelandii plants infected with red clover necrotic mosaic dianthovirus (RCNMV) by differential centrifugation, solubilization with dodecyl beta-D-maltopyranoside, and chromatography on columns of Sephacryl S-400 and Q-Sepharose. Analysis of the purified polymerase by SDS-polyacrylamide gel electrophoresis, followed by silver staining or immunoblotting, showed that it contained virus-encoded proteins of molecular masses 27 kDa and 88 kDa together with several minor proteins possibly of host origin. After removal of endogenous RNA with micrococcal nuclease, the polymerase became template-dependent. It was also template-specific, being able to utilize as templates RNA of two strains of RCNMV, but not RNAs of three viruses in different taxonomic groups, namely cucumber mosaic cucumovirus, tomato bushy stunt tombusvirus and tomato mosaic tobamovirus. The products of RNA polymerase reactions were double-stranded RNAs corresponding to RCNMV RNAs 1 and 2. The ability of the template-dependent RNA polymerase to synthesize RNA was completely inhibited by antibodies to a peptide containing the GDD motif, whereas the activity of the template-bound enzyme was unaffected by these antibodies.

  6. Modulation of RNA polymerase II phosphorylation downstream of pathogen perception orchestrates plant immunity.

    Science.gov (United States)

    Li, Fangjun; Cheng, Cheng; Cui, Fuhao; de Oliveira, Marcos V V; Yu, Xiao; Meng, Xiangzong; Intorne, Aline C; Babilonia, Kevin; Li, Maoying; Li, Bo; Chen, Sixue; Ma, Xianfeng; Xiao, Shunyuan; Zheng, Yi; Fei, Zhangjun; Metz, Richard P; Johnson, Charles D; Koiwa, Hisashi; Sun, Wenxian; Li, Zhaohu; de Souza Filho, Gonçalo A; Shan, Libo; He, Ping

    2014-12-10

    Perception of microbe-associated molecular patterns (MAMPs) elicits host transcriptional reprogramming as part of the immune response. Although pathogen perception is well studied, the signaling networks orchestrating immune gene expression remain less clear. In a genetic screen for components involved in the early immune gene transcription reprogramming, we identified Arabidopsis RNA polymerase II C-terminal domain (CTD) phosphatase-like 3 (CPL3) as a negative regulator of immune gene expression. MAMP perception induced rapid and transient cyclin-dependent kinase C (CDKC)-mediated phosphorylation of Arabidopsis CTD. The CDKCs, which are in turn phosphorylated and activated by a canonical MAP kinase (MAPK) cascade, represent a point of signaling convergence downstream of multiple immune receptors. CPL3 directly dephosphorylated CTD to counteract MAPK-mediated CDKC regulation. Thus, modulation of the phosphorylation dynamics of eukaryotic RNA polymerase II transcription machinery by MAPKs, CTD kinases, and phosphatases constitutes an essential mechanism for rapid orchestration of host immune gene expression and defense upon pathogen attacks.

  7. Research Progress on Plant RNA-dependant RNA Polymerase%植物中依赖于RNA的RNA聚合酶研究进展

    Institute of Scientific and Technical Information of China (English)

    徐涛; 王磊

    2011-01-01

    依赖于RNA的RNA聚合酶(RDR)能够以单链RNA为模版合成互补RNA链,产生双链RNA.双链RNA在细胞内被类似RNaseⅢ的酶DCL加工成20~ 24 nt的小分子干扰RNA(siRNA).siRNA可以在转录水平或转录后水平抑制靶基因的表达.RDR通过基因沉默途径参与植物的生长发育调节、逆境应答以及表观遗传修饰等许多生物学过程.加深对植物RDR表达模式、生化活性及生物学功能等方面的理解将有利于植物基因沉默的发展和运用.%RNA-dependant RNA polymerase (RDR) could synthesize RNA strand complementary using single-stranded RNA as template to produce double-stranded RNA. Then the double-stranded RNAs are processed into 20~24 nt small interfering RNAs (siRNA) by DCL similar to cellular Rnase ID -like, which could transcriptionally or posttranscriptionally repress the expression of target genes. Through gene silencing pathway, RDR participates in multiple biological processes, such as plant developmental regulation, stress response and epigenetic modification. Thorough understanding about the expression profile, biochemical property and biological function of plant RDR will benefit the development and utilization of plant gene silencing.

  8. Alphavirus polymerase and RNA replication.

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    Pietilä, Maija K; Hellström, Kirsi; Ahola, Tero

    2017-01-16

    Alphaviruses are typically arthropod-borne, and many are important pathogens such as chikungunya virus. Alphaviruses encode four nonstructural proteins (nsP1-4), initially produced as a polyprotein P1234. nsP4 is the core RNA-dependent RNA polymerase but all four nsPs are required for RNA synthesis. The early replication complex (RC) formed by the polyprotein P123 and nsP4 synthesizes minus RNA strands, and the late RC composed of fully processed nsP1-nsP4 is responsible for the production of genomic and subgenomic plus strands. Different parts of nsP4 recognize the promoters for minus and plus strands but the binding also requires the other nsPs. The alphavirus polymerase has been purified and is capable of de novo RNA synthesis only in the presence of the other nsPs. The purified nsP4 also has terminal adenylyltransferase activity, which may generate the poly(A) tail at the 3' end of the genome. Membrane association of the nsPs is vital for replication, and alphaviruses induce membrane invaginations called spherules, which form a microenvironment for RNA synthesis by concentrating replication components and protecting double-stranded RNA intermediates. The RCs isolated as crude membrane preparations are active in RNA synthesis in vitro, but high-resolution structure of the RC has not been achieved, and thus the arrangement of viral and possible host components remains unknown. For some alphaviruses, Ras-GTPase-activating protein (Src-homology 3 (SH3) domain)-binding proteins (G3BPs) and amphiphysins have been shown to be essential for RNA replication and are present in the RCs. Host factors offer an additional target for antivirals, as only few alphavirus polymerase inhibitors have been described.

  9. Extraction of nuclei from sonchus yellow net rhabdovirus-infected plants yields a polymerase that synthesizes viral mRNAs and polyadenylated plus-strand leader RNA.

    Science.gov (United States)

    Wagner, J D; Choi, T J; Jackson, A O

    1996-01-01

    Although the primary sequence of the genome of the plant rhabdovirus sonchus yellow net virus (SYNV) has been determined, little is known about the composition of the viral polymerase or the mechanics of viral transcription and replication. In this paper, we report the partial isolation and characterization of an active SYNV polymerase from nuclei of SYNV-infected leaf tissue. A salt extraction procedure is shown to be an effective purification step for recovery of the polymerase from the nuclei. Full-length, polyadenylated SYNV N and M2 mRNAs and plus-strand leader RNA are among the products of the in vitro polymerase reactions. Polyadenylation of the plus-strand leader RNA in vitro is shown with RNase H and specific oligonucleotides. This is the first report of a polyadenylated plus-strand leader RNA for a minus-strand RNA virus, a feature that may reflect adaptation of SYNV to replication in the nucleus. Analysis of the SYNV proteins present in the polymerase extract suggests that the N, M2, and L proteins are components of the transcription complex. Overall, the system we developed promises to be useful for an in-depth characterization of the mechanics of SYNV RNA synthesis.

  10. Norovirus Proteinase-Polymerase and Polymerase Are Both Active Forms of RNA-Dependent RNA Polymerase

    OpenAIRE

    Belliot, Gaël; Sosnovtsev, Stanislav V.; Chang, Kyeong-Ok; Babu, Vijay; Uche, Uzo; Arnold, Jamie J.; Cameron, Craig E.; Green, Kim Y.

    2005-01-01

    In vitro mapping studies of the MD145 norovirus (Caliciviridae) ORF1 polyprotein identified two stable cleavage products containing the viral RNA-dependent RNA polymerase (RdRp) domains: ProPol (a precursor comprised of both the proteinase and polymerase) and Pol (the mature polymerase). The goal of this study was to identify the active form (or forms) of the norovirus polymerase. The recombinant ProPol (expressed as Pro−Pol with an inactivated proteinase domain to prevent autocleavage) and r...

  11. The Functions of RNA-Dependent RNA Polymerases in Arabidopsis

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    Willmann, Matthew R.; Endres, Matthew W.; Cook, Rebecca T.; Gregory, Brian D.

    2011-01-01

    One recently identified mechanism that regulates mRNA abundance is RNA silencing, and pioneering work in Arabidopsis thaliana and other genetic model organisms helped define this process. RNA silencing pathways are triggered by either self-complementary fold-back structures or the production of double-stranded RNA (dsRNA) that gives rise to small RNAs (smRNAs) known as microRNAs (miRNAs) or small-interfering RNAs (siRNAs). These smRNAs direct sequence-specific regulation of various gene transcripts, repetitive sequences, viruses, and mobile elements via RNA cleavage, translational inhibition, or transcriptional silencing through DNA methylation and heterochromatin formation. Early genetic screens in Arabidopsis were instrumental in uncovering numerous proteins required for these important regulatory pathways. Among the factors identified by these studies were RNA-dependent RNA polymerases (RDRs), which are proteins that synthesize siRNA-producing dsRNA molecules using a single-stranded RNA (ssRNA) molecule as a template. Recently, a growing body of evidence has implicated RDR-dependent RNA silencing in many different aspects of plant biology ranging from reproductive development to pathogen resistance. Here, we focus on the specific functions of the six Arabidopsis RDRs in RNA silencing, their ssRNA substrates and resulting RDR-dependent smRNAs, and the numerous biological functions of these proteins in plant development and stress responses. PMID:22303271

  12. The RNA polymerase II elongation complex.

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    Aso, T; Conaway, J W; Conaway, R C

    1995-11-01

    The initiation stage of transcription by RNA polymerase II has long been regarded as the primary site for regulation of eukaryotic gene expression. Nevertheless, a growing body of evidence reveals that the RNA polymerase II elongation complex is also a major target for regulation. Biochemical studies are implicating an increasing number of transcription factors in the regulation of elongation, and these transcription factors are being found to function by a diverse collection of mechanisms. Moreover, unexpected features of the structure and catalytic mechanism of RNA polymerase II are forcing a reconsideration of long-held views on the mechanics of some of the most basic aspects of polymerase function. In this review, we will describe recent insights into the structures and functions of RNA polymerase II and the transcription factors that control its activity during the elongation stage of eukaryotic messenger RNA synthesis.

  13. Reinitiated viral RNA-dependent RNA polymerase resumes replication at a reduced rate

    NARCIS (Netherlands)

    Vilfan, I.D.; Candelli, A.; Hage, S.; Aalto, A.P.; Poranen, M.M.; Bamford, D.H.; Dekker, N.H.

    2008-01-01

    RNA-dependent RNA polymerases (RdRP) form an important class of enzymes that is responsible for genome replication and transcription in RNA viruses and involved in the regulation of RNA interference in plants and fungi. The RdRP kinetics have been extensively studied, but pausing, an important regul

  14. Norovirus proteinase-polymerase and polymerase are both active forms of RNA-dependent RNA polymerase.

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    Belliot, Gaël; Sosnovtsev, Stanislav V; Chang, Kyeong-Ok; Babu, Vijay; Uche, Uzo; Arnold, Jamie J; Cameron, Craig E; Green, Kim Y

    2005-02-01

    In vitro mapping studies of the MD145 norovirus (Caliciviridae) ORF1 polyprotein identified two stable cleavage products containing the viral RNA-dependent RNA polymerase (RdRp) domains: ProPol (a precursor comprised of both the proteinase and polymerase) and Pol (the mature polymerase). The goal of this study was to identify the active form (or forms) of the norovirus polymerase. The recombinant ProPol (expressed as Pro(-)Pol with an inactivated proteinase domain to prevent autocleavage) and recombinant Pol were purified after synthesis in bacteria and shown to be active RdRp enzymes. In addition, the mutant His-E1189A-ProPol protein (with active proteinase but with the natural ProPol cleavage site blocked) was active as an RdRp, confirming that the norovirus ProPol precursor could possess two enzymatic activities simultaneously. The effects of several UTP analogs on the RdRp activity of the norovirus and feline calicivirus Pro(-)Pol enzymes were compared and found to be similar. Our data suggest that the norovirus ProPol is a bifunctional enzyme during virus replication. The availability of this recombinant ProPol enzyme might prove useful in the development of antiviral drugs for control of the noroviruses associated with acute gastroenteritis.

  15. RNA-Dependent RNA Polymerase Activity in Influenza Virions

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    Penhoet, Edward; Miller, Henry; Doyle, Michael; Blatti, Stanley

    1971-01-01

    An RNA-dependent RNA polymerase activity has been detected in purified preparations of influenza virus. In contrast to the replicase activity induced in influenza-infected cells, the virion-associated enzyme has an absolute requirement for Mn++. Most of the RNA synthesized in vitro is complementary to virion RNA. PMID:5288388

  16. Free RNA polymerase in Escherichia coli.

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    Patrick, Michael; Dennis, Patrick P; Ehrenberg, Mans; Bremer, Hans

    2015-12-01

    The frequencies of transcription initiation of regulated and constitutive genes depend on the concentration of free RNA polymerase holoenzyme [Rf] near their promoters. Although RNA polymerase is largely confined to the nucleoid, it is difficult to determine absolute concentrations of [Rf] at particular locations within the nucleoid structure. However, relative concentrations of free RNA polymerase at different growth rates, [Rf]rel, can be estimated from the activities of constitutive promoters. Previous studies indicated that the rrnB P2 promoter is constitutive and that [Rf]rel in the vicinity of rrnB P2 increases with increasing growth rate. Recently it has become possible to directly visualize Rf in growing Escherichia coli cells. Here we examine some of the important issues relating to gene expression based on these new observations. We conclude that: (i) At a growth rate of 2 doublings/h, there are about 1000 free and 2350 non-specifically DNA-bound RNA polymerase molecules per average cell (12 and 28%, respectively, of 8400 total) which are in rapid equilibrium. (ii) The reversibility of the non-specific binding generates more than 1000 free RNA polymerase molecules every second in the immediate vicinity of the DNA. Of these, most rebind non-specifically to the DNA within a few ms; the frequency of non-specific binding is at least two orders of magnitude greater than specific binding and transcript initiation. (iii) At a given amount of RNA polymerase per cell, [Rf] and the density of non-specifically DNA-bound RNA polymerase molecules along the DNA both vary reciprocally with the amount of DNA in the cell. (iv) At 2 doublings/h an E. coli cell contains, on the average, about 1 non-specifically bound RNA polymerase per 9 kbp of DNA and 1 free RNA polymerase per 20 kbp of DNA. However some DNA regions (i.e. near active rRNA operons) may have significantly higher than average [Rf].

  17. RNA polymerase activity of Ustilago maydis virus

    Energy Technology Data Exchange (ETDEWEB)

    Yie, S.W.

    1986-01-01

    Ustilago maydis virus has an RNA polymerase enzyme which is associated with virion capsids. In the presence of Mg/sup 2 +/ ion and ribonucleotide triphosphate, the enzyme catalyzes the in vitro synthesis of mRNA by using dsRNA as a template. The products of the UmV RNA polymerase were both ssRNA and dsRNA. The dsRNA was determined by characteristic mobilities in gel electrophoresis, lack of sensitivity to RNase, and specific hybridization tests. The ssRNAs were identified by elution from a CF-11 column and by their RNase sensitivity. On the basis of the size of ssRNAs, it was concluded that partial transcripts were produced from H dsRNA segments, and full length transcripts were produced from M and L dsRNA segments. The following observations indicates that transcription occurs by strand displacement; (1) Only the positive strand of M2 dsRNA was labeled by the in vitro reaction. (2) The M2 dsRNA which had been labeled with /sup 32/''P-UTP in vitro could be chased from dsRNA with unlabeled UTP. The transcription products of three UmV strains were compared, and the overall pattern of transcription was very similar among them.

  18. Extraction of nuclei from sonchus yellow net rhabdovirus-infected plants yields a polymerase that synthesizes viral mRNAs and polyadenylated plus-strand leader RNA.

    OpenAIRE

    Wagner, J D; Choi, T. J.; Jackson, A O

    1996-01-01

    Although the primary sequence of the genome of the plant rhabdovirus sonchus yellow net virus (SYNV) has been determined, little is known about the composition of the viral polymerase or the mechanics of viral transcription and replication. In this paper, we report the partial isolation and characterization of an active SYNV polymerase from nuclei of SYNV-infected leaf tissue. A salt extraction procedure is shown to be an effective purification step for recovery of the polymerase from the nuc...

  19. Structural biology of bacterial RNA polymerase.

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    Murakami, Katsuhiko S

    2015-05-11

    Since its discovery and characterization in the early 1960s (Hurwitz, J. The discovery of RNA polymerase. J. Biol. Chem. 2005, 280, 42477-42485), an enormous amount of biochemical, biophysical and genetic data has been collected on bacterial RNA polymerase (RNAP). In the late 1990s, structural information pertaining to bacterial RNAP has emerged that provided unprecedented insights into the function and mechanism of RNA transcription. In this review, I list all structures related to bacterial RNAP (as determined by X-ray crystallography and NMR methods available from the Protein Data Bank), describe their contributions to bacterial transcription research and discuss the role that small molecules play in inhibiting bacterial RNA transcription.

  20. Structural Biology of Bacterial RNA Polymerase

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    Katsuhiko S. Murakami

    2015-05-01

    Full Text Available Since its discovery and characterization in the early 1960s (Hurwitz, J. The discovery of RNA polymerase. J. Biol. Chem. 2005, 280, 42477–42485, an enormous amount of biochemical, biophysical and genetic data has been collected on bacterial RNA polymerase (RNAP. In the late 1990s, structural information pertaining to bacterial RNAP has emerged that provided unprecedented insights into the function and mechanism of RNA transcription. In this review, I list all structures related to bacterial RNAP (as determined by X-ray crystallography and NMR methods available from the Protein Data Bank, describe their contributions to bacterial transcription research and discuss the role that small molecules play in inhibiting bacterial RNA transcription.

  1. RNA polymerase II collision interrupts convergent transcription

    DEFF Research Database (Denmark)

    Hobson, David J; Wei, Wu; Steinmetz, Lars M

    2012-01-01

    Antisense noncoding transcripts, genes-within-genes, and convergent gene pairs are prevalent among eukaryotes. The existence of such transcription units raises the question of what happens when RNA polymerase II (RNAPII) molecules collide head-to-head. Here we use a combination of biochemical...

  2. The RNA polymerase I transcription machinery

    OpenAIRE

    Russell, Jackie; Zomerdijk, Joost C. B. M.

    2006-01-01

    The rRNAs constitute the catalytic and structural components of the ribosome, the protein synthesis machinery of cells. The level of rRNA synthesis, mediated by Pol I (RNA polymerase I), therefore has a major impact on the life and destiny of a cell. In order to elucidate how cells achieve the stringent control of Pol I transcription, matching the supply of rRNA to demand under different cellular growth conditions, it is essential to understand the components and mechanics of the Pol I transc...

  3. Chemical fidelity of an RNA polymerase ribozyme

    DEFF Research Database (Denmark)

    Attwater, J.; Tagami, S.; Kimoto, M.

    2013-01-01

    The emergence of catalytically active RNA enzymes (ribozymes) is widely believed to have been an important transition in the origin of life. In the context of a likely heterogeneous chemical environment, substrate specificity and selectivity of these primordial enzymes would have been critical...... for function. Here we have explored the chemical fidelity, i.e. substrate selectivity and specificity for both single and multiple catalytic steps of the Z RNA polymerase ribozyme-a modern day analogue of the primordial RNA replicase. Using a wide range of nucleotide analogues and ionic conditions, we observe...

  4. Nucleolin Is Required for RNA Polymerase I Transcription In Vivo▿

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    Rickards, Brenden; Flint, S. J.; Cole, Michael D.; LeRoy, Gary

    2007-01-01

    Eukaryotic genomes are packaged with histones and accessory proteins in the form of chromatin. RNA polymerases and their accessory proteins are sufficient for transcription of naked DNA, but not of chromatin, templates in vitro. In this study, we purified and identified nucleolin as a protein that allows RNA polymerase II to transcribe nucleosomal templates in vitro. As immunofluorescence confirmed that nucleolin localizes primarily to nucleoli with RNA polymerase I, we demonstrated that nucleolin allows RNA polymerase I transcription of chromatin templates in vitro. The results of chromatin immunoprecipitation experiments established that nucleolin is associated with chromatin containing rRNA genes transcribed by RNA polymerase I but not with genes transcribed by RNA polymerase II or III. Knockdown of nucleolin by RNA interference resulted in specific inhibition of RNA polymerase I transcription. We therefore propose that an important function of nucleolin is to permit RNA polymerase I to transcribe nucleolar chromatin. PMID:17130237

  5. Origin and Evolution of RNA-Dependent RNA Polymerase.

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    de Farias, Savio T; Dos Santos Junior, Ariosvaldo P; Rêgo, Thais G; José, Marco V

    2017-01-01

    RNA-dependent RNA polymerases (RdRp) are very ancient enzymes and are essential for all viruses with RNA genomes. We reconstruct the origin and evolution of this polymerase since the initial stages of the origin of life. The origin of the RdRp was traced back from tRNA ancestors. At the origin of the RdRp the most ancient part of the protein is the cofactor-binding site that had the capacity of binding to simple molecules as magnesium, calcium, and ribonucleotides. Our results suggest that RdRp originated from junctions of proto-tRNAs that worked as the first genes at the emergence of the primitive translation system, where the RNA was the informational molecule. The initial domain, worked as a building block for the emergence of the fingers and thumb domains. From the ancestral RdRp, we could establish the evolutionary stages of viral evolution from a rooted ancestor to modern viruses. It was observed that the selective pressure under the RdRp was the organization and functioning of the genome, where RNA double-stranded and RNA single-stranded virus formed a separate group. We propose an evolutionary route to the polymerases and the results suggest an ancient scenario for the origin of RNA viruses.

  6. Origin and Evolution of RNA-Dependent RNA Polymerase

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    Savio T. de Farias

    2017-09-01

    Full Text Available RNA-dependent RNA polymerases (RdRp are very ancient enzymes and are essential for all viruses with RNA genomes. We reconstruct the origin and evolution of this polymerase since the initial stages of the origin of life. The origin of the RdRp was traced back from tRNA ancestors. At the origin of the RdRp the most ancient part of the protein is the cofactor-binding site that had the capacity of binding to simple molecules as magnesium, calcium, and ribonucleotides. Our results suggest that RdRp originated from junctions of proto-tRNAs that worked as the first genes at the emergence of the primitive translation system, where the RNA was the informational molecule. The initial domain, worked as a building block for the emergence of the fingers and thumb domains. From the ancestral RdRp, we could establish the evolutionary stages of viral evolution from a rooted ancestor to modern viruses. It was observed that the selective pressure under the RdRp was the organization and functioning of the genome, where RNA double-stranded and RNA single-stranded virus formed a separate group. We propose an evolutionary route to the polymerases and the results suggest an ancient scenario for the origin of RNA viruses.

  7. Biochemical characterization of rhinovirus RNA-dependent RNA polymerase.

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    Hung, Magdeleine; Gibbs, Craig S; Tsiang, Manuel

    2002-11-01

    Human rhinoviruses (HRV) represent the single most important causative agent of the common cold. The HRV genome encodes an RNA-dependent RNA polymerase (RdRp) designated 3D polymerase that is required for replication of the HRV RNA genome. We have expressed and purified recombinant HRV-16 3D polymerase to near homogeneity from Escherichia coli transformed with an expression plasmid containing the full-length 460 amino acid HRV-16 3D sequence with a methionine at the N-terminus and a glycine-serine linker followed by a 6-histidine affinity tag at the C-terminus. The purified recombinant protein has rifampicin-resistant activity in a poly(A)-dependent poly(U) polymerase assay while corresponding fractions similarly purified from E. coli transformed with an expression plasmid without the HRV-16 3D sequence showed no activity. The optimal conditions for temperature, pH, divalent cations Mg(2+) and Mn(2+), and KCl were determined. The recombinant protein has RNA polymerase activity on homopolymeric templates poly(A) and poly(C) and heteropolymeric RNA templates primed with either RNA or DNA oligonucleotide primers or self-primed by a copy-back mechanism. A unique, secondary structureless heteropolymeric RNA template that is an efficient substrate was developed to facilitate kinetic characterizations of the enzyme. In the presence of Mg(2+), the enzyme displayed strong base and sugar specificity. However, when Mg(2+) was replaced by Mn(2+) specificity for ribonucleotides was lost, utilization of deoxynucleotides became possible and primer-independent activity was observed on the poly(C) template. Zn(2+) was found to inhibit HRV-16 3D polymerase with an IC(50) as low as 0.6 microM by a mechanism distinct from the magnesium ion stimulation. The activity of this 6His-tagged HRV-16 3D polymerase was compared with that of a recombinant HRV-16 3D polymerase expressed without the 6His-tag and was found to be identical. The availability of recombinant rhinovirus RdRp in a

  8. Modeling RNA polymerase interaction in mitochondria of chordates

    Directory of Open Access Journals (Sweden)

    Lyubetsky Vassily A

    2012-08-01

    Full Text Available Abstract Background In previous work, we introduced a concept, a mathematical model and its computer realization that describe the interaction between bacterial and phage type RNA polymerases, protein factors, DNA and RNA secondary structures during transcription, including transcription initiation and termination. The model accurately reproduces changes of gene transcription level observed in polymerase sigma-subunit knockout and heat shock experiments in plant plastids. The corresponding computer program and a user guide are available at http://lab6.iitp.ru/en/rivals. Here we apply the model to the analysis of transcription and (partially translation processes in the mitochondria of frog, rat and human. Notably, mitochondria possess only phage-type polymerases. We consider the entire mitochondrial genome so that our model allows RNA polymerases to complete more than one circle on the DNA strand. Results Our model of RNA polymerase interaction during transcription initiation and elongation accurately reproduces experimental data obtained for plastids. Moreover, it also reproduces evidence on bulk RNA concentrations and RNA half-lives in the mitochondria of frog, human with or without the MELAS mutation, and rat with normal (euthyroid or hyposecretion of thyroid hormone (hypothyroid. The transcription characteristics predicted by the model include: (i the fraction of polymerases terminating at a protein-dependent terminator in both directions (the terminator polarization, (ii the binding intensities of the regulatory protein factor (mTERF with the termination site and, (iii the transcription initiation intensities (initiation frequencies of all promoters in all five conditions (frog, healthy human, human with MELAS syndrome, healthy rat, and hypothyroid rat with aberrant mtDNA methylation. Using the model, absolute levels of all gene transcription can be inferred from an arbitrary array of the three transcription characteristics, whereas, for

  9. RNA polymerase: the vehicle of transcription.

    Science.gov (United States)

    Borukhov, Sergei; Nudler, Evgeny

    2008-03-01

    RNA polymerase (RNAP) is the principal enzyme of gene expression and regulation for all three divisions of life: Eukaryota, Archaea and Bacteria. Recent progress in the structural and biochemical characterization of RNAP illuminates this enzyme as a flexible, multifunctional molecular machine. During each step of the transcription cycle, RNAP undergoes elaborate conformational changes. As many fundamental and previously mysterious aspects of how RNAP works begin to be understood, this enzyme reveals intriguing similarities to man-made engineered devices. These resemblances can be found in the mechanics of RNAP-DNA complex formation, in RNA chain initiation and in the elongation processes. Here we highlight recent advances in understanding RNAP function and regulation.

  10. A dominant mutation in mediator of paramutation2, one of three second-largest subunits of a plant-specific RNA polymerase, disrupts multiple siRNA silencing processes.

    Directory of Open Access Journals (Sweden)

    Lyudmila Sidorenko

    2009-11-01

    Full Text Available Paramutation involves homologous sequence communication that leads to meiotically heritable transcriptional silencing. We demonstrate that mop2 (mediator of paramutation2, which alters paramutation at multiple loci, encodes a gene similar to Arabidopsis NRPD2/E2, the second-largest subunit of plant-specific RNA polymerases IV and V. In Arabidopsis, Pol-IV and Pol-V play major roles in RNA-mediated silencing and a single second-largest subunit is shared between Pol-IV and Pol-V. Maize encodes three second-largest subunit genes: all three genes potentially encode full length proteins with highly conserved polymerase domains, and each are expressed in multiple overlapping tissues. The isolation of a recessive paramutation mutation in mop2 from a forward genetic screen suggests limited or no functional redundancy of these three genes. Potential alternative Pol-IV/Pol-V-like complexes could provide maize with a greater diversification of RNA-mediated transcriptional silencing machinery relative to Arabidopsis. Mop2-1 disrupts paramutation at multiple loci when heterozygous, whereas previously silenced alleles are only up-regulated when Mop2-1 is homozygous. The dramatic reduction in b1 tandem repeat siRNAs, but no disruption of silencing in Mop2-1 heterozygotes, suggests the major role for tandem repeat siRNAs is not to maintain silencing. Instead, we hypothesize the tandem repeat siRNAs mediate the establishment of the heritable silent state-a process fully disrupted in Mop2-1 heterozygotes. The dominant Mop2-1 mutation, which has a single nucleotide change in a domain highly conserved among all polymerases (E. coli to eukaryotes, disrupts both siRNA biogenesis (Pol-IV-like and potentially processes downstream (Pol-V-like. These results suggest either the wild-type protein is a subunit in both complexes or the dominant mutant protein disrupts both complexes. Dominant mutations in the same domain in E. coli RNA polymerase suggest a model for Mop2

  11. In vitro transcription of Sonchus yellow net virus RNA by a virus-associated RNA-dependent RNA polymerase.

    NARCIS (Netherlands)

    Flore, P.H.

    1986-01-01

    The aim of the investigation presented in this thesis was to elucidate the nature of the RNA- dependent RNA polymerase, thought to be associated with Sonchus yellow net virus (SYNV), a rhabdovirus infecting plants. This research was initiated to shed light on the transcription activity in rhabdoviru

  12. Methylated-antibody affinity purification to improve proteomic identification of plant RNA polymerase Pol V complex and the interacting proteins

    Science.gov (United States)

    Qin, Guochen; Ma, Jun; Chen, Xiaomei; Chu, Zhaoqing; She, Yi-Min

    2017-01-01

    Affinity purification followed by enzymatic digestion and mass spectrometry has been widely utilized for the sensitive detection of interacting proteins and protein complexes in various organisms. In plants, the method is technically challenging due to the low abundance proteins, non-specific binding and difficulties of eluting interacting proteins from antibody beads. In this report, we describe a strategy to modify antibodies by reductive methylation of lysines without affecting their binding properties, followed by on-bead digestion of bound proteins with endoproteinase Lys-C. By this method, the antibody remains intact and does not interfere with the downstream identification of interacting proteins. Non-specific binding proteins were excluded using 14N/15N-metabolic labeling of wild-type and the transgenic plant counterparts. The method was employed to identify 12 co-immunoprecipitated protein subunits in Pol V complex and to discover 17 potential interacting protein targets in Arabidopsis. Our results demonstrated that the modification of antibodies by reductive dimethylation can improve the reliability and sensitivity of identifying low-abundance proteins through on-bead digestion and mass spectrometry. We also show that coupling this technique with chemical crosslinking enables in-depth characterization of endogenous protein complexes and the protein-protein interaction networks including mapping the surface topology and post-translational modifications of interacting proteins. PMID:28224978

  13. Emerging roles for RNA polymerase II CTD in Arabidopsis.

    Science.gov (United States)

    Hajheidari, Mohsen; Koncz, Csaba; Eick, Dirk

    2013-11-01

    Post-translational modifications of the carboxy-terminal domain of the largest subunit of RNA polymerase II (RNAPII CTD) provide recognition marks to coordinate recruitment of numerous nuclear factors controlling transcription, cotranscriptional RNA processing, chromatin remodeling, and RNA export. Compared with the progress in yeast and mammals, deciphering the regulatory roles of position-specific combinatorial CTD modifications, the so-called CTD code, is still at an early stage in plants. In this review, we discuss some of the recent advances in understanding of the molecular mechanisms controlling the deposition and recognition of RNAPII CTD marks in plants during the transcriptional cycle and highlight some intriguing differences between regulatory components characterized in yeast, mammals, and plants.

  14. The RNA polymerase I transcription machinery.

    Science.gov (United States)

    Russell, Jackie; Zomerdijk, Joost C B M

    2006-01-01

    The rRNAs constitute the catalytic and structural components of the ribosome, the protein synthesis machinery of cells. The level of rRNA synthesis, mediated by Pol I (RNA polymerase I), therefore has a major impact on the life and destiny of a cell. In order to elucidate how cells achieve the stringent control of Pol I transcription, matching the supply of rRNA to demand under different cellular growth conditions, it is essential to understand the components and mechanics of the Pol I transcription machinery. In this review, we discuss: (i) the molecular composition and functions of the Pol I enzyme complex and the two main Pol I transcription factors, SL1 (selectivity factor 1) and UBF (upstream binding factor); (ii) the interplay between these factors during pre-initiation complex formation at the rDNA promoter in mammalian cells; and (iii) the cellular control of the Pol I transcription machinery.

  15. Solving the RNA polymerase I structural puzzle

    Energy Technology Data Exchange (ETDEWEB)

    Moreno-Morcillo, María [European Molecular Biology Laboratory, Meyerhofstrasse 1, 69117 Heidelberg (Germany); Taylor, Nicholas M. I. [Consejo Superior de Investigaciones Científicas, Ramiro de Maeztu 9, 28040 Madrid (Spain); Gruene, Tim [Georg-August-University, Tammannstrasse 4, 37077 Göttingen (Germany); Legrand, Pierre [SOLEIL Synchrotron, L’Orme de Merisiers, Saint Aubin, Gif-sur-Yvette (France); Rashid, Umar J. [European Molecular Biology Laboratory, Meyerhofstrasse 1, 69117 Heidelberg (Germany); Ruiz, Federico M. [Consejo Superior de Investigaciones Científicas, Ramiro de Maeztu 9, 28040 Madrid (Spain); Steuerwald, Ulrich; Müller, Christoph W. [European Molecular Biology Laboratory, Meyerhofstrasse 1, 69117 Heidelberg (Germany); Fernández-Tornero, Carlos, E-mail: cftornero@cib.csic.es [Consejo Superior de Investigaciones Científicas, Ramiro de Maeztu 9, 28040 Madrid (Spain); European Molecular Biology Laboratory, Meyerhofstrasse 1, 69117 Heidelberg (Germany)

    2014-10-01

    Details of the RNA polymerase I crystal structure determination provide a framework for solution of the structures of other multi-subunit complexes. Simple crystallographic experiments are described to extract relevant biological information such as the location of the enzyme active site. Knowing the structure of multi-subunit complexes is critical to understand basic cellular functions. However, when crystals of these complexes can be obtained they rarely diffract beyond 3 Å resolution, which complicates X-ray structure determination and refinement. The crystal structure of RNA polymerase I, an essential cellular machine that synthesizes the precursor of ribosomal RNA in the nucleolus of eukaryotic cells, has recently been solved. Here, the crucial steps that were undertaken to build the atomic model of this multi-subunit enzyme are reported, emphasizing how simple crystallographic experiments can be used to extract relevant biological information. In particular, this report discusses the combination of poor molecular replacement and experimental phases, the application of multi-crystal averaging and the use of anomalous scatterers as sequence markers to guide tracing and to locate the active site. The methods outlined here will likely serve as a reference for future structural determination of large complexes at low resolution.

  16. The role of hydrogen peroxide and nitric oxide in the induction of plant-encoded RNA-dependent RNA polymerase 1 in the basal defense against Tobacco mosaic virus.

    Directory of Open Access Journals (Sweden)

    Yang-Wen-Ke Liao

    Full Text Available Plant RNA-dependent RNA Polymerase 1 (RDR1 is an important element of the RNA silencing pathway in the plant defense against viruses. RDR1 expression can be elicited by viral infection and salicylic acid (SA, but the mechanisms of signaling during this process remains undefined. The involvement of hydrogen peroxide (H2O2 and nitric oxide (NO in RDR1 induction in the compatible interactions between Tobacco mosaic tobamovirus (TMV and Nicotiana tabacum, Nicotiana benthamiana, and Arabidopsis thaliana was examined. TMV inoculation onto the lower leaves of N. tabacum induced the rapid accumulation of H2O2 and NO followed by the increased accumulation of RDR1 transcripts in the non-inoculated upper leaves. Pretreatment with exogenous H2O2 and NO on upper leaf led to increased RDR1 expression and systemic TMV resistance. Conversely, dimethylthiourea (an H2O2 scavenger and 2-(4-carboxyphenyl- 4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (an NO scavenger partly blocked TMV- and SA-induced RDR1 expression and increased TMV susceptibility, whereas pretreatment with exogenous H2O2 and NO failed to diminish TMV infection in N. benthamiana plants with naturally occurring RDR1 loss-of-function. Furthermore, in N. tabacum and A. thaliana, TMV-induced H2O2 accumulation was NO-dependent, whereas NO generation was not affected by H2O2. These results suggest that, in response to TMV infection, H2O2 acts downstream of NO to mediate induction of RDR1, which plays a critical role in strengthening RNA silencing to restrict systemic viral infection.

  17. Proteinase-Polymerase Precursor as the Active Form of Feline Calicivirus RNA-Dependent RNA Polymerase

    OpenAIRE

    Wei, Lai; Huhn, Jason S.; Mory, Aaron; Pathak, Harsh B.; Sosnovtsev, Stanislav V.; Green, Kim Y.; Cameron, Craig E.

    2001-01-01

    The objective of this study was to identify the active form of the feline calicivirus (FCV) RNA-dependent RNA polymerase (RdRP). Multiple active forms of the FCV RdRP were identified. The most active enzyme was the full-length proteinase-polymerase (Pro-Pol) precursor protein, corresponding to amino acids 1072 to 1763 of the FCV polyprotein encoded by open reading frame 1 of the genome. Deletion of 163 amino acids from the amino terminus of Pro-Pol (the Val-1235 amino terminus) caused a three...

  18. Baculovirus RNA Polymerase: Activities, Composition, and Evolution

    Institute of Scientific and Technical Information of China (English)

    A.Lorena Passarelli

    2007-01-01

    Baculoviruses are the only nuclear replicating DNA-containing viruses that encode their own DNA-directed RNA polymerase (RNAP). The baculovirus RNAP is specific for the transcription of genes expressed after virus DNA replication. It is composed of four subunits, making it the simplest multisubunit RNAP known. Two subunits contain motifs found at the catalytic center of other RNAPs and a third has capping enzyme functions. The function of the fourth subunit is not known. Structural studies on this unique RNAP will provide new insights into the functions of this enzyme and the regulation of viral genes and may be instrumental to optimize the baculovirus gene expression system.

  19. ppGpp: magic beyond RNA polymerase.

    Science.gov (United States)

    Dalebroux, Zachary D; Swanson, Michele S

    2012-02-16

    During stress, bacteria undergo extensive physiological transformations, many of which are coordinated by ppGpp. Although ppGpp is best known for enhancing cellular resilience by redirecting the RNA polymerase (RNAP) to certain genes, it also acts as a signal in many other cellular processes in bacteria. After a brief overview of ppGpp biosynthesis and its impact on promoter selection by RNAP, we discuss how bacteria exploit ppGpp to modulate the synthesis, stability or activity of proteins or regulatory RNAs that are crucial in challenging environments, using mechanisms beyond the direct regulation of RNAP activity.

  20. Nascent transcription affected by RNA polymerase IV in Zea mays.

    Science.gov (United States)

    Erhard, Karl F; Talbot, Joy-El R B; Deans, Natalie C; McClish, Allison E; Hollick, Jay B

    2015-04-01

    All eukaryotes use three DNA-dependent RNA polymerases (RNAPs) to create cellular RNAs from DNA templates. Plants have additional RNAPs related to Pol II, but their evolutionary role(s) remain largely unknown. Zea mays (maize) RNA polymerase D1 (RPD1), the largest subunit of RNA polymerase IV (Pol IV), is required for normal plant development, paramutation, transcriptional repression of certain transposable elements (TEs), and transcriptional regulation of specific alleles. Here, we define the nascent transcriptomes of rpd1 mutant and wild-type (WT) seedlings using global run-on sequencing (GRO-seq) to identify the broader targets of RPD1-based regulation. Comparisons of WT and rpd1 mutant GRO-seq profiles indicate that Pol IV globally affects transcription at both transcriptional start sites and immediately downstream of polyadenylation addition sites. We found no evidence of divergent transcription from gene promoters as seen in mammalian GRO-seq profiles. Statistical comparisons identify genes and TEs whose transcription is affected by RPD1. Most examples of significant increases in genic antisense transcription appear to be initiated by 3'-proximal long terminal repeat retrotransposons. These results indicate that maize Pol IV specifies Pol II-based transcriptional regulation for specific regions of the maize genome including genes having developmental significance.

  1. The punctilious RNA polymerase II core promoter.

    Science.gov (United States)

    Vo Ngoc, Long; Wang, Yuan-Liang; Kassavetis, George A; Kadonaga, James T

    2017-07-01

    The signals that direct the initiation of transcription ultimately converge at the core promoter, which is the gateway to transcription. Here we provide an overview of the RNA polymerase II core promoter in bilateria (bilaterally symmetric animals). The core promoter is diverse in terms of its composition and function yet is also punctilious, as it acts with strict rules and precision. We additionally describe an expanded view of the core promoter that comprises the classical DNA sequence motifs, sequence-specific DNA-binding transcription factors, chromatin signals, and DNA structure. This model may eventually lead to a more unified conceptual understanding of the core promoter. © 2017 Vo ngoc et al.; Published by Cold Spring Harbor Laboratory Press.

  2. Basic mechanism of transcription by RNA polymerase II

    Science.gov (United States)

    Svetlov, Vladimir; Nudler, Evgeny

    2012-01-01

    RNA polymerase II-like enzymes carry out transcription of genomes in Eukaryota, Archaea, and some viruses. They also exhibit fundamental similarity to RNA polymerases from bacteria, chloroplasts, and mitochondria. In this review we take an inventory of recent studiesilluminating different steps of basic transcription mechanism, likely common for most multi-subunit RNA polymerases. Through the amalgamation of structural and computational chemistry data we attempt to highlight the most feasible reaction pathway for the two-metal nucleotidyl transfer mechanism, and to evaluate the way catalysis can be linked to translocation in the mechano-chemical cycle catalyzed by RNA polymerase II. PMID:22982365

  3. Primer-dependent and primer-independent initiation of double stranded RNA synthesis by purified arabidopsis RNA-dependent RNA polymerases RDR2 and RDR6

    DEFF Research Database (Denmark)

    Devert, Anthony; Fabre, Nicolas; Floris, Maina Huguette Joséphine

    2015-01-01

    Cellular RNA-dependent RNA polymerases (RDRs) are fundamental components of RNA silencing in plants and many other eukaryotes. In Arabidopsis thaliana genetic studies have demonstrated that RDR2 and RDR6 are involved in the synthesis of double stranded RNA (dsRNA) from single stranded RNA (ssRNA......-dependent initiation to generate dsRNA from a transcript targeted by primary siRNA or microRNA (miRNA). However, the biochemical activities of RDR proteins are still partly understood. Here, we obtained active recombinant RDR2 and RDR6 in a purified form. We demonstrate that RDR2 and RDR6 have primer......-independent and primer-dependent RNA polymerase activities with different efficiencies. We further show that RDR2 and RDR6 can initiate dsRNA synthesis either by elongation of 21- to 24- nucleotides RNAs hybridized to complementary RNA template or by elongation of self-primed RNA template. These findings provide new...

  4. The RNA polymerase of marine cyanophage Syn5.

    Science.gov (United States)

    Zhu, Bin; Tabor, Stanley; Raytcheva, Desislava A; Hernandez, Alfredo; King, Jonathan A; Richardson, Charles C

    2013-02-01

    A single subunit DNA-dependent RNA polymerase was identified and purified to apparent homogeneity from cyanophage Syn5 that infects the marine cyanobacteria Synechococcus. Syn5 is homologous to bacteriophage T7 that infects Escherichia coli. Using the purified enzyme its promoter has been identified by examining transcription of segments of Syn5 DNA and sequencing the 5'-termini of the transcripts. Only two Syn5 RNAP promoters, having the sequence 5'-ATTGGGCACCCGTAA-3', are found within the Syn5 genome. One promoter is located within the Syn5 RNA polymerase gene and the other is located close to the right genetic end of the genome. The purified enzyme and its promoter have enabled a determination of the requirements for transcription. Unlike the salt-sensitive bacteriophage T7 RNA polymerase, this marine RNA polymerase requires 160 mm potassium for maximal activity. The optimal temperature for Syn5 RNA polymerase is 24 °C, much lower than that for T7 RNA polymerase. Magnesium is required as a cofactor although some activity is observed with ferrous ions. Syn5 RNA polymerase is more efficient in utilizing low concentrations of ribonucleotides than T7 RNA polymerase.

  5. Extragenic accumulation of RNA polymerase II enhances transcription by RNA polymerase III.

    Directory of Open Access Journals (Sweden)

    Imke Listerman

    2007-11-01

    Full Text Available Recent genomic data indicate that RNA polymerase II (Pol II function extends beyond conventional transcription of primarily protein-coding genes. Among the five snRNAs required for pre-mRNA splicing, only the U6 snRNA is synthesized by RNA polymerase III (Pol III. Here we address the question of how Pol II coordinates the expression of spliceosome components, including U6. We used chromatin immunoprecipitation (ChIP and high-resolution mapping by PCR to localize both Pol II and Pol III to snRNA gene regions. We report the surprising finding that Pol II is highly concentrated approximately 300 bp upstream of all five active human U6 genes in vivo. The U6 snRNA, an essential component of the spliceosome, is synthesized by Pol III, whereas all other spliceosomal snRNAs are Pol II transcripts. Accordingly, U6 transcripts were terminated in a Pol III-specific manner, and Pol III localized to the transcribed gene regions. However, synthesis of both U6 and U2 snRNAs was alpha-amanitin-sensitive, indicating a requirement for Pol II activity in the expression of both snRNAs. Moreover, both Pol II and histone tail acetylation marks were lost from U6 promoters upon alpha-amanitin treatment. The results indicate that Pol II is concentrated at specific genomic regions from which it can regulate Pol III activity by a general mechanism. Consequently, Pol II coordinates expression of all RNA and protein components of the spliceosome.

  6. RNA-dependent RNA polymerases from cowpea mosaic virus-infected cowpea leaves

    NARCIS (Netherlands)

    Dorssers, L.C.J.

    1983-01-01

    The aim of the research described in this thesis was the purification and identification of the RNA-dependent RNA polymerase engaged in replicating viral RNA in cowpea mosaic virus (CPMV)- infected cowpea leaves.Previously, an RNA-dependent RNA polymerase produced upon infection of Vigna unguiculata

  7. Persistent nuclear actin filaments inhibit transcription by RNA polymerase II.

    Science.gov (United States)

    Serebryannyy, Leonid A; Parilla, Megan; Annibale, Paolo; Cruz, Christina M; Laster, Kyle; Gratton, Enrico; Kudryashov, Dmitri; Kosak, Steven T; Gottardi, Cara J; de Lanerolle, Primal

    2016-09-15

    Actin is abundant in the nucleus and it is clear that nuclear actin has important functions. However, mystery surrounds the absence of classical actin filaments in the nucleus. To address this question, we investigated how polymerizing nuclear actin into persistent nuclear actin filaments affected transcription by RNA polymerase II. Nuclear filaments impaired nuclear actin dynamics by polymerizing and sequestering nuclear actin. Polymerizing actin into stable nuclear filaments disrupted the interaction of actin with RNA polymerase II and correlated with impaired RNA polymerase II localization, dynamics, gene recruitment, and reduced global transcription and cell proliferation. Polymerizing and crosslinking nuclear actin in vitro similarly disrupted the actin-RNA-polymerase-II interaction and inhibited transcription. These data rationalize the general absence of stable actin filaments in mammalian somatic nuclei. They also suggest a dynamic pool of nuclear actin is required for the proper localization and activity of RNA polymerase II.

  8. Evolutionary connection between the catalytic subunits of DNA-dependent RNA polymerases and eukaryotic RNA-dependent RNA polymerases and the origin of RNA polymerases

    Directory of Open Access Journals (Sweden)

    Aravind L

    2003-01-01

    Full Text Available Abstract Background The eukaryotic RNA-dependent RNA polymerase (RDRP is involved in the amplification of regulatory microRNAs during post-transcriptional gene silencing. This enzyme is highly conserved in most eukaryotes but is missing in archaea and bacteria. No evolutionary relationship between RDRP and other polymerases has been reported so far, hence the origin of this eukaryote-specific polymerase remains a mystery. Results Using extensive sequence profile searches, we identified bacteriophage homologs of the eukaryotic RDRP. The comparison of the eukaryotic RDRP and their homologs from bacteriophages led to the delineation of the conserved portion of these enzymes, which is predicted to harbor the catalytic site. Further, detailed sequence comparison, aided by examination of the crystal structure of the DNA-dependent RNA polymerase (DDRP, showed that the RDRP and the β' subunit of DDRP (and its orthologs in archaea and eukaryotes contain a conserved double-psi β-barrel (DPBB domain. This DPBB domain contains the signature motif DbDGD (b is a bulky residue, which is conserved in all RDRPs and DDRPs and contributes to catalysis via a coordinated divalent cation. Apart from the DPBB domain, no similarity was detected between RDRP and DDRP, which leaves open two scenarios for the origin of RDRP: i RDRP evolved at the onset of the evolution of eukaryotes via a duplication of the DDRP β' subunit followed by dramatic divergence that obliterated the sequence similarity outside the core catalytic domain and ii the primordial RDRP, which consisted primarily of the DPBB domain, evolved from a common ancestor with the DDRP at a very early stage of evolution, during the RNA world era. The latter hypothesis implies that RDRP had been subsequently eliminated from cellular life forms and might have been reintroduced into the eukaryotic genomes through a bacteriophage. Sequence and structure analysis of the DDRP led to further insights into the

  9. Favipiravir (T-705), a novel viral RNA polymerase inhibitor

    OpenAIRE

    Furuta, Yousuke; Gowen, Brian B.; Takahashi, Kazumi; Shiraki, Kimiyasu; Smee, Donald F.; Barnard, Dale L.

    2013-01-01

    Favipiravir (T-705; 6-fluoro-3-hydroxy-2-pyrazinecarboxamide) is an antiviral drug that selectively inhibits the RNA-dependent RNA polymerase of influenza virus. It is phosphoribosylated by cellular enzymes to its active form, favipiravir-ribofuranosyl-5′-triphosphate (RTP). Its antiviral effect is attenuated by the addition of purine nucleic acids, indicating the viral RNA polymerase mistakenly recognizes favipiravir-RTP as a purine nucleotide. Favipiravir is active against a broad range of ...

  10. Cloning the Horse RNA Polymerase I Promoter and Its Application to Studying Influenza Virus Polymerase Activity.

    Science.gov (United States)

    Lu, Gang; He, Dong; Wang, Zengchao; Ou, Shudan; Yuan, Rong; Li, Shoujun

    2016-05-31

    An influenza virus polymerase reconstitution assay based on the human, dog, or chicken RNA polymerase I (PolI) promoter has been developed and widely used to study the polymerase activity of the influenza virus in corresponding cell types. Although it is an important member of the influenza virus family and has been known for sixty years, no studies have been performed to clone the horse PolI promoter or to study the polymerase activity of equine influenza virus (EIV) in horse cells. In our study, the horse RNA PolI promoter was cloned from fetal equine lung cells. Using the luciferase assay, it was found that a 500 bp horse RNA PolI promoter sequence was required for efficient transcription. Then, using the developed polymerase reconstitution assay based on the horse RNA PolI promoter, the polymerase activity of two EIV strains was compared, and equine myxovirus resistance A protein was identified as having the inhibiting EIV polymerase activity function in horse cells. Our study enriches our knowledge of the RNA PolI promoter of eukaryotic species and provides a useful tool for the study of influenza virus polymerase activity in horse cells.

  11. Optical tweezers studies of transcription by eukaryotic RNA polymerases.

    Science.gov (United States)

    Lisica, Ana; Grill, Stephan W

    2017-03-01

    Transcription is the first step in the expression of genetic information and it is carried out by large macromolecular enzymes called RNA polymerases. Transcription has been studied for many years and with a myriad of experimental techniques, ranging from bulk studies to high-resolution transcript sequencing. In this review, we emphasise the advantages of using single-molecule techniques, particularly optical tweezers, to study transcription dynamics. We give an overview of the latest results in the single-molecule transcription field, focusing on transcription by eukaryotic RNA polymerases. Finally, we evaluate recent quantitative models that describe the biophysics of RNA polymerase translocation and backtracking dynamics.

  12. Primer-Dependent and Primer-Independent Initiation of Double Stranded RNA Synthesis by Purified Arabidopsis RNA-Dependent RNA Polymerases RDR2 and RDR6

    Science.gov (United States)

    Devert, Anthony; Fabre, Nicolas; Floris, Maïna; Canard, Bruno; Robaglia, Christophe; Crété, Patrice

    2015-01-01

    Cellular RNA-dependent RNA polymerases (RDRs) are fundamental components of RNA silencing in plants and many other eukaryotes. In Arabidopsis thaliana genetic studies have demonstrated that RDR2 and RDR6 are involved in the synthesis of double stranded RNA (dsRNA) from single stranded RNA (ssRNA) targeted by RNA silencing. The dsRNA is subsequently cleaved by the ribonuclease DICER-like into secondary small interfering RNAs (siRNAs) that reinforce and/or maintain the silenced state of the target RNA. Models of RNA silencing propose that RDRs could use primer-independent and primer-dependent initiation to generate dsRNA from a transcript targeted by primary siRNA or microRNA (miRNA). However, the biochemical activities of RDR proteins are still partly understood. Here, we obtained active recombinant RDR2 and RDR6 in a purified form. We demonstrate that RDR2 and RDR6 have primer-independent and primer-dependent RNA polymerase activities with different efficiencies. We further show that RDR2 and RDR6 can initiate dsRNA synthesis either by elongation of 21- to 24- nucleotides RNAs hybridized to complementary RNA template or by elongation of self-primed RNA template. These findings provide new insights into our understanding of the molecular mechanisms of RNA silencing in plants. PMID:25793874

  13. Understanding the Molecular Basis of RNA Polymerase II Transcription

    OpenAIRE

    Zhang, Su; Wang, Dong

    2013-01-01

    Synthetic nucleic acid analogues have profoundly advanced our knowledge of DNA and RNA, as well as the complex biological processes that involve nucleic acids. As a pivotal enzyme, eukaryotic RNA polymerase II (Pol II) is responsible for transcribing DNA into messenger RNA, which serves as a template to direct protein synthesis. Chemically modified nucleic acid analogues have greatly facilitated the structural elucidation of RNA Pol II elongation complex and understanding the key chemical int...

  14. Characterization of genes encoding poly(A polymerases in plants: evidence for duplication and functional specialization.

    Directory of Open Access Journals (Sweden)

    Lisa R Meeks

    Full Text Available BACKGROUND: Poly(A polymerase is a key enzyme in the machinery that mediates mRNA 3' end formation in eukaryotes. In plants, poly(A polymerases are encoded by modest gene families. To better understand this multiplicity of genes, poly(A polymerase-encoding genes from several other plants, as well as from Selaginella, Physcomitrella, and Chlamydomonas, were studied. METHODOLOGY/PRINCIPAL FINDINGS: Using bioinformatics tools, poly(A polymerase-encoding genes were identified in the genomes of eight species in the plant lineage. Whereas Chlamydomonas reinhardtii was found to possess a single poly(A polymerase gene, other species possessed between two and six possible poly(A polymerase genes. With the exception of four intron-lacking genes, all of the plant poly(A polymerase genes (but not the C. reinhardtii gene possessed almost identical intron positions within the poly(A polymerase coding sequences, suggesting that all plant poly(A polymerase genes derive from a single ancestral gene. The four Arabidopsis poly(A polymerase genes were found to be essential, based on genetic analysis of T-DNA insertion mutants. GFP fusion proteins containing three of the four Arabidopsis poly(A polymerases localized to the nucleus, while one such fusion protein was localized in the cytoplasm. The fact that this latter protein is largely pollen-specific suggests that it has important roles in male gametogenesis. CONCLUSIONS/SIGNIFICANCE: Our results indicate that poly(A polymerase genes have expanded from a single ancestral gene by a series of duplication events during the evolution of higher plants, and that individual members have undergone sorts of functional specialization so as to render them essential for plant growth and development. Perhaps the most interesting of the plant poly(A polymerases is a novel cytoplasmic poly(A polymerase that is expressed in pollen in Arabidopsis; this is reminiscent of spermatocyte-specific cytoplasmic poly(A polymerases in

  15. Recognition of prokaryotic transcription terminators by spinach chloroplast RNA polymerase.

    OpenAIRE

    Chen,L.J.; Orozco, E M

    1988-01-01

    To determine whether chloroplast RNA polymerase will accurately terminate transcription in vitro, we have fused the spinach chloroplast rbcL promoter to the 3' end of the rbcL gene as well as to various factor independent transcription terminators from E. coli. Transcription of the rbcL minigene did not result in production of the expected 265 nucleotide RNA. However, the spinach chloroplast RNA polymerase did terminate transcription with varying efficiency at the thra, rrnB, rrnC and gene 32...

  16. File list: Pol.Unc.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.10.RNA_Polymerase_II.AllCell ce10 RNA polymerase RNA Polymerase II Unclassi...fied http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Unc.10.RNA_Polymerase_II.AllCell.bed ...

  17. File list: Pol.Unc.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Unclassif...ied SRX254629 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Unc.05.RNA_Polymerase_II.AllCell.bed ...

  18. File list: Pol.Lng.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  19. File list: Pol.PSC.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  20. File list: Pol.Spl.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  1. File list: Pol.Brs.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  2. File list: Pol.Dig.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  3. File list: Pol.Emb.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  4. File list: Pol.Unc.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  5. File list: Pol.Neu.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  6. File list: Pol.Liv.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  7. File list: Pol.PSC.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  8. File list: Pol.Epd.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  9. File list: Pol.Neu.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  10. File list: Pol.Unc.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  11. File list: Pol.Oth.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  12. File list: Pol.Myo.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  13. File list: Pol.Neu.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  14. File list: Pol.Unc.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  15. File list: Pol.Myo.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  16. File list: Pol.Emb.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

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  17. File list: Pol.Bld.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  18. File list: Pol.Spl.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  19. File list: Pol.ALL.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  20. File list: Pol.PSC.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

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  1. File list: Pol.Spl.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  2. File list: Pol.Adp.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  3. File list: Pol.ALL.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  4. File list: Pol.ALL.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  5. File list: Pol.Gon.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  6. File list: Pol.Pan.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  7. File list: Pol.Liv.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  8. File list: Pol.Prs.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  9. File list: Pol.Unc.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Bon.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  11. File list: Pol.CDV.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  12. File list: Pol.ALL.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  13. File list: Pol.PSC.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  14. File list: Pol.Emb.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.Unc.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  16. File list: Pol.ALL.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  17. File list: Pol.Gon.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  18. File list: Pol.Spl.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  19. File list: Pol.Bon.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  20. File list: Pol.Kid.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  1. File list: Pol.Plc.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  2. File list: Pol.Lng.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  3. File list: Pol.Oth.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  4. File list: Pol.Plc.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  5. File list: Pol.Pan.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  6. File list: Pol.Oth.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  7. File list: Pol.Dig.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  8. File list: Pol.Lar.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  9. File list: Pol.Unc.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Prs.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  11. File list: Pol.Liv.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  12. File list: Pol.Prs.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  13. File list: Pol.Liv.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  14. File list: Pol.Emb.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.Liv.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  16. File list: Pol.Liv.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  17. File list: Pol.Myo.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  18. File list: Pol.Kid.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  19. File list: Pol.ALL.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  20. File list: Pol.Bon.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  1. File list: Pol.ALL.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.50.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II All cell ...050605,SRX013073 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.ALL.50.RNA_polymerase_II.AllCell.bed ...

  2. File list: Pol.Bon.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bon.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Bone SRX1...035115,SRX731126 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Bon.05.RNA_Polymerase_II.AllCell.bed ...

  3. File list: Pol.Dig.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Dig.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Digestiv...//dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Dig.50.RNA_polymerase_II.AllCell.bed ...

  4. File list: Pol.Pan.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Pancreas ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Pan.05.RNA_Polymerase_II.AllCell.bed ...

  5. File list: Pol.Bon.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bon.20.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Bone ht...tp://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Bon.20.RNA_Polymerase_III.AllCell.bed ...

  6. File list: Pol.Spl.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Spl.50.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Spleen ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Spl.50.RNA_Polymerase_III.AllCell.bed ...

  7. File list: Pol.Neu.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Neu.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Neural S...6,SRX743834,SRX743838,SRX743840,SRX743832 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Neu.50.RNA_polymerase_II.AllCell.bed ...

  8. File list: Pol.Oth.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Oth.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Others S...RX1027436,SRX1027435,SRX1027434,SRX1027433,SRX668218,SRX099880,SRX099879 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Oth.50.RNA_polymerase_II.AllCell.bed ...

  9. File list: Pol.CDV.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Unc.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.10.RNA_polymerase_II.AllCell sacCer3 RNA polymerase RNA polymerase II Uncla...ssified http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.Unc.10.RNA_polymerase_II.AllCell.bed ...

  11. File list: Pol.Neu.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Neu.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Neural SR...,SRX026423,SRX026425 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Neu.05.RNA_Polymerase_II.AllCell.bed ...

  12. File list: Pol.Unc.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.05.RNA_Polymerase_II.AllCell sacCer3 RNA polymerase RNA Polymerase II Uncla...ssified http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.Unc.05.RNA_Polymerase_II.AllCell.bed ...

  13. File list: Pol.Prs.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Prostate...557,SRX173197,SRX173198 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Prs.20.RNA_polymerase_II.AllCell.bed ...

  14. File list: Pol.Emb.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.05.RNA_Polymerase_II.AllCell ce10 RNA polymerase RNA Polymerase II Embryo h...ttp://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Emb.05.RNA_Polymerase_II.AllCell.bed ...

  15. File list: Pol.ALL.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.50.RNA_Polymerase_II.AllCell sacCer3 RNA polymerase RNA Polymerase II All c...ell types SRX092435,SRX497381,SRX360914,SRX497380,SRX497382,SRX360917 http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.ALL.50.RNA_Polymerase_II.AllCell.bed ...

  16. File list: Pol.Oth.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Oth.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Others... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Oth.20.RNA_polymerase_III.AllCell.bed ...

  17. File list: Pol.Neu.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Neu.20.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Neural ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Neu.20.RNA_Polymerase_III.AllCell.bed ...

  18. File list: Pol.Lng.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Lung S...RX016555,SRX150101,SRX150102 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.20.RNA_polymerase_III.AllCell.bed ...

  19. File list: Pol.ALL.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II All cell...,SRX1013886,SRX1013900 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.ALL.10.RNA_polymerase_II.AllCell.bed ...

  20. File list: Pol.Unc.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.20.RNA_polymerase_III.AllCell ce10 RNA polymerase RNA polymerase III Unclas...sified http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Unc.20.RNA_polymerase_III.AllCell.bed ...

  1. File list: Pol.Myo.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Muscle h...ttp://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Myo.10.RNA_polymerase_II.AllCell.bed ...

  2. File list: Pol.Utr.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Utr.50.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Uterus ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Utr.50.RNA_Polymerase_III.AllCell.bed ...

  3. File list: Pol.Dig.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Dig.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Digestive... tract SRX112957,SRX143802 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Dig.05.RNA_Polymerase_II.AllCell.bed ...

  4. File list: Pol.Unc.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.10.RNA_polymerase_II.AllCell ce10 RNA polymerase RNA polymerase II Unclassi...p://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Unc.10.RNA_polymerase_II.AllCell.bed ...

  5. File list: Pol.Oth.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Oth.10.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Others ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Oth.10.RNA_Polymerase_III.AllCell.bed ...

  6. File list: Pol.Plc.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Plc.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Placenta ...SRX160402,SRX112969 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Plc.50.RNA_Polymerase_II.AllCell.bed ...

  7. File list: Pol.Neu.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Neu.10.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Neural SR...,SRX026424,SRX685285 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Neu.10.RNA_Polymerase_II.AllCell.bed ...

  8. File list: Pol.Lng.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Lung SRX... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.50.RNA_polymerase_II.AllCell.bed ...

  9. File list: Pol.Unc.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.50.RNA_polymerase_II.AllCell sacCer3 RNA polymerase RNA polymerase II Uncla...ssified http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.Unc.50.RNA_polymerase_II.AllCell.bed ...

  10. File list: Pol.Adl.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adl.50.RNA_polymerase_III.AllCell ce10 RNA polymerase RNA polymerase III Adult ...SRX331268,SRX331270,SRX395531 http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Adl.50.RNA_polymerase_III.AllCell.bed ...

  11. File list: Pol.Unc.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Unclassi...fied http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Unc.20.RNA_polymerase_II.AllCell.bed ...

  12. File list: Pol.Bld.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bld.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Blood SR...,SRX017986,SRX017985,SRX728781,SRX017717,SRX005163,SRX024360,SRX017718 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Bld.10.RNA_polymerase_II.AllCell.bed ...

  13. File list: Pol.Lar.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lar.20.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Larvae SR...SRX661503,SRX026742,SRX013070,SRX013072,SRX182775,SRX151961,SRX013082,SRX013113 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Lar.20.RNA_polymerase_II.AllCell.bed ...

  14. File list: Pol.ALL.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.10.RNA_Polymerase_II.AllCell ce10 RNA polymerase RNA Polymerase II All cell...X1388758,SRX1388756,SRX1388757 http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.ALL.10.RNA_Polymerase_II.AllCell.bed ...

  15. File list: Pol.Epd.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Epd.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Epiderm...is http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Epd.05.RNA_Polymerase_III.AllCell.bed ...

  16. File list: Pol.ALL.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.10.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II All cell ...050604,SRX050605,SRX013077 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.ALL.10.RNA_polymerase_II.AllCell.bed ...

  17. File list: Pol.Pan.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Pancrea...s http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Pan.05.RNA_Polymerase_III.AllCell.bed ...

  18. File list: Pol.Adp.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adp.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Adipocyte... SRX800011,SRX800010,SRX800016,SRX800017,SRX341031,SRX341032,SRX341029,SRX341030 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Adp.05.RNA_Polymerase_II.AllCell.bed ...

  19. File list: Pol.Kid.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Kid.10.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Kidney ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Kid.10.RNA_Polymerase_III.AllCell.bed ...

  20. File list: Pol.Prs.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.05.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Prostate...363,SRX173198,SRX173197 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Prs.05.RNA_polymerase_II.AllCell.bed ...

  1. File list: Pol.Myo.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Muscle SR.../dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Myo.50.RNA_Polymerase_II.AllCell.bed ...

  2. File list: Pol.Emb.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Embryo SR...SRX099707 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Emb.50.RNA_Polymerase_II.AllCell.bed ...

  3. File list: Pol.Pan.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.20.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Pancreas ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Pan.20.RNA_Polymerase_II.AllCell.bed ...

  4. File list: Pol.CDV.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.CDV.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Cardiovas...X373591,SRX373605,SRX680476,SRX346170,SRX346169 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.CDV.50.RNA_Polymerase_II.AllCell.bed ...

  5. File list: Pol.YSt.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.YSt.50.RNA_Polymerase_II.AllCell sacCer3 RNA polymerase RNA Polymerase II Yeast... strain SRX092435,SRX497381,SRX360914,SRX497380,SRX497382,SRX360917 http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.YSt.50.RNA_Polymerase_II.AllCell.bed ...

  6. File list: Pol.Adp.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adp.20.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Adipocyte... SRX800011,SRX800010,SRX341031,SRX341032,SRX341029,SRX800016,SRX800017,SRX341030 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Adp.20.RNA_Polymerase_II.AllCell.bed ...

  7. File list: Pol.PSC.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.PSC.05.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Pluripot...833412,SRX149642,SRX702059 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.PSC.05.RNA_polymerase_II.AllCell.bed ...

  8. File list: Pol.Adp.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adp.10.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Adipocyte... SRX800011,SRX800010,SRX800016,SRX341031,SRX341032,SRX341029,SRX800017,SRX341030 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Adp.10.RNA_Polymerase_II.AllCell.bed ...

  9. File list: Pol.Unc.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.20.RNA_Polymerase_II.AllCell sacCer3 RNA polymerase RNA Polymerase II Uncla...ssified http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.Unc.20.RNA_Polymerase_II.AllCell.bed ...

  10. File list: Pol.Lng.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.05.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Lung SRX... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.05.RNA_polymerase_II.AllCell.bed ...

  11. File list: Pol.Plc.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Plc.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Placenta... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Plc.20.RNA_polymerase_II.AllCell.bed ...

  12. File list: Pol.ALL.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.10.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III All cel...l types ERX204069 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.ALL.10.RNA_Polymerase_III.AllCell.bed ...

  13. File list: Pol.Epd.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Epd.10.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Epiderm...is http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Epd.10.RNA_Polymerase_III.AllCell.bed ...

  14. File list: Pol.Myo.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.20.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Muscle SR.../dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Myo.20.RNA_Polymerase_II.AllCell.bed ...

  15. File list: Pol.Unc.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.05.RNA_polymerase_II.AllCell ce10 RNA polymerase RNA polymerase II Unclassi...p://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Unc.05.RNA_polymerase_II.AllCell.bed ...

  16. File list: Pol.Brs.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Brs.10.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Breast ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Brs.10.RNA_Polymerase_III.AllCell.bed ...

  17. File list: Pol.Lng.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Lung SRX... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.10.RNA_polymerase_II.AllCell.bed ...

  18. File list: Pol.Kid.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Kid.10.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Kidney SR...X661587,SRX062964,SRX143850,SRX236087,SRX020250 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Kid.10.RNA_Polymerase_II.AllCell.bed ...

  19. File list: Pol.Prs.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Prostate...866,SRX173198,SRX173197 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Prs.10.RNA_polymerase_II.AllCell.bed ...

  20. File list: Pol.Lar.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lar.05.RNA_polymerase_III.AllCell ce10 RNA polymerase RNA polymerase III Larvae... http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Lar.05.RNA_polymerase_III.AllCell.bed ...

  1. File list: Pol.Pan.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Pancreas... SRX190244 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Pan.50.RNA_polymerase_II.AllCell.bed ...

  2. File list: Pol.Bld.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bld.20.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Blood h...ttp://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Bld.20.RNA_Polymerase_III.AllCell.bed ...

  3. File list: Pol.Emb.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Embryo ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Emb.05.RNA_Polymerase_III.AllCell.bed ...

  4. File list: Pol.Unc.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  5. File list: Pol.Adp.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  6. File list: Pol.Unc.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  7. File list: Pol.Dig.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  8. File list: Pol.Plc.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  9. File list: Pol.CDV.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Myo.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  11. File list: Pol.Adl.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  12. File list: Pol.Lng.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  13. File list: Pol.Pan.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  14. File list: Pol.Lng.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.YSt.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  16. File list: Pol.Oth.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  17. File list: Pol.Unc.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  18. File list: Pol.Kid.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  19. File list: Pol.PSC.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  20. File list: Pol.Unc.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  1. File list: Pol.Myo.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  2. File list: Pol.ALL.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  3. File list: Pol.Utr.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  4. File list: Pol.PSC.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.PSC.05.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Pluripote...SRX213760,SRX355582 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.PSC.05.RNA_Polymerase_II.AllCell.bed ...

  5. File list: Pol.Adl.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  6. File list: Pol.Prs.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Prostat...e http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Prs.05.RNA_Polymerase_III.AllCell.bed ...

  7. File list: Pol.ALL.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  8. File list: Pol.Lng.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Lung ht...tp://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Lng.05.RNA_Polymerase_III.AllCell.bed ...

  9. File list: Pol.Emb.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.20.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Embryo SR...SRX099707 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Emb.20.RNA_Polymerase_II.AllCell.bed ...

  10. File list: Pol.Emb.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  11. File list: Pol.CDV.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.CDV.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Cardiov...ascular http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.CDV.05.RNA_Polymerase_III.AllCell.bed ...

  12. File list: Pol.Dig.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Dig.10.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Digestive... tract SRX112957,SRX143802 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Dig.10.RNA_Polymerase_II.AllCell.bed ...

  13. File list: Pol.Myo.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Muscle ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Myo.05.RNA_Polymerase_III.AllCell.bed ...

  14. File list: Pol.Liv.05.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.Bld.50.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bld.50.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Blood h...ttp://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Bld.50.RNA_Polymerase_III.AllCell.bed ...

  16. File list: Pol.Utr.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Utr.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Uterus ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Utr.05.RNA_Polymerase_III.AllCell.bed ...

  17. File list: Pol.Oth.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Oth.20.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Others ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Oth.20.RNA_Polymerase_III.AllCell.bed ...

  18. File list: Pol.Epd.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Epd.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Epidermis... http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Epd.50.RNA_Polymerase_II.AllCell.bed ...

  19. File list: Pol.CDV.20.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.CDV.20.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Cardiov...ascular http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.CDV.20.RNA_Polymerase_III.AllCell.bed ...

  20. File list: Pol.Bon.20.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bon.20.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Bone SRX1...035115,SRX731126 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Bon.20.RNA_Polymerase_II.AllCell.bed ...

  1. File list: Pol.Spl.10.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Spl.10.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Spleen ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Spl.10.RNA_Polymerase_III.AllCell.bed ...

  2. File list: Pol.Pan.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Pancreas ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Pan.50.RNA_Polymerase_II.AllCell.bed ...

  3. File list: Pol.Unc.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  4. File list: Pol.Pan.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.10.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Pancreas ...http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Pan.10.RNA_Polymerase_II.AllCell.bed ...

  5. File list: Pol.Brs.50.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Brs.50.RNA_Polymerase_II.AllCell mm9 RNA polymerase RNA Polymerase II Breast SR...078990 http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Brs.50.RNA_Polymerase_II.AllCell.bed ...

  6. File list: Pol.Adp.05.RNA_Polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adp.05.RNA_Polymerase_III.AllCell mm9 RNA polymerase RNA Polymerase III Adipocy...te http://dbarchive.biosciencedbc.jp/kyushu-u/mm9/assembled/Pol.Adp.05.RNA_Polymerase_III.AllCell.bed ...

  7. File list: Pol.Brs.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  8. File list: Pol.Emb.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.05.RNA_polymerase_II.AllCell ce10 RNA polymerase RNA polymerase II Embryo S...,SRX043867 http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Emb.05.RNA_polymerase_II.AllCell.bed ...

  9. File list: Pol.Plc.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Plc.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Placen...ta http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Plc.05.RNA_polymerase_III.AllCell.bed ...

  10. File list: Pol.ALL.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II All cell...33,SRX016705,SRX518262 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.ALL.50.RNA_polymerase_II.AllCell.bed ...

  11. File list: Pol.Dig.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Dig.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Digest...ive tract http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Dig.05.RNA_polymerase_III.AllCell.bed ...

  12. File list: Pol.Liv.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Liv.10.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Liver ...http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Liv.10.RNA_polymerase_III.AllCell.bed ...

  13. File list: Pol.Unc.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.10.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Unclassif...ied SRX110774 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Unc.10.RNA_polymerase_II.AllCell.bed ...

  14. File list: Pol.ALL.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.PSC.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.PSC.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Pluripot...702062,SRX702057,SRX702061 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.PSC.50.RNA_polymerase_II.AllCell.bed ...

  16. File list: Pol.Pan.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  17. File list: Pol.ALL.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III All ce...,SRX015144,SRX018606,SRX017002,SRX017001 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.ALL.20.RNA_polymerase_III.AllCell.bed ...

  18. File list: Pol.Liv.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Liv.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Liver SR...1013886 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Liv.50.RNA_polymerase_II.AllCell.bed ...

  19. File list: Pol.Utr.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Utr.50.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Uterus... SRX017002,SRX017001,SRX018606 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Utr.50.RNA_polymerase_III.AllCell.bed ...

  20. File list: Pol.Oth.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  1. File list: Pol.Dig.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Dig.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Digestiv...//dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Dig.20.RNA_polymerase_II.AllCell.bed ...

  2. File list: Pol.Adl.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  3. File list: Pol.Brs.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  4. File list: Pol.Unc.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Unclassi...fied http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Unc.50.RNA_polymerase_II.AllCell.bed ...

  5. File list: Pol.Bon.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bon.10.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Bone h...ttp://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Bon.10.RNA_polymerase_III.AllCell.bed ...

  6. File list: Pol.Adp.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adp.50.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Adipoc...yte http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Adp.50.RNA_polymerase_III.AllCell.bed ...

  7. File list: Pol.Prs.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Prosta...te http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Prs.05.RNA_polymerase_III.AllCell.bed ...

  8. File list: Pol.ALL.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  9. File list: Pol.Adp.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Bld.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  11. File list: Pol.ALL.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  12. File list: Pol.Myo.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  13. File list: Pol.Liv.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Liv.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Liver ...http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Liv.20.RNA_polymerase_III.AllCell.bed ...

  14. File list: Pol.Neu.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.Kid.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  16. File list: Pol.Myo.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Muscle... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Myo.20.RNA_polymerase_III.AllCell.bed ...

  17. File list: Pol.Bld.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  18. File list: Pol.Dig.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  19. File list: Pol.Kid.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Kid.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Kidney S...SRX1206066,SRX1206067,SRX003882,SRX003883,SRX1206065,SRX367323,SRX326416 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Kid.50.RNA_polymerase_II.AllCell.bed ...

  20. File list: Pol.Lng.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.50.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Lung S...RX016555,SRX150101,SRX150102 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.50.RNA_polymerase_III.AllCell.bed ...

  1. File list: Pol.Lng.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Lung S...RX016555,SRX150101,SRX150102 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.05.RNA_polymerase_III.AllCell.bed ...

  2. File list: Pol.Adl.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  3. File list: Pol.Emb.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  4. File list: Pol.Myo.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  5. File list: Pol.ALL.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  6. File list: Pol.Bon.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  7. File list: Pol.Gon.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Gon.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Gonad ...http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Gon.20.RNA_polymerase_III.AllCell.bed ...

  8. File list: Pol.Adl.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  9. File list: Pol.Emb.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Myo.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.10.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Muscle... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Myo.10.RNA_polymerase_III.AllCell.bed ...

  11. File list: Pol.Oth.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Oth.05.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Others S...RX1027435,SRX668218,SRX1027436,SRX1027434,SRX1027433,SRX099879,SRX099880 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Oth.05.RNA_polymerase_II.AllCell.bed ...

  12. File list: Pol.Emb.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.10.RNA_polymerase_III.AllCell ce10 RNA polymerase RNA polymerase III Embryo... http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Emb.10.RNA_polymerase_III.AllCell.bed ...

  13. File list: Pol.Unc.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.05.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Unclassif...ied SRX110774 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Unc.05.RNA_polymerase_II.AllCell.bed ...

  14. File list: Pol.Myo.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Myo.05.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Muscle h...ttp://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Myo.05.RNA_polymerase_II.AllCell.bed ...

  15. File list: Pol.Unc.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Unclas...sified http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Unc.20.RNA_polymerase_III.AllCell.bed ...

  16. File list: Pol.Bld.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Bld.50.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Blood ...SRX150560,SRX018610,SRX015143,SRX017006,SRX150396,SRX015144 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Bld.50.RNA_polymerase_III.AllCell.bed ...

  17. File list: Pol.Pup.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pup.10.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Pupae SRX...013069 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Pup.10.RNA_polymerase_II.AllCell.bed ...

  18. File list: Pol.YSt.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.YSt.20.RNA_polymerase_II.AllCell sacCer3 RNA polymerase RNA polymerase II Yeast... strain http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.YSt.20.RNA_polymerase_II.AllCell.bed ...

  19. File list: Pol.Plc.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Plc.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Placen...ta http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Plc.20.RNA_polymerase_III.AllCell.bed ...

  20. File list: Pol.Pan.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Pancre...as http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Pan.20.RNA_polymerase_III.AllCell.bed ...

  1. File list: Pol.ALL.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III All ce...,SRX150396,SRX015144,SRX150101,SRX150102 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.ALL.05.RNA_polymerase_III.AllCell.bed ...

  2. File list: Pol.Pup.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pup.05.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Pupae SRX...013069 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Pup.05.RNA_polymerase_II.AllCell.bed ...

  3. File list: Pol.Utr.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Utr.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Uterus... SRX017001,SRX018606,SRX017002 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Utr.05.RNA_polymerase_III.AllCell.bed ...

  4. File list: Pol.Pan.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Pancre...as http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Pan.05.RNA_polymerase_III.AllCell.bed ...

  5. File list: Pol.ALL.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.50.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III All ce...,SRX017001,SRX018606,SRX150396,SRX015144 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.ALL.50.RNA_polymerase_III.AllCell.bed ...

  6. File list: Pol.Lng.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lng.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Lung SRX... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Lng.20.RNA_polymerase_II.AllCell.bed ...

  7. File list: Pol.ALL.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.20.RNA_polymerase_II.AllCell ce10 RNA polymerase RNA polymerase II All cell...3874,SRX003817,SRX043845,SRX043964,SRX043967,SRX043881,SRX043879 http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.ALL.20.RNA_polymerase_II.AllCell.bed ...

  8. File list: Pol.Emb.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.05.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Embryo SR...7582,SRX013077,SRX050604,SRX050605 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Emb.05.RNA_polymerase_II.AllCell.bed ...

  9. File list: Pol.PSC.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.PSC.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Pluripot...670820,SRX702057,SRX702061 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.PSC.20.RNA_polymerase_II.AllCell.bed ...

  10. File list: Pol.Pan.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Pancreas... SRX190244 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Pan.10.RNA_polymerase_II.AllCell.bed ...

  11. File list: Pol.Epd.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Epd.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Epidermi...247,SRX080162,SRX807622 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Epd.50.RNA_polymerase_II.AllCell.bed ...

  12. File list: Pol.Kid.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Kid.20.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Kidney S...SRX1206072,SRX1206066,SRX326423,SRX1206067,SRX003883,SRX003882,SRX367323 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Kid.20.RNA_polymerase_II.AllCell.bed ...

  13. File list: Pol.Brs.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Brs.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Breast... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Brs.05.RNA_polymerase_III.AllCell.bed ...

  14. File list: Pol.Epd.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Epd.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Epidermi...246,SRX663247,SRX807622 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Epd.10.RNA_polymerase_II.AllCell.bed ...

  15. File list: Pol.Pan.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Pan.05.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Pancreas... SRX190244 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Pan.05.RNA_polymerase_II.AllCell.bed ...

  16. File list: Pol.Unc.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Unc.50.RNA_polymerase_II.AllCell ce10 RNA polymerase RNA polymerase II Unclassi...p://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Unc.50.RNA_polymerase_II.AllCell.bed ...

  17. File list: Pol.Prs.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.10.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Prosta...te http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Prs.10.RNA_polymerase_III.AllCell.bed ...

  18. File list: Pol.ALL.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.ALL.10.RNA_polymerase_II.AllCell sacCer3 RNA polymerase RNA polymerase II All c...ell types http://dbarchive.biosciencedbc.jp/kyushu-u/sacCer3/assembled/Pol.ALL.10.RNA_polymerase_II.AllCell.bed ...

  19. File list: Pol.Adp.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Adp.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Adipoc...yte http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Adp.20.RNA_polymerase_III.AllCell.bed ...

  20. File list: Pol.Utr.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Utr.20.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Uterus... SRX018606,SRX017002,SRX017001 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Utr.20.RNA_polymerase_III.AllCell.bed ...

  1. File list: Pol.PSC.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.PSC.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Plurip...otent stem cell http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.PSC.05.RNA_polymerase_III.AllCell.bed ...

  2. File list: Pol.Lar.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lar.05.RNA_polymerase_II.AllCell dm3 RNA polymerase RNA polymerase II Larvae SR...SRX151962,SRX182775,SRX661503,SRX013070,SRX013072,SRX013113,SRX013082,SRX151961 http://dbarchive.biosciencedbc.jp/kyushu-u/dm3/assembled/Pol.Lar.05.RNA_polymerase_II.AllCell.bed ...

  3. File list: Pol.Lar.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Lar.50.RNA_polymerase_III.AllCell ce10 RNA polymerase RNA polymerase III Larvae... http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Lar.50.RNA_polymerase_III.AllCell.bed ...

  4. File list: Pol.Epd.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Epd.50.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Epider...mis SRX016997 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Epd.50.RNA_polymerase_III.AllCell.bed ...

  5. File list: Pol.Dig.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Dig.10.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Digestiv...//dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Dig.10.RNA_polymerase_II.AllCell.bed ...

  6. File list: Pol.Oth.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Oth.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Others... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Oth.05.RNA_polymerase_III.AllCell.bed ...

  7. File list: Pol.Emb.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Emb.20.RNA_polymerase_II.AllCell ce10 RNA polymerase RNA polymerase II Embryo S...,SRX043869 http://dbarchive.biosciencedbc.jp/kyushu-u/ce10/assembled/Pol.Emb.20.RNA_polymerase_II.AllCell.bed ...

  8. File list: Pol.Prs.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Prs.50.RNA_polymerase_II.AllCell hg19 RNA polymerase RNA polymerase II Prostate...932,SRX020922,SRX022582 http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Prs.50.RNA_polymerase_II.AllCell.bed ...

  9. File list: Pol.Neu.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

    Full Text Available Pol.Neu.05.RNA_polymerase_III.AllCell hg19 RNA polymerase RNA polymerase III Neural... http://dbarchive.biosciencedbc.jp/kyushu-u/hg19/assembled/Pol.Neu.05.RNA_polymerase_III.AllCell.bed ...

  10. File list: Pol.Utr.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  11. File list: Pol.Bon.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  12. File list: Pol.Unc.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  13. File list: Pol.Unc.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  14. File list: Pol.Plc.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.Unc.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  16. File list: Pol.Epd.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  17. File list: Pol.Gon.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  18. File list: Pol.CDV.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  19. File list: Pol.Bon.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  20. File list: Pol.Gon.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  1. File list: Pol.Gon.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  2. File list: Pol.Unc.05.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  3. File list: Pol.Kid.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  4. File list: Pol.Lar.20.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  5. File list: Pol.Plc.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  6. File list: Pol.Emb.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  7. File list: Pol.Adl.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  8. File list: Pol.Neu.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  9. File list: Pol.ALL.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. File list: Pol.Kid.05.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  11. File list: Pol.PSC.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  12. File list: Pol.Utr.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  13. File list: Pol.Unc.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

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  14. File list: Pol.Unc.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  15. File list: Pol.YSt.50.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  16. File list: Pol.CDV.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

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  17. File list: Pol.CDV.10.RNA_polymerase_II.AllCell [Chip-atlas[Archive

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  18. File list: Pol.Oth.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

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    Lifescience Database Archive (English)

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  7. File list: Pol.Oth.50.RNA_polymerase_III.AllCell [Chip-atlas[Archive

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  8. File list: Pol.Pan.10.RNA_polymerase_III.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  9. File list: Pol.Unc.20.RNA_polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  10. Synthesis of 2′-Fluoro RNA by Syn5 RNA polymerase

    Science.gov (United States)

    Zhu, Bin; Hernandez, Alfredo; Tan, Min; Wollenhaupt, Jan; Tabor, Stanley; Richardson, Charles C.

    2015-01-01

    The substitution of 2′-fluoro for 2′-hydroxyl moieties in RNA substantially improves the stability of RNA. RNA stability is a major issue in RNA research and applications involving RNA. We report that the RNA polymerase from the marine cyanophage Syn5 has an intrinsic low discrimination against the incorporation of 2′-fluoro dNMPs during transcription elongation. The presence of both magnesium and manganese ions at high concentrations further reduce this discrimination without decreasing the efficiency of incorporation. We have constructed a Syn5 RNA polymerase in which tyrosine 564 is replaced with phenylalanine (Y564F) that further decreases the discrimination against 2′-fluoro-dNTPs during RNA synthesis. Sequence elements in DNA templates that affect the yield of RNA and incorporation of 2′-fluoro-dNMPs by Syn5 RNA polymerase have been identified. PMID:25897116

  11. Transcription of the major neurospora crassa microRNA-like small RNAs relies on RNA polymerase III.

    Directory of Open Access Journals (Sweden)

    Qiuying Yang

    Full Text Available Most plant and animal microRNAs (miRNAs are transcribed by RNA polymerase II. We previously discovered miRNA-like small RNAs (milRNAs in the filamentous fungus Neurospora crassa and uncovered at least four different pathways for milRNA production. To understand the evolutionary origin of milRNAs, we determined the roles of polymerases II and III (Pol II and Pol III in milRNA transcription. Our results show that Pol III is responsible for the transcription of the major milRNAs produced in this organism. The inhibition of Pol III activity by an inhibitor or by gene silencing abolishes the production of most abundant milRNAs and pri-milRNAs. In addition, Pol III associates with these milRNA producing loci. Even though silencing of Pol II does not affect the synthesis of the most abundant milRNAs, Pol II or both Pol II and Pol III are associated with some milRNA-producing loci, suggesting a regulatory interaction between the two polymerases for some milRNA transcription. Furthermore, we show that one of the Pol III-transcribed milRNAs is derived from a tRNA precursor, and its biogenesis requires RNase Z, which cleaves the tRNA moiety to generate pre-milRNA. Our study identifies the transcriptional machinery responsible for the synthesis of fungal milRNAs and sheds light on the evolutionary origin of eukaryotic small RNAs.

  12. Abortive initiation by Saccharomyces cerevisiae RNA polymerase III.

    Science.gov (United States)

    Bhargava, P; Kassavetis, G A

    1999-09-10

    Promoter escape can be rate-limiting for transcription by bacterial RNA polymerases and RNA polymerase II of higher eukaryotes. Formation of a productive elongation complex requires disengagement of RNA polymerase from promoter-bound eukaryotic transcription factors or bacterial sigma factors. RNA polymerase III (pol III) stably associates with the TFIIIB-DNA complex even in the absence of localized DNA unwinding associated with the open promoter complex. To explore the role that release of pol III from the TFIIIB-DNA complex plays in limiting the overall rate of transcription, we have examined the early steps of RNA synthesis. We find that, on average, only three rounds of abortive initiation precede the formation of each elongation complex and that nearly all pol III molecules escape the abortive initiation phase of transcription without significant pausing or arrest. However, when elongation is limited to 5 nucleotides, the intrinsic exoribonuclease activity of pol III cleaves 5-mer RNA at a rate considerably faster than product release or reinitiation. This cleavage also occurs in the normal process of forming a productive elongation complex. The possible role of nucleolytic retraction in disengaging pol III from TFIIIB is discussed.

  13. Structural Basis of RNA Polymerase I Transcription Initiation.

    Science.gov (United States)

    Engel, Christoph; Gubbey, Tobias; Neyer, Simon; Sainsbury, Sarah; Oberthuer, Christiane; Baejen, Carlo; Bernecky, Carrie; Cramer, Patrick

    2017-03-23

    Transcription initiation at the ribosomal RNA promoter requires RNA polymerase (Pol) I and the initiation factors Rrn3 and core factor (CF). Here, we combine X-ray crystallography and cryo-electron microscopy (cryo-EM) to obtain a molecular model for basal Pol I initiation. The three-subunit CF binds upstream promoter DNA, docks to the Pol I-Rrn3 complex, and loads DNA into the expanded active center cleft of the polymerase. DNA unwinding between the Pol I protrusion and clamp domains enables cleft contraction, resulting in an active Pol I conformation and RNA synthesis. Comparison with the Pol II system suggests that promoter specificity relies on a distinct "bendability" and "meltability" of the promoter sequence that enables contacts between initiation factors, DNA, and polymerase. Copyright © 2017 Elsevier Inc. All rights reserved.

  14. Conformational Selection and Induced Fit for RNA Polymerase and RNA/DNA Hybrid Backtracked Recognition

    Directory of Open Access Journals (Sweden)

    Haifeng eChen

    2015-11-01

    Full Text Available RNA polymerase catalyzes transcription with a high fidelity. If DNA/RNA mismatch or DNA damage occurs downstream, a backtracked RNA polymerase can proofread this situation. However, the backtracked mechanism is still poorly understood. Here we have performed multiple explicit-solvent molecular dynamics (MD simulations on bound and apo DNA/RNA hybrid to study backtracked recognition. MD simulations at room temperature suggest that specific electrostatic interactions play key roles in the backtracked recognition between the polymerase and DNA/RNA hybrid. Kinetics analysis at high temperature shows that bound and apo DNA/RNA hybrid unfold via a two-state process. Both kinetics and free energy landscape analyses indicate that bound DNA/RNA hybrid folds in the order of DNA/RNA contracting, the tertiary folding and polymerase binding. The predicted Φ-values suggest that C7, G9, dC12, dC15 and dT16 are key bases for the backtracked recognition of DNA/RNA hybrid. The average RMSD values between the bound structures and the corresponding apo ones and Kolmogorov-Smirnov (KS P test analyses indicate that the recognition between DNA/RNA hybrid and polymerase might follow an induced fit mechanism for DNA/RNA hybrid and conformation selection for polymerase. Furthermore, this method could be used to relative studies of specific recognition between nucleic acid and protein.

  15. Stochastic resetting in backtrack recovery by RNA polymerases

    CERN Document Server

    Roldán, Édgar; Sánchez-Taltavull, Daniel; Grill, Stephan W

    2016-01-01

    Transcription is a key process in gene expression, in which RNA polymerases produce a complementary RNA copy from a DNA template. RNA polymerization is frequently interrupted by backtracking, a process in which polymerases perform a random walk along the DNA template. Recovery of polymerases from the transcriptionally-inactive backtracked state is determined by a kinetic competition between 1D diffusion and RNA cleavage. Here we describe backtrack recovery as a continuous-time random walk, where the time for a polymerase to recover from a backtrack of a given depth is described as a first-passage time of a random walker to reach an absorbing state. We represent RNA cleavage as a stochastic resetting process, and derive exact expressions for the recovery time distributions and mean recovery times from a given initial backtrack depth for both continuous and discrete-lattice descriptions of the random walk. We show that recovery time statistics do not depend on the discreteness of the DNA lattice when the rate o...

  16. FACT facilitates chromatin transcription by RNA polymerases I and III

    DEFF Research Database (Denmark)

    Birch, Joanna L; Tan, Bertrand C-M; Panov, Kostya I

    2009-01-01

    Efficient transcription elongation from a chromatin template requires RNA polymerases (Pols) to negotiate nucleosomes. Our biochemical analyses demonstrate that RNA Pol I can transcribe through nucleosome templates and that this requires structural rearrangement of the nucleosomal core particle....... The subunits of the histone chaperone FACT (facilitates chromatin transcription), SSRP1 and Spt16, co-purify and co-immunoprecipitate with mammalian Pol I complexes. In cells, SSRP1 is detectable at the rRNA gene repeats. Crucially, siRNA-mediated repression of FACT subunit expression in cells results...

  17. Influenza virus RNA polymerase: insights into the mechanisms of viral RNA synthesis

    Science.gov (United States)

    te Velthuis, Aartjan J.W.; Fodor, Ervin

    2016-01-01

    The genome of influenza viruses consists of multiple segments of single stranded negative-sense RNA. Each of these segments is bound by the heterotrimeric viral RNA-dependent RNA polymerase and multiple copies of nucleoprotein, forming viral ribonucleoprotein (vRNP) complexes. It is in the context of these vRNPs that the viral RNA polymerase carries out transcription of viral genes and replication of the viral RNA genome. In this Review, we discuss our current knowledge of the structure of the influenza virus RNA polymerase, how it carries out transcription and replication, and how its activities are modulated by viral and host factors. Furthermore, we discuss how advances in our understanding of polymerase function could help identifying new antiviral targets. PMID:27396566

  18. Micro-RNA quantification using DNA polymerase and pyrophosphate quantification.

    Science.gov (United States)

    Yu, Hsiang-Ping; Hsiao, Yi-Ling; Pan, Hung-Yin; Huang, Chih-Hung; Hou, Shao-Yi

    2011-12-15

    A rapid quantification method for micro-RNA based on DNA polymerase activity and pyrophosphate quantification has been developed. The tested micro-RNA serves as the primer, unlike the DNA primer in all DNA sequencing methods, and the DNA probe serves as the template for DNA replication. After the DNA synthesis, the pyrophosphate detection and quantification indicate the existence and quantity of the tested miRNA. Five femtomoles of the synthetic RNA could be detected. In 20-100 μg RNA samples purified from SiHa cells, the measurement was done using the proposed assay in which hsa-miR-16 and hsa-miR-21 are 0.34 fmol/μg RNA and 0.71 fmol/μg RNA, respectively. This simple and inexpensive assay takes less than 5 min after total RNA purification and preparation. The quantification is not affected by the pre-miRNA which cannot serve as the primer for the DNA synthesis in this assay. This assay is general for the detection of the target RNA or DNA with a known matched DNA template probe, which could be widely used for detection of small RNA, messenger RNA, RNA viruses, and DNA. Therefore, the method could be widely used in RNA and DNA assays. Copyright © 2011 Elsevier Inc. All rights reserved.

  19. Active RNA polymerases: mobile or immobile molecular machines?

    Directory of Open Access Journals (Sweden)

    Argyris Papantonis

    Full Text Available It is widely assumed that active RNA polymerases track along their templates to produce a transcript. We test this using chromosome conformation capture and human genes switched on rapidly and synchronously by tumour necrosis factor alpha (TNFalpha; one is 221 kbp SAMD4A, which a polymerase takes more than 1 h to transcribe. Ten minutes after stimulation, the SAMD4A promoter comes together with other TNFalpha-responsive promoters. Subsequently, these contacts are lost as new downstream ones appear; contacts are invariably between sequences being transcribed. Super-resolution microscopy confirms that nascent transcripts (detected by RNA fluorescence in situ hybridization co-localize at relevant times. Results are consistent with an alternative view of transcription: polymerases fixed in factories reel in their respective templates, so different parts of the templates transiently lie together.

  20. A Perspective on the Enhancer Dependent Bacterial RNA Polymerase

    Directory of Open Access Journals (Sweden)

    Nan Zhang

    2015-05-01

    Full Text Available Here we review recent findings and offer a perspective on how the major variant RNA polymerase of bacteria, which contains the sigma54 factor, functions for regulated gene expression. We consider what gaps exist in our understanding of its genetic, biochemical and biophysical functioning and how they might be addressed.

  1. Transcription rate of RNA polymerase under rotary torque

    Science.gov (United States)

    Kiryu, H.

    2004-04-01

    We investigated the transcription rates of RNA polymerases that were subjected to rotational drag. By combining chemical kinetics with mechanical equations, we derived formulas for the transcription rate in the case where the torque was caused by the hydrodynamic drag to DNA rotation.

  2. DNA dependent RNA polymerases from the fungus Aspergillus nidulans

    NARCIS (Netherlands)

    Stunnenberg, H.G.

    1981-01-01

    The aim of the work presented here was the isolation and characterization of the DNA-dependent RNA polymerases from the fungus Aspergillus nidulans, which was a part of a project concerning the regulation of gene expression in this lower eukaryote.The transcription of a genome and the regulation mec

  3. DNA-dependent RNA polymerases from the fungus Aspergillus nidulans

    NARCIS (Netherlands)

    Stunnenberg, H.G.

    1981-01-01

    The aim of the work presented here was the isolation and characterization of the DNA-dependent RNA polymerases from the fungus Aspergillus nidulans, which was a part of a project concerning the regulation of gene expression in this lower eukaryote.

    The transcription of

  4. Single molecule studies of RNA polymerase II transcription in vitro.

    Science.gov (United States)

    Horn, Abigail E; Goodrich, James A; Kugel, Jennifer F

    2014-01-01

    Eukaryotic mRNA transcription by RNA polymerase II (RNAP II) is the first step in gene expression and a key determinant of cellular regulation. Elucidating the mechanism by which RNAP II synthesizes RNA is therefore vital to determining how genes are controlled under diverse biological conditions. Significant advances in understanding RNAP II transcription have been achieved using classical biochemical and structural techniques; however, aspects of the transcription mechanism cannot be assessed using these approaches. The application of single-molecule techniques to study RNAP II transcription has provided new insight only obtainable by studying molecules in this complex system one at a time.

  5. Fast transcription rates of RNA polymerase II in human cells

    Science.gov (United States)

    Maiuri, Paolo; Knezevich, Anna; De Marco, Alex; Mazza, Davide; Kula, Anna; McNally, Jim G; Marcello, Alessandro

    2011-01-01

    Averaged estimates of RNA polymerase II (RNAPII) elongation rates in mammalian cells have been shown to range between 1.3 and 4.3 kb min−1. In this work, nascent RNAs from an integrated human immunodeficiency virus type 1-derived vector were detectable at the single living cell level by fluorescent RNA tagging. At steady state, a constant number of RNAs was measured corresponding to a minimal density of polymerases with negligible fluctuations over time. Recovery of fluorescence after photobleaching was complete within seconds, indicating a high rate of RNA biogenesis. The calculated transcription rate above 50 kb min−1 points towards a wide dynamic range of RNAPII velocities in living cells. PMID:22015688

  6. Ubiquitylation and degradation of elongating RNA polymerase II

    DEFF Research Database (Denmark)

    Wilson, Marcus D; Harreman, Michelle; Svejstrup, Jesper Q

    2013-01-01

    During its journey across a gene, RNA polymerase II has to contend with a number of obstacles to its progression, including nucleosomes, DNA-binding proteins, DNA damage, and sequences that are intrinsically difficult to transcribe. Not surprisingly, a large number of elongation factors have evol....... In this review, we describe the mechanisms and factors responsible for the last resort mechanism of transcriptional elongation. This article is part of a Special Issue entitled: RNA polymerase II Transcript Elongation.......During its journey across a gene, RNA polymerase II has to contend with a number of obstacles to its progression, including nucleosomes, DNA-binding proteins, DNA damage, and sequences that are intrinsically difficult to transcribe. Not surprisingly, a large number of elongation factors have...... evolved to ensure that transcription stalling or arrest does not occur. If, however, the polymerase cannot be restarted, it becomes poly-ubiquitylated and degraded by the proteasome. This process is highly regulated, ensuring that only RNAPII molecules that cannot otherwise be salvaged are degraded...

  7. Noncoding transcription by alternative RNA polymerases dynamically regulates an auxin-driven chromatin loop.

    Science.gov (United States)

    Ariel, Federico; Jegu, Teddy; Latrasse, David; Romero-Barrios, Natali; Christ, Aurélie; Benhamed, Moussa; Crespi, Martin

    2014-08-07

    The eukaryotic epigenome is shaped by the genome topology in three-dimensional space. Dynamic reversible variations in this epigenome structure directly influence the transcriptional responses to developmental cues. Here, we show that the Arabidopsis long intergenic noncoding RNA (lincRNA) APOLO is transcribed by RNA polymerases II and V in response to auxin, a phytohormone controlling numerous facets of plant development. This dual APOLO transcription regulates the formation of a chromatin loop encompassing the promoter of its neighboring gene PID, a key regulator of polar auxin transport. Altering APOLO expression affects chromatin loop formation, whereas RNA-dependent DNA methylation, active DNA demethylation, and Polycomb complexes control loop dynamics. This dynamic chromatin topology determines PID expression patterns. Hence, the dual transcription of a lincRNA influences local chromatin topology and directs dynamic auxin-controlled developmental outputs on neighboring genes. This mechanism likely underscores the adaptive success of plants in diverse environments and may be widespread in eukaryotes.

  8. Structural basis of transcription initiation by bacterial RNA polymerase holoenzyme.

    Science.gov (United States)

    Basu, Ritwika S; Warner, Brittany A; Molodtsov, Vadim; Pupov, Danil; Esyunina, Daria; Fernández-Tornero, Carlos; Kulbachinskiy, Andrey; Murakami, Katsuhiko S

    2014-08-29

    The bacterial RNA polymerase (RNAP) holoenzyme containing σ factor initiates transcription at specific promoter sites by de novo RNA priming, the first step of RNA synthesis where RNAP accepts two initiating ribonucleoside triphosphates (iNTPs) and performs the first phosphodiester bond formation. We present the structure of de novo transcription initiation complex that reveals unique contacts of the iNTPs bound at the transcription start site with the template DNA and also with RNAP and demonstrate the importance of these contacts for transcription initiation. To get further insight into the mechanism of RNA priming, we determined the structure of initially transcribing complex of RNAP holoenzyme with 6-mer RNA, obtained by in crystallo transcription approach. The structure highlights RNAP-RNA contacts that stabilize the short RNA transcript in the active site and demonstrates that the RNA 5'-end displaces σ region 3.2 from its position near the active site, which likely plays a key role in σ ejection during the initiation-to-elongation transition. Given the structural conservation of the RNAP active site, the mechanism of de novo RNA priming appears to be conserved in all cellular RNAPs. © 2014 by The American Society for Biochemistry and Molecular Biology, Inc.

  9. Dynamic phosphorylation patterns of RNA polymerase II CTD during transcription.

    Science.gov (United States)

    Heidemann, Martin; Hintermair, Corinna; Voß, Kirsten; Eick, Dirk

    2013-01-01

    The eukaryotic RNA polymerase II (RNAPII) catalyzes the transcription of all protein encoding genes and is also responsible for the generation of small regulatory RNAs. RNAPII has evolved a unique domain composed of heptapeptide repeats with the consensus sequence Tyr1-Ser2-Pro3-Thr4-Ser5-Pro6-Ser7 at the C-terminus (CTD) of its largest subunit (Rpb1). Dynamic phosphorylation patterns of serine residues in CTD during gene transcription coordinate the recruitment of factors to the elongating RNAPII and to the nascent transcript. Recent studies identified threonine 4 and tyrosine 1 as new CTD modifications and thereby expanded the "CTD code". In this review, we focus on CTD phosphorylation and its function in the RNAPII transcription cycle. We also discuss in detail the limitations of the phosphospecific CTD antibodies, which are used in all studies. This article is part of a Special Issue entitled: RNA Polymerase II Transcript Elongation.

  10. Functional state of rat liver RNA polymerase IA and IB.

    Science.gov (United States)

    Zoncheddu, A; Accomando, R; Pertica, M; Orunesu, M

    1979-01-01

    Phosphocellulose chromatography has been employed to characterize RNA polymerase I present in two different functional states in rat liver cells. The actively transcribing enzyme solubilized from nuclei appears to belong both to the IA and IB classes, whereas the non-transcribing enzyme present in the cytoplasmic fraction has been found to belong only to the IA class. Indirect and direct evidence indicates, however, that in isolated nuclei only the IB form is to be regarded as the physiological form of the enzyme, the IA form arising as a procedural artefact during the extraction process. It may, therefore, be concluded that rat liver IA and IB RNA polymerase are to be strictly regarded as the non-transcribing and transcribing form of the enzyme, respectively.

  11. Structure and function of the bacteriophage T7 RNA polymerase (or, the virtues of simplicity).

    Science.gov (United States)

    McAllister, W T

    1993-01-01

    A consideration of the properties of a number of mutants of T7 RNA polymerase, together with emerging structural information (Sousa et al., 1993) allows an interpretation of the the mechanics of transcription by this relatively simple RNA polymerase. Evidence indicating features in common with other nucleotide polymerases (such as DNA polymerases and reverse transcriptases) is reviewed.

  12. Structural basis of transcription initiation by RNA polymerase II.

    OpenAIRE

    Sainsbury, S.; Bernecky, C.; Cramer, P

    2015-01-01

    Transcription of eukaryotic protein-coding genes commences with the assembly of a conserved initiation complex, which consists of RNA polymerase II (Pol II) and the general transcription factors, at promoter DNA. After two decades of research, the structural basis of transcription initiation is emerging. Crystal structures of many components of the initiation complex have been resolved, and structural information on Pol II complexes with general transcription factors has recently been obtaine...

  13. [Poised RNA polymerase II and master regulation in Metazoa].

    Science.gov (United States)

    Kashkin, K N; Sverdlov, E D

    2015-01-01

    This review is devoted to the mechanisms of transcriptional pause and poised state of RNA polymerase II. Features of poised promoters and chromatin are considered in brief. Role of regulated transcriptional pause as discrete and important stage in regulation of master genes that determine stem-cell differentiation, cell lineage and development in Metazoa is discussed. This work was supported by the Russian Science Foundation (project No. 14-50-00131).

  14. Structural basis of transcription initiation by RNA polymerase II.

    Science.gov (United States)

    Sainsbury, Sarah; Bernecky, Carrie; Cramer, Patrick

    2015-03-01

    Transcription of eukaryotic protein-coding genes commences with the assembly of a conserved initiation complex, which consists of RNA polymerase II (Pol II) and the general transcription factors, at promoter DNA. After two decades of research, the structural basis of transcription initiation is emerging. Crystal structures of many components of the initiation complex have been resolved, and structural information on Pol II complexes with general transcription factors has recently been obtained. Although mechanistic details await elucidation, available data outline how Pol II cooperates with the general transcription factors to bind to and open promoter DNA, and how Pol II directs RNA synthesis and escapes from the promoter.

  15. Mechanism of histone survival during transcription by RNA polymerase II.

    Science.gov (United States)

    Kulaeva, Olga I; Studitsky, Vasily M

    2010-01-01

    This work is related to and stems from our recent NSMB paper, "Mechanism of chromatin remodeling and recovery during passage of RNA polymerase II" (December 2009). Synopsis. Recent genomic studies from many laboratories have suggested that nucleosomes are not displaced from moderately transcribed genes. Furthermore, histones H3/H4 carrying the primary epigenetic marks are not displaced or exchanged (in contrast to H2A/H2B histones) during moderate transcription by RNA polymerase II (Pol II) in vivo. These exciting observations suggest that the large molecule of Pol II passes through chromatin structure without even transient displacement of H3/H4 histones. The most recent analysis of the RNA polymerase II (Pol II)-type mechanism of chromatin remodeling in vitro (described in our NSMB 2009 paper) suggests that nucleosome survival is tightly coupled with formation of a novel intermediate: a very small intranucleosomal DNA loop (Ø-loop) containing transcribing Pol II. In the submitted manuscript we critically evaluate one of the key predictions of this model: the lack of even transient displacement of histones H3/H4 during Pol II transcription in vitro. The data suggest that, indeed, histones H3/H4 are not displaced during Pol II transcription in vitro. These studies are directly connected with the observation in vivo on the lack of exchange of histones H3/H4 during Pol II transcription.

  16. Favipiravir (T-705), a novel viral RNA polymerase inhibitor.

    Science.gov (United States)

    Furuta, Yousuke; Gowen, Brian B; Takahashi, Kazumi; Shiraki, Kimiyasu; Smee, Donald F; Barnard, Dale L

    2013-11-01

    Favipiravir (T-705; 6-fluoro-3-hydroxy-2-pyrazinecarboxamide) is an antiviral drug that selectively inhibits the RNA-dependent RNA polymerase of influenza virus. It is phosphoribosylated by cellular enzymes to its active form, favipiravir-ribofuranosyl-5'-triphosphate (RTP). Its antiviral effect is attenuated by the addition of purine nucleic acids, indicating the viral RNA polymerase mistakenly recognizes favipiravir-RTP as a purine nucleotide. Favipiravir is active against a broad range of influenza viruses, including A(H1N1)pdm09, A(H5N1) and the recently emerged A(H7N9) avian virus. It also inhibits influenza strains resistant to current antiviral drugs, and shows a synergistic effect in combination with oseltamivir, thereby expanding influenza treatment options. A Phase III clinical evaluation of favipiravir for influenza therapy has been completed in Japan and two Phase II studies have been completed in the United States. In addition to its anti-influenza activity, favipiravir blocks the replication of many other RNA viruses, including arenaviruses (Junin, Machupo and Pichinde); phleboviruses (Rift Valley fever, sandfly fever and Punta Toro); hantaviruses (Maporal, Dobrava, and Prospect Hill); flaviviruses (yellow fever and West Nile); enteroviruses (polio- and rhinoviruses); an alphavirus, Western equine encephalitis virus; a paramyxovirus, respiratory syncytial virus; and noroviruses. With its unique mechanism of action and broad range of antiviral activity, favipiravir is a promising drug candidate for influenza and many other RNA viral diseases for which there are no approved therapies.

  17. Identification and characterization of barley RNA-directed RNA polymerases

    DEFF Research Database (Denmark)

    Madsen, Christian Toft; Stephens, Jennifer; Hornyik, Csaba

    2009-01-01

    in dicot species. In this report, we identi!ed and characterized HvRDR1, HvRDR2 and HvRDR6 genes in the monocot plant barley (Hordeum vulgare). We analysed their expression under various biotic and abiotic stresses including fungal and viral infections, salicylic acid treatment as well as during plant...... development. The different classes and subclasses of barley RDRs displayed contrasting expression patterns during pathogen challenge and development suggesting their involvement in speci!c regulatory pathways. Their response to heat and salicylic acid treatment suggests a conserved pattern of expression...

  18. The structure of an RNAi polymerase links RNA silencing and transcription.

    Directory of Open Access Journals (Sweden)

    Paula S Salgado

    2006-12-01

    Full Text Available RNA silencing refers to a group of RNA-induced gene-silencing mechanisms that developed early in the eukaryotic lineage, probably for defence against pathogens and regulation of gene expression. In plants, protozoa, fungi, and nematodes, but apparently not insects and vertebrates, it involves a cell-encoded RNA-dependent RNA polymerase (cRdRP that produces double-stranded RNA triggers from aberrant single-stranded RNA. We report the 2.3-A resolution crystal structure of QDE-1, a cRdRP from Neurospora crassa, and find that it forms a relatively compact dimeric molecule, each subunit of which comprises several domains with, at its core, a catalytic apparatus and protein fold strikingly similar to the catalytic core of the DNA-dependent RNA polymerases responsible for transcription. This evolutionary link between the two enzyme types suggests that aspects of RNA silencing in some organisms may recapitulate transcription/replication pathways functioning in the ancient RNA-based world.

  19. Characterization of soluble RNA-dependent RNA polymerase from dengue virus serotype 2: The polyhistidine tag compromises the polymerase activity.

    Science.gov (United States)

    Kamkaew, Maliwan; Chimnaronk, Sarin

    2015-08-01

    The viral RNA polymerase is an attractive target for inhibition in the treatment of viral infections. In the case of dengue virus (DENV), a member of the genus Flavivirus, the RNA-dependent RNA polymerase (RdRp) activity resides in the C-terminal two-thirds of non-structural protein (NS) 5 responsible for the de novo synthesis of the viral RNA genome. Among four distinct, but closely related dengue serotypes, serotype 2 (DENV-2) produces more severe diseases than other serotypes. It has been reported that bacterial production of the recombinant DENV-2 RdRp was difficult due to its low expression and solubility levels. To facilitate functional and structural analyses, we here demonstrate complete protocols for overexpression and purification of soluble DENV-2 RdRp, increasing protein yields by a remarkable 10 times compared to earlier reports. Three different forms of DENV-2 RdRp as either N- or C-terminally His-tagged fusions, or without tag, were purified to homogeneity. We show here that the presence of both the N- and C-terminal His-tag had a deleterious effect on polymerase activity and, in contrast to earlier studies, our non-tagged RdRp did not require manganese ions to activate RNA polymerization. We also determined an apparent Kd value of 53nM for binding to the 5'-UTR RNA by surface plasmon resonance (SPR). Our work provide a more suitable material for basic research of viral RdRp and for drug development.

  20. Functional Diversification of Maize RNA Polymerase IV and V subtypes via Alternative Catalytic Subunits

    Energy Technology Data Exchange (ETDEWEB)

    Haag, Jeremy R.; Brower-Toland, Brent; Krieger, Elysia K.; Sidorenko, Lyudmila; Nicora, Carrie D.; Norbeck, Angela D.; Irsigler, Andre; LaRue, Huachun; Brzeski, Jan; Mcginnis, Karen A.; Ivashuta, Sergey; Pasa-Tolic, Ljiljana; Chandler, Vicki L.; Pikaard, Craig S.

    2014-10-01

    Unlike nuclear multisubunit RNA polymerases I, II, and III, whose subunit compositions are conserved throughout eukaryotes, plant RNA polymerases IV and V are nonessential, Pol II-related enzymes whose subunit compositions are still evolving. Whereas Arabidopsis Pols IV and V differ from Pol II in four or five of their 12 subunits, respectively, and differ from one another in three subunits, proteomic ana- lyses show that maize Pols IV and V differ from Pol II in six subunits but differ from each other only in their largest subunits. Use of alternative catalytic second subunits, which are nonredundant for development and paramutation, yields at least two sub- types of Pol IV and three subtypes of Pol V in maize. Pol IV/Pol V associations with MOP1, RMR1, AGO121, Zm_DRD1/CHR127, SHH2a, and SHH2b extend parallels between paramutation in maize and the RNA-directed DNA methylation pathway in Arabidopsis.

  1. Archaeal rRNA operons, intron splicing and homing endonucleases, RNA polymerase operons and phylogeny

    DEFF Research Database (Denmark)

    Garrett, Roger Antony; Aagaard, Claus Sindbjerg; Andersen, Morten;

    1994-01-01

    Over the past decade our laboratory has had a strong interest in defining the phylogenetic status of the archaea. This has involved determining and analysing the sequences of operons of both rRNAs and RNA polymerases and it led to the discovery of the first archaeal rRNA intron. What follows...

  2. Comparative overview of RNA polymerase II and III transcription cycles, with focus on RNA polymerase III termination and reinitiation.

    Science.gov (United States)

    Arimbasseri, Aneeshkumar G; Rijal, Keshab; Maraia, Richard J

    2014-01-01

    In eukaryotes, RNA polymerase (RNAP) III transcribes hundreds of genes for tRNAs and 5S rRNA, among others, which share similar promoters and stable transcription initiation complexes (TIC), which support rapid RNAP III recycling. In contrast, RNAP II transcribes a large number of genes with highly variable promoters and interacting factors, which exert fine regulatory control over TIC lability and modifications of RNAP II at different transitional points in the transcription cycle. We review data that illustrate a relatively smooth continuity of RNAP III initiation-elongation-termination and reinitiation toward its function to produce high levels of tRNAs and other RNAs that support growth and development.

  3. Structural basis for transcription elongation by bacterial RNA polymerase.

    Science.gov (United States)

    Vassylyev, Dmitry G; Vassylyeva, Marina N; Perederina, Anna; Tahirov, Tahir H; Artsimovitch, Irina

    2007-07-12

    The RNA polymerase elongation complex (EC) is both highly stable and processive, rapidly extending RNA chains for thousands of nucleotides. Understanding the mechanisms of elongation and its regulation requires detailed information about the structural organization of the EC. Here we report the 2.5-A resolution structure of the Thermus thermophilus EC; the structure reveals the post-translocated intermediate with the DNA template in the active site available for pairing with the substrate. DNA strand separation occurs one position downstream of the active site, implying that only one substrate at a time can specifically bind to the EC. The upstream edge of the RNA/DNA hybrid stacks on the beta'-subunit 'lid' loop, whereas the first displaced RNA base is trapped within a protein pocket, suggesting a mechanism for RNA displacement. The RNA is threaded through the RNA exit channel, where it adopts a conformation mimicking that of a single strand within a double helix, providing insight into a mechanism for hairpin-dependent pausing and termination.

  4. An alternative RNA polymerase I structure reveals a dimer hinge.

    Science.gov (United States)

    Kostrewa, Dirk; Kuhn, Claus-D; Engel, Christoph; Cramer, Patrick

    2015-09-01

    RNA polymerase I (Pol I) is the central, 14-subunit enzyme that synthesizes the ribosomal RNA (rRNA) precursor in eukaryotic cells. The recent crystal structure of Pol I at 2.8 Å resolution revealed two novel elements: the `expander' in the active-centre cleft and the `connector' that mediates Pol I dimerization [Engel et al. (2013), Nature (London), 502, 650-655]. Here, a Pol I structure in an alternative crystal form that was solved by molecular replacement using the original atomic Pol I structure is reported. The resulting alternative structure lacks the expander but still shows an expanded active-centre cleft. The neighbouring Pol I monomers form a homodimer with a relative orientation distinct from that observed previously, establishing the connector as a hinge between Pol I monomers.

  5. Mutational analysis of the SDD sequence motif of a PRRSV RNA-dependent RNA polymerase.

    Science.gov (United States)

    Zhou, Yan; Zheng, Haihong; Gao, Fei; Tian, Debin; Yuan, Shishan

    2011-09-01

    The subgenomic mRNA transcription and genomic replication of the porcine reproductive and respiratory syndrome virus (PRRSV) are directed by the viral replicase. The replicase is expressed in the form of two polyproteins and is subsequently processed into smaller nonstructural proteins (nsps). nsp9, containing the viral replicase, has characteristic sequence motifs conserved among the RNA-dependent RNA polymerases (RdRp) of positive-strand (PS) RNA viruses. To test whether the conserved SDD motif can tolerate other conserved motifs of RNA viruses and the influence of every residue on RdRp catalytic activity, many amino acids substitutions were introduced into it. Only one nsp9 substitution, of serine by glycine (S3050G), could rescue mutant viruses. The rescued virus was genetically stable. Alteration of either aspartate residue was not tolerated, destroyed the polymerase activity, and abolished virus transcription, but did not eliminate virus replication. We also found that the SDD motif was essentially invariant for the signature sequence of PRRSV RdRp. It could not accommodate other conserved motifs found in other RNA viral polymerases, except the GDD motif, which is conserved in all the other PS RNA viruses. These findings indicated that nidoviruses are evolutionarily related to other PS RNA viruses. Our studies support the idea that the two aspartate residues of the SDD motif are critical and essential for PRRSV transcription and represent a sequence variant of the GDD motif in PS RNA viruses.

  6. Regulation of RNA-dependent RNA polymerase 1 and isochorismate synthase gene expression in Arabidopsis.

    Directory of Open Access Journals (Sweden)

    Lydia J R Hunter

    Full Text Available BACKGROUND: RNA-dependent RNA polymerases (RDRs function in anti-viral silencing in Arabidopsis thaliana and other plants. Salicylic acid (SA, an important defensive signal, increases RDR1 gene expression, suggesting that RDR1 contributes to SA-induced virus resistance. In Nicotiana attenuata RDR1 also regulates plant-insect interactions and is induced by another important signal, jasmonic acid (JA. Despite its importance in defense RDR1 regulation has not been investigated in detail. METHODOLOGY/PRINCIPAL FINDINGS: In Arabidopsis, SA-induced RDR1 expression was dependent on 'NON-EXPRESSER OF PATHOGENESIS-RELATED GENES 1', indicating regulation involves the same mechanism controlling many other SA- defense-related genes, including pathogenesis-related 1 (PR1. Isochorismate synthase 1 (ICS1 is required for SA biosynthesis. In defensive signal transduction RDR1 lies downstream of ICS1. However, supplying exogenous SA to ics1-mutant plants did not induce RDR1 or PR1 expression to the same extent as seen in wild type plants. Analysing ICS1 gene expression using transgenic plants expressing ICS1 promoter:reporter gene (β-glucuronidase constructs and by measuring steady-state ICS1 transcript levels showed that SA positively regulates ICS1. In contrast, ICS2, which is expressed at lower levels than ICS1, is unaffected by SA. The wound-response hormone JA affects expression of Arabidopsis RDR1 but jasmonate-induced expression is independent of CORONATINE-INSENSITIVE 1, which conditions expression of many other JA-responsive genes. Transiently increased RDR1 expression following tobacco mosaic virus inoculation was due to wounding and was not a direct effect of infection. RDR1 gene expression was induced by ethylene and by abscisic acid (an important regulator of drought resistance. However, rdr1-mutant plants showed normal responses to drought. CONCLUSIONS/SIGNIFICANCE: RDR1 is regulated by a much broader range of phytohormones than previously thought

  7. RNA polymerase and the ribosome: the close relationship.

    Science.gov (United States)

    McGary, Katelyn; Nudler, Evgeny

    2013-04-01

    In bacteria transcription and translation are linked in time and space. When coupled to RNA polymerase (RNAP), the translating ribosome ensures transcriptional processivity by preventing RNAP backtracking. Recent advances in the field have characterized important linker proteins that bridge the gap between transcription and translation: In particular, the NusE(S10):NusG complex and the NusG homolog, RfaH. The direct link between the moving ribosome and RNAP provides a basis for maintaining genomic integrity while enabling efficient transcription and timely translation of various genes within the bacterial cell. Copyright © 2013 Elsevier Ltd. All rights reserved.

  8. The bridge helix coordinates movements of modules in RNA polymerase

    Directory of Open Access Journals (Sweden)

    Landick Robert

    2010-11-01

    Full Text Available Abstract The RNA polymerase 'bridge helix' is a metastable α-helix that spans the leading edge of the enzyme active-site cleft. A new study published in BMC Biology reveals surprising tolerance to helix-disrupting changes in a region previously thought crucial for translocation, and suggests roles for two hinge-like segments of the bridge helix in coordinating modules that move during the nucleotide-addition cycle. See Research article: http://www.biomedcentral.com/1741-7007/8/134

  9. [Procedure for purifying RNA polymerase II from human placenta].

    Science.gov (United States)

    Kandyba, L V; Matsanova, V R; Shamovskiĭ, I V; Raĭt, V K

    1994-12-01

    DNA-dependent RNA polymerase IIB having a specific activity of 320 u./mg has been isolated from the term placenta homogenate using extraction performed at 4-6 degrees C in the presence of 75 mM ammonium sulfate and 1.5% nonidet P40, fractionation on DEAE-cellulose DE 23, desalting and heparin-agarose chromatography, resulting in 330-fold purification and a 18% yield. Technical details have been determined which are of crucial importance for reproducibility of affinity chromatography. The possibility of proteolysis of the IIc subunit during enzyme purification has been demonstrated.

  10. RNA-DNA Differences Are Generated in Human Cells within Seconds after RNA Exits Polymerase II

    Directory of Open Access Journals (Sweden)

    Isabel X. Wang

    2014-03-01

    Full Text Available RNA sequences are expected to be identical to their corresponding DNA sequences. Here, we found all 12 types of RNA-DNA sequence differences (RDDs in nascent RNA. Our results show that RDDs begin to occur in RNA chains ∼55 nt from the RNA polymerase II (Pol II active site. These RDDs occur so soon after transcription that they are incompatible with known deaminase-mediated RNA-editing mechanisms. Moreover, the 55 nt delay in appearance indicates that they do not arise during RNA synthesis by Pol II or as a direct consequence of modified base incorporation. Preliminary data suggest that RDD and R-loop formations may be coupled. These findings identify sequence substitution as an early step in cotranscriptional RNA processing.

  11. Rat1p maintains RNA polymerase II CTD phosphorylation balance

    DEFF Research Database (Denmark)

    Jimeno-González, Silvia; Schmid, Manfred; Malagon, Francisco

    2014-01-01

    In S. cerevisiae, the 5'-3' exonuclease Rat1p partakes in transcription termination. Although Rat1p-mediated RNA degradation has been suggested to play a role for this activity, the exact mechanisms by which Rat1p helps release RNA polymerase II (RNAPII) from the DNA template are poorly understood....... Here we describe a function of Rat1p in regulating phosphorylation levels of the C-terminal domain (CTD) of the largest RNAPII subunit, Rpb1p, during transcription elongation. The rat1-1 mutant exhibits highly elevated levels of CTD phosphorylation as well as RNAPII distribution and transcription...... termination defects. These phenotypes are all rescued by overexpression of the CTD phosphatase Fcp1p, suggesting a functional relationship between the absence of Rat1p activity, elevated CTD phosphorylation, and transcription defects. We also demonstrate that rat1-1 cells display increased RNAPII...

  12. Cloning and expression of autogenes encoding RNA polymerases of T7-like bacteriophages

    Energy Technology Data Exchange (ETDEWEB)

    Studier, F. William (Stony Brook, NY); Dubendorff, John W. (Sound Beach, NY)

    1998-01-01

    This invention relates to the cloning and expression of autogenes encoding RNA polymerases of T7 and T7-like bacteriophages, in which the RNA polymerase gene is transcribed from a promoter which is recognized by the encoded RNA polymerase. Cloning of T7 autogenes was achieved by reducing the activity of the RNA polymerase sufficiently to permit host cell growth. T7 RNA polymerase activity was controlled by combining two independent methods: lac-repression of the recombinant lac operator-T7 promoter in the autogene and inhibition of the polymerase by T7 lysozyme. Expression systems for producing the RNA polymerases of T7 and other T7-like bacteriophages, and expression systems for producing selected gene products are described, as well as other related materials and methods.

  13. Cloning and expression of autogenes encoding RNA polymerases of T7-like bacteriophages

    Energy Technology Data Exchange (ETDEWEB)

    Studier, F.W.; Dubendorff, J.W.

    1998-10-20

    This invention relates to the cloning and expression of autogenes encoding RNA polymerases of T7 and T7-like bacteriophages, in which the RNA polymerase gene is transcribed from a promoter which is recognized by the encoded RNA polymerase. Cloning of T7 autogenes was achieved by reducing the activity of the RNA polymerase sufficiently to permit host cell growth. T7 RNA polymerase activity was controlled by combining two independent methods: lac-repression of the recombinant lac operator-T7 promoter in the autogene and inhibition of the polymerase by T7 lysozyme. Expression systems for producing the RNA polymerases of T7 and other T7-like bacteriophages, and expression systems for producing selected gene products are described, as well as other related materials and methods. 12 figs.

  14. Cloning and expression of autogenes encoding RNA polymerases of T7-like bacteriophages

    Energy Technology Data Exchange (ETDEWEB)

    Studier, F.W.; Dubendorff, J.W.

    1998-11-03

    This invention relates to the cloning and expression of autogenes encoding RNA polymerases of T7 and T7-like bacteriophages, in which the RNA polymerase gene is transcribed from a promoter which is recognized by the encoded RNA polymerase. Cloning of T7 autogenes was achieved by reducing the activity of the RNA polymerase sufficiently to permit host cell growth. T7 RNA polymerase activity was controlled by combining two independent methods: lac-repression of the recombinant lac operator-T7 promoter in the autogene and inhibition of the polymerase by T7 lysozyme. Expression systems for producing the RNA polymerases of T7 and other T7-like bacteriophages, and expression systems for producing selected gene products are described, as well as other related materials and methods. 12 figs.

  15. Coupling of RNA Polymerase II Transcription Elongation with Pre-mRNA Splicing.

    Science.gov (United States)

    Saldi, Tassa; Cortazar, Michael A; Sheridan, Ryan M; Bentley, David L

    2016-06-19

    Pre-mRNA maturation frequently occurs at the same time and place as transcription by RNA polymerase II. The co-transcriptionality of mRNA processing has permitted the evolution of mechanisms that functionally couple transcription elongation with diverse events that occur on the nascent RNA. This review summarizes the current understanding of the relationship between transcriptional elongation through a chromatin template and co-transcriptional splicing including alternative splicing decisions that affect the expression of most human genes. Copyright © 2016 Elsevier Ltd. All rights reserved.

  16. Guanosine tetraphosphate as a global regulator of bacterial RNA synthesis: a model involving RNA polymerase pausing and queuing.

    Science.gov (United States)

    Bremer, H; Ehrenberg, M

    1995-05-17

    A recently reported comparison of stable RNA (rRNA, tRNA) and mRNA synthesis rates in ppGpp-synthesizing and ppGpp-deficient (delta relA delta spoT) bacteria has suggested that ppGpp inhibits transcription initiation from stable RNA promoters, as well as synthesis of (bulk) mRNA. Inhibition of stable RNA synthesis occurs mainly during slow growth of bacteria when cytoplasmic levels of ppGpp are high. In contrast, inhibition of mRNA occurs mainly during fast growth when ppGpp levels are low, and it is associated with a partial inactivation of RNA polymerase. To explain these observations it has been proposed that ppGpp causes transcriptional pausing and queuing during the synthesis of mRNA. Polymerase queuing requires high rates of transcription initiation in addition to polymerase pausing, and therefore high concentrations of free RNA polymerase. These conditions are found in fast growing bacteria. Furthermore, the RNA polymerase queues lead to a promoter blocking when RNA polymerase molecules stack up from the pause site back to the (mRNA) promoter. This occurs most frequently at pause sites close to the promoter. Blocking of mRNA promoters diverts RNA polymerase to stable RNA promoters. In this manner ppGpp could indirectly stimulate synthesis of stable RNA at high growth rates. In the present work a mathematical analysis, based on the theory of queuing, is presented and applied to the global control of transcription in bacteria. This model predicts the in vivo distribution of RNA polymerase over stable RNA and mRNA genes for both ppGpp-synthesizing and ppGpp-deficient bacteria in response to different environmental conditions. It also shows how small changes in basal ppGpp concentrations can produce large changes in the rate of stable RNA synthesis.

  17. Improved crystallization of the coxsackievirus B3 RNA-dependent RNA polymerase

    Energy Technology Data Exchange (ETDEWEB)

    Jabafi, Ilham; Selisko, Barbara; Coutard, Bruno; De Palma, Armando M.; Neyts, Johan; Egloff, Marie-Pierre; Grisel, Sacha; Dalle, Karen; Campanacci, Valerie; Spinelli, Silvia; Cambillau, Christian; Canard, Bruno; Gruez, Arnaud, E-mail: arnaud.gruez@maem.uhp-nancy.fr [Centre National de la Recherche Scientifique and Universités d’Aix-Marseille I et II, UMR 6098, Architecture et Fonction des Macromolécules Biologiques, Ecole Supérieure d’Ingénieurs de Luminy-Case 925, 163 Avenue de Luminy, 13288 Marseille CEDEX 9 (France)

    2007-06-01

    The first crystal of a coxsackievirus RNA-dependent RNA polymerase is reported. The Picornaviridae virus family contains a large number of human pathogens such as poliovirus, hepatitis A virus and rhinoviruses. Amongst the viruses belonging to the genus Enterovirus, several serotypes of coxsackievirus coexist for which neither vaccine nor therapy is available. Coxsackievirus B3 is involved in the development of acute myocarditis and dilated cardiomyopathy and is thought to be an important cause of sudden death in young adults. Here, the first crystal of a coxsackievirus RNA-dependent RNA polymerase is reported. Standard crystallization methods yielded crystals that were poorly suited to X-ray diffraction studies, with one axis being completely disordered. Crystallization was improved by testing crystallization solutions from commercial screens as additives. This approach yielded crystals that diffracted to 2.1 Å resolution and that were suitable for structure determination.

  18. DDR complex facilitates global association of RNA polymerase V to promoters and evolutionarily young transposons.

    Science.gov (United States)

    Zhong, Xuehua; Hale, Christopher J; Law, Julie A; Johnson, Lianna M; Feng, Suhua; Tu, Andy; Jacobsen, Steven E

    2012-09-01

    The plant-specific DNA-dependent RNA polymerase V (Pol V) evolved from Pol II to function in an RNA-directed DNA methylation pathway. Here, we have identified targets of Pol V in Arabidopsis thaliana on a genome-wide scale using ChIP-seq of NRPE1, the largest catalytic subunit of Pol V. We found that Pol V is enriched at promoters and evolutionarily recent transposons. This localization pattern is highly correlated with Pol V-dependent DNA methylation and small RNA accumulation. We also show that genome-wide chromatin association of Pol V is dependent on all members of a putative chromatin-remodeling complex termed DDR. Our study presents a genome-wide view of Pol V occupancy and sheds light on the mechanistic basis of Pol V localization. Furthermore, these findings suggest a role for Pol V and RNA-directed DNA methylation in genome surveillance and in responding to genome evolution.

  19. File list: Pol.NoD.10.RNA_Polymerase_II.AllCell [Chip-atlas[Archive

    Lifescience Database Archive (English)

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  20. RNA-dependent RNA polymerase 6 delays accumulation and precludes meristem invasion of a viroid that replicates in the nucleus.

    Science.gov (United States)

    Di Serio, Francesco; Martínez de Alba, Angel-Emilio; Navarro, Beatriz; Gisel, Andreas; Flores, Ricardo

    2010-03-01

    The detection of viroid-derived small RNAs (vd-sRNAs) similar to the small interfering RNAs (siRNAs, 21 to 24 nucleotides [nt]) in plants infected by nuclear-replicating members of the family Pospiviroidae (type species, Potato spindle tuber viroid [PSTVd]) indicates that they are inducers and targets of the RNA-silencing machinery of their hosts. RNA-dependent RNA polymerase 6 (RDR6) catalyzes an amplification circuit producing the double-stranded precursors of secondary siRNAs. Recently, the role of RDR6 in restricting systemic spread of certain RNA viruses and precluding their invasion of the apical growing tip has been documented using RDR6-silenced Nicotiana benthamiana (NbRDR6i) plants. Here we show that RDR6 is also engaged in regulating PSTVd levels: accumulation of PSTVd genomic RNA was increased in NbRDR6i plants with respect to the wild-type controls (Nbwt) early in infection, whereas this difference decreased or disappeared in later infection stages. Moreover, in situ hybridization revealed that RDR6 is involved in restricting PSTVd access in floral and vegetative meristems, thus providing firm genetic evidence for an antiviroid RNA silencing mechanism. RNA gel blot hybridization and deep sequencing showed in wt and RDR6i backgrounds that PSTVd sRNAs (i) accumulate to levels paralleling their genomic RNA, (ii) display similar patterns with prevailing 22- or 21-nt plus-strand species, and (iii) adopt strand-specific hot spot profiles along the genomic RNA. Therefore, the surveillance mechanism restraining entry of some RNA viruses into meristems likely also controls PSTVd access in N. benthamiana. Unexpectedly, deep sequencing also disclosed in NbRDR6i plants a profile of RDR6-derived siRNA dominated by 21-nt plus-strand species mapping within a narrow window of the hairpin RNA stem expressed transgenically for silencing RDR6, indicating that minus-strand siRNAs silencing the NbRDR6 mRNA represent a minor fraction of the total siRNA population.

  1. Cyclin-dependent kinase 9 links RNA polymerase II transcription to processing of ribosomal RNA.

    Science.gov (United States)

    Burger, Kaspar; Mühl, Bastian; Rohrmoser, Michaela; Coordes, Britta; Heidemann, Martin; Kellner, Markus; Gruber-Eber, Anita; Heissmeyer, Vigo; Strässer, Katja; Eick, Dirk

    2013-07-19

    Ribosome biogenesis is a process required for cellular growth and proliferation. Processing of ribosomal RNA (rRNA) is highly sensitive to flavopiridol, a specific inhibitor of cyclin-dependent kinase 9 (Cdk9). Cdk9 has been characterized as the catalytic subunit of the positive transcription elongation factor b (P-TEFb) of RNA polymerase II (RNAPII). Here we studied the connection between RNAPII transcription and rRNA processing. We show that inhibition of RNAPII activity by α-amanitin specifically blocks processing of rRNA. The block is characterized by accumulation of 3' extended unprocessed 47 S rRNAs and the entire inhibition of other 47 S rRNA-specific processing steps. The transcription rate of rRNA is moderately reduced after inhibition of Cdk9, suggesting that defective 3' processing of rRNA negatively feeds back on RNAPI transcription. Knockdown of Cdk9 caused a strong reduction of the levels of RNAPII-transcribed U8 small nucleolar RNA, which is essential for 3' rRNA processing in mammalian cells. Our data demonstrate a pivotal role of Cdk9 activity for coupling of RNAPII transcription with small nucleolar RNA production and rRNA processing.

  2. Structural basis of transcription: separation of RNA from DNA by RNA polymerase II.

    Science.gov (United States)

    Westover, Kenneth D; Bushnell, David A; Kornberg, Roger D

    2004-02-13

    The structure of an RNA polymerase II-transcribing complex has been determined in the posttranslocation state, with a vacancy at the growing end of the RNA-DNA hybrid helix. At the opposite end of the hybrid helix, the RNA separates from the template DNA. This separation of nucleic acid strands is brought about by interaction with a set of proteins loops in a strand/loop network. Formation of the network must occur in the transition from abortive initiation to promoter escape.

  3. Characterization of a 7-kilodalton subunit of vaccinia virus DNA-dependent RNA polymerase with structural similarities to the smallest subunit of eukaryotic RNA polymerase II.

    Science.gov (United States)

    Amegadzie, B Y; Ahn, B Y; Moss, B

    1992-05-01

    A previously unrecognized 7-kDa polypeptide copurified with the DNA-dependent RNA polymerase of vaccinia virus virions. Internal amino acid sequences of the small protein matched a viral genomic open reading frame of 63 codons. Antipeptide antiserum was used to confirm the specific and complete association of the 7-kDa protein with RNA polymerase. The amino acid sequence predicted from the viral gene, named rpo7, was 23% identical to that of the smallest subunit of Saccharomyces cerevisiae RNA polymerase II, and a metal-binding motif, Cys-X-X-Cys-Gly, was located at precisely the same location near the N terminus in the two proteins. RNA analyses demonstrated early transcriptional initiation and termination signals in the rpo7 gene sequence. The viral RNA polymerase subunit was synthesized during the early phase of infection and continued to accumulate during the late phase.

  4. Crystal structure of Zika virus NS5 RNA-dependent RNA polymerase

    Science.gov (United States)

    Godoy, Andre S.; Lima, Gustavo M. A.; Oliveira, Ketllyn I. Z.; Torres, Naiara U.; Maluf, Fernando V.; Guido, Rafael V. C.; Oliva, Glaucius

    2017-01-01

    The current Zika virus (ZIKV) outbreak became a global health threat of complex epidemiology and devastating neurological impacts, therefore requiring urgent efforts towards the development of novel efficacious and safe antiviral drugs. Due to its central role in RNA viral replication, the non-structural protein 5 (NS5) RNA-dependent RNA-polymerase (RdRp) is a prime target for drug discovery. Here we describe the crystal structure of the recombinant ZIKV NS5 RdRp domain at 1.9 Å resolution as a platform for structure-based drug design strategy. The overall structure is similar to other flaviviral homologues. However, the priming loop target site, which is suitable for non-nucleoside polymerase inhibitor design, shows significant differences in comparison with the dengue virus structures, including a tighter pocket and a modified local charge distribution. PMID:28345596

  5. On the evolution of the single-subunit RNA polymerases.

    Science.gov (United States)

    Cermakian, N; Ikeda, T M; Miramontes, P; Lang, B F; Gray, M W; Cedergren, R

    1997-12-01

    Many eukaryotic nuclear genomes as well as mitochondrial plasmids contain genes displaying evident sequence similarity to those encoding the single-subunit RNA polymerase (ssRNAP) of bacteriophage T7 and its relatives. We have collected and aligned these ssRNAP sequences and have constructed unrooted phylogenetic trees that demonstrate the separation of ssRNAPs into three well-defined and nonoverlapping clusters (phage-encoded, nucleus-encoded, and plasmid-encoded). Our analyses indicate that these three subfamiles of T7-like RNAPs shared a common ancestor; however, the order in which the groups diverged cannot be inferred from available data. On the basis of structural similarities and mutational data, we suggest that the ancestral ssRNAP gene may have arisen via duplication and divergence of a DNA polymerase or reverse transcriptase gene. Considering the current phylogenetic distribution of ssRNAP sequences, we further suggest that the origin of the ancestral ssRNAP gene closely paralleled in time the introduction of mitochondria into eukaryotic cells through a eubacterial endosymbiosis.

  6. Structural basis of transcription by bacterial and eukaryotic RNA polymerases.

    Science.gov (United States)

    Sekine, Shun-ichi; Tagami, Shunsuke; Yokoyama, Shigeyuki

    2012-02-01

    DNA-dependent RNA polymerase (RNAP) is responsible for cellular gene transcription. Although crystallographic studies on prokaryotic and eukaryotic RNAPs have elucidated the basic RNAP architectures, the structural details of many essential events during transcription initiation, elongation, and termination are still largely unknown. Recent crystallographic studies on a bacterial RNAP and yeast RNAP II have revealed different RNAP structural states from that of the normal transcribing complex, as well as the basis of transcription factor functions, advancing our understanding of transcription. These studies have highlighted unexpected similarities in many fundamental aspects of transcription mechanisms between the bacterial and eukaryotic transcription machineries. Remarkable differences also exist between the bacterial and eukaryotic transcription systems, suggesting directions for future studies. Copyright © 2011 Elsevier Ltd. All rights reserved.

  7. Molecular evolution of the RNA polymerase II CTD.

    Science.gov (United States)

    Chapman, Rob D; Heidemann, Martin; Hintermair, Corinna; Eick, Dirk

    2008-06-01

    In higher eukaryotes, an unusual C-terminal domain (CTD) is crucial to the function of RNA polymerase II in transcription. The CTD consists of multiple heptapeptide repeats; differences in the number of repeats between organisms and their degree of conservation have intrigued researchers for two decades. Here, we review the evolution of the CTD at the molecular level. Several primitive motifs have been integrated into compound heptads that can be readily amplified. The selection of phosphorylatable residues in the heptad repeat provided the opportunity for advanced gene regulation in eukaryotes. Current findings suggest that the CTD should be considered as a collection of continuous overlapping motifs as opposed to a specific functional unit defined by a heptad.

  8. Trypanosoma brucei: a putative RNA polymerase II promoter.

    Science.gov (United States)

    Bayele, Henry K

    2009-12-01

    RNA polymerase II (pol II) promoters are rare in the African trypanosome Trypanosoma brucei because gene regulation in the parasite is complex and polycistronic. Here, we describe a putative pol II promoter and its structure-function relationship. The promoter has features of an archetypal eukaryotic pol II promoter including putative canonical CCAAT and TATA boxes, and an initiator element. However, the spatial arrangement of these elements is only similar to yeast pol II promoters. Deletion mapping and transcription assays enabled delineation of a minimal promoter that could drive orientation-independent reporter gene expression suggesting that it may be a bidirectional promoter. In vitro transcription in a heterologous nuclear extract revealed that the promoter can be recognized by the basal eukaryotic transcription complex. This suggests that the transcription machinery in the parasite may be very similar to those of other eukaryotes.

  9. DNA structure in human RNA polymerase II promoters

    DEFF Research Database (Denmark)

    Pedersen, Anders Gorm; Baldi, Pierre; Chauvin, Yves

    1998-01-01

    the high-bendability regions position nucleosomes at the downstream end of the transcriptional start point, and consider the possibility of interaction between histone-like TAFs and this area. We also propose the use of this structural signature in computational promoter-finding algorithms.......The fact that DNA three-dimensional structure is important for transcriptional regulation begs the question of whether eukaryotic promoters contain general structural features independently of what genes they control. We present an analysis of a large set of human RNA polymerase II promoters...... with a very low level of sequence similarity. The sequences, which include both TATA-containing and TATA-less promoters, are aligned by hidden Markov models. Using three different models of sequence-derived DNA bendability, the aligned promoters display a common structural profile with bendability being low...

  10. Structural and functional characterization of sapovirus RNA-dependent RNA polymerase.

    Science.gov (United States)

    Fullerton, Stephen W B; Blaschke, Martina; Coutard, Bruno; Gebhardt, Julia; Gorbalenya, Alexander; Canard, Bruno; Tucker, Paul A; Rohayem, Jacques

    2007-02-01

    Sapoviruses are one of the major agents of acute gastroenteritis in childhood. They form a tight genetic cluster (genus) in the Caliciviridae family that regroups both animal and human pathogenic strains. No permissive tissue culture has been developed for human sapovirus, limiting its characterization to surrogate systems. We report here on the first extensive characterization of the key enzyme of replication, the RNA-dependent RNA polymerase (RdRp) associated with the 3D(pol)-like protein. Enzymatically active sapovirus 3D(pol) and its defective mutant were expressed in Escherichia coli and purified. The overall structure of the sapovirus 3D(pol) was determined by X-ray crystallography to 2.32-A resolution. It revealed a right hand fold typical for template-dependent polynucleotide polymerases. The carboxyl terminus is located within the active site cleft, as observed in the RdRp of some (norovirus) but not other (lagovirus) caliciviruses. Sapovirus 3D(pol) prefers Mn(2+) over Mg(2+) but may utilize either as a cofactor in vitro. In a synthetic RNA template-dependent reaction, sapovirus 3D(pol) synthesizes a double-stranded RNA or labels the template 3' terminus by terminal transferase activity. Initiation of RNA synthesis occurs de novo on heteropolymeric templates or in a primer-dependent manner on polyadenylated templates. Strikingly, this mode of initiation of RNA synthesis was also described for norovirus, but not for lagovirus, suggesting structural and functional homologies in the RNA-dependent RNA polymerase of human pathogenic caliciviruses. This first experimental evidence makes sapovirus 3D(pol) an attractive target for developing drugs to control calicivirus infection in humans.

  11. Improving Saccharomyces cerevisiae ethanol production and tolerance via RNA polymerase II subunit Rpb7

    National Research Council Canada - National Science Library

    Zilong Qiu; Rongrong Jiang

    2017-01-01

    .... Here we try to improve Saccharomyces cerevisiae ethanol tolerance and productivity by reprogramming its transcription profile through rewiring its key transcription component RNA polymerase II (RNAP II...

  12. Initiation of RNA Polymerization and Polymerase Encapsidation by a Small dsRNA Virus.

    Directory of Open Access Journals (Sweden)

    Aaron M Collier

    2016-04-01

    Full Text Available During the replication cycle of double-stranded (ds RNA viruses, the viral RNA-dependent RNA polymerase (RdRP replicates and transcribes the viral genome from within the viral capsid. How the RdRP molecules are packaged within the virion and how they function within the confines of an intact capsid are intriguing questions with answers that most likely vary across the different dsRNA virus families. In this study, we have determined a 2.4 Å resolution structure of an RdRP from the human picobirnavirus (hPBV. In addition to the conserved polymerase fold, the hPBV RdRP possesses a highly flexible 24 amino acid loop structure located near the C-terminus of the protein that is inserted into its active site. In vitro RNA polymerization assays and site-directed mutagenesis showed that: (1 the hPBV RdRP is fully active using both ssRNA and dsRNA templates; (2 the insertion loop likely functions as an assembly platform for the priming nucleotide to allow de novo initiation; (3 RNA transcription by the hPBV RdRP proceeds in a semi-conservative manner; and (4 the preference of virus-specific RNA during transcription is dictated by the lower melting temperature associated with the terminal sequences. Co-expression of the hPBV RdRP and the capsid protein (CP indicated that, under the conditions used, the RdRP could not be incorporated into the recombinant capsids in the absence of the viral genome. Additionally, the hPBV RdRP exhibited higher affinity towards the conserved 5'-terminal sequence of the viral RNA, suggesting that the RdRP molecules may be encapsidated through their specific binding to the viral RNAs during assembly.

  13. Structural basis of initial RNA polymerase II transcription.

    Science.gov (United States)

    Cheung, Alan C M; Sainsbury, Sarah; Cramer, Patrick

    2011-11-04

    During transcription initiation by RNA polymerase (Pol) II, a transient open promoter complex (OC) is converted to an initially transcribing complex (ITC) containing short RNAs, and to a stable elongation complex (EC). We report structures of a Pol II-DNA complex mimicking part of the OC, and of complexes representing minimal ITCs with 2, 4, 5, 6, and 7 nucleotide (nt) RNAs, with and without a non-hydrolyzable nucleoside triphosphate (NTP) in the insertion site +1. The partial OC structure reveals that Pol II positions the melted template strand opposite the active site. The ITC-mimicking structures show that two invariant lysine residues anchor the 3'-proximal phosphate of short RNAs. Short DNA-RNA hybrids adopt a tilted conformation that excludes the +1 template nt from the active site. NTP binding induces complete DNA translocation and the standard hybrid conformation. Conserved NTP contacts indicate a universal mechanism of NTP selection. The essential residue Q1078 in the closed trigger loop binds the NTP 2'-OH group, explaining how the trigger loop couples catalysis to NTP selection, suppressing dNTP binding and DNA synthesis.

  14. Rat1p maintains RNA polymerase II CTD phosphorylation balance

    Science.gov (United States)

    Jimeno-González, Silvia; Schmid, Manfred; Malagon, Francisco; Haaning, Line Lindegaard; Jensen, Torben Heick

    2014-01-01

    In S. cerevisiae, the 5′-3′ exonuclease Rat1p partakes in transcription termination. Although Rat1p-mediated RNA degradation has been suggested to play a role for this activity, the exact mechanisms by which Rat1p helps release RNA polymerase II (RNAPII) from the DNA template are poorly understood. Here we describe a function of Rat1p in regulating phosphorylation levels of the C-terminal domain (CTD) of the largest RNAPII subunit, Rpb1p, during transcription elongation. The rat1-1 mutant exhibits highly elevated levels of CTD phosphorylation as well as RNAPII distribution and transcription termination defects. These phenotypes are all rescued by overexpression of the CTD phosphatase Fcp1p, suggesting a functional relationship between the absence of Rat1p activity, elevated CTD phosphorylation, and transcription defects. We also demonstrate that rat1-1 cells display increased RNAPII transcription kinetics, a feature that may contribute to the cellular phenotypes of the mutant. Consistently, the rat1-1 allele is synthetic lethal with the rpb1-E1103G mutation, causing increased RNAPII speed, and is suppressed by the rpb2-10 mutation, causing slowed transcription. Thus, Rat1p plays more complex roles in controlling transcription than previously thought. PMID:24501251

  15. Plant RNA binding proteins for control of RNA virus infection

    OpenAIRE

    Huh, Sung Un; Paek, Kyung-Hee

    2013-01-01

    Plant RNA viruses have effective strategies to infect host plants through either direct or indirect interactions with various host proteins, thus suppressing the host immune system. When plant RNA viruses enter host cells exposed RNAs of viruses are recognized by the host immune system through processes such as siRNA-dependent silencing. Interestingly, some host RNA binding proteins have been involved in the inhibition of RNA virus replication, movement, and translation through RNA-specific b...

  16. Noncoding transcription by alternative rna polymerases dynamically regulates an auxin-driven chromatin loop

    KAUST Repository

    Ariel, Federico D.

    2014-08-01

    The eukaryotic epigenome is shaped by the genome topology in three-dimensional space. Dynamic reversible variations in this epigenome structure directly influence the transcriptional responses to developmental cues. Here, we show that the Arabidopsis long intergenic noncoding RNA (lincRNA) APOLO is transcribed by RNA polymerases II and V in response to auxin, a phytohormone controlling numerous facets of plant development. This dual APOLO transcription regulates the formation of a chromatin loop encompassing the promoter of its neighboring gene PID, a key regulator of polar auxin transport. Altering APOLO expression affects chromatin loop formation, whereas RNA-dependent DNA methylation, active DNA demethylation, and Polycomb complexes control loop dynamics. This dynamic chromatin topology determines PID expression patterns. Hence, the dual transcription of a lincRNA influences local chromatin topology and directs dynamic auxin-controlled developmental outputs on neighboring genes. This mechanism likely underscores the adaptive success of plants in diverse environments and may be widespread in eukaryotes. © 2014 Elsevier Inc.

  17. Transcriptional interference by RNA polymerase pausing and dislodgement of transcription factors.

    Science.gov (United States)

    Palmer, Adam C; Egan, J Barry; Shearwin, Keith E

    2011-01-01

    Transcriptional interference is the in cis suppression of one transcriptional process by another. Mathematical modeling shows that promoter occlusion by elongating RNA polymerases cannot produce strong interference. Interference may instead be generated by (1) dislodgement of slow-to-assemble pre-initiation complexes and transcription factors and (2) prolonged occlusion by paused RNA polymerases.

  18. Structural basis of transcription: Mismatch-specific fidelity mechanisms and paused RNA polymerase II with frayed RNA

    OpenAIRE

    Sydow, J.; Brueckner, F.; Cheung, A; Damsma, G.; Dengl, S.; Lehmann, E.; Vassylyev, D.; Cramer, P

    2009-01-01

    We show that RNA polymerase (Pol) II prevents erroneous transcription in vitro with different strategies that depend on the type of DNA,RNA base mismatch. Certain mismatches are efficiently formed but impair RNA extension. Other mismatches allow for RNA extension but are inefficiently formed and efficiently proofread by RNA cleavage. X-ray analysis reveals that a T,U mismatch impairs RNA extension by forming a wobble base pair at the Pol II active center that dissociates the catalytic metal i...

  19. The Maize Imprinted Gene Floury3 Encodes a PLATZ Protein Required for tRNA and 5S rRNA Transcription Through Interaction with RNA Polymerase III.

    Science.gov (United States)

    Li, Qi; Wang, Jiechen; Ye, Jianwei; Zheng, Xixi; Xiang, Xiaoli; Li, Changsheng; Fu, Miaomiao; Wang, Qiong; Zhang, Zhi-Yong; Wu, Yongrui

    2017-09-05

    Maize (Zea mays) floury3 (fl3) is a classic semi-dominant negative mutant that exhibits severe defects in the endosperm but fl3 plants otherwise appear normal. We cloned the fl3 gene and determined that it encodes a PLATZ (plant AT-rich sequence- and zinc-binding) protein. The mutation in fl3 resulted in an Asn to His replacement in the conserved PLATZ domain, creating a dominant allele. Fl3 is specifically expressed in starchy endosperm cells and regulated by genomic imprinting, which leads to the suppressed expression of fl3 when transmitted through the male, perhaps as a consequence the semi-dominant behavior. Yeast two-hybrid screening and bimolecular luciferase complementation (BiLC) experiments revealed that FL3 interacts with the RNA polymerase III subunit 53 (RPC53) and transcription factor class C 1 (TFC1), two critical factors of the RNA polymerase III (RNAPIII) transcription complex. In the fl3 endosperm, the levels of many tRNAs and 5S rRNA that are transcribed by RNAPIII are significantly reduced, suggesting that the incorrectly folded fl3 protein may impair the function of RNAPIII. The transcriptome is dramatically altered in fl3 mutants, in which the down-regulated genes are primarily enriched in pathways related to translation, ribosome, misfolded protein responses and nutrient reservoir activity. Collectively, these changes may lead to defects in endosperm development and storage reserve filling in fl3 seeds. © 2017 American Society of Plant Biologists. All rights reserved.

  20. Structural visualization of the p53/RNA polymerase II assembly.

    Science.gov (United States)

    Singh, Sameer K; Qiao, Zhen; Song, Lihua; Jani, Vijay; Rice, William; Eng, Edward; Coleman, Robert A; Liu, Wei-Li

    2016-11-15

    The master tumor suppressor p53 activates transcription in response to various cellular stresses in part by facilitating recruitment of the transcription machinery to DNA. Recent studies have documented a direct yet poorly characterized interaction between p53 and RNA polymerase II (Pol II). Therefore, we dissected the human p53/Pol II interaction via single-particle cryo-electron microscopy, structural docking, and biochemical analyses. This study reveals that p53 binds Pol II via the Rpb1 and Rpb2 subunits, bridging the DNA-binding cleft of Pol II proximal to the upstream DNA entry site. In addition, the key DNA-binding surface of p53, frequently disrupted in various cancers, remains exposed within the assembly. Furthermore, the p53/Pol II cocomplex displays a closed conformation as defined by the position of the Pol II clamp domain. Notably, the interaction of p53 and Pol II leads to increased Pol II elongation activity. These findings indicate that p53 may structurally regulate DNA-binding functions of Pol II via the clamp domain, thereby providing insights into p53-regulated Pol II transcription.

  1. Nucleosome Positioning and NDR Structure at RNA Polymerase III Promoters

    Science.gov (United States)

    Helbo, Alexandra Søgaard; Lay, Fides D.; Jones, Peter A.; Liang, Gangning; Grønbæk, Kirsten

    2017-02-01

    Chromatin is structurally involved in the transcriptional regulation of all genes. While the nucleosome positioning at RNA polymerase II (pol II) promoters has been extensively studied, less is known about the chromatin structure at pol III promoters in human cells. We use a high-resolution analysis to show substantial differences in chromatin structure of pol II and pol III promoters, and between subtypes of pol III genes. Notably, the nucleosome depleted region at the transcription start site of pol III genes extends past the termination sequences, resulting in nucleosome free gene bodies. The +1 nucleosome is located further downstream than at pol II genes and furthermore displays weak positioning. The variable position of the +1 location is seen not only within individual cell populations and between cell types, but also between different pol III promoter subtypes, suggesting that the +1 nucleosome may be involved in the transcriptional regulation of pol III genes. We find that expression and DNA methylation patterns correlate with distinct accessibility patterns, where DNA methylation associates with the silencing and inaccessibility at promoters. Taken together, this study provides the first high-resolution map of nucleosome positioning and occupancy at human pol III promoters at specific loci and genome wide.

  2. Antibacterial Nucleoside-Analog Inhibitor of Bacterial RNA Polymerase.

    Science.gov (United States)

    Maffioli, Sonia I; Zhang, Yu; Degen, David; Carzaniga, Thomas; Del Gatto, Giancarlo; Serina, Stefania; Monciardini, Paolo; Mazzetti, Carlo; Guglierame, Paola; Candiani, Gianpaolo; Chiriac, Alina Iulia; Facchetti, Giuseppe; Kaltofen, Petra; Sahl, Hans-Georg; Dehò, Gianni; Donadio, Stefano; Ebright, Richard H

    2017-06-15

    Drug-resistant bacterial pathogens pose an urgent public-health crisis. Here, we report the discovery, from microbial-extract screening, of a nucleoside-analog inhibitor that inhibits bacterial RNA polymerase (RNAP) and exhibits antibacterial activity against drug-resistant bacterial pathogens: pseudouridimycin (PUM). PUM is a natural product comprising a formamidinylated, N-hydroxylated Gly-Gln dipeptide conjugated to 6'-amino-pseudouridine. PUM potently and selectively inhibits bacterial RNAP in vitro, inhibits bacterial growth in culture, and clears infection in a mouse model of Streptococcus pyogenes peritonitis. PUM inhibits RNAP through a binding site on RNAP (the NTP addition site) and mechanism (competition with UTP for occupancy of the NTP addition site) that differ from those of the RNAP inhibitor and current antibacterial drug rifampin (Rif). PUM exhibits additive antibacterial activity when co-administered with Rif, exhibits no cross-resistance with Rif, and exhibits a spontaneous resistance rate an order-of-magnitude lower than that of Rif. PUM is a highly promising lead for antibacterial therapy. Copyright © 2017 Elsevier Inc. All rights reserved.

  3. CaRDR1, an RNA-Dependent RNA Polymerase Plays a Positive Role in Pepper Resistance against TMV.

    Science.gov (United States)

    Qin, Lei; Mo, Ning; Zhang, Yang; Muhammad, Tayeb; Zhao, Guiye; Zhang, Yan; Liang, Yan

    2017-01-01

    RNA silencing functions as a major natural antiviral defense mechanism in plants. RNA-dependent RNA polymerases (RDRs) that catalyze the synthesis of double-stranded RNAs, are considered as a fundamental element in RNA silencing pathways. In Arabidopsis thaliana, RDR1, 2 and 6 play important roles in anti-viral RNA silencing. Expression of RDR1 can be elevated following plant treatment with defense hormones and virus infection. RDR1 has been studied in several crop species, but not in pepper (Capsicum annuum L.). Here, a RDR1 gene was isolated from Capsicum annuum L., designated as CaRDR1. The full-length cDNA of CaRDR1 was 3,351 bp, encoding a 1,116-amino acid protein, which contains conserved regions, such as the most remarkable motif DLDGD. The transcripts of CaRDR1 could be induced by salicylic acid (SA), abscisic acid (ABA), H2O2, and tobacco mosaic virus (TMV). Silencing of CaRDR1 in pepper resulted in increased susceptibility to TMV as evident by severe symptom, increased of TMV-CP transcript, higher malondialdehyde (MDA) content and lower antioxidant enzymes activities compared with that of control plants. CaRDR1-overexpressing in Nicotiana benthamiana showed mild disease symptom and reduced TMV-CP transcripts than that of empty vector (EV) following TMV inoculation. The RNA silencing related genes, including NbAGO2, NbDCL2, NbDCL3, and NbDCL4 elevated expression in overexpressed plants. Alternative oxidase (AOX), the terminal oxidase of the cyanide (CN)-resistant alternative respiratory pathway, catalyze oxygen-dependent oxidation of ubiquinol in plants. It has an important function in plant defense against TMV. In addition, CaRDR1 overexpression promoted the expression of NbAOX1a and NbAOX1b. In conclusion, these results suggest that CaRDR1 plays a positive role in TMV resistance by regulating antioxidant enzymes activities and RNA silencing-related genes expression to suppress the replication and movement of TMV.

  4. The influence of RNA-dependent RNA polymerase 1 on potato virus Y infection and on other antiviral response genes.

    Science.gov (United States)

    Rakhshandehroo, Farshad; Takeshita, Minoru; Squires, Julie; Palukaitis, Peter

    2009-10-01

    The gene encoding RNA-dependent RNA polymerase 1 (RDR1) is involved in basal resistance to several viruses. Expression of the RDR1 gene also is induced in resistance to Tobacco mosaic virus (TMV) mediated by the N gene in tobacco (Nicotiana tabacum cv. Samsun NN) in an incompatible hypersensitive response, as well as in a compatible response against Potato virus Y (PVY). Reducing the accumulation of NtRDR1 transcripts by RNA inhibition mediated by transgenic expression of a double-stranded RNA hairpin corresponding to part of the RDR1 gene resulted in little or no induction of accumulation of RDR1 transcripts after infection by PVY. Plants with lower accumulation of RDR1 transcripts showed much higher accumulation levels of PVY. Reduced accumulation of NtRDR1 transcripts also resulted in lower or no induced expression of three other antiviral, defense-related genes after infection by PVY. These genes encoded a mitochondrial alternative oxidase, an inhibitor of virus replication (IVR), and a transcription factor, ERF5, all involved in resistance to infection by TMV, as well as RDR6, involved in RNA silencing. The extent of the effect on the induced NtIVR and NtERF5 genes correlated with the extent of suppression of the NtRDR1 gene.

  5. Functional Diversification of Maize RNA Polymerase IV and V Subtypes via Alternative Catalytic Subunits

    Directory of Open Access Journals (Sweden)

    Jeremy R. Haag

    2014-10-01

    Full Text Available Unlike nuclear multisubunit RNA polymerases I, II, and III, whose subunit compositions are conserved throughout eukaryotes, plant RNA polymerases IV and V are nonessential, Pol II-related enzymes whose subunit compositions are still evolving. Whereas Arabidopsis Pols IV and V differ from Pol II in four or five of their 12 subunits, respectively, and differ from one another in three subunits, proteomic analyses show that maize Pols IV and V differ from Pol II in six subunits but differ from each other only in their largest subunits. Use of alternative catalytic second subunits, which are nonredundant for development and paramutation, yields at least two subtypes of Pol IV and three subtypes of Pol V in maize. Pol IV/Pol V associations with MOP1, RMR1, AGO121, Zm_DRD1/CHR127, SHH2a, and SHH2b extend parallels between paramutation in maize and the RNA-directed DNA methylation pathway in Arabidopsis.

  6. RNA polymerase supply and flux through the lac operon in Escherichia coli

    Science.gov (United States)

    Sendy, Bandar; Lee, David J.; Bryant, Jack A.

    2016-01-01

    Chromatin immunoprecipitation, followed by quantification of immunoprecipitated DNA, can be used to measure RNA polymerase binding to any DNA segment in Escherichia coli. By calibrating measurements against the signal from a single RNA polymerase bound at a single promoter, we can calculate both promoter occupancy levels and the flux of transcribing RNA polymerase through transcription units. Here, we have applied the methodology to the E. coli lactose operon promoter. We confirm that promoter occupancy is limited by recruitment and that the supply of RNA polymerase to the lactose operon promoter depends on its location in the E. coli chromosome. Measurements of RNA polymerase binding to DNA segments within the lactose operon show that flux of RNA polymerase through the operon is low, with, on average, over 18 s elapsing between the passage of transcribing polymerases. Similar low levels of flux were found when semi-synthetic promoters were used to drive transcript initiation, even when the promoter elements were changed to ensure full occupancy of the promoter by RNA polymerase. This article is part of the themed issue ‘The new bacteriology’. PMID:27672157

  7. Contributions of in vitro transcription to the understanding of human RNA polymerase III transcription.

    Science.gov (United States)

    Dumay-Odelot, Hélène; Durrieu-Gaillard, Stéphanie; El Ayoubi, Leyla; Parrot, Camila; Teichmann, Martin

    2014-01-01

    Human RNA polymerase III transcribes small untranslated RNAs that contribute to the regulation of essential cellular processes, including transcription, RNA processing and translation. Analysis of this transcription system by in vitro transcription techniques has largely contributed to the discovery of its transcription factors and to the understanding of the regulation of human RNA polymerase III transcription. Here we review some of the key steps that led to the identification of transcription factors and to the definition of minimal promoter sequences for human RNA polymerase III transcription.

  8. Splicing of Nascent RNA Coincides with Intron Exit from RNA Polymerase II.

    Science.gov (United States)

    Carrillo Oesterreich, Fernando; Herzel, Lydia; Straube, Korinna; Hujer, Katja; Howard, Jonathon; Neugebauer, Karla M

    2016-04-01

    Protein-coding genes in eukaryotes are transcribed by RNA polymerase II (Pol II) and introns are removed from pre-mRNA by the spliceosome. Understanding the time lag between Pol II progression and splicing could provide mechanistic insights into the regulation of gene expression. Here, we present two single-molecule nascent RNA sequencing methods that directly determine the progress of splicing catalysis as a function of Pol II position. Endogenous genes were analyzed on a global scale in budding yeast. We show that splicing is 50% complete when Pol II is only 45 nt downstream of introns, with the first spliced products observed as introns emerge from Pol II. Perturbations that slow the rate of spliceosome assembly or speed up the rate of transcription caused splicing delays, showing that regulation of both processes determines in vivo splicing profiles. We propose that matched rates streamline the gene expression pathway, while allowing regulation through kinetic competition.

  9. The modeled structure of the RNA dependent RNA polymerase of GBV-C Virus suggests a role for motif E in Flaviviridae RNA polymerases

    Directory of Open Access Journals (Sweden)

    Dutartre Hélène

    2005-10-01

    Full Text Available Abstract Background The Flaviviridae virus family includes major human and animal pathogens. The RNA dependent RNA polymerase (RdRp plays a central role in the replication process, and thus is a validated target for antiviral drugs. Despite the increasing structural and enzymatic characterization of viral RdRps, detailed molecular replication mechanisms remain unclear. The hepatitis C virus (HCV is a major human pathogen difficult to study in cultured cells. The bovine viral diarrhea virus (BVDV is often used as a surrogate model to screen antiviral drugs against HCV. The structure of BVDV RdRp has been recently published. It presents several differences relative to HCV RdRp. These differences raise questions about the relevance of BVDV as a surrogate model, and cast novel interest on the "GB" virus C (GBV-C. Indeed, GBV-C is genetically closer to HCV than BVDV, and can lead to productive infection of cultured cells. There is no structural data for the GBV-C RdRp yet. Results We show in this study that the GBV-C RdRp is closest to the HCV RdRp. We report a 3D model of the GBV-C RdRp, developed using sequence-to-structure threading and comparative modeling based on the atomic coordinates of the HCV RdRp structure. Analysis of the predicted structural features in the phylogenetic context of the RNA polymerase family allows rationalizing most of the experimental data available. Both available structures and our model are explored to examine the catalytic cleft, allosteric and substrate binding sites. Conclusion Computational methods were used to infer evolutionary relationships and to predict the structure of a viral RNA polymerase. Docking a GTP molecule into the structure allows defining a GTP binding pocket in the GBV-C RdRp, such as that of BVDV. The resulting model suggests a new proposition for the mechanism of RNA synthesis, and may prove useful to design new experiments to implement our knowledge on the initiation mechanism of RNA

  10. RNA-directed DNA methylation and demethylation in plants

    Institute of Scientific and Technical Information of China (English)

    CHINNUSAMY; Viswanathan

    2009-01-01

    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 com- plementary siRNAs and the associated RdDM effector complex to the target loci in a transcrip- tion-coupled DNA methylation process. Small RNA binding proteins such as ROS3 may direct tar- get-specific DNA demethylation by the ROS1 family of DNA demethylases. Chromatin remodeling en- zymes 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. Lo- cus-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.

  11. RNA Editing in Plant Mitochondria

    Science.gov (United States)

    Hiesel, Rudolf; Wissinger, Bernd; Schuster, Wolfgang; Brennicke, Axel

    1989-12-01

    Comparative sequence analysis of genomic and complementary DNA clones from several mitochondrial genes in the higher plant Oenothera revealed nucleotide sequence divergences between the genomic and the messenger RNA-derived sequences. These sequence alterations could be most easily explained by specific post-transcriptional nucleotide modifications. Most of the nucleotide exchanges in coding regions lead to altered codons in the mRNA that specify amino acids better conserved in evolution than those encoded by the genomic DNA. Several instances show that the genomic arginine codon CGG is edited in the mRNA to the tryptophan codon TGG in amino acid positions that are highly conserved as tryptophan in the homologous proteins of other species. This editing suggests that the standard genetic code is used in plant mitochondria and resolves the frequent coincidence of CGG codons and tryptophan in different plant species. The apparently frequent and non-species-specific equivalency of CGG and TGG codons in particular suggests that RNA editing is a common feature of all higher plant mitochondria.

  12. Structural Analysis of Monomeric RNA-Dependent Polymerases: Evolutionary and Therapeutic Implications.

    Directory of Open Access Journals (Sweden)

    Rodrigo Jácome

    Full Text Available The crystal structures of monomeric RNA-dependent RNA polymerases and reverse transcriptases of more than 20 different viruses are available in the Protein Data Bank. They all share the characteristic right-hand shape of DNA- and RNA polymerases formed by the fingers, palm and thumb subdomains, and, in many cases, "fingertips" that extend from the fingers towards the thumb subdomain, giving the viral enzyme a closed right-hand appearance. Six conserved structural motifs that contain key residues for the proper functioning of the enzyme have been identified in all these RNA-dependent polymerases. These enzymes share a two divalent metal-ion mechanism of polymerization in which two conserved aspartate residues coordinate the interactions with the metal ions to catalyze the nucleotidyl transfer reaction. The recent availability of crystal structures of polymerases of the Orthomyxoviridae and Bunyaviridae families allowed us to make pairwise comparisons of the tertiary structures of polymerases belonging to the four main RNA viral groups, which has led to a phylogenetic tree in which single-stranded negative RNA viral polymerases have been included for the first time. This has also allowed us to use a homology-based structural prediction approach to develop a general three-dimensional model of the Ebola virus RNA-dependent RNA polymerase. Our model includes several of the conserved structural motifs and residues described in other viral RNA-dependent RNA polymerases that define the catalytic and highly conserved palm subdomain, as well as portions of the fingers and thumb subdomains. The results presented here help to understand the current use and apparent success of antivirals, i.e. Brincidofovir, Lamivudine and Favipiravir, originally aimed at other types of polymerases, to counteract the Ebola virus infection.

  13. Biochemical characterization of a recombinant Japanese encephalitis virus RNA-dependent RNA polymerase

    Directory of Open Access Journals (Sweden)

    Kim Chan-Mi

    2007-07-01

    Full Text Available Abstract Background Japanese encephalitis virus (JEV NS5 is a viral nonstructural protein that carries both methyltransferase and RNA-dependent RNA polymerase (RdRp domains. It is a key component of the viral RNA replicase complex that presumably includes other viral nonstructural and cellular proteins. The biochemical properties of JEV NS5 have not been characterized due to the lack of a robust in vitro RdRp assay system, and the molecular mechanisms for the initiation of RNA synthesis by JEV NS5 remain to be elucidated. Results To characterize the biochemical properties of JEV RdRp, we expressed in Escherichia coli and purified an enzymatically active full-length recombinant JEV NS5 protein with a hexahistidine tag at the N-terminus. The purified NS5 protein, but not the mutant NS5 protein with an Ala substitution at the first Asp of the RdRp-conserved GDD motif, exhibited template- and primer-dependent RNA synthesis activity using a poly(A RNA template. The NS5 protein was able to use both plus- and minus-strand 3'-untranslated regions of the JEV genome as templates in the absence of a primer, with the latter RNA being a better template. Analysis of the RNA synthesis initiation site using the 3'-end 83 nucleotides of the JEV genome as a minimal RNA template revealed that the NS5 protein specifically initiates RNA synthesis from an internal site, U81, at the two nucleotides upstream of the 3'-end of the template. Conclusion As a first step toward the understanding of the molecular mechanisms for JEV RNA replication and ultimately for the in vitro reconstitution of viral RNA replicase complex, we for the first time established an in vitro JEV RdRp assay system with a functional full-length recombinant JEV NS5 protein and characterized the mechanisms of RNA synthesis from nonviral and viral RNA templates. The full-length recombinant JEV NS5 will be useful for the elucidation of the structure-function relationship of this enzyme and for the

  14. Episodic adaptive diversification of classical swine fever virus RNA-dependent RNA polymerase NS5B.

    Science.gov (United States)

    Li, Yan; Yang, Zexiao

    2015-12-01

    Classical swine fever virus (CSFV) is the pathogen that causes a highly infectious disease of pigs and has led to disastrous losses to pig farms and related industries. The RNA-dependent RNA polymerase (RdRp) NS5B is a central component of the replicase complex (RC) in some single-stranded RNA viruses, including CSFV. On the basis of genetic variation, the CSFV RdRps could be clearly divided into 2 major groups and a minor group, which is consistent with the phylogenetic relationships and virulence diversification of the CSFV isolates. However, the adaptive signature underlying such an evolutionary profile of the polymerase and the virus is still an interesting open question. We analyzed the evolutionary trajectory of the CSFV RdRps over different timescales to evaluate the potential adaptation. We found that adaptive selection has driven the diversification of the RdRps between, but not within, CSFV major groups. Further, the major adaptive divergence-related sites are located in the surfaces relevant to the interaction with other component(s) of RC and the entrance and exit of the template-binding channel. These results might shed some light on the nature of the RdRp in virulence diversification of CSFV groups.

  15. Transcription inactivation through local refolding of the RNA polymerase structure

    Energy Technology Data Exchange (ETDEWEB)

    Belogurov, Georgiy A.; Vassylyeva, Marina N.; Sevostyanova, Anastasiya; Appleman, James R.; Xiang, Alan X.; Lira, Ricardo; Webber, Stephen E.; Klyuyev, Sergiy; Nudler, Evgeny; Artsimovitch, Irina; Vassylyev, Dmitry G.; (OSU); (UAB); (Anadys); (NYUSM)

    2009-02-12

    Structural studies of antibiotics not only provide a shortcut to medicine allowing for rational structure-based drug design, but may also capture snapshots of dynamic intermediates that become 'frozen' after inhibitor binding. Myxopyronin inhibits bacterial RNA polymerase (RNAP) by an unknown mechanism. Here we report the structure of dMyx - a desmethyl derivative of myxopyronin B - complexed with a Thermus thermophilus RNAP holoenzyme. The antibiotic binds to a pocket deep inside the RNAP clamp head domain, which interacts with the DNA template in the transcription bubble. Notably, binding of dMyx stabilizes refolding of the {beta}'-subunit switch-2 segment, resulting in a configuration that might indirectly compromise binding to, or directly clash with, the melted template DNA strand. Consistently, footprinting data show that the antibiotic binding does not prevent nucleation of the promoter DNA melting but instead blocks its propagation towards the active site. Myxopyronins are thus, to our knowledge, a first structurally characterized class of antibiotics that target formation of the pre-catalytic transcription initiation complex - the decisive step in gene expression control. Notably, mutations designed in switch-2 mimic the dMyx effects on promoter complexes in the absence of antibiotic. Overall, our results indicate a plausible mechanism of the dMyx action and a stepwise pathway of open complex formation in which core enzyme mediates the final stage of DNA melting near the transcription start site, and that switch-2 might act as a molecular checkpoint for DNA loading in response to regulatory signals or antibiotics. The universally conserved switch-2 may have the same role in all multisubunit RNAPs.

  16. Polyadenylation of RNA transcribed from mammalian SINEs by RNA polymerase III: Complex requirements for nucleotide sequences.

    Science.gov (United States)

    Borodulina, Olga R; Golubchikova, Julia S; Ustyantsev, Ilia G; Kramerov, Dmitri A

    2016-02-01

    It is generally accepted that only transcripts synthesized by RNA polymerase II (e.g., mRNA) were subject to AAUAAA-dependent polyadenylation. However, we previously showed that RNA transcribed by RNA polymerase III (pol III) from mouse B2 SINE could be polyadenylated in an AAUAAA-dependent manner. Many species of mammalian SINEs end with the pol III transcriptional terminator (TTTTT) and contain hexamers AATAAA in their A-rich tail. Such SINEs were united into Class T(+), whereas SINEs lacking the terminator and AATAAA sequences were classified as T(-). Here we studied the structural features of SINE pol III transcripts that are necessary for their polyadenylation. Eight and six SINE families from classes T(+) and T(-), respectively, were analyzed. The replacement of AATAAA with AACAAA in T(+) SINEs abolished the RNA polyadenylation. Interestingly, insertion of the polyadenylation signal (AATAAA) and pol III transcription terminator in T(-) SINEs did not result in polyadenylation. The detailed analysis of three T(+) SINEs (B2, DIP, and VES) revealed areas important for the polyadenylation of their pol III transcripts: the polyadenylation signal and terminator in A-rich tail, β region positioned immediately downstream of the box B of pol III promoter, and τ region located upstream of the tail. In DIP and VES (but not in B2), the τ region is a polypyrimidine motif which is also characteristic of many other T(+) SINEs. Most likely, SINEs of different mammals acquired these structural features independently as a result of parallel evolution. Copyright © 2015 Elsevier B.V. All rights reserved.

  17. Mutational analysis of the promoter recognized by Chlamydia and Escherichia coli sigma(28) RNA polymerase.

    Science.gov (United States)

    Yu, Hilda Hiu Yin; Di Russo, Elizabeth G; Rounds, Megan A; Tan, Ming

    2006-08-01

    sigma(28) RNA polymerase is an alternative RNA polymerase that has been postulated to have a role in developmental gene regulation in Chlamydia. Although a consensus bacterial sigma(28) promoter sequence has been proposed, it is based on a relatively small number of defined promoters, and the promoter structure has not been systematically analyzed. To evaluate the sequence of the sigma(28)-dependent promoter, we performed a comprehensive mutational analysis of the Chlamydia trachomatis hctB promoter, testing the effect of point substitutions on promoter activity. We defined a -35 element recognized by chlamydial sigma(28) RNA polymerase that resembles the consensus -35 sequence. Within the -10 element, however, chlamydial sigma(28) RNA polymerase showed a striking preference for a CGA sequence at positions -12 to -10 rather than the longer consensus -10 sequence. We also observed a strong preference for this CGA sequence by Escherichia coli sigma(28) RNA polymerase, suggesting that this previously unrecognized motif is the critical component of the -10 promoter element recognized by sigma(28) RNA polymerase. Although the consensus spacer length is 11 nucleotides (nt), we found that sigma(28) RNA polymerase from both Chlamydia and E. coli transcribed a promoter with either an 11- or 12-nt spacer equally well. Altogether, we found very similar results for sigma(28) RNA polymerase from C. trachomatis and E. coli, suggesting that promoter recognition by this alternative RNA polymerase is well conserved among bacteria. The preferred sigma(28) promoter that we defined in the context of the hctB promoter is TAAAGwwy-n(11/12)-ryCGAwrn, where w is A or T, r is a purine, y is a pyrimidine, n is any nucleotide, and n(11/12) is a spacer of 11 or 12 nt.

  18. An RNA polymerase II-and AGO4-associated protein acts in RNA-directed DNA methylation

    KAUST Repository

    Gao, Zhihuan

    2010-04-21

    DNA methylation is an important epigenetic mark in many eukaryotes. In plants, 24-nucleotide small interfering RNAs (siRNAs) bound to the effector protein, Argonaute 4 (AGO4), can direct de novo DNA methylation by the methyltransferase DRM2 (refs 2, 4-6). Here we report a new regulator of RNA-directed DNA methylation (RdDM) in Arabidopsis: RDM1. Loss-of-function mutations in the RDM1 gene impair the accumulation of 24-nucleotide siRNAs, reduce DNA methylation, and release transcriptional gene silencing at RdDM target loci. RDM1 encodes a small protein that seems to bind single-stranded methyl DNA, and associates and co-localizes with RNA polymerase II (Pol II, also known as NRPB), AGO4 and DRM2 in the nucleus. Our results indicate that RDM1 is a component of the RdDM effector complex and may have a role in linking siRNA production with pre-existing or de novo cytosine methylation. Our results also indicate that, although RDM1 and Pol V (also known as NRPE) may function together at some RdDM target sites in the peri-nucleolar siRNA processing centre, Pol II rather than Pol V is associated with the RdDM effector complex at target sites in the nucleoplasm. © 2010 Macmillan Publishers Limited. All rights reserved.

  19. RNA-directed DNA methylation and demethylation in plants

    Institute of Scientific and Technical Information of China (English)

    CHINNUSAMY Viswanathan; ZHU Jian-Kang

    2009-01-01

    A-dlrected 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-containlng RlSC (RNA-induced silencing complex) that targets the de novo DNA methyltransferase DRM2 to RdDM target locl. Nascent RNA transcripts from the target loci are generated by another plant-specific RNA polymerase, Pol V, and these transcripts help recruit com-plementary siRNAs and the associated RdDM effector complex to the target loci in a transcrip-tion-coupled DNA methylation process. Small RNA binding proteins such as ROS3 may direct tar-get-specific DNA demethyiation by the ROS1 family of DNA demethylases. Chromatin remodeling en-zymes and histone modifying enzymes also participate in DNA methylation and possibly demethylation.One of the well studied functions of RdOM 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.

  20. RNA polymerase motors on DNA track: effects of traffic congestion on RNA synthesis

    CERN Document Server

    Tripathi, Tripti

    2007-01-01

    RNA polymerase (RNAP) is an enzyme that synthesizes a messenger RNA (mRNA) strand which is complementary to a single-stranded DNA template. From the perspective of physicists, an RNAP is a molecular motor that utilizes chemical energy input to move along the track formed by a ssDNA. In some circumstances, which are described in this paper, a large number of RNAPs move simultaneously along the same track. We refer to such collective movements of the RNAPs as RNAP traffic because of the similarities between the collective dynamics of the RNAPs on ssDNA track and that of vehicles in highway traffic. In this paper we develop a theoretical model for RNAP traffic by incorporating the steric interactions between RNAPs as well as the mechano-chemical cycle of individual RNAPs during the elongation of the mRNA. By a combination of analytical and numerical techniques, we calculate the rates of mRNA synthesis and the average density profile of the RNAPs on the ssDNA track. We also suggest novel experiments for testing o...

  1. A genetic analysis of Plasmodium falciparum RNA polymerase II subunits in yeast.

    Science.gov (United States)

    Hazoume, Adonis; Naderi, Kambiz; Candolfi, Ermanno; Kedinger, Claude; Chatton, Bruno; Vigneron, Marc

    2011-04-01

    RNA polymerase II is an essential nuclear multi subunit enzyme that transcribes nearly the whole genome. Its inhibition by the alpha-amanitin toxin leads to cell death. The enzyme of Plasmodium falciparum remains poorly characterized. Using a complementation assay in yeast as a genetic test, we demonstrate that five Plasmodium putative RNA polymerase subunits are indeed functional in vivo. The active site of this enzyme is built from the two largest subunits. Using site directed mutagenesis we were able to modify the active site of the yeast RNA polymerase II so as to introduce Plasmodium or human structural motifs. The resulting strains allow the screening of chemical libraries for potential specific inhibitors.

  2. In Vitro Assays for RNA Binding and Protein Priming of Hepatitis B Virus Polymerase.

    Science.gov (United States)

    Clark, Daniel N; Jones, Scott A; Hu, Jianming

    2017-01-01

    The hepatitis B virus (HBV) polymerase synthesizes the viral DNA genome from the pre-genomic RNA (pgRNA) template through reverse transcription. Initiation of viral DNA synthesis is accomplished via a novel protein priming mechanism, so named because the polymerase itself acts as a primer, whereby the initiating nucleotide becomes covalently linked to a tyrosine residue on the viral polymerase. Protein priming, in turn, depends on specific recognition of the packaging signal on pgRNA called epsilon. These early events in viral DNA synthesis can now be dissected in vitro as described here.The polymerase is expressed in mammalian cells and purified by immunoprecipitation. The purified protein is associated with host cell factors, is enzymatically active, and its priming activity is epsilon dependent. A minimal epsilon RNA construct from pgRNA is co-expressed with the polymerase in cells. This RNA binds to and co-immunoprecipitates with the polymerase. Modifications can be made to either the epsilon RNA or the polymerase protein by manipulating the expression plasmids. Also, the priming reaction itself can be modified to assay for the initiation or subsequent DNA synthesis during protein priming, the susceptibility of the polymerase to chemical inhibitors, and the precise identification of the DNA products upon their release from the polymerase. The identity of associated host factors can also be evaluated. This protocol closely mirrors our current understanding of the RNA binding and protein priming steps of the HBV replication cycle, and it is amenable to modification. It should therefore facilitate both basic research and drug discovery.

  3. RNA Polymerase III Output Is Functionally Linked to tRNA Dimethyl-G26 Modification.

    Directory of Open Access Journals (Sweden)

    Aneeshkumar G Arimbasseri

    2015-12-01

    Full Text Available Control of the differential abundance or activity of tRNAs can be important determinants of gene regulation. RNA polymerase (RNAP III synthesizes all tRNAs in eukaryotes and it derepression is associated with cancer. Maf1 is a conserved general repressor of RNAP III under the control of the target of rapamycin (TOR that acts to integrate transcriptional output and protein synthetic demand toward metabolic economy. Studies in budding yeast have indicated that the global tRNA gene activation that occurs with derepression of RNAP III via maf1-deletion is accompanied by a paradoxical loss of tRNA-mediated nonsense suppressor activity, manifested as an antisuppression phenotype, by an unknown mechanism. We show that maf1-antisuppression also occurs in the fission yeast S. pombe amidst general activation of RNAP III. We used tRNA-HydroSeq to document that little changes occurred in the relative levels of different tRNAs in maf1Δ cells. By contrast, the efficiency of N2,N2-dimethyl G26 (m(22G26 modification on certain tRNAs was decreased in response to maf1-deletion and associated with antisuppression, and was validated by other methods. Over-expression of Trm1, which produces m(22G26, reversed maf1-antisuppression. A model that emerges is that competition by increased tRNA levels in maf1Δ cells leads to m(22G26 hypomodification due to limiting Trm1, reducing the activity of suppressor-tRNASerUCA and accounting for antisuppression. Consistent with this, we show that RNAP III mutations associated with hypomyelinating leukodystrophy decrease tRNA transcription, increase m(22G26 efficiency and reverse antisuppression. Extending this more broadly, we show that a decrease in tRNA synthesis by treatment with rapamycin leads to increased m(22G26 modification and that this response is conserved among highly divergent yeasts and human cells.

  4. Looking for inhibitors of the dengue virus NS5 RNA-dependent RNA-polymerase using a molecular docking approach

    Science.gov (United States)

    Galiano, Vicente; Garcia-Valtanen, Pablo; Micol, Vicente; Encinar, José Antonio

    2016-01-01

    The dengue virus (DENV) nonstructural protein 5 (NS5) contains both an N-terminal methyltransferase domain and a C-terminal RNA-dependent RNA polymerase domain. Polymerase activity is responsible for viral RNA synthesis by a de novo initiation mechanism and represents an attractive target for antiviral therapy. The incidence of DENV has grown rapidly and it is now estimated that half of the human population is at risk of becoming infected with this virus. Despite this, there are no effective drugs to treat DENV infections. The present in silico study aimed at finding new inhibitors of the NS5 RNA-dependent RNA polymerase of the four serotypes of DENV. We used a chemical library comprising 372,792 nonnucleotide compounds (around 325,319 natural compounds) to perform molecular docking experiments against a binding site of the RNA template tunnel of the virus polymerase. Compounds with high negative free energy variation (ΔG <−10.5 kcal/mol) were selected as putative inhibitors. Additional filters for favorable druggability and good absorption, distribution, metabolism, excretion, and toxicity were applied. Finally, after the screening process was completed, we identified 39 compounds as lead DENV polymerase inhibitor candidates. Potentially, these compounds could act as efficient DENV polymerase inhibitors in vitro and in vivo.

  5. Identification of distinct biological functions for four 3'-5' RNA polymerases.

    Science.gov (United States)

    Long, Yicheng; Abad, Maria G; Olson, Erik D; Carrillo, Elisabeth Y; Jackman, Jane E

    2016-09-30

    The superfamily of 3'-5' polymerases synthesize RNA in the opposite direction to all other DNA/RNA polymerases, and its members include eukaryotic tRNA(His) guanylyltransferase (Thg1), as well as Thg1-like proteins (TLPs) of unknown function that are broadly distributed, with family members in all three domains of life. Dictyostelium discoideum encodes one Thg1 and three TLPs (DdiTLP2, DdiTLP3 and DdiTLP4). Here, we demonstrate that depletion of each of the genes results in a significant growth defect, and that each protein catalyzes a unique biological reaction, taking advantage of specialized biochemical properties. DdiTLP2 catalyzes a mitochondria-specific tRNA(His) maturation reaction, which is distinct from the tRNA(His) maturation reaction typically catalyzed by Thg1 enzymes on cytosolic tRNA. DdiTLP3 catalyzes tRNA repair during mitochondrial tRNA 5'-editing in vivo and in vitro, establishing template-dependent 3'-5' polymerase activity of TLPs as a bona fide biological activity for the first time since its unexpected discovery more than a decade ago. DdiTLP4 is cytosolic and, surprisingly, catalyzes robust 3'-5' polymerase activity on non-tRNA substrates, strongly implying further roles for TLP 3'-5' polymerases in eukaryotes.

  6. Foot-and-mouth disease virus-induced RNA polymerase is associated with Golgi apparatus.

    OpenAIRE

    Polatnick, J; Wool, S H

    1985-01-01

    Electrophoretic analysis of the Golgi apparatus isolated by differential centrifugation from radiolabeled cells infected with foot-and-mouth disease virus showed about 10 protein bands. The virus-induced RNA polymerase was identified by immunoprecipitation and electron microscope staining procedures. Pulse-chase experiments indicated that the polymerase passed through the Golgi apparatus in less than 1 h.

  7. Multiple isoelectric forms of poliovirus RNA-dependent RNA polymerase: Evidence for phosphorylation

    Energy Technology Data Exchange (ETDEWEB)

    Ransone, L.J.; Dasgupta, A. (Univ. of California, Los Angeles (USA))

    1989-11-01

    Poliovirus-specific RNA-dependent RNA polymerase (3Dpol) was purified to apparent homogeneity. A single polypeptide of an apparent molecular weight of 63,000 catalyzes the synthesis of dimeric and monomeric RNA products in response to the poliovirion RNA template. Analysis of purified 3Dpol by two-dimensional electrophoresis showed multiple forms of 3Dpol, suggesting posttranslational modification of the protein in virus-infected cells. The two major forms of 3Dpol appear to have approximate pI values of 7.1 and 7.4. Incubation of purified 3Dpol with calf intestinal phosphatase resulted in almost complete disappearance of the pI 7.1 form and a concomitant increase in the intensity of the pI 7.4 form of 3Dpol. Addition of 32P-labeled Pi during infection of HeLa cells with poliovirus resulted in specific labeling of 3Dpol and 3CD, a viral protein which contains the entire 3Dpol sequence. Both 3Dpol and 3CD appear to be phosphorylated at serine residues. Ribosomal salt washes prepared from both mock- and poliovirus-infected cells contain phosphatases capable of dephosphorylating quantitatively the phosphorylated form (pI 7.1) of 3Dpol.

  8. Inositol pyrophosphates regulate RNA polymerase I-mediated rRNA transcription in Saccharomyces cerevisiae.

    Science.gov (United States)

    Thota, Swarna Gowri; Unnikannan, C P; Thampatty, Sitalakshmi R; Manorama, R; Bhandari, Rashna

    2015-02-15

    Ribosome biogenesis is an essential cellular process regulated by the metabolic state of a cell. We examined whether inositol pyrophosphates, energy-rich derivatives of inositol that act as metabolic messengers, play a role in ribosome synthesis in the budding yeast, Saccharomyces cerevisiae. Yeast strains lacking the inositol hexakisphosphate (IP6) kinase Kcs1, which is required for the synthesis of inositol pyrophosphates, display increased sensitivity to translation inhibitors and decreased protein synthesis. These phenotypes are reversed on expression of enzymatically active Kcs1, but not on expression of the inactive form. The kcs1Δ yeast cells exhibit reduced levels of ribosome subunits, suggesting that they are defective in ribosome biogenesis. The rate of rRNA synthesis, the first step of ribosome biogenesis, is decreased in kcs1Δ yeast strains, suggesting that RNA polymerase I (Pol I) activity may be reduced in these cells. We determined that the Pol I subunits, A190, A43 and A34.5, can accept a β-phosphate moiety from inositol pyrophosphates to undergo serine pyrophosphorylation. Although there is impaired rRNA synthesis in kcs1Δ yeast cells, we did not find any defect in recruitment of Pol I on rDNA, but observed that the rate of transcription elongation was compromised. Taken together, our findings highlight inositol pyrophosphates as novel regulators of rRNA transcription.

  9. Structural basis of transcription: nucleotide selection by rotation in the RNA polymerase II active center.

    Science.gov (United States)

    Westover, Kenneth D; Bushnell, David A; Kornberg, Roger D

    2004-11-12

    Binding of a ribonucleoside triphosphate to an RNA polymerase II transcribing complex, with base pairing to the template DNA, was revealed by X-ray crystallography. Binding of a mismatched nucleoside triphosphate was also detected, but in an adjacent site, inverted with respect to the correctly paired nucleotide. The results are consistent with a two-step mechanism of nucleotide selection, with initial binding to an entry (E) site beneath the active center in an inverted orientation, followed by rotation into the nucleotide addition (A) site for pairing with the template DNA. This mechanism is unrelated to that of single subunit RNA polymerases and so defines a new paradigm for the large, multisubunit enzymes. Additional findings from these studies include a third nucleotide binding site that may define the length of backtracked RNA; DNA double helix unwinding in advance of the polymerase active center; and extension of the diffraction limit of RNA polymerase II crystals to 2.3 A.

  10. Mammalian RNA polymerase II core promoters: insights from genome-wide studies

    DEFF Research Database (Denmark)

    Sandelin, Albin; Carninci, Piero; Lenhard, Boris

    2007-01-01

    The identification and characterization of mammalian core promoters and transcription start sites is a prerequisite to understanding how RNA polymerase II transcription is controlled. New experimental technologies have enabled genome-wide discovery and characterization of core promoters, revealin...

  11. Sequence and analysis of the gene for bacteriophage T3 RNA polymerase.

    Science.gov (United States)

    McGraw, N J; Bailey, J N; Cleaves, G R; Dembinski, D R; Gocke, C R; Joliffe, L K; MacWright, R S; McAllister, W T

    1985-01-01

    The RNA polymerases encoded by bacteriophages T3 and T7 have similar structures, but exhibit nearly exclusive template specificities. We have determined the nucleotide sequence of the region of T3 DNA that encodes the T3 RNA polymerase (the gene 1.0 region), and have compared this sequence with the corresponding region of T7 DNA. The predicted amino acid sequence of the T3 RNA polymerase exhibits very few changes when compared to the T7 enzyme (82% of the residues are identical). Significant differences appear to cluster in three distinct regions in the amino-terminal half of the protein. Analysis of the data from both enzymes suggests features that may be important for polymerase function. In particular, a region that differs between the T3 and T7 enzymes exhibits significant homology to the bi-helical domain that is common to many sequence-specific DNA binding proteins. The region that flanks the structural gene contains a number of regulatory elements including: a promoter for the E. coli RNA polymerase, a potential processing site for RNase III and a promoter for the T3 polymerase. The promoter for the T3 RNA polymerase is located only 12 base pairs distal to the stop codon for the structural gene. PMID:3903658

  12. Efficient Interaction between Arenavirus Nucleoprotein (NP) and RNA-Dependent RNA Polymerase (L) Is Mediated by the Virus Nucleocapsid (NP-RNA) Template.

    Science.gov (United States)

    Iwasaki, Masaharu; Ngo, Nhi; Cubitt, Beatrice; de la Torre, Juan C

    2015-05-01

    In this study, we document that efficient interaction between arenavirus nucleoprotein (NP) and RNA-dependent RNA polymerase (L protein), the two trans-acting viral factors required for both virus RNA replication and gene transcription, requires the presence of virus-specific RNA sequences located within the untranslated 5' and 3' termini of the viral genome.

  13. Modus operandi of the bacterial RNA polymerase containing the sigma54 promoter-specificity factor.

    Science.gov (United States)

    Wigneshweraraj, Sivaramesh; Bose, Daniel; Burrows, Patricia C; Joly, Nicolas; Schumacher, Jörg; Rappas, Mathieu; Pape, Tillmann; Zhang, Xiaodong; Stockley, Peter; Severinov, Konstantin; Buck, Martin

    2008-05-01

    Bacterial sigma (sigma) factors confer gene specificity upon the RNA polymerase, the central enzyme that catalyses gene transcription. The binding of the alternative sigma factor sigma(54) confers upon the RNA polymerase special functional and regulatory properties, making it suited for control of several major adaptive responses. Here, we summarize our current understanding of the interactions the sigma(54) factor makes with the bacterial transcription machinery.

  14. Structures of coxsackievirus, rhinovirus, and poliovirus polymerase elongation complexes solved by engineering RNA mediated crystal contacts.

    Science.gov (United States)

    Gong, Peng; Kortus, Matthew G; Nix, Jay C; Davis, Ralph E; Peersen, Olve B

    2013-01-01

    RNA-dependent RNA polymerases play a vital role in the growth of RNA viruses where they are responsible for genome replication, but do so with rather low fidelity that allows for the rapid adaptation to different host cell environments. These polymerases are also a target for antiviral drug development. However, both drug discovery efforts and our understanding of fidelity determinants have been hampered by a lack of detailed structural information about functional polymerase-RNA complexes and the structural changes that take place during the elongation cycle. Many of the molecular details associated with nucleotide selection and catalysis were revealed in our recent structure of the poliovirus polymerase-RNA complex solved by first purifying and then crystallizing stalled elongation complexes. In the work presented here we extend that basic methodology to determine nine new structures of poliovirus, coxsackievirus, and rhinovirus elongation complexes at 2.2-2.9 Å resolution. The structures highlight conserved features of picornaviral polymerases and the interactions they make with the template and product RNA strands, including a tight grip on eight basepairs of the nascent duplex, a fully pre-positioned templating nucleotide, and a conserved binding pocket for the +2 position template strand base. At the active site we see a pre-bound magnesium ion and there is conservation of a non-standard backbone conformation of the template strand in an interaction that may aid in triggering RNA translocation via contact with the conserved polymerase motif B. Moreover, by engineering plasticity into RNA-RNA contacts, we obtain crystal forms that are capable of multiple rounds of in-crystal catalysis and RNA translocation. Together, the data demonstrate that engineering flexible RNA contacts to promote crystal lattice formation is a versatile platform that can be used to solve the structures of viral RdRP elongation complexes and their catalytic cycle intermediates.

  15. Structures of coxsackievirus, rhinovirus, and poliovirus polymerase elongation complexes solved by engineering RNA mediated crystal contacts.

    Directory of Open Access Journals (Sweden)

    Peng Gong

    Full Text Available RNA-dependent RNA polymerases play a vital role in the growth of RNA viruses where they are responsible for genome replication, but do so with rather low fidelity that allows for the rapid adaptation to different host cell environments. These polymerases are also a target for antiviral drug development. However, both drug discovery efforts and our understanding of fidelity determinants have been hampered by a lack of detailed structural information about functional polymerase-RNA complexes and the structural changes that take place during the elongation cycle. Many of the molecular details associated with nucleotide selection and catalysis were revealed in our recent structure of the poliovirus polymerase-RNA complex solved by first purifying and then crystallizing stalled elongation complexes. In the work presented here we extend that basic methodology to determine nine new structures of poliovirus, coxsackievirus, and rhinovirus elongation complexes at 2.2-2.9 Å resolution. The structures highlight conserved features of picornaviral polymerases and the interactions they make with the template and product RNA strands, including a tight grip on eight basepairs of the nascent duplex, a fully pre-positioned templating nucleotide, and a conserved binding pocket for the +2 position template strand base. At the active site we see a pre-bound magnesium ion and there is conservation of a non-standard backbone conformation of the template strand in an interaction that may aid in triggering RNA translocation via contact with the conserved polymerase motif B. Moreover, by engineering plasticity into RNA-RNA contacts, we obtain crystal forms that are capable of multiple rounds of in-crystal catalysis and RNA translocation. Together, the data demonstrate that engineering flexible RNA contacts to promote crystal lattice formation is a versatile platform that can be used to solve the structures of viral RdRP elongation complexes and their catalytic cycle

  16. Genetic Transformation of Citrus Paradisi with Antisense and untranslatable RNA-dependent RNA Polymerase Genes of Citrus Tristeza Closterovirus

    Science.gov (United States)

    Expression of the RNA-dependent RNA polymerase (RdRp) of Citrus tristeza virus (CTV) was studied in vivo and in vitro using a polyclonal antiserum raised against the recombinant CTV-RdRp protein. Although 56 kDa CTV-RdRp is thought to be expressed by a +1 translational frameshift at the carboxyl te...

  17. Basic Mechanisms in RNA Polymerase I Transcription of the Ribosomal RNA Genes

    Science.gov (United States)

    Goodfellow, Sarah J.; Zomerdijk, Joost C. B. M.

    2013-01-01

    RNA Polymerase (Pol) I produces ribosomal (r)RNA, an essential component of the cellular protein synthetic machinery that drives cell growth, underlying many fundamental cellular processes. Extensive research into the mechanisms governing transcription by Pol I has revealed an intricate set of control mechanisms impinging upon rRNA production. Pol I-specific transcription factors guide Pol I to the rDNA promoter and contribute to multiple rounds of transcription initiation, promoter escape, elongation and termination. In addition, many accessory factors are now known to assist at each stage of this transcription cycle, some of which allow the integration of transcriptional activity with metabolic demands. The organisation and accessibility of rDNA chromatin also impinge upon Pol I output, and complex mechanisms ensure the appropriate maintenance of the epigenetic state of the nucleolar genome and its effective transcription by Pol I. The following review presents our current understanding of the components of the Pol I transcription machinery, their functions and regulation by associated factors, and the mechanisms operating to ensure the proper transcription of rDNA chromatin. The importance of such stringent control is demonstrated by the fact that deregulated Pol I transcription is a feature of cancer and other disorders characterised by abnormal translational capacity. PMID:23150253

  18. RNA polymerase II/TFIIF structure and conserved organization of the initiation complex.

    Science.gov (United States)

    Chung, Wen-Hsiang; Craighead, John L; Chang, Wei-Hau; Ezeokonkwo, Chukwudi; Bareket-Samish, Avital; Kornberg, Roger D; Asturias, Francisco J

    2003-10-01

    The structure of an RNA polymerase II/general transcription factor TFIIF complex was determined by cryo-electron microscopy and single particle analysis. Density due to TFIIF was not concentrated in one area but rather was widely distributed across the surface of the polymerase. The largest subunit of TFIIF interacted with the dissociable Rpb4/Rpb7 polymerase subunit complex and with the mobile "clamp." The distribution of the second largest subunit of TFIIF was very similar to that previously reported for the sigma subunit in the bacterial RNA polymerase holoenzyme, consisting of a series of globular domains extending along the polymerase active site cleft. This result indicates that the second TFIIF subunit is a true structural homolog of the bacterial sigma factor and reveals an important similarity of the transcription initiation mechanism between bacteria and eukaryotes. The structure of the RNAPII/TFIIF complex suggests a model for the organization of a minimal transcription initiation complex.

  19. Structure-function studies of the influenza virus RNA polymerase PA subunit

    Institute of Scientific and Technical Information of China (English)

    Mark; BARTLAM

    2009-01-01

    The influenza virus RNA-dependent RNA polymerase is a heterotrimeric complex (PA, PB1 and PB2) with multiple enzymatic activities for catalyzing viral RNA transcription and replication. The roles of PB1 and PB2 have been clearly defined, but PA is less well understood. The critical role of the polymerase complex in the influenza virus life cycle and high sequence conservation suggest it should be a major target for therapeutic intervention. However, until very recently, functional studies and drug discovery targeting the influenza polymerase have been hampered by the lack of three-dimensional structural information. We will review the recent progress in the structure and function of the PA subunit of influenza polymerase, and discuss prospects for the development of anti-influenza therapeutics based on available structures.

  20. Structure-function studies of the influenza virus RNA polymerase PA subunit

    Institute of Scientific and Technical Information of China (English)

    LIU YingFang; LOU ZhiYong; Mark BARTLAM; RAO ZiHe

    2009-01-01

    The influenza virus RNA-dependent RNA polymerase is a heterotrimeric complex (PA, PB1 and PB2) with multiple enzymatic activities for catalyzing viral RNA transcription and replication. The roles of PB1 and PB2 have been clearly defined, but PA is less well understood. The critical role of the poly-merase complex in the influenza virus life cycle and high sequence conservation suggest it should be a major target for therapeutic intervention. However, until very recently, functional studies and drug discovery targeting the influenza polymerase have been hampered by the lack of three-dimensional structural information. We will review the recent progress in the structure and function of the PA sub-unit of influenza polymerase, and discuss prospects for the development of anti-influenza therapeutics based on available structures.

  1. Definition of the minimal viral components required for the initiation of unprimed RNA synthesis by influenza virus RNA polymerase.

    Science.gov (United States)

    Lee, M T Michael; Bishop, Konrad; Medcalf, Liz; Elton, Debra; Digard, Paul; Tiley, Laurence

    2002-01-15

    The first 11 nt at the 5' end of influenza virus genomic RNA were shown to be both necessary and sufficient for specific binding by the influenza virus polymerase. A novel in vitro transcription assay, in which the polymerase was bound to paramagnetic beads via a biotinylated 5'-vRNA oligonucleotide, was used to study the activities of different forms of the polymerase. Complexes composed of co-expressed PB1/PB2/PA proteins and a sub-complex composed of PB1/PA bound to the 5'-vRNA oligonucleotide, whereas PB1 expressed alone did not. The enriched 5'-vRNA/PB1/PB2/PA complex was highly active for ApG and globin mRNA primed transcription on a model 3'-vRNA template. RNA synthesis in the absence of added primers produced products with 5'-terminal tri- or diphosphate groups, indicating that genuine unprimed initiation of transcription also occurred. No transcriptase activity was detected for the PB1/PA complex. These results demonstrate a role for PA in the enhancement of 5' end binding activity of PB1, a role for PB2 in the assembly of a polymerase complex able to perform both cap-dependent and -independent synthesis and that NP is not required for the initiation of replicative transcription.

  2. Identification, molecular cloning and expression analysis of five RNA-dependent RNA polymerase genes in Salvia miltiorrhiza.

    Science.gov (United States)

    Shao, Fenjuan; Lu, Shanfa

    2014-01-01

    RNA-dependent RNA polymerases (RDRs) act as key components of the small RNA biogenesis pathways and play significant roles in post-transcriptional gene silencing (PTGS) and antiviral defense. However, there is no information about the RDR gene family in Salvia miltiorrhiza, an emerging model medicinal plant with great economic value. Through genome-wide predication and subsequent molecular cloning, five full-length S. miltiorrhiza RDR genes, termed SmRDR1-SmRDR5, were identified. The length of SmRDR cDNAs varies between 3,262 (SmRDR5) and 4,130 bp (SmRDR3). The intron number of SmRDR genes varies from 3 (SmRDR1, SmRDR3 and SmRDR4) to 17 (SmRDR5). All of the deduced SmRDR protein sequences contain the conserved RdRp domain. Moreover, SmRDR2 and SmRDR4 have an additional RRM domain. Based on the phylogenetic tree constructed with sixteen RDRs from Arabidopsis, rice and S. miltiorrhiza, plant RDRs may be divided into four groups (RDR1-RDR4). The RDR1 group contains an AtRDR and an OsRDR, while includes two SmRDRs. On the contrary, the RDR3 group contains three AtRDRs and two OsRDRs, but has only one SmRDR. SmRDRs were differentially expressed in flowers, leaves, stems and roots of S. miltiorrhiza and responsive to methyl jasmonate treatment and cucumber mosaic virus infection. The results suggest the involvement of RDRs in S. miltiorrhiza development and response to abiotic and biotic stresses. It provides a foundation for further studying the regulation and biological functions of SmRDRs and the biogenesis pathways of small RNAs in S. miltiorrhiza.

  3. Identification, molecular cloning and expression analysis of five RNA-dependent RNA polymerase genes in Salvia miltiorrhiza.

    Directory of Open Access Journals (Sweden)

    Fenjuan Shao

    Full Text Available RNA-dependent RNA polymerases (RDRs act as key components of the small RNA biogenesis pathways and play significant roles in post-transcriptional gene silencing (PTGS and antiviral defense. However, there is no information about the RDR gene family in Salvia miltiorrhiza, an emerging model medicinal plant with great economic value. Through genome-wide predication and subsequent molecular cloning, five full-length S. miltiorrhiza RDR genes, termed SmRDR1-SmRDR5, were identified. The length of SmRDR cDNAs varies between 3,262 (SmRDR5 and 4,130 bp (SmRDR3. The intron number of SmRDR genes varies from 3 (SmRDR1, SmRDR3 and SmRDR4 to 17 (SmRDR5. All of the deduced SmRDR protein sequences contain the conserved RdRp domain. Moreover, SmRDR2 and SmRDR4 have an additional RRM domain. Based on the phylogenetic tree constructed with sixteen RDRs from Arabidopsis, rice and S. miltiorrhiza, plant RDRs may be divided into four groups (RDR1-RDR4. The RDR1 group contains an AtRDR and an OsRDR, while includes two SmRDRs. On the contrary, the RDR3 group contains three AtRDRs and two OsRDRs, but has only one SmRDR. SmRDRs were differentially expressed in flowers, leaves, stems and roots of S. miltiorrhiza and responsive to methyl jasmonate treatment and cucumber mosaic virus infection. The results suggest the involvement of RDRs in S. miltiorrhiza development and response to abiotic and biotic stresses. It provides a foundation for further studying the regulation and biological functions of SmRDRs and the biogenesis pathways of small RNAs in S. miltiorrhiza.

  4. Uncovering layers of human RNA polymerase II transcription

    DEFF Research Database (Denmark)

    Jensen, Torben Heick

    In recent years DNA microarray and high-throughput sequencing technologies have challenged the “gene-centric” view that pre-mRNA is the only RNA species transcribed off protein-coding genes. Instead unorthodox transcription from within genic- and intergenic regions has been demonstrated to occur...

  5. dsRNA interference on expression of a RNA-dependent RNA polymerase gene of Bombyx mori cytoplasmic polyhedrosis virus.

    Science.gov (United States)

    Pan, Zhong-Hua; Gao, Kun; Hou, Cheng-Xiang; Wu, Ping; Qin, Guang-Xing; Geng, Tao; Guo, Xi-Jie

    2015-07-01

    Bombyx mori cytoplasmic polyhedrosis virus (BmCPV) is one of the major viral pathogens in silkworm. Its infection often results in significant losses to sericulture. Studies have demonstrated that RNAi is one of the important anti-viral mechanisms in organisms. In this study, three dsRNAs targeting the RNA-dependent RNA polymerase (RDRP) gene of BmCPV were designed and synthesized with 2'-F modification to explore their interference effects on BmCPV replication in silkworm larvae. The results showed that injecting dsRNA in the dosage of 4-6 ng per mg body weight into the 5th instar larvae can interfere with the BmCPV-RDRP expression by 93% after virus infection and by 99.9% before virus infection. In addition, the expression of two viral structural protein genes (genome RNA segments 1 and 5) was also decreased with the decrease of RDRP expression, suggesting that RNAi interference of BmCPV-RDRP expression could affect viral replication. The study provides an effective method for investigating virus replication as well as the virus-host interactions in the silkworm larvae using dsRNA.

  6. RNA silencing movement in plants

    Institute of Scientific and Technical Information of China (English)

    Glykeria Mermigka; Frederic Verret; Kriton Kalantidis

    2016-01-01

    Multicellular organisms, like higher plants, need to coordinate their growth and development and to cope with environmental cues. To achieve this, various signal molecules are transported between neighboring cells and distant organs to control the fate of the recipient cells and organs. RNA silencing produces cell non-autonomous signal molecules that can move over short or long distances leading to the sequence specific silencing of a target gene in a well defined area of cells or throughout the entire plant, respectively. The nature of these signal molecules, the route of silencing spread, and the genes involved in their production, movement and reception are discussed in this review. Additionally, a short section on features of silencing spread in animal models is presented at the end of this review.

  7. Increased levels of rat liver RNA polymerase I(A) and I(B) following the administration of triiodothyronine.

    Science.gov (United States)

    Zoncheddu, A; Accomando, R; Pertica, M; Carlini, A; Orunesu, M

    1981-06-15

    The levels of the transcribing RNA polymerase I(B) in the nucleus and of the non-transcribing RNA polymerase I(A) in the cytoplasm are both approximately doubled 24 h after a single i.p. injection of triiodothyronine into thyroidectomized rats. This suggests that the triiodothyronine-induced stimulation of ribosomal RNA synthesis is associated with an increase in the total RNA polymerase I content of rat liver cells.

  8. New insights into the promoterless transcription of DNA coligo templates by RNA polymerase III.

    Science.gov (United States)

    Lama, Lodoe; Seidl, Christine I; Ryan, Kevin

    2014-01-01

    Chemically synthesized DNA can carry small RNA sequence information but converting that information into small RNA is generally thought to require large double-stranded promoters in the context of plasmids, viruses and genes. We previously found evidence that circularized oligodeoxynucleotides (coligos) containing certain sequences and secondary structures can template the synthesis of small RNA by RNA polymerase III in vitro and in human cells. By using immunoprecipitated RNA polymerase III we now report corroborating evidence that this enzyme is the sole polymerase responsible for coligo transcription. The immobilized polymerase enabled experiments showing that coligo transcripts can be formed through transcription termination without subsequent 3' end trimming. To better define the determinants of productive transcription, a structure-activity relationship study was performed using over 20 new coligos. The results show that unpaired nucleotides in the coligo stem facilitate circumtranscription, but also that internal loops and bulges should be kept small to avoid secondary transcription initiation sites. A polymerase termination sequence embedded in the double-stranded region of a hairpin-encoding coligo stem can antagonize transcription. Using lessons learned from new and old coligos, we demonstrate how to convert poorly transcribed coligos into productive templates. Our findings support the possibility that coligos may prove useful as chemically synthesized vectors for the ectopic expression of small RNA in human cells.

  9. Identification of distinct biological functions for four 3′-5′ RNA polymerases

    Science.gov (United States)

    Long, Yicheng; Abad, Maria G.; Olson, Erik D.; Carrillo, Elisabeth Y.; Jackman, Jane E.

    2016-01-01

    The superfamily of 3′-5′ polymerases synthesize RNA in the opposite direction to all other DNA/RNA polymerases, and its members include eukaryotic tRNAHis guanylyltransferase (Thg1), as well as Thg1-like proteins (TLPs) of unknown function that are broadly distributed, with family members in all three domains of life. Dictyostelium discoideum encodes one Thg1 and three TLPs (DdiTLP2, DdiTLP3 and DdiTLP4). Here, we demonstrate that depletion of each of the genes results in a significant growth defect, and that each protein catalyzes a unique biological reaction, taking advantage of specialized biochemical properties. DdiTLP2 catalyzes a mitochondria-specific tRNAHis maturation reaction, which is distinct from the tRNAHis maturation reaction typically catalyzed by Thg1 enzymes on cytosolic tRNA. DdiTLP3 catalyzes tRNA repair during mitochondrial tRNA 5′-editing in vivo and in vitro, establishing template-dependent 3′-5′ polymerase activity of TLPs as a bona fide biological activity for the first time since its unexpected discovery more than a decade ago. DdiTLP4 is cytosolic and, surprisingly, catalyzes robust 3′-5′ polymerase activity on non-tRNA substrates, strongly implying further roles for TLP 3′-5′ polymerases in eukaryotes. PMID:27484477

  10. Structural basis of transcription: mismatch-specific fidelity mechanisms and paused RNA polymerase II with frayed RNA.

    Science.gov (United States)

    Sydow, Jasmin F; Brueckner, Florian; Cheung, Alan C M; Damsma, Gerke E; Dengl, Stefan; Lehmann, Elisabeth; Vassylyev, Dmitry; Cramer, Patrick

    2009-06-26

    We show that RNA polymerase (Pol) II prevents erroneous transcription in vitro with different strategies that depend on the type of DNARNA base mismatch. Certain mismatches are efficiently formed but impair RNA extension. Other mismatches allow for RNA extension but are inefficiently formed and efficiently proofread by RNA cleavage. X-ray analysis reveals that a TU mismatch impairs RNA extension by forming a wobble base pair at the Pol II active center that dissociates the catalytic metal ion and misaligns the RNA 3' end. The mismatch can also stabilize a paused state of Pol II with a frayed RNA 3' nucleotide. The frayed nucleotide binds in the Pol II pore either parallel or perpendicular to the DNA-RNA hybrid axis (fraying sites I and II, respectively) and overlaps the nucleoside triphosphate (NTP) site, explaining how it halts transcription during proofreading, before backtracking and RNA cleavage.

  11. Crystal Structure of the Catalytic Core of an RNA-Polymerase Ribozyme

    Energy Technology Data Exchange (ETDEWEB)

    Shechner, David M.; Grant, Robert A.; Bagby, Sarah C.; Koldobskaya, Yelena; Piccirilli, Joseph A.; Bartel, David P.; (MIT); (HHMI); (UC)

    2010-09-02

    Primordial organisms of the putative RNA world would have required polymerase ribozymes able to replicate RNA. Known ribozymes with polymerase activity best approximating that needed for RNA replication contain at their catalytic core the class I RNA ligase, an artificial ribozyme with a catalytic rate among the fastest of known ribozymes. Here we present the 3.0 angstrom crystal structure of this ligase. The architecture resembles a tripod, its three legs converging near the ligation junction. Interacting with this tripod scaffold through a series of 10 minor-groove interactions (including two A-minor triads) is the unpaired segment that contributes to and organizes the active site. A cytosine nucleobase and two backbone phosphates abut the ligation junction; their location suggests a model for catalysis resembling that of proteinaceous polymerases.

  12. RNA silencing and plant viral diseases.

    Science.gov (United States)

    Wang, Ming-Bo; Masuta, Chikara; Smith, Neil A; Shimura, Hanako

    2012-10-01

    RNA silencing plays a critical role in plant resistance against viruses, with multiple silencing factors participating in antiviral defense. Both RNA and DNA viruses are targeted by the small RNA-directed RNA degradation pathway, with DNA viruses being also targeted by RNA-directed DNA methylation. To evade RNA silencing, plant viruses have evolved a variety of counter-defense mechanisms such as expressing RNA-silencing suppressors or adopting silencing-resistant RNA structures. This constant defense-counter defense arms race is likely to have played a major role in defining viral host specificity and in shaping viral and possibly host genomes. Recent studies have provided evidence that RNA silencing also plays a direct role in viral disease induction in plants, with viral RNA-silencing suppressors and viral siRNAs as potentially the dominant players in viral pathogenicity. However, questions remain as to whether RNA silencing is the principal mediator of viral pathogenicity or if other RNA-silencing-independent mechanisms also account for viral disease induction. RNA silencing has been exploited as a powerful tool for engineering virus resistance in plants as well as in animals. Further understanding of the role of RNA silencing in plant-virus interactions and viral symptom induction is likely to result in novel anti-viral strategies in both plants and animals.

  13. Crystal structure of complete rhinovirus RNA polymerase suggests front loading of protein primer.

    Science.gov (United States)

    Appleby, Todd C; Luecke, Hartmut; Shim, Jae Hoon; Wu, Jim Z; Cheney, I Wayne; Zhong, Weidong; Vogeley, Lutz; Hong, Zhi; Yao, Nanhua

    2005-01-01

    Picornaviruses utilize virally encoded RNA polymerase and a uridylylated protein primer to ensure replication of the entire viral genome. The molecular details of this mechanism are not well understood due to the lack of structural information. We report the crystal structure of human rhinovirus 16 3D RNA-dependent RNA polymerase (HRV16 3Dpol) at a 2.4-A resolution, representing the first complete polymerase structure from the Picornaviridae family. HRV16 3Dpol shares the canonical features of other known polymerase structures and contains an N-terminal region that tethers the fingers and thumb subdomains, forming a completely encircled active site cavity which is accessible through a small tunnel on the backside of the molecule. The small thumb subdomain contributes to the formation of a large cleft on the front face of the polymerase which also leads to the active site. The cleft appears large enough to accommodate a template:primer duplex during RNA elongation or a protein primer during the uridylylation stage of replication initiation. Based on the structural features of HRV16 3Dpo1 and the catalytic mechanism known for all polymerases, a front-loading model for uridylylation is proposed.

  14. Uncovering layers of human RNA polymerase II transcription

    DEFF Research Database (Denmark)

    Jensen, Torben Heick

    In recent years DNA microarray and high-throughput sequencing technologies have challenged the “gene-centric” view that pre-mRNA is the only RNA species transcribed off protein-coding genes. Instead unorthodox transcription from within genic- and intergenic regions has been demonstrated to occur...... and unstable RNAs emitted from within, and immediately upstream human protein-coding genes. Mechanisms of their production and turn-over as well as their possible functions will be discussed...

  15. Potent host-directed small-molecule inhibitors of myxovirus RNA-dependent RNA-polymerases.

    Directory of Open Access Journals (Sweden)

    Stefanie A Krumm

    Full Text Available Therapeutic targeting of host cell factors required for virus replication rather than of pathogen components opens new perspectives to counteract virus infections. Anticipated advantages of this approach include a heightened barrier against the development of viral resistance and a broadened pathogen target spectrum. Myxoviruses are predominantly associated with acute disease and thus are particularly attractive for this approach since treatment time can be kept limited. To identify inhibitor candidates, we have analyzed hit compounds that emerged from a large-scale high-throughput screen for their ability to block replication of members of both the orthomyxovirus and paramyxovirus families. This has returned a compound class with broad anti-viral activity including potent inhibition of different influenza virus and paramyxovirus strains. After hit-to-lead chemistry, inhibitory concentrations are in the nanomolar range in the context of immortalized cell lines and human PBMCs. The compound shows high metabolic stability when exposed to human S-9 hepatocyte subcellular fractions. Antiviral activity is host-cell species specific and most pronounced in cells of higher mammalian origin, supporting a host-cell target. While the compound induces a temporary cell cycle arrest, host mRNA and protein biosynthesis are largely unaffected and treated cells maintain full metabolic activity. Viral replication is blocked at a post-entry step and resembles the inhibition profile of a known inhibitor of viral RNA-dependent RNA-polymerase (RdRp activity. Direct assessment of RdRp activity in the presence of the reagent reveals strong inhibition both in the context of viral infection and in reporter-based minireplicon assays. In toto, we have identified a compound class with broad viral target range that blocks host factors required for viral RdRp activity. Viral adaptation attempts did not induce resistance after prolonged exposure, in contrast to rapid

  16. Cystoviral polymerase complex protein P7 uses its acidic C-terminal tail to regulate the RNA-directed RNA polymerase P2.

    Science.gov (United States)

    Alphonse, Sébastien; Arnold, Jamie J; Bhattacharya, Shibani; Wang, Hsin; Kloss, Brian; Cameron, Craig E; Ghose, Ranajeet

    2014-07-15

    In bacteriophages of the cystovirus family, the polymerase complex (PX) encodes a 75-kDa RNA-directed RNA polymerase (P2) that transcribes the double-stranded RNA genome. Also a constituent of the PX is the essential protein P7 that, in addition to accelerating PX assembly and facilitating genome packaging, plays a regulatory role in transcription. Deletion of P7 from the PX leads to aberrant plus-strand synthesis suggesting its influence on the transcriptase activity of P2. Here, using solution NMR techniques and the P2 and P7 proteins from cystovirus ϕ12, we demonstrate their largely electrostatic interaction in vitro. Chemical shift perturbations on P7 in the presence of P2 suggest that this interaction involves the dynamic C-terminal tail of P7, more specifically an acidic cluster therein. Patterns of chemical shift changes induced on P2 by the P7 C-terminus resemble those seen in the presence of single-stranded RNA suggesting similarities in binding. This association between P2 and P7 reduces the affinity of the former toward template RNA and results in its decreased activity both in de novo RNA synthesis and in extending a short primer. Given the presence of C-terminal acidic tracts on all cystoviral P7 proteins, the electrostatic nature of the P2/P7 interaction is likely conserved within the family and could constitute a mechanism through which P7 regulates transcription in cystoviruses.

  17. Identification of an ortholog of the eukaryotic RNA polymerase III subunit RPC34 in Crenarchaeota and Thaumarchaeota suggests specialization of RNA polymerases for coding and non-coding RNAs in Archaea.

    NARCIS (Netherlands)

    Blombach, F.; Makarova, K.S.; Marrero, J.; Siebers, B.G.; Koonin, E.V.; Oost, J. van der

    2009-01-01

    One of the hallmarks of eukaryotic information processing is the co-existence of 3 distinct, multi-subunit RNA polymerase complexes that are dedicated to the transcription of specific classes of coding or non-coding RNAs. Archaea encode only one RNA polymerase that resembles the eukaryotic RNA polym

  18. Identification of an ortholog of the eukaryotic RNA polymerase III subunit RPC34 in Crenarchaeota and Thaumarchaeota suggests specialization of RNA polymerases for coding and non-coding RNAs in Archaea

    NARCIS (Netherlands)

    Blombach, F.; Makarova, K.S.; Marrero, J.; Siebers, B.; Koonin, E.V.; Oost, van der J.

    2009-01-01

    One of the hallmarks of eukaryotic information processing is the co-existence of 3 distinct, multi-subunit RNA polymerase complexes that are dedicated to the transcription of specific classes of coding or non-coding RNAs. Archaea encode only one RNA polymerase that resembles the eukaryotic RNA polym

  19. On the role of the Escherichia coli RNA polymerase sigma factor in T4 phage development.

    Science.gov (United States)

    Zograff, Y N

    1981-01-01

    The rpoD800 mutation causing the temperature sensitivity of Escherichia coli RNA polymerase sigma factor has been used to demonstrate that the bacterial sigma factor is necessary throughout T4 phage development. In T4-infected RpoD800 mutant cells RNA synthesis is equally depressed at restrictive temperature at early and late stages of infection. The results show the bacterial sigma factor to be necessary for the synthesis of all RNA types in infected cells.

  20. Rifampicin-resistance, rpoB polymorphism and RNA polymerase genetic engineering.

    Science.gov (United States)

    Alifano, Pietro; Palumbo, Carla; Pasanisi, Daniela; Talà, Adelfia

    2015-05-20

    Following its introduction in 1967, rifampicin has become a mainstay of therapy in the treatment of tuberculosis, leprosy and many other widespread diseases. Its potent antibacterial activity is due to specific inhibition of bacterial RNA polymerase. However, resistance to rifampicin was reported shortly after its introduction in the medical practice. Studies in the model organism Escherichia coli helped to define the molecular mechanism of rifampicin-resistance demonstrating that resistance is mostly due to chromosomal mutations in rpoB gene encoding the RNA polymerase β chain. These studies also revealed the amazing potential of the molecular genetics to elucidate the structure-function relationships in bacterial RNA polymerase. The scope of this paper is to illustrate how rifampicin-resistance has been recently exploited to better understand the regulatory mechanisms that control bacterial cell physiology and virulence, and how this information has been used to maneuver, on a global scale, gene expression in bacteria of industrial interest. In particular, we reviewed recent literature regarding: (i) the effects of rpoB mutations conferring rifampicin-resistance on transcription dynamics, bacterial fitness, physiology, metabolism and virulence; (ii) the occurrence in nature of "mutant-type" or duplicated rifampicin-resistant RNA polymerases; and (iii) the RNA polymerase genetic engineering method for strain improvement and drug discovery.