EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Influenza virus RNA polymerase is composed of three virus-coded proteins, and is involved in both transcription and replication of the negative-strand genome RNA. Subunit PB1 plays key roles in both the RNA polymerase assembly and the catalytic function of RNA polymerization. Using yeast two-hybrid screening, a HeLa cell protein with the molecular mass of 45 kDa was identified. After cloning and sequencing, this protein was identified to be Ebp1, ErbB3-binding protein. Epb1 specifically interacts with PB1 both in vitro and in vivo, and Epb1 contact site on PB1 was mapped at its binding site of transcription primers. Ebp1 was found to interfere with in vitro RNA synthesis by influenza virus RNA polymerase (3P complex), but no inhibition was observed for capped RNA endonuclease and RNA-cap binding, the intrinsic activities of RNA polymerase. Since inhibition was not observed against other nucleic acid polymerases tested, we propose that Ebp1 is a selective inhibitor of influenza viral RNA polymerase. Accordingly over-expression of Ebp1 interfered with virus production. The PB1-contact site on Ebp1 overlaps with the interaction site with ErbB3 (epidermal receptor tyrosine kinase), androgen receptor (AR) and retinoblastoma gene product (Rb), which are involved in controlling cell proliferation and differentiation.
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PMID:Host factor Ebp1: selective inhibitor of influenza virus transcriptase. 1729 34

The genome of influenza A virus is organized into eight ribonucleoprotein complexes (RNPs), each containing one RNA polymerase complex. This RNA polymerase has also been found non-associated to RNPs and is possibly involved in distinct functions in the infection cycle. We have expressed the virus RNA polymerase complex by co-tranfection of the PB1, PB2 and PA genes in mammalian cells and the heterotrimer was purified by the TAP tag procedure. Its 3D structure was determined by electron microscopy and single-particle image processing. The model obtained resembles the structure previously reported for the polymerase complex associated to viral RNPs but appears to be in a more open conformation. Detailed model comparison indicated that specific areas of the complex show important conformational changes as compared to the structure for the RNP-associated polymerase, particularly in regions known to interact with the adjacent NP monomers in the RNP. Also, the PB2 subunit seems to undergo a substantial displacement as a result of the association of the polymerase to RNPs. The structural model presented suggests that a core conformation of the polymerase in solution exists but the interaction with other partners, such as proteins or RNA, will trigger distinct conformational changes to activate new functional properties.
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PMID:Three-dimensional model for the isolated recombinant influenza virus polymerase heterotrimer. 1751 66

The rescue of influenza viruses by reverse genetics has been described only for the influenza A and B viruses. Based on a similar approach, we developed a reverse-genetics system that allows the production of influenza C viruses entirely from cloned cDNA. The complete sequences of the 3' and 5' noncoding regions of type C influenza virus C/Johannesburg/1/66 necessary for the cloning of the cDNA were determined for the seven genomic segments. Human embryonic kidney cells (293T) were transfected simultaneously with seven plasmids that direct the synthesis of each of the seven viral RNA segments of the C/JHB/1/66 virus under the control of the human RNA polymerase I promoter and with four plasmids encoding the viral nucleoprotein and the PB2, PB1, and P3 proteins of the viral polymerase complex. This strategy yielded between 10(3) and 10(4) PFU of virus per ml of supernatant at 8 to 10 days posttransfection. Additional viruses with substitutions introduced in the hemagglutinin-esterase-fusion protein were successfully produced by this method, and their growth phenotype was evaluated. This efficient system, which does not require helper virus infection, should be useful in viral mutagenesis studies and for generation of expression vectors from type C influenza virus.
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PMID:Rescue of influenza C virus from recombinant DNA. 1768 50

The cellular protein Ebp1 was identified to interact with PB1 protein of influenza virus RNA polymerase, and inhibit both RNA synthesis in vitro and influenza virus replication in vivo [Honda, A., Okamoto, T., Ishihama, A., 2007. Host factor Ebp1: selective inhibitor of influenza virus transcriptase. Genes Cells 12, 133-142]. The intracellular localization of Ebp1 that is involved in cell proliferation control was analyzed by direct immunostaining of cells before and after influenza virus infection. Ebp1 was found to localize in the nuclear membrane of uninfected cells, and to form nuclear aggregates with viral P proteins in virus-infected cells.
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PMID:Role of host protein Ebp1 in influenza virus growth: intracellular localization of Ebp1 in virus-infected and uninfected cells. 1788 19

The RNA polymerase of influenza A virus is a heterotrimeric complex of PB1, PB2 and PA subunits that is required for transcription and replication of the viral genome. Here, we demonstrate a differential requirement of the PA subunit for binding to the vRNA and cRNA promoters--specifically, PA is more important for binding to the cRNA than the vRNA promoter. Furthermore, five point mutations were identified in the L163-I178 region of PA, which resulted in an inhibition of polymerase activity when provided with a cRNA compared to vRNA promoter. Cross-linking studies suggested that this inhibition was due to a reduction in promoter binding of the mutant polymerases to the cRNA promoter. We conclude that the L163-I178 region of PA is directly or indirectly involved in cRNA promoter binding and suggest a novel function for PA in modulating promoter binding.
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PMID:Differential role of the influenza A virus polymerase PA subunit for vRNA and cRNA promoter binding. 1790 3

The influenza A virus genome consists of eight negative-sense RNA segments that must each be packaged to produce an infectious virion. We have previously mapped the minimal cis-acting regions necessary for efficient packaging of the PA, PB1, and PB2 segments, which encode the three protein subunits of the viral RNA polymerase. The packaging signals in each of these RNAs lie within two separate regions at the 3' and 5' termini, each encompassing the untranslated region and extending up to 80 bases into the adjacent coding sequence. In this study, we introduced scanning mutations across the coding regions in each of these RNA segments in order to finely define the packaging signals. We found that mutations producing the most severe defects were confined to a few discrete 5' sites in the PA or PB1 coding regions but extended across the entire (80-base) 5' coding region of PB2. In sequence comparisons among more than 580 influenza A strains from diverse hosts, these highly deleterious mutations were each found to affect one or more conserved bases, though they did not all lie within the most broadly conserved portions of the regions that we interrogated. We have introduced silent and conserved mutations to the critical packaging sites, which did not affect protein function but impaired viral replication at levels roughly similar to those of their defects in RNA packaging. Interestingly, certain mutations showed strong tendencies to revert to wild-type sequences, which implies that these putative packaging signals are critical for the influenza life cycle.
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PMID:Mutational analyses of packaging signals in influenza virus PA, PB1, and PB2 genomic RNA segments. 1795 57

Synthesis of influenza virus mRNA by the viral RNA polymerase complex is primed by capped RNA fragments generated by endonuclease cleavage of host pre-mRNA by the polymerase subunit PB1. In previous studies, endonuclease and promoter-binding sites have been described in the C-terminal region of PB1. Here, we have identified an additional region near the C-terminus of PB1 involved in producing capped RNA primers for viral transcription. In particular, mutations of basic amino acids K669, R670, and R672 inhibited primer-dependent viral mRNA synthesis. In contrast, primer-independent cRNA and vRNA syntheses were only marginally affected. Additionally, recombinant viruses containing the K669A or R672A mutations expressed reduced amounts of mRNA compared to cRNA during infection and were attenuated in cell culture. Further in vitro analysis showed that these mutations inhibited the ability of the polymerase to initiate mRNA synthesis by causing a reduction in binding to the vRNA promoter and capped RNA. These results suggest that this region plays a critical role in the regulation of viral mRNA transcription.
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PMID:A cluster of conserved basic amino acids near the C-terminus of the PB1 subunit of the influenza virus RNA polymerase is involved in the regulation of viral transcription. 1819 35

The viral RNA polymerase complex of influenza A virus consists of three subunits PB1, PB2 and PA. Recently, the cellular chaperone Hsp90 was shown to play a role in nuclear import and assembly of the trimeric polymerase complex by binding to PB1 and PB2. Here we show that Hsp90 inhibitors, geldanamycin or its derivative 17-AAG, delay the growth of influenza virus in cell culture resulting in a 1-2 log reduction in viral titre early in infection. We suggest that this is caused by the reduced half-life of PB1 and PB2 and inhibition of nuclear import of PB1 and PA which lead to reduction in viral RNP assembly. Hsp90 inhibitors may represent a new class of antiviral compounds against influenza viruses.
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PMID:Hsp90 inhibitors reduce influenza virus replication in cell culture. 1857 Sep 72

Current anti-influenza drugs target the viral neuraminidase or inhibit the function of the ion channel M2 protein. Not only is the supply of these drugs unlikely to meet the demand during a large influenza epidemic/ pandemic, but also has an emergence of drug resistant influenza virus variants been documented. Thus a new effective drug or antiviral alternative is required. The influenza virus RNA polymerase complex consists of nucleoproteins (NP) that bind to three polymerase subunits: two basic polymerases, PB1 and PB2, and an acidic polymerase (PA). These proteins play a pivotal role in the virus life cycle; thus they are potential targets for the development of new anti-influenza agents. In this study, we produced human monoclonal antibodies that bound to the influenza A polymerase proteins by using a human antibody phage display library. Complementary DNA was prepared from the total RNA of a highly pathogenic avian influenza (HPAI) virus: A/duck/Thailand/144/2005(H5N1). The cDNA synthesized from the total virus RNA was used as template for the amplification of the gene segments encoding the N-terminal halves of the PB1, PB2 and PA polymerase proteins which encompassed the biologically active portions of the respective proteins. The cDNA amplicons were individually cloned into appropriate vectors and the recombinant vectors were introduced into Escherichia coli bacteria. Transformed E. coli clones were selected, and induced to express the recombinant proteins. Individually purified proteins were used as antigens in bio-panning to select the phage clones displaying specific human monoclonal single chain variable fragments (HuScFv) from a human antibody phage display library constructed from Thai blood donors in our laboratory. The purified HuScFv that bound specifically to the recombinant polymerase proteins were prepared. The inhibitory effects on the biological functions of the respective polymerase proteins should be tested. We envisage the use of the HuScFv in their cell penetrating version (transbodies) as an alternative influenza therapeutic to current anti-virus drugs.
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PMID:Human monoclonal single chain antibodies (HuScFv) that bind to the polymerase proteins of influenza A virus. 1859 27

Influenza A virus is a major human and animal pathogen with the potential to cause catastrophic loss of life. The virus reproduces rapidly, mutates frequently and occasionally crosses species barriers. The recent emergence in Asia of avian influenza related to highly pathogenic forms of the human virus has highlighted the urgent need for new effective treatments. Here we demonstrate the importance to viral replication of a subunit interface in the viral RNA polymerase, thereby providing a new set of potential drug binding sites entirely independent of surface antigen type. No current medication targets this heterotrimeric polymerase complex. All three subunits, PB1, PB2 and PA, are required for both transcription and replication. PB1 carries the polymerase active site, PB2 includes the capped-RNA recognition domain, and PA is involved in assembly of the functional complex, but so far very little structural information has been reported for any of them. We describe the crystal structure of a large fragment of one subunit (PA) of influenza A RNA polymerase bound to a fragment of another subunit (PB1). The carboxy-terminal domain of PA forms a novel fold, and forms a deep, highly hydrophobic groove into which the amino-terminal residues of PB1 can fit by forming a 3(10) helix.
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PMID:The structural basis for an essential subunit interaction in influenza virus RNA polymerase. 1866 Aug 1

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