EC:2.7.7.48 - FACTA Search

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

The Hepatitis C virus is a positive-stranded RNA virus which is the causal agent for a chronic liver infection afflicting more than 170,000,000 people world-wide. The HCV genome is approximately 9.6 kb in length and the proteome encoded is a polyprotein of a little more than 3000 amino acid residues. This polyprotein is processed by a combination of host and viral proteases into structural and non-structural proteins. The functions of most of these proteins have been established by analogy to other viruses and by sequence homology to known proteins, as well as subsequent biochemical analysis. Two of the non-structural proteins, NS4b and NS5a, are still of unknown function. The development of antivirals for this infectious agent has been hampered by the lack of robust and economical cell culture and animal infection systems. Recent progress in the molecular virology of HCV has come about due to the definition of molecular clones, which are infectious in the chimpanzee, the development of a subgenomic replicon system in Huh7 cells, and the description of a transgenic mouse model for HCV infection. Recent progress in the structural biology of the virus has led to the determination of high resolution three-dimensional structures of a number of the key virally encoded enzymes, including the NS3 protease, NS3 helicase, and NS5b RNA-dependent RNA polymerase. In some cases these structures have been determined in complex with substrates, co-factors (NS4a), and inhibitors. Finally, a variety of techniques have been used to define host factors, which may be required for HCV replication, although this work is just beginning.
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PMID:Recent advances in the molecular biology of hepatitis C virus. 1167 30

The complete nucleotide sequence of the genomic RNA of Tulip virus X Japanese isolate (TVX-J) has been determined. The sequence is 6056 nucleotides in length, excluding the poly(A) tail at the 3' terminus, and contains five open reading frames (ORFs) coding for proteins of Mr 153, 25, 12, 10, and 22 kDa (ORFs 1 through 5, respectively). The genome organization of TVX-J is similar to that of potexviruses, and the encoded proteins share a high degree of homology to the corresponding proteins of other potexviruses. Phylogenetic analyses based on the RNA-dependent RNA polymerase (RdRp) protein (the methyltransferase, helicase, and polymerase domains) encoded by ORF1 and the capsid protein (CP) encoded by ORF5, revealed a close relationship of TVX-J to Plantago asiatica mosaic virus (PlAMV). Pairwise comparison analyses revealed that the relationship between TVX and PlAMV is intermediate between that of strains and species, though previously they have not been considered related. Due to the relatively distant relationships of their replication apparatus and triple gene blocks, we conclude that TVX and PlAMV should be classified as distinct viruses. In addition, the borderline between species and strains of potexviruses is discussed.
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PMID:Complete nucleotide sequence of Tulip virus X (TVX-J): the border between species and strains within the genus Potexvirus. 1181 81

We recently developed a model for flavivirus infection in mice and hamsters using the Modoc virus (MODV), a flavivirus with no known vector (P. Leyssen, A. Van Lommel, C. Drosten, H. Schmitz, E. De Clercq, and J. Neyts, 2001, Virology 279, 27-37). We now present the coding and noncoding sequence of MODV. The Modoc virus genome was determined to be 10,600 nucleotides in length with a single open reading frame extending from nucleotides 110 to 10,234, encoding 3374 amino acids. The deduced gene order of the single open reading frame is C-prM-E-NS1-NS2A-NS2B-NS3-NS4A-NS4B-NS5, which is exactly the same as that of the mosquito- and tick-borne flaviviruses. It is flanked by a 5'- and 3'-untranslated region (UTR) of 109 and 366 nucleotides, respectively. Alignment of the MODV amino acid sequence with that of 20 other flaviviruses revealed several regions with high sequence similarity corresponding to functionally important domains (e.g., the serine protease/helicase/NTPase of NS3 and the methyltransferase/RNA-dependent RNA polymerase of NS5) and conserved sites for proteolytic cleavage by viral and cellular proteases. Phylogenetic analysis of the entire coding region confirmed the classification of MODV within the flaviviruses with no known vector, which is in agreement with previous findings based on partial NS5 sequences. A detailed comparative analysis of the putative folding patterns of the 5'- and 3'-UTR of MODV and of the tick- and mosquito-borne viruses was carried out. Structural elements in the 5'- and 3' UTR of MODV that are preserved among vector-borne flaviviruses were noted and so were structural elements distinguishing the MODV UTRs from mosquito-borne and tick-borne flaviviruses. Also the putative secondary structure of circularized MODV RNA is presented.
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PMID:Complete genome sequence, taxonomic assignment, and comparative analysis of the untranslated regions of the Modoc virus, a flavivirus with no known vector. 1185 6

We show that in Dictyostelium discoideum an endogenous gene as well as a transgene can be silenced by introduction of a gene construct that is transcribed into a hairpin RNA. Gene silencing was accompanied by the appearance of sequence-specific RNA about 23mers and seemed to have a limited capacity. The three Dictyostelium homologues of the RNA-directed RNA polymerase (RrpA, RrpB, and DosA) all contain an N-terminal helicase domain homologous to the one in the dicer nuclease, suggesting exon shuffling between RNA-directed RNA polymerase and the dicer homologue. Only the knock-out of rrpA resulted in a loss of the hairpin RNA effect and simultaneously in a loss of detectable about 23mers. However, about 23mers were still generated by the Dictyostelium dsRNase in vitro with extracts from rrpA(-), rrpB(-), and DosA(-) cells. Both RrpA and a target gene were required for production of detectable amounts of about 23mers, suggesting that target sequences are involved in about 23mer amplification.
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PMID:RNAi in Dictyostelium: the role of RNA-directed RNA polymerases and double-stranded RNase. 1185 3

The single-stranded genomic RNA of Taura syndrome virus (TSV) is 10205 nucleotides in length, excluding the 3' poly(A) tail, and contains two large open reading frames (ORFs) that are separated by an intergenic region of 207 nucleotides. The ORFs are flanked by a 377 nucleotide 5' untranslated region (UTR) and a 226 nucleotide 3' UTR followed by a poly(A) tail. The predicted amino acid sequence of ORF1 revealed sequence motifs characteristic of a helicase, a protease and an RNA-dependent RNA polymerase, similar to the non-structural proteins of several plant and animal RNA viruses. In addition, a short amino acid sequence located in the N-terminal region of ORF1 presented a significant similarity with a baculovirus IAP repeat (BIR) domain of inhibitor of apoptosis proteins from double-stranded DNA viruses and from animals. The presence of this BIR-like sequence is the first reported in a single-stranded RNA virus, but its function is unknown. The N-terminal amino acid sequence of three TSV capsid proteins (55, 40 and 24 kDa) were mapped in ORF2, which is not in the same reading frame as ORF1 and possesses an AUG codon upstream of the structural genes. However, the intergenic region shows nucleotide sequence similarity with those of the genus Cricket paralysis-like viruses, suggesting a similar non-AUG-mediated translation mechanism. The structure of the TSV genome [5' UTR-non-structural proteins-intergenic UTR-structural proteins-3' UTR-poly(A) tail] is similar to those of small insect-infecting RNA viruses, which were recently regrouped into a new virus genus, Cricket paralysis-like viruses.
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PMID:Shrimp Taura syndrome virus: genomic characterization and similarity with members of the genus Cricket paralysis-like viruses. 1190 42

Hepatitis C virus (HCV) NS5B protein has been shown to have RNA-dependent RNA polymerase (RdRp) activity by itself and is a key enzyme involved in viral replication. Using analyses with the yeast two-hybrid system and in vitro binding assay, we found that human eukaryotic initiation factor 4AII (heIF4AII), which is a component of the eIF4F complex and RNA-dependent ATPase/helicase, interacted with NS5B protein. These two proteins were shown to be partially colocalized in the perinuclear region. The binding site in HCV NS5B protein was localized within amino acid residues 495 to 537 near the C terminus. Since eIF4A has a helicase activity and functions in a bidirectional manner, the binding of HCV NS5B protein to heIF4AII raises the possibility that heIF4AII facilitates the genomic RNA synthesis of NS5B protein by unwinding the secondary structure of the HCV genome and is a host component of viral replication complex.
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PMID:Human eukaryotic initiation factor 4AII associates with hepatitis C virus NS5B protein in vitro. 1192 17

Continuous efforts are vital to develop new treatment strategies to improve sustained response rates, especially for difficult to treat patients infected with the hepatitis C virus. Despite the introduction of ribavirin, more than 50% of the patients do not eliminate the virus with the current standard therapy of interferon-a (IFN) and ribavirin. Options to further enhance response rates include modification of the IFN-dosing schedule with daily dosing of IFN, new IFN such as consensus interferon or modified IFN with longer half-life and more favourable pharmacokinetics such as pegylated IFN (PEG-IFN). Clinical trials with new IFN showed that consensus IFN may improve response rates in unsuccessfully pre-treated patients and patients with HCV-genotype-1. Treatments with PEG-IFN will double response rates achieved with standard IFN monotherapy. The combination of PEG-IFN and ribavirin improves the virological response to more than 50% and even to more than 80% in patients with genotype 2 or 3. By now, standard therapy of chronic hepatitis C has been changed to the combination of PEG-IFN plus ribavirin. Future anti-viral drugs may comprise molecules that directly inhibit HCV proteins and interfere with viral replication. NS3/4A serine protease, ribonucleic acid (RNA) helicase, RNA-dependent RNA polymerase may be potential targets for new drugs. Furthermore antisense oligonucleotides or ribozymes may become new treatment options to inhibit HCV replication. Finally, immunotherapies to enhance HCV-specific immune responses are also attractive strategies to control HCV infection and to prevent chronic liver disease.
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PMID:Hepatitis C: therapeutic perspectives. 1194 60

Double-stranded RNA (dsRNA) viruses in some fungi are associated with hypovirulence and have been used or proposed as biological control agents. We isolated 7.5-kb dsRNAs from 13 of 286 field strains of Fusarium graminearum isolated from maize in Korea. One of these strains, DK21, was examined in more detail. This strain had pronounced morphological changes, including reduction in mycelial growth, increased pigmentation, reduced virulence towards wheat, and decreased (60-fold) production of trichothecene mycotoxins. The presence or absence of the 7.5-kb dsRNA was correlated with the changes in pathogenicity and morphology. The dsRNA could be transferred to virus-free strains by hyphal fusion, and the recipient strain acquired the virus-associated phenotype of the donor strain. The dsRNA was transmitted to approximately 50% of the conidia, and only colonies resulting from conidia carrying the mycovirus had the virus-associated phenotype. Partial nucleotide sequences of the purified dsRNA identify an RNA-dependent RNA polymerase sequence and an ATP-dependent helicase that are closely related to those of Cryphonectria hypovirus and Barley yellow mosaic virus. Collectively, these results suggest that this dsRNA isolated from F. graminearum encodes traits for hypovirulence.
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PMID:Double-stranded RNA mycovirus from Fusarium graminearum. 1197 30

RNA interference (RNAi) is the process of sequence-specific, posttranscriptional gene silencing in animals and plants initiated by double-stranded (ds) RNA that is homologous to the silenced gene. This technology has usually involved injection or transfection of dsRNA in model nonvertebrate organisms. The longer dsRNAs are processed into short (19 25 nucleotides) small interfering RNAs (siRNAs) by a ribonucleotide protein complex that includes an RNAse III related nuclease (Dicer), a helicase family member, and possibly a kinase and an RNA-dependent RNA polymerase (RdRP). In mammalian cells it is known that dsRNA 30 base pairs or longer can trigger interferon responses that are intrinsically sequence-nonspecific, thus limiting the application of RNAi as an experimental and therapeutic agent. Duplexes of 21-nucleotide siRNAs with short 3' overhangs, however, can mediate RNAi in a sequence-specific manner in cultured mammalian cells. One limitation in the use of siRNA as a therapeutic reagent in vertebrate cells is that short, highly defined RNAs need to be delivered to target cells--a feat thus far only accomplished by the use of synthetic, duplex RNAs delivered exogenously to cells. In this report, we describe a mammalian Pol III promoter system capable of expressing functional double-stranded siRNAs following transfection into human cells. In the case of the 293 cells cotransfected with the HIV-1 pNL4-3 proviral DNA and the siRNA-producing constructs, we were able to achieve up to 4 logs of inhibition of expression from the HIV-1 DNA.
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PMID:Expression of small interfering RNAs targeted against HIV-1 rev transcripts in human cells. 1261 May 64

The genome of rubella virus (RV) is translated into a polyprotein precusor, p200, of the nonstructural proteins (NSPs). This is proteolytically processed by a viral-encoded protease into two mature products, p150 and p90. p150 contains sequence corresponding to the predicted methyltransferase and protease activities, while p90 has sequence for the proposed helicase and RNA-dependent RNA polymerase activities. Processing of p200 is essential for RV viral replication. RV NSPs are responsible for viral RNA replication, in which a full-length negative-strand RNA serves as the intermediate for the replication of positive-strand genomic RNA and the transcription of subgenomic RNA. Previously we demonstrated that p200 synthesizes negative- but not positive-strand RNA, and that cleavage products p150/p90 are required for efficient production of positive-strand RNA. To determine whether p150 or p90 alone or together is involved in positive-strand RNA synthesis, vaccinia virus recombinants expressing individual NSPs were constructed and characterized. These were used in in vivo rescue experiments to complement replication-defective mutants in virus replication. A protease-inactive mutant was rescued by p200 or p150 provided in trans by using vaccinia virus recombinants. Thus this protease can function in trans. Rescue of cleavage-defective mutant by either p200 alone, or p150 plus p90 but not by p150 or p90 alone suggests that p150 and p90 function together as a replication complex in positive-strand RNA synthesis.
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PMID:Rescue of rubella virus replication-defective mutants using vaccinia virus recombinant expressing rubella virus nonstructural proteins. 1207 35

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