Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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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)

Currently available sequence information suggests that the genome organization of hepatitis C virus is similar to that of flaviviruses. A positive-stranded genomic RNA contains a single long open reading frame (ORF) which is flanked by 5' and 3' noncoding sequences. This RNA codes for structural proteins at the 5' end (starting with the capsid protein) and a set of nonstructural proteins in the remainder of the genome. The latter provide essential virus-specific functions for the viral life cycle, such as protease, helicase, and RNA replicase activities. The sequence motifs characteristic of the corresponding functional protein domains are separated by similar spacings in the nonstructural regions of hepatitis C virus and flaviviruses. The structural region of the hepatitis C virus appears to consist of a capsid protein which is larger than that of flaviviruses and two putative envelope proteins which are presumably different in molecular weight and much more heavily glycosylated than their counterparts in flaviviruses. A study group of the International Committee on the Taxonomy of viruses proposes to include hepatitis C virus as a genus into the family 'flaviviridae'.
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PMID:Comparative molecular biology of flaviviruses and hepatitis C virus. 133 20

The complete nucleotide sequence of apple stem grooving virus (ASGV) genome has been determined. The genome is 6496 nucleotides in length excluding a 3'-terminal poly(A) tail and contains two overlapping open reading frames (ORFs). ORF1 begins at nucleotide position 37 and is terminated at position 6341, encoding a protein with a molecular weight of 241 kDa. ORF2, which is in a different reading frame within ORF1, begins at position 4788 and can encode a 36-kDa protein. The 241-kDa protein contains two consensus sequences associated with the RNA-dependent RNA polymerase and the NTP-binding helicase. Comparisons of amino acid sequences around these conserved motifs with other RNA viruses revealed that ASGV has extensive similarities with apple chlorotic leaf spot, tymo-, carla-, and potexviruses, and is a member of the sindbis-like supergroup. ASGV coat protein is found to be located in the C-terminal region of the 241-kDa polyprotein. The 36-kDa protein encoded by ORF2 contains the consensus sequence Gly-Asp-Ser-Gly found in the active site of several cellular and viral serine proteases.
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PMID:The nucleotide sequence of apple stem grooving capillovirus genome. 141 30

Computer-assisted comparison of the nonstructural polyprotein of hepatitis E virus (HEV) with proteins of other positive-strand RNA viruses allowed the identification of the following putative functional domains: (i) RNA-dependent RNA polymerase, (ii) RNA helicase, (iii) methyltransferase, (iv) a domain of unknown function ("X" domain) flanking the papain-like protease domains in the polyproteins of animal positive-strand RNA viruses, and (v) papain-like cysteine protease domain distantly related to the putative papain-like protease of rubella virus (RubV). Comparative analysis of the polymerase and helicase sequences of positive-strand RNA viruses belonging to the so-called "alpha-like" supergroup revealed grouping between HEV, RubV, and beet necrotic yellow vein virus (BNYVV), a plant furovirus. Two additional domains have been identified: one showed significant conservation between HEV, RubV, and BNYVV, and the other showed conservation specifically between HEV and RubV. The large nonstructural proteins of HEV, RubV, and BNYVV retained similar domain organization, with the exceptions of relocation of the putative protease domain in HEV as compared to RubV and the absence of the protease and X domains in BNYVV. These observations show that HEV, RubV, and BNYVV encompass partially conserved arrays of distinctive putative functional domains, suggesting that these viruses constitute a distinct monophyletic group within the alpha-like supergroup of positive-strand RNA viruses.
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PMID:Computer-assisted assignment of functional domains in the nonstructural polyprotein of hepatitis E virus: delineation of an additional group of positive-strand RNA plant and animal viruses. 151 55

cDNA clones representing the ssRNA genome of the NY-RPV isolate of barley yellow dwarf luteovirus (BYDV) were sequenced and 5600 nucleotides of the genome were determined. The deduced genome organization has limited similarity to that of another BYDV isolate, Vic-PAV, but is identical to that of beet western yellows (BWYV) and potato leafroll (PLRV) luteoviruses. NY-RPV has six major positive-sense open reading frames (ORFs) and, by comparison with RNA-dependent RNA polymerase and nucleic acid helicase consensus sequence motifs, it is postulated that NY-RPV ORF2 and ORF3 encode the viral replicase, which is expressed by a translational frameshift mechanism. The region of the NY-RPV genome containing the 22K coat protein ORF, the apparently associated internal apparent VPg ORF and the ORF immediately 3'-proximal (ORF6) to the coat protein ORF are organized as reported for other luteoviruses. Evidence is presented showing that ORF6 is expressed by readthrough of the coat protein gene termination codon, and that this protein is associated with the intact virus as a 65K protein. Although NY-RPV infects graminaceous rather than dicotyledonous plants, the taxonomic relationships between BYDV isolates and other luteoviruses deduced from the genome organization and sequence data strongly suggest that NY-RPV is distinct from the PAV-like isolates of BYDV and is more closely related to BWYV and PLRV.
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PMID:Nucleotide sequence analysis and genomic organization of the NY-RPV isolate of barley yellow dwarf virus. 184 Jun 12

The 5'-most gene, gene 1, of the genome of murine coronavirus, mouse hepatitis virus (MHV), is presumed to encode the viral RNA-dependent RNA polymerase. We have determined the complete sequence of this gene of the JHM strain by cDNA cloning and sequencing. The total length of this gene is 21,798 nucleotides long, which includes two overlapping, large open reading frames. The first open reading frame, ORF 1a, is 4488 amino acids long. The second open reading frame, ORF 1b, overlaps ORF 1a for 75 nucleotides, and is 2731 amino acids long. The overlapping region may fold into a pseudoknot RNA structure, similar to the corresponding region of the RNA of avian coronavirus, infectious bronchitis virus (IBV). The in vitro transcription and translation studies of this region indicated that these two ORFs were most likely translated into one polyprotein by a ribosomal frameshifting mechanism. Thus, the predicted molecular weight of the gene 1 product is more than 800,000 Da. The sequence of ORF 1b is very similar to the corresponding ORF of IBV. In contrast, the ORF 1a of these two viruses differ in size and have a high degree of divergence. The amino acid sequence analysis suggested that ORF 1a contains several functional domains, including two hydrophobic, membrane-anchoring domains, and three cysteine-rich domains. It also contains a picornaviral 3C-like protease domain and two papain-like protease domains. The presence of these protease domains suggests that the polyprotein is most likely processed into multiple protein products. In contrast, the ORF 1b contains polymerase, helicase, and zinc-finger motifs. These sequence studies suggested that the MHV gene 1 product is involved in RNA synthesis, and that this product is processed autoproteolytically after translation. This study completes the sequence of the MHV genome, which is 31 kb long, and constitutes the largest viral RNA known.
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PMID:The complete sequence (22 kilobases) of murine coronavirus gene 1 encoding the putative proteases and RNA polymerase. 184 89

RNA-dependent RNA polymerase (RdRp) was solubilized and purified from cellular membranes isolated from alfalfa mosaic virus (AIMV)-infected tobacco by employing a procedure recently described for brome mosaic virus RdRp [R. Quadt and E.M.J. Jaspars, 1990, Virology 178, 189-194]. The purified AIMV RdRp is completely dependent on added template RNAs and exhibits a high degree of template specificity. Analysis of the protein composition of AIMV RdRp showed that AIMV-encoded proteins P1 and P2 and the coat protein (CP) are present in the active enzyme complex. Minus-strand synthesis by the AIMV RdRp is inhibited by AIMV CP. Native double-stranded AIMV RNAs are utilized as template for viral RNA synthesis by AIMV RdRp indicating that a helicase activity is present in the purified AIMV RdRp preparation.
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PMID:Analysis of the protein composition of alfalfa mosaic virus RNA-dependent RNA polymerase. 202 68

Barley stripe mosaic hordeivirus (BSMV) has a tripartite positive-sense RNA genome which encodes seven major polypeptides. Infectious in vitro transcripts derived from full-length wild-type and mutant cDNA clones have been used to investigate the contribution made by various BSMV gene products to viral RNA replication and systemic movement. We show that whereas all three of the BSMV RNA components are required for plant infection, RNAs alpha and gamma can replicate together in barley protoplasts, and therefore RNA beta must encode functions required for systemic invasion of plants. The alpha a and gamma a proteins, which contain helicase and RNA polymerase sequence motifs, together comprise the essential virus-encoded components of BSMV RNA replicase. A second BSMV protein (beta b) which contains a helicase motif is not required for RNA replication. A small cysteine-rich protein (gamma b) is dispensable for infection of plants, but in its absence the accumulation of viral coat (beta a) and beta b proteins is significantly reduced. In addition, mutations in both the gamma b and gamma a (replicase) proteins can affect the systemic movement phenotype.
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PMID:Identification of barley stripe mosaic virus genes involved in viral RNA replication and systemic movement. 220 52

We have examined the mechanism by which ribavirin inhibits the multiplication of reovirus. At a concentration of 12.5 microM (3 micrograms/ml) ribavirin inhibits viral multiplication, ssRNA formation, dsRNA formation, and protein synthesis by about 90%; when much higher concentrations are used for brief periods of time, the primary target of ribavirin is seen to be viral ssRNA synthesis. When the effect of ribavirin triphosphate (RTP) was tested on the in vitro transcription by cores of the dsRNA genome segments into plus-stranded RNA, elongation, that is, the formation of intact mRNA molecules, was found to be inhibited to the greatest extent; initiation was at least 2.5 times less sensitive, and cap formation and methylation were almost unaffected. The inhibition of elongation and initiation was not competitive with respect to any of the four nucleoside triphosphates. Remarkably, the transcription of plus strands into minus strands by immature reovirus particles (the replicase reaction) was insensitive to RTP. A model is proposed that envisages RTP binding to a site close to the catalytic site of the transcriptase. This binding is postulated to inhibit the helicase function of the transcriptase and lower its affinity for template RNA so that the likelihood of premature termination is greatly increased. The helicase activity is not, of course, necessary for the transcription of plus strands into minus strands, which would account for the differential sensitivity of the transcriptase and the replicase to RTP.
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PMID:Studies on the mechanism of the antiviral activity of ribavirin against reovirus. 290 88

Monoclonal antibodies were produced using a purified cucumber mosaic virus (CMV) replicase complex, and Escherichia coli-expressed CMV 1a and 2a proteins, as immunogens. Five out of eight monoclonal antibodies, which bound to the 1a and 2a proteins in immunoblots, inhibited the RNA-dependent RNA polymerase (RdRp) activity of the purified replicase complex in vitro. Epitope mapping showed that two of the inhibitory antibodies interacted with regions of the 1a protein containing putative helicase and methyltransferase domains respectively. Two other inhibitory antibodies mapped to a region of the 2a protein containing the GDD motif which is highly conserved in RdRps. Prior interaction of the latter antibodies with a peptide containing the GDD motif prevented the antibody-mediated inhibition of the replicase. Polyclonal antibodies which inhibited the RdRp activity of the replicase complex were also produced using peptides corresponding to conserved helicase and polymerase motifs in the 1a and 2a proteins. The greatest inhibition was shown by antibodies to a peptide containing the GDD motif. These results demonstrate the functional importance of the identified sequence motifs in CMV RNA replication and indicate that the motifs are located in the replicase complex at positions accessible to antibodies, consistent with roles in interacting with the RNA template, RNA primer and enzyme substrates.
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PMID:Localization of functional regions of the cucumber mosaic virus RNA replicase using monoclonal and polyclonal antibodies. 752 62

The sequence of the entire genome of citrus tristeza virus (CTV), Florida isolate T36, was completed. The 19,296-nt CTV genome encodes 12 open reading frames (ORFs) potentially coding for at least 17 protein products. The 5'-proximal ORF 1a starts at nucleotide 108 and encodes a large polyprotein with calculated MW of 349 kDa containing domains characteristic of (from 5' to 3') two papain-like proteases (P-PRO), a methyltransferase (MT), and a helicase (HEL). Alignment of the putative P-PRO sequences of CTV with the related proteases of beet yellows closterovirus (BYV) and potyviruses allowed the prediction of catalytic cysteine and histidine residues as well as two cleavage sites, namely Val-Gly/Gly for the 5' proximal P-PRO domain and Met-Gly/Gly for the 5' distal P-PRO domain. The autoproteolytic cleavage of the polyprotein at these sites would release two N-terminal leader proteins of 54 and 55 kDa, respectively, and a 240-kDa C-terminal fragment containing MT and HEL domains. The apparent duplication of the leader domain distinguishes CTV from BYV and accounts for most of the size increase in the ORF 1a product of CTV. The downstream ORF 1b encodes a 57-kDa putative RNA-dependent RNA polymerase (RdRp), which is probably expressed via a +1 ribosomal frameshift. Sequence analysis of the frameshift region suggests that this +1 frameshift probably occurs at a rare arginine codon CGG and that elements of the RNA secondary structure are unlikely to be involved in this process. The complete polyprotein resulting from this frameshift event has a calculated MW of 401 kDa and after cleavage of the two N-terminal leaders would yield a 292-kDa protein containing the MT, HEL, and RdRp domains. Phylogenetic analysis of the three replication-associated domains, MT, HEL, and RdRp, indicates that CTV and BYV form a separate closterovirus lineage within the alpha-like supergroup of positive-strand RNA viruses. Two gene blocks or modules can be easily identified in the CTV genome. The first includes the replicative MT, HEL, and RdRp genes and is conserved throughout the entire alpha-like superfamily. The second block consists of five ORFs, 3 to 7, conserved among closteroviruses, including genes for the CTV homolog of HSP70 proteins and a duplicate of the coat protein gene. The 3'-terminal ORFs 8 to 11 encode a putative RNA-binding protein (ORF 11), and three proteins with unknown functions; this gene array is poorly conserved among closteroviruses.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Complete sequence of the citrus tristeza virus RNA genome. 774 24


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