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)

The tRNA-like structure at the 3' end of turnip yellow mosaic virus (TYMV) RNA was studied in order to determine the role of this structure in the initiation of minus-strand synthesis in vitro. Deletions in the 5'-to-3' direction up to the pseudoknot structure did not result in a decrease of transcription efficiency. However, transcription efficiency was reduced twofold when a fragment of 21 nucleotides, comprising the 3'-terminal hairpin, was used as a template. tRNA(Phe) from yeast, Escherichia coli 5S rRNA, and the 3'-terminal 208 nucleotides of alfalfa mosaic virus RNA 3 could not be transcribed by the RNA-dependent RNA polymerase (RdRp) of TYMV. Various mutations in the sequences of loop regions L1 and L2 or of stem region S1 of the pseudoknot were tested to further investigate the importance of the pseudoknot structure. The results were compared with those obtained in an earlier study on aminoacylation with the same mutants (R. M. W. Mans, M. H. van Steeg, P. W. G. Verlaan, C. W. A. Pleij, and L. Bosch, J. Mol. Biol. 223:221-232; 1992). Mutants which still harbor a stable pseudoknot, as proven by probing its structure, have a transcription efficiency very close to that of the wild-type virus. Disruption of the pseudoknot structure, however, gives rise to a drop in transcription efficiency to about 50%. No indications of base-specific interactions between L1, L2, or S1 of the pseudoknot and the RdRp were found.
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PMID:The role of the pseudoknot at the 3' end of turnip yellow mosaic virus RNA in minus-strand synthesis by the viral RNA-dependent RNA polymerase. 922 89

From mutational analysis of the 3'-terminal hairpin of turnip yellow mosaic virus (TYMV) RNA and use of nonstructured C-rich RNA templates, we conclude that the main determinant in the tRNA-like structure of TYMV RNA for initiation of minus-strand synthesis by the viral RNA-dependent RNA polymerase (RdRp) is the non-base-paired 3' ACC(A) end. Base pairing of this 3' end reduces the transcription efficiency drastically, and deletion of only the 3'-terminal A residue results in a fivefold drop in efficiency. The two C residues of the 3' ACCA end are required for efficient transcription, as shown by substitution mutations. However, the 5' A residue is not specifically involved in initiation of transcription, as shown by substitution mutations. Furthermore, the hairpin stem and loop upstream of the 3' ACCA end also do not interact with the RdRp in a base-specific way. However, for efficient transcription, the hairpin stem should be at least five bp in length, while the calculated deltaG value should be less than -10.5 kcal/mol. Unexpectedly, the use of nonstructured C-rich RNA templates showed that the RdRp can start internally on an NCCN or NUCN sequence. Therefore, a possible function of the tRNA-like structure of TYMV RNA may be to prevent internal initiation of minus-strand synthesis.
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PMID:Minimal template requirements for initiation of minus-strand synthesis in vitro by the RNA-dependent RNA polymerase of turnip yellow mosaic virus. 955 83

RNA viruses which do not have a poly(A) tail or a tRNA-like structure for the protection of their vulnerable 3' termini may have developed a different strategy to maintain their genome integrity. We provide evidence that deletions of up to 7 nucleotides from the 3' terminus of cucumber mosaic cucumovirus (CMV) satellite RNA (satRNA) were repaired in planta in the presence of the helper virus (HV) CMV. Sequence comparison of 3'-end-repaired satRNA progenies, and of satRNA and HV RNA, suggested that the repair was not dependent on a viral template. The 3' end of CMV satRNA lacking the last three cytosines was not repaired in planta in the presence of tomato aspermy cucumovirus (TAV), although TAV is an efficient helper for the replication of CMV satRNA. With use of pseudorecombinants constructed by the interchange of RNAs 1 and 2 of TAV and CMV, evidence was provided that the 3'-end repair was controlled by RNAs 1 and 2 of CMV, which encode subunits of the viral RNA replicase. These results, and the observation of short repeated sequences close to the 3' terminus of repaired molecules, suggest that the HV replicase maintains the integrity of the satRNA genome, playing a role analogous to that of cellular telomerases.
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PMID:Template-independent repair of the 3' end of cucumber mosaic virus satellite RNA controlled by RNAs 1 and 2 of helper virus. 957 76

Cucumber mosaic virus (CMV) is an icosahedrion plant virus and contains three different single-stranded positive sense genomic RNAs. The very 3' ends of each of the genomic RNAs can fold into a tRNA-like structure. Based on the structural analysis of the 3' tRNA-like structure of the brome mosaic virus (BMV), we superimposed and redrew the 3' tRNA-like structure of CMV. We homogenized virus infected or healthy tobacco leaves with polytron and carried out low speed centrifugation twice and ultra-centrifugation three times to get detergent solubilized membrane bound fractions. We accidentally found that these fractions were enriched with a host-encoded RNA-dependent RNA polymerase (RdRp) activity. Similar activity could also be found in other plants tested. Alternately, the membrane bound fraction could be simply precipitated by low speed centrifugation (3,000 g) and high speed ultra-centrifugation (40,000 g). The pellet was then suspended in a detergent-containing buffer, after which 25%-55% glycerol gradient fractionation was performed. Activity was tested through the incorporation of [alpha-32P]UTP using endogenous CMV RNAs as templates on each fraction collected. It was found that most of the fractions contained the viral-encoded RNA-dependent RNA polymerase. The products of RdRp reaction were found to have a double-stranded from through further analysis of the RNase protection assay.
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PMID:The preparation of RNA-dependent RNA polymerase complex from virus infected plants. 961 71

Based solely on the information that beet virus Q (BVQ) contains tubular particles, the entire nucleotide sequence of its tripartite genome was determined from unpurified virus in ca. 40 ml crude sap from locally infected Chenopodium quinoa. A starting sequence for RNA 1 was generated using primers corresponding to highly conserved helicase domains in the respective RNAs of furo-, pomo-, peclu-, hordei- and tobraviruses, and was extended by a walking random-primed cDNA approach. The similarity of the 3' ends of furoviral RNAs allowed starting sequences for BVQ RNAs 2 and 3 to be obtained once the 3' end of RNA 1 was known. BVQ RNA 1 encodes a protein with a methyltransferase-like, a variable and a helicase-like region, and for a readthrough protein which, in addition, contains an RNA-dependent RNA polymerase region. RNA 2 carries the coat protein gene, a coat protein read-through protein gene and two additional ORFs which may have arisen by deletions from an originally larger readthrough domain. RNA 3 carries a triple gene block resembling that of several other rod-shaped viruses. The 5' UTRs of the three RNAs have the potential to form a series of hairpins with C-A and C-C mismatches resembling those found in tymoviral RNAs. The 3' ends can be folded into tRNA-like structures which are preceded by a long hairpin-like structure and an upstream pseudoknot domain. BVQ belongs to the recently proposed genus Pomovirus; it shows evolutionary relationships to furoviruses in sensu stricto, peclu-, hordei-, tobra-, tymo-, tobamo-, carla- and potexviruses.
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PMID:Genome properties of beet virus Q, a new furo-like virus from sugarbeet, determined from unpurified virus. 971 54

A turnip yellow mosaic virus RNA-dependent RNA polymerase activity was used to study the template requirements for in vitro minus strand synthesis, which is initiated specifically opposite the 3'-CCA that terminates the 3'-tRNA-like structure. A deletion survey confirmed earlier results suggesting the absence of minus strand promoter elements upstream of the pseudoknotted acceptor stem and 3'-terminus. Reiteration of this 27-nt domain provided two competing initiation sites. By varying the added downstream element, it was shown that the pseudoknotted domain could be functionally replaced by various simple stem/loops, although with some decrease in activity. The addition of varying numbers of consecutive -CCA- triplets to the 3' end of the tRNA-like structure resulted in accurate initiation from each added triplet. A similar spectrum of initiations occurred with an unstructured RNA consisting of 12 consecutive -CCA- triplets and no additional viral sequence. Substitution mutations revealed no influence on minus strand synthesis of the identity of the nucleotide immediately upstream of a -CC- initiation site, but a preference for a purine immediately downstream. The introduction of secondary structure into the linear template showed that the usage of potential -CCR- initiation sites is influenced by nonspecific secondary structure. We conclude that specificity arises from the requirement that a -CCR- sequence be sterically accessible. This mechanism is only applicable to interactions that do not involve RNA unwinding during site selection, but may be used commonly in positive strand RNA virus replication and be applicable to other RNA-protein interactions.
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PMID:Specific site selection in RNA resulting from a combination of nonspecific secondary structure and -CCR- boxes: initiation of minus strand synthesis by turnip yellow mosaic virus RNA-dependent RNA polymerase. 974 Jan 27

Each of the brome mosaic virus (BMV) genomic RNAs contains a conserved tRNA-like structure that is sufficient to direct minus-strand RNA synthesis in vitro. The tRNA-like promoters, tB1 and tB3, direct approximately equal amounts of synthesis in vitro. However, 5' sequences were found to affect the amount of minus-strand synthesis, suggesting that sequences beyond the tRNA-like structure are important in moderating minus-strand synthesis. Consistent with this, sequences upstream the tRNA-like structure are able to partially suppress mutations at or near the initiation site. This activity is observed in the 5' sequences of both BMV and CMV (cucumber mosaic virus) templates. However, a chimeric RNA containing the CMV tRNA-like promoter fused to the 5' sequences of BMV was not able to suppress mutations at the initiation site, suggesting that homologous 5' and 3' sequences are required to affect initiation. The ability to suppress mutations at the initiation site was correlated with a slight increase in the ability of the BMV RNA-dependent RNA polymerase to interact with the RNA.
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PMID:Sequences 5' of the conserved tRNA-like promoter modulate the initiation of minus-strand synthesis by the brome mosaic virus RNA-dependent RNA polymerase. 987 26

The approximately 150 nt tRNA-like structure present at the 3' end of each of the brome mosaic virus (BMV) genomic RNAs is sufficient to direct minus-strand RNA synthesis. RNAs containing mutations in the tRNA-like structure that decrease minus-strand synthesis were tested for their ability to interact with RdRp (RNA-dependent RNA polymerase) using a template competition assay. Mutations that are predicted to disrupt the pseudoknot and stem B1 do not affect the ability of the tRNA-like structure to interact with RdRp. Similarly, the +1 and +2 nucleotides are not required for stable template-RdRp interaction. Mutations in the bulge and hairpin loops of stem C decreased the ability of the tRNA-like structure to interact with RdRp. Furthermore, in the absence of the rest of the BMV tRNA, stem C is able to interact with RdRp. The addition of an accessible initiation sequence containing ACCA3' to stem C created an RNA capable of directing RNA synthesis. Synthesis from this minimal minus-strand template is dependent on sequences in the hairpin and bulged loops.
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PMID:A minimal RNA promoter for minus-strand RNA synthesis by the brome mosaic virus polymerase complex. 1002 45

Reverse transcriptase enzymes (RT) convert single-stranded retroviral RNA genomes into double-stranded DNA. The RT enzyme can use both RNA and DNA primers, the former being used exclusively during initiation of minus- and plus-strand synthesis. Initiation of minus-strand DNA synthesis occurs by extension of a tRNA primer that is associated with the viral genome, and plus-strand DNA synthesis is initiated from an RNase H- resistant polypurine tract of the genomic RNA that remains bound to the newly synthesized minus-strand DNA. All other phases of reverse transcription represent elongation of a DNA primer. We demonstrate that the polymerase fidelity of RT enzymes is significantly higher in tRNA-primed reverse transcription compared with DNA-primed reactions. Two mechanistic explanations can be proposed. First, the type of template-primer (T- P) duplex (RNA-RNA versus RNA-DNA) may affect the RT enzyme conformation such that the discrimination against incorrect nucleotides is affected. Second, the tRNA primer may act as a fidelity co-factor through specific association with the RT enzyme. According to the latter hypothesis, the increased fidelity observed for an RNA-RNA T-P should persist at a distance from the initiation site, where the enzyme-bound nucleic acid duplex will consist of RNA-cDNA. However, we measured that the effect of tRNA on the fidelity is detectable only at a short distance from the initiation site. These results indicate that the type of T-P duplex influences the fidelity of reverse transcription, suggesting that two small segments of the viral genome downstream of the initiation sites for minus- and plus-strand DNA synthesis are copied with a fidelity that is greater than average.
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PMID:The fidelity of reverse transcription differs in reactions primed with RNA versus DNA primers. 1008 43

We have developed a reconstituted system which models the events associated with human immunodeficiency virus type 1 (HIV-1) plus-strand transfer. These events include synthesis of plus-strand strong-stop DNA [(+) SSDNA] from a minus-strand DNA donor template covalently attached to human tRNA3Lys, tRNA primer removal, and annealing of (+) SSDNA to the minus-strand DNA acceptor template. Termination of (+) SSDNA synthesis at the methyl A (nucleotide 58) near the 3' end of tRNA3Lys reconstitutes the 18-nucleotide primer binding site (PBS). Analysis of (+) SSDNA synthesis in vitro and in HIV-1 endogenous reactions indicated another major termination site: the pseudouridine at nucleotide 55. In certain HIV-1 strains, complementarity between nucleotides 56 to 58 and the first three bases downstream of the PBS could allow all of the (+) SSDNA products to be productively transferred. Undermodification of the tRNA may be responsible for termination beyond the methyl A. In studies of tRNA removal, we find that initial cleavage of the 3' rA by RNase H is not sufficient to achieve successful strand transfer. The RNA-DNA hybrid formed by the penultimate 17 bases of tRNA still annealed to (+) SSDNA must also be destabilized. This can occur by removal of additional 3'-terminal bases by RNase H (added either in cis or trans). Alternatively, the nucleic acid chaperone activity of nucleocapsid protein (NC) can catalyze this destabilization. NC stimulates annealing of the complementary PBS sequences in (+) SSDNA and the acceptor DNA template. Reverse transcriptase also promotes annealing but to a lesser extent than NC.
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PMID:Molecular requirements for human immunodeficiency virus type 1 plus-strand transfer: analysis in reconstituted and endogenous reverse transcription systems. 1023 40


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