EC:2.7.7.49 - FACTA Search

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Query: EC:2.7.7.49 (reverse transcriptase)
31,746 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The Mauriceville plasmid and the closely related Varkud plasmid of Neurospora spp. are retroelements that propagate in mitochondria. Replication appears to occur by a novel mechanism in which a monomer-length plasmid transcript having a 3' tRNA-like structure ending in CCA is reverse transcribed to give a full-length minus-strand cDNA beginning at or near the 3' end of the RNA. Here, we show that the plasmids are transcribed in vitro by the Neurospora mitochondrial RNA polymerase, with the major in vitro transcription start site approximately 260 bp upstream of the 5' end of the plasmid transcript. The location of the transcription start site suggests that the monomer-length transcripts are generated by transcription around the plasmid combined with a site-specific RNA cleavage after the 3'-CCA sequence. The 5' ends of minus-strand cDNAs in ribonucleoprotein particles were analyzed to obtain insight into the mechanism of initiation of reverse transcription in vivo. A major class of minus-strand cDNAs begins opposite C2 of the 3'-CCA sequence, the same site used for de novo initiation of cDNA synthesis by the plasmid reverse transcriptase in vitro. A second class of minus-strand cDNAs begins with putative primer sequences that correspond to cDNA copies of the plasmid or mitochondrial transcripts. These findings are consistent with the possibility that the plasmid reverse transcriptase initiates minus-strand cDNA synthesis in vivo both by de novo initiation and by a novel template-switching mechanism in which the 3' OH of a previously synthesized cDNA is used to prime the synthesis of a new minus-strand cDNA directly at the 3' end of the plasmid transcript.
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PMID:The Mauriceville plasmid of Neurospora spp. uses novel mechanisms for initiating reverse transcription in vivo. 816 65

The ribonucleoprotein telomerase, a specialized cellular reverse transcriptase, synthesizes one strand of the telomeric DNA of eukaryotes. We analyzed telomere maintenance in two immortalized human cell lines: the B-cell line JY616 and the T-cell line Jurkat E6-1, and determined whether known inhibitors of retroviral reverse transcriptases could perturb telomere lengths and growth rates of these cells in culture. Dideoxyguanosine (ddG) caused reproducible, progressive telomere shortening over several weeks of passaging, after which the telomeres stabilized and remained short. However, the prolonged passaging in ddG caused no observable effects on cell population doubling rates or morphology. Azidothymidine (AZT) caused progressive telomere shortening in some but not all T- and B-cell cultures. Telomerase activity was present in both cell lines and was inhibited in vitro by ddGTP and AZT triphosphate. Prolonged passaging in arabinofuranyl-guanosine, dideoxyinosine (ddI), dideoxyadenosine (ddA), didehydrothymidine (d4T), or phosphonoformic acid (foscarnet) did not cause reproducible telomere shortening or decreased cell growth rates or viabilities. Combining AZT, foscarnet, and/or arabinofuranyl-guanosine with ddG did not significantly augment the effects of ddG alone. Strikingly, with or without inhibitors, telomere lengths were often highly unstable in both cell lines and varied between parallel cell cultures. We propose that telomere lengths in these T- and B-cell lines are determined by both telomerase and telomerase-independent mechanisms.
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PMID:Effects of reverse transcriptase inhibitors on telomere length and telomerase activity in two immortalized human cell lines. 852 29

The ribonucleoprotein enzyme telomerase is a specialized reverse transcriptase that synthesizes telomeric DNA by copying a template sequence within the telomerase RNA. Here we analyze the actions of telomerase from Tetrahymena thermophila assembled in vivo with mutated or wild-type telomerase RNA to define further the roles of particular telomerase RNA residues involved in essential enzymatic functions: templating, substrate alignment, and promotion of polymerization. Position 49 of the telomerase RNA defined the 3' templating residue boundary, demonstrating that seven positions, residues 43 to 49, are capable of acting as templating residues. We demonstrate directly that positioning of the primer substrate involves Watson-Crick base pairing between the primer with telomerase RNA residues. Unexpectedly, formation of a Watson-Crick base pair specifically between the primer DNA and telomerase RNA residue 50 is critical in promoting primer elongation. In contrast, mutant telomerase with the cytosine at position 49 mutated to a G exhibited efficient 3' mispair extension. This work provides new evidence for specific primer-telomerase interactions, as well as base-specific interactions involving the telomerase RNA, playing roles in essential active-site functions of telomerase.
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PMID:Specific RNA residue interactions required for enzymatic functions of Tetrahymena telomerase. 852 30

The heat shock protein Hsp90 is known as an essential component of several signal transduction pathways and has now been identified as an essential host factor for hepatitis B virus replication. Hsp90 interacts with the viral reverse transcriptase to facilitate the formation of a ribonucleoprotein (RNP) complex between the polymerase and an RNA ligand. This RNP complex is required early in replication for viral assembly and initiation of DNA synthesis through a protein-priming mechanism. These results thus invoke a role for the Hsp90 pathway in the formation of an RNP.
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PMID:Hsp90 is required for the activity of a hepatitis B virus reverse transcriptase. 857 14

Inhibition of gene expression by phosphorothioate oligomers is complex and involves specific and nonspecific mechanisms. Oligomers that contain a G-quartet elicit distinct effects in vitro and in vivo that are dependent on the context of the G-quartet's occurrence within a sequence. The enzyme telomerase, a ribonucleoprotein, has a stretch of C residues in the RNA template, which are used to add terminal dG-rich telomeric repeats to the ends of chromosomes. Some but not all phosphorothioates containing a G-quartet, depending on the context of occurrence, inhibited telomerase activity in vitro. Non-G-quartet phosphorothioates did not inhibit this activity. Activities of control enzymes, such as reverse transcriptase or taq polymerase, were not affected by the G-quartet oligomers. Neither phosphodiester nor chimeric oligomers of a G-quartet-containing oligomer were as potent inhibition of telomerase activity as phosphorothioate oligomers. These results may provide a molecular target to study the effects of G-quartet-containing oligomers.
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PMID:Telomerase as a potential molecular target to study G-quartet phosphorothioates. 878 90

Telomerase is a specialized reverse transcriptase that contains its own RNA template for synthesis of telomeric DNA [Greider, C. W., & Blackburn, E. H. (1989) Nature 337, 331-337; Shippen-Lentz, D., & Blackburn, E. H. (1990) Science 247, 546-552]. The activity of this ribonucleoprotein enzyme has been associated with cancer cells [Kim et al. (1994) Science 266, 2011-2015] and is thus a potential target for anticancer chemotherapy. Telomeric DNA.RNA hybrids are important intermediates in telomerase function and form after extension of the growing telomere on the telomerase RNA template. Translocation is a critical step in telomerase function and consists of unwinding of the telomeric DNA.telomerase RNA hybrid followed by repositioning of the 3'-end of the extended telomere. A central question in telomerase function is how translocation of the extended telomere occurs in the absence of ATP or GTP. It has been hypothesized that unwinding of the telomeric hybrid may be facilitated by the formation of stable hairpins or G-quadruplexes by the telomere product (i.e., a hybrid to G-quadruplex transition) and that this may provide at least part of the driving force for translocation [Shippen-Lentz & Blackburn, 1990; Zahler et al. (1991) Nature 350, 718-720]. However, so far there has been no effort aimed at examining the possibility that a hybrid/G-quadruplex equilibrium can occur and to what extent this equilibrium depends on buffer and concentration conditions. Examination of these transitions may provide insight into telomerase function and may also provide clues for the development of anti-telomerase agents. Using a model system consisting of the DNA.RNA hybrid d(GGTTAGGGTTAG).r(cuaacccuaacc), we present evidence that a thermally induced transition of telomeric DNA.RNA hybrid to G-quadruplex can occur under certain conditions. These results provide support for the hypothesis that G-quadruplex formation by the telomere product may in fact regulate telomerase function at the translocation step (Zahler et al., 1991) and suggest an Achilles' heel for indirectly targeting telomerase. Thus, on the basis of the insight gained from the present studies and the results of Zahler et al. (1991), we propose that ligands that selectively bind or cleave G-quadruplex structures may modulate telomerase processivity.
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PMID:Thermally induced DNA.RNA hybrid to G-quadruplex transitions: possible implications for telomere synthesis by telomerase. 897 82

Assembly of hepadnaviruses depends on the formation of a ribonucleoprotein (RNP) complex comprising the viral polymerase polypeptide and an RNA segment, epsilon, present on pregenomic RNA. This interaction, in turn, activates the reverse transcription reaction, which is primed by a tyrosine residue on the polymerase. We have shown recently that the formation of this RNP complex in an avian hepadnavirus, the duck hepatitis B virus, depends on cellular factors that include the heat shock protein 90 (Hsp90). We now report that RNP formation also requires ATP hydrolysis and the function of p23, a recently identified chaperone partner for Hsp90. Furthermore, we also provide evidence that the chaperone complex is incorporated into the viral nucleocapsids in a polymerase-dependent reaction. Based on these findings, we propose a model for hepadnavirus assembly and priming of viral DNA synthesis where a dynamic, energy-driven process, mediated by a multi-component chaperone complex consisting of Hsp90, p23 and, potentially, additional factors, maintains the reverse transcriptase in a specific conformation that is competent for RNA packaging and protein priming of viral DNA synthesis.
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PMID:Hepadnavirus assembly and reverse transcription require a multi-component chaperone complex which is incorporated into nucleocapsids. 900 68

The ribonucleoprotein enzyme telomerase adds telomeric DNA to chromosomal ends. In most eukaryotes the telomeric repeat units are repeated precisely, consistent with the action of a telomerase that faithfully copies its RNA template. In contrast, Saccharomyces cerevisiae telomeric repeats are degenerate, suggesting that its telomerase has unusual mechanistic properties. We mutated the S. cerevisiae telomerase RNA (TLC1) with a series of 3-base (GUG) substitutions in and next to the 17-nucleotide templating domain. All mutant telomerases were active in TLC1/tlc1 diploids and synthesized patterns of mixed wild-type and mutant telomeric repeats into telomeric DNA, consistent with nonprocessive action. Telomerase isolated from cells containing each mutated tlc1 allele by itself had altered reaction properties in vitro. One mutant template enzyme, 476GUG, was active in vivo and in vitro in the presence of wild-type TLC1 RNA but lacked detectable activity in its absence. Haploid tlc1-476GUG cells containing only this mutant tlc1 allele underwent senescence. Other tlc1 template region mutations allowed maintenance of shortened telomeres in vivo but altered specific enzymatic properties of telomerase in vitro, including induction of primer-template slippage (472GUG) or alteration of the 5' boundary of the template (467GUG). These data demonstrate that telomerase RNA bases influence enzyme activity profoundly, suggesting that their roles are not confined to serving simply as the template for this specialized reverse transcriptase.
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PMID:Telomerase RNA mutations in Saccharomyces cerevisiae alter telomerase action and reveal nonprocessivity in vivo and in vitro. 904 65

Telomerase is a ribonucleoprotein enzyme essential for the replication of chromosome termini in most eukaryotes. Telomerase RNA components have been identified from many organisms, but no protein component has been demonstrated to catalyze telomeric DNA extension. Telomerase was purified from Euplotes aediculatus, a ciliated protozoan, and one of its proteins was partially sequenced by nanoelectrospray tandem mass spectrometry. Cloning and sequence analysis of the corresponding gene revealed that this 123-kilodalton protein (p123) contains reverse transcriptase motifs. A yeast (Saccharomyces cerevisiae) homolog was found and subsequently identified as EST2 (ever shorter telomeres), deletion of which had independently been shown to produce telomere defects. Introduction of single amino acid substitutions within the reverse transcriptase motifs of Est2 protein led to telomere shortening and senescence in yeast, indicating that these motifs are important for catalysis of telomere elongation in vivo. In vitro telomeric DNA extension occurred with extracts from wild-type yeast but not from est2 mutants or mutants deficient in telomerase RNA. Thus, the reverse transcriptase protein fold, previously known to be involved in retroviral replication and retrotransposition, is essential for normal chromosome telomere replication in diverse eukaryotes.
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PMID:Reverse transcriptase motifs in the catalytic subunit of telomerase. 928 Oct 66

Hepatitis B viruses (HBVs) replicate by reverse transcription of an RNA intermediate. Packaging of this RNA pregenome into nucleocapsids and replication initiation depend crucially on the interaction of the reverse transcriptase, P protein, with the cis-acting, 5' end-proximal encapsidation signal epsilon. The overall secondary structure is similar in all of the hepadnaviral epsilon signals, with a lower and an upper stem, separated by a bulge, and an apical loop. However, while epsilon is almost perfectly conserved in all mammalian viruses, the epsilon signals of duck HBV (DHBV) and heron HBV (D epsilon and H epsilon, respectively) differ substantially in their upper stem regions, both in primary sequence and in secondary structure; nonetheless, H epsilon interacts productively with DHBV P protein, as shown by its ability to stimulate priming, i.e., the covalent attachment of a deoxynucleoside monophosphate to the protein. In this study, we extensively mutated the variable and the conserved positions in the upper stem of D epsilon and correlated the functional activities of the variant RNAs in a priming assay with secondary structure and physical P protein binding. These data revealed a proper overall structure, with the bulge and certain key residues, e.g., in the loop, being important constraints in protein binding. Many mutations at the evolutionarily variable positions complied with these criteria and yielded priming-competent RNAs. However, most mutants at the conserved positions outside the loop were defective in priming even though they had epsilon-like structures and bound to P protein; conversely, one point mutant in the loop with an apical structure different from those of D epsilon and H epsilon was priming competent. These results suggest that P protein binding can induce differently structured epsilon RNAs to adopt a new, common conformation, and they support an induced-fit model of the epsilon-P interaction in which both components undergo extensive structural alterations during formation of a priming-competent ribonucleoprotein complex.
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PMID:Sequence- and structure-specific determinants in the interaction between the RNA encapsidation signal and reverse transcriptase of avian hepatitis B viruses. 918 60

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