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)

We surveyed the occurrence of unique restriction sites on the cDNAs of viroids, virusoids, and plant viral satellite RNAs that have a circular RNA as an intermediate of replication and found that four such sites would linearize their circular cDNAs. A rapid and simple method was then developed for cloning a naturally occurring viroid from Nematanthus wettsteinii plants. First-strand cDNA was synthesized using random hexanucleotide DNA primers and M-MuLV reverse transcriptase (Superscript RT). Second-strand DNA was synthesized by employing the replacement synthesis method using Escherichia coli RNase H, E. coli DNA polymerase I, E. coli DNA ligase, and beta-NAD+. The circular double-stranded DNA was analyzed for the presence of commonly available, unique restriction sites and subsequently linearized with a selected restriction enzyme. The linear cDNA was ligated to dephosphorylated plasmid vector pGEM 3Z f(+) and cloned in E. coli strain DH5 alpha. This cDNA cloning procedure is suitable for cloning sequence variants of well-characterized viroids, virusoids, certain plant viral satellite RNAs, and new such pathogens of unknown sequence.
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PMID:A rapid and versatile method for cloning viroids or other circular plant pathogenic RNAs. 138 86

Cytosine arabinoside (araC) is a potent antileukemic agent that is misincorporated into DNA in the course of its action. We have developed a chemical synthetic method that allows site-specific introduction of araC into synthetic DNA oligomers. We describe here the utilization of these oligomers as primer/template substrates for in vitro DNA synthesis reactions and as fragments for DNA ligation. These studies were undertaken to investigate the manner in which sites of araC misincorporation constitute sites of DNA dysfunction. AraCMP at the primer terminus dramatically reduced the rate of next nucleotide addition for Escherichia coli polymerase I (Klenow fragment) (Pol I), T4 polymerase, HeLa cell polymerase alpha 2 (Pol alpha 2), and AMV reverse transcriptase. Polymerases with associated 3'-5' exonuclease activity preferentially excised araCMP from the primer terminus prior to chain elongation. AraCMP-terminated fragments were ligated more slowly than control fragments by T4 DNA ligase. AraCMP located at an internucleotide site in the template markedly slowed replicative bypass for Pol I, T4 polymerase, and Pol alpha 2, but not for reverse transcriptase. Synthesis was partially arrested after insertion of the correct nucleotide opposite the lesion site. These results suggest a complex mechanism for the inhibition of DNA replication by araC when it is misincorporated into DNA.
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PMID:Functional consequences of the arabinosylcytosine structural lesion in DNA. 245 56

We have developed a technique for synthesis of single stranded complementary DNA (ss cDNA) using specifically designed phage ssDNA as vector primer. This vector (pPBS27) was constructed by introducing a poly(dT) tail adjacent to the XbaI site of pTZ18R, which can exist either as a plasmid in Escherichia coli or as a ssDNA phage. The pPBS27 phage vector is linearized with XbaI using a restriction-site-directed fragment and used to anneal a mixture of poly(A) + RNA for cDNA synthesis by reverse transcriptase. The RNA is then hydrolysed with NaOH and a poly(dG) tail added to the 3' end of the vector-cDNA with terminal transferase. The linear hybrid ssDNA is then closed by annealing with a 15-mer site-directed fragment oligodeoxynucleotide molecule and ligated with T4 DNA ligase. Almost 10(5) E. coli transformants per microgram of vector primer can be obtained in two days.
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PMID:Use of a phage vector for rapid synthesis and cloning of single-stranded cDNA. 303 56

We have developed conditions for efficient cDNA cloning of nanogram amounts of purified mRNAs coding for cystathionine beta-synthase [L-serine hydro-lyase (adding homocysteine), EC 4.2.1.22] and for the cytosolic precursors of mitochondrial ornithine transcarbamylase (carbamoylphosphate:L-ornithine carbamoyltransferase, EC 2.1.3.3) and the beta subunit of propionyl-CoA carboxylase [propanoyl-CoA: carbon-dioxide ligase (ADP-forming), EC 6.4.1.3]. The three mRNAs, prepared by sequential immunoselection from the same batch of rat liver polysomes, were pooled (20 ng each), and cDNA was synthesized by using avian reverse transcriptase. The second DNA strand was prepared by "nick-translation repair" of the cDNA . mRNA hybrid with RNase H, polymerase I, and DNA ligase from Escherichia coli. The double-stranded (ds) DNA was tailed with deoxycytidine residues, annealed with Pst I-cut/dG-tailed pBR322, and used to transform E. coli. The library generated by this three-step procedure contained 5000 independent colonies. A 550-base-pair (bp) cDNA clone of the beta subunit of propionyl-CoA carboxylase was detected by hybrid-selected translation; it was then used to screen the library for longer cDNAs. Two hybridizing cDNAs, 1200 and 1000 bp long with a 200-bp overlap, representing together a full-length copy of the coding region and 446 bp of 3' untranslated sequence, were recovered. Each plasmid mapped to the region q13.3----q22 of human chromosome 3. Cystathionine beta-synthase clones were obtained by screening the library with a single-stranded [32P]cDNA prepared directly from the highly purified synthase mRNA by reverse transcriptase. The longest hybridizing cDNA of 1700 bp was used in hybrid-selected translation and detected a polypeptide of 63 kDa, identical in size to rat liver synthase. In situ hybridization of this cDNA to q22 of human chromosome 21 confirmed two previous tentative assignments of the synthase locus to this chromosome.
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PMID:Cloning and screening with nanogram amounts of immunopurified mRNAs: cDNA cloning and chromosomal mapping of cystathionine beta-synthase and the beta subunit of propionyl-CoA carboxylase. 345 73

We describe a simple method for joining the 5'-protruding, single-stranded DNA ends generated by restriction enzymes. The method allows ends with different sequences to be joined and prevents identical ends from being joined. This is accomplished by partially filling the single strands in a controlled reverse transcriptase reaction. Partial filling can create new single-stranded ends that can be ligated to different, partially filled ends. In almost all useful cases, partial filling simultaneously eliminates the self-complementarity of identical ends and thus prevents them from being joined by DNA ligase. Although all possible combinations of partially filled ends were not tested, the tests performed indicate that the method is fairly general. We demonstrate that ends of the same length can be ligated with useful efficiency if they are: 1) one nucleotide long and complementary; 2) two nucleotides long and complementary or have a mismatch (dA:dC) at one position; or 3) three nucleotides long and, in our test, have a dT:dC mismatch at the middle position.
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PMID:Different restriction enzyme-generated sticky DNA ends can be joined in vitro. 619 44

DNA amplification systems are powerful technologies with the potential to impact a wide range of diagnostic applications. In this study we explored the feasibility and limitations of a modified ligase chain reaction (Gap-LCR) in detection and discrimination of DNAs that differ by a single base. LCR is a DNA amplification technology based on the ligation of two pairs of synthetic oligonucleotides which hybridize at adjacent positions to complementary strands of a target DNA. Multiple rounds of denaturation, annealing and ligation with a thermostable ligase result in the exponential amplification of the target DNA. A modification of LCR, Gap-LCR was developed to reduce the background generated by target-independent, blunt-end ligation. In Gap-LCR, DNA polymerase fills in a gap between annealed probes which are subsequently joined by DNA ligase. We have designed synthetic DNA targets with single base pair differences and analyzed them in a system where three common probes plus an allele-specific probe were used. A single base mismatch either at the ultimate 3' end or penultimate 3' end of the allele specific probe was sufficient for discrimination, though better discrimination was obtained with a mismatch at the penultimate 3' position. Comparison of Gap-LCR to allele-specific PCR (ASPCR) suggested that Gap-LCR has the advantage of having the additive effect of polymerase and ligase on specificity. As a model system, Gap-LCR was tested on a mutation in the reverse transcriptase gene of HIV, specifically, one of the mutations that confers AZT resistance. Mutant DNA could be detected and discriminated in the presence of up to 10,000-fold excess of wild-type DNA.
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PMID:Detection of point mutations with a modified ligase chain reaction (Gap-LCR). 753 8

DNA topoisomerase I (topo I) is a member of a group of essential nuclear enzymes which control and modify the topological state of DNA and is recognized as the target for anticancer drugs. During the course of the catalytic activity of topo I, a covalent bond is formed between a tyrosine group at the active site of the enzyme and a 3' phosphate group along the DNA backbone. This chemical reaction resembles the protein kinase-mediated tyrosine phosphorylation process. We assumed, therefore, that tyrphostins, potent and selective blockers of protein tyrosine kinases, might affect topo I activity. We found that of three derivatives of tyrphostins (AG-555, AG-18, and AG-213) that inhibited topo I activity in an in vitro assay, AG-555 was the most active. Examination of the mechanism by which these compounds act as topo I inhibitors revealed that AG-555 blocked the binding of this enzyme to the DNA due to its interaction with the topo I enzyme. We showed that its mode of action differed from that observed for camptothecin, a known topo I inhibitor. However, AG-555 did not affect the activity of other major DNA binding enzymes (i.e., DNA ligase, DNA polymerase I, and reverse transcriptase). This study suggests that tyrphostins may serve as a new class of topo I inhibitors, and these results also present additional explanations for their antiproliferative effect.
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PMID:Inhibition of topoisomerase I activity by tyrphostin derivatives, protein tyrosine kinase blockers: mechanism of action. 792 31

The family Poxviridae contains two subfamilies: the Entomopoxvirinae (poxviruses of insects) and the Chordopoxvirinae (poxviruses of vertebrates). Here we present the first characterization of the genome of an entomopoxvirus (EPV) which infects the North American migratory grasshopper Melanoplus sanguinipes and other important orthopteran pests. The 236-kbp M. sanguinipes EPV (MsEPV) genome consists of a central coding region bounded by 7-kbp inverted terminal repeats and contains 267 open reading frames (ORFs), of which 107 exhibit similarity to previously described genes. The presence of genes not previously described in poxviruses, and in some cases in any other known virus, suggests significant viral adaptation to the arthropod host and the external environment. Genes predicting interactions with host cellular mechanisms include homologues of the inhibitor of apoptosis protein, stress response protein phosphatase 2C, extracellular matrixin metalloproteases, ubiquitin, calcium binding EF-hand protein, glycosyltransferase, and a triacylglyceride lipase. MsEPV genes with putative functions in prevention and repair of DNA damage include a complete base excision repair pathway (uracil DNA glycosylase, AP endonuclease, DNA polymerase beta, and an NAD+-dependent DNA ligase), a photoreactivation repair pathway (cyclobutane pyrimidine dimer photolyase), a LINE-type reverse transcriptase, and a mutT homologue. The presence of these specific repair pathways may represent viral adaptation for repair of environmentally induced DNA damage. The absence of previously described poxvirus enzymes involved in nucleotide metabolism and the presence of a novel thymidylate synthase homologue suggest that MsEPV is heavily reliant on host cell nucleotide pools and the de novo nucleotide biosynthesis pathway. MsEPV and lepidopteran genus B EPVs lack genome colinearity and exhibit a low level of amino acid identity among homologous genes (20 to 59%), perhaps reflecting a significant evolutionary distance between lepidopteran and orthopteran viruses. Divergence between MsEPV and the Chordopoxvirinae is indicated by the presence of only 49 identifiable chordopoxvirus homologues, low-level amino acid identity among these genes (20 to 48%), and the presence in MsEPV of 43 novel ORFs in five gene families. Genes common to both poxvirus subfamilies, which include those encoding enzymes involved in RNA transcription and modification, DNA replication, protein processing, virion assembly, and virion structural proteins, define the genetic core of the Poxviridae.
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PMID:The genome of Melanoplus sanguinipes entomopoxvirus. 984 59

Model oligodeoxyribonucleotide substrates representing viral DNA integration intermediates with a gap and a two-nucleotide 5' overhang were used to examine late steps in human immunodeficiency virus, type 1 (HIV-1) retroviral integrase (IN)-catalyzed DNA integration in vitro. HIV-1 or avian myeloblastosis virus reverse transcriptase (RT) were capable of quantitatively filling in the gap to create a nicked substrate but did not remove the 5' overhang. HIV-1 IN also failed to remove the 5' overhang with the gapped substrate. However, with a nicked substrate formed by RT, HIV-1 IN removed the overhang and covalently closed the nick in a disintegration-like reaction. The efficiency of this closure reaction was very low. Such closure was not stimulated by the addition of HMG-(I/Y), suggesting that this protein only acts during the early processing and joining reactions. Addition of Flap endonuclease-1, a nuclease known to remove 5' overhangs, abolished the closure reaction catalyzed by IN. A series of base pair inversions, introduced into the HIV-1 U5 long terminal repeat sequence adjacent to and/or including the conserved CA dinucleotide, produced no or only a small decrease in the HIV-1 IN-dependent strand closure reaction. These same mutations caused a significant decrease in the efficiency of concerted DNA integration by a modified donor DNA in vitro, suggesting that recognition of the ends of the long terminal repeat sequence is required only in the early steps of DNA integration. Finally, a combination of HIV-1 RT, Flap endonuclease-1, and DNA ligase is capable of quantitatively forming covalently closed DNA with these model substrates. These results support the hypothesis that cellular enzyme(s) may catalyze the late steps of retroviral DNA integration.
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PMID:Modeling the late steps in HIV-1 retroviral integrase-catalyzed DNA integration. 1100 85

The findings presented here originally arose from the suggestion that the synthesis of dinucleoside polyphosphates (Np(n)N) may be a general process involving enzyme ligases catalyzing the transfer of a nucleotidyl moiety via nucleotidyl-containing intermediates, with release of pyrophosphate. Within this context, the characteristics of the following enzymes are presented. Firefly luciferase (EC 1.12. 13.7), an oxidoreductase with characteristics of a ligase, synthesizes a variety of (di)nucleoside polyphosphates with four or more inner phosphates. The discrepancy between the kinetics of light production and that of Np(n)N synthesis led to the finding that E*L-AMP (L = dehydroluciferin), formed from the E*LH(2)-AMP complex (LH(2) = luciferin) shortly after the onset of the reaction, was the main intermediate in the synthesis of (di)nucleoside polyphosphates. Acetyl-CoA synthetase (EC 6.2.1.1) and acyl-CoA synthetase (EC 6.2.1. 8) are ligases that synthesize p(4)A from ATP and P(3) and, to a lesser extent, Np(n)N. T4 DNA ligase (EC 6.5.1.1) and T4 RNA ligase (EC 6.5.1.3) catalyze the synthesis of Np(n)N through the formation of an E-AMP complex with liberation of pyrophosphate. DNA is an inhibitor of the synthesis of Np(n)N and conversely, P(3) or nucleoside triphosphates inhibit the ligation of a single-strand break in duplex DNA catalyzed by T4 DNA ligase, which could have therapeutic implications. The synthesis of Np(n)N catalyzed by T4 RNA ligase is inhibited by nucleoside 3'(2'),5'-bisphosphates. Reverse transcriptase (EC 2.7.7.49), although not a ligase, catalyzes, as reported by others, the synthesis of Np(n)ddN in the process of removing a chain termination residue at the 3'-OH end of a growing DNA chain.
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PMID:Synthesis of dinucleoside polyphosphates catalyzed by firefly luciferase and several ligases. 1100 93

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