Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.7 (DNA polymerase)
 17,007 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The in vitro accuracy of DNA replication has been investigated through the measurement of the frequency with which noncomplementary nucleotides were incorporated during polynucleotide replication. The effect of beta-propiolactone treatment of deoxynucleotide templates, ribopolynucleotide templates, and the DNA polymerase from avian myeloblastosis virus was determined. Treatment of the deoxynucleotide template, poly(dA) (see article) oligo(dT) 12-18, by beta-propiolactone resulted in an increased frequency of noncomplementary nucleotide incorporation during DNA polymerization. Carcinogen treatment of the ribonucleotide templates, poly(rA) (see article) oligo(dT) 12-18, and poly(rC) (see article) oligo(dG) 12-18, and carcinogen treatment of avian myeloblastosis virus DNA polymerase did not alter the frequency of noncomplementary nucleotide incorporation. This suggested that carcinogen-induced error incorporation during DNA synthesis was restricted solely to the treatment of a deoxynucleotide template.
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PMID:Restriction of carcinogen-induced error incorporation during in vitro DNA synthesis. 126 Jul 50

Carcinogen-induced expression of the integrated viral genome was examined on SV40-transformed Chinese hamster cells. Carcinogen treatment markedly increased the transcription rate and the steady state mRNA level of both early and late viral transcripts. Carcinogen-induced transcription was mediated by RNA polymerase II. The increase in viral gene expression was also detected at the protein level, although at a reduced amplitude. Enhanced transcription was apparent as early as 12 hr postexposure and was considerably elevated after 24-36 hr. The increased gene expression depended on the existence of a functional replication machinery, as indicated by two lines of evidence. First, a cell line that harbors origin-deleted SV40 failed to respond to carcinogen treatment by increasing transcription and expression of T antigen. Furthermore, carcinogen-induced overtranscription was inhibited by aphidicolin, an inhibitor of DNA polymerase alpha. The involvement of the replication apparatus in the enhanced expression points to mechanistic similarities between the carcinogen-induced viral gene expression in the drug-treated semipermissive cells and the SV40 lytic pathway under permissive conditions. It is therefore suggested that cellular permissivity to viral development is enhanced following exposure to carcinogens. The implications of these findings for the nature of cellular permissivity to viral infection and the synergistic effects of carcinogens and tumor viruses are discussed.
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PMID:Carcinogen-induced activation of SV40 gene expression in a semi-permissive environment. 132 84

Exposure to chemical carcinogens provides a means for the enhancement of the frequency of gene amplification and for the facilitation of research into its mechanism(s). Using carcinogen-induced SV40 amplification as a model system it was shown that amplification of the viral sequences occurs via a replication-dependent mode. This process involves overactivation of the origin region and the generation of inverted repeats. Carcinogen-induced enhancement of gene amplification is triggered by cellular factors that could act in trans. An in vitro amplification system, based on extracts from carcinogen-treated cells and SV40 template sequences, was used to further characterize the amplification intermediates. The major products of overreplication in this system consist of sequences derived from the origin region. Our studies suggest that the ability to overreplicate the origin region in vitro derives from the combined action of carcinogen-induced factors that trigger overinitiation, with the inherent inability of Chinese hamster cell extracts to fully replicate large plasmid templates. The newly replicated sequences are not associated with the parental molecule and contain hairpin or stem and loop structures. Based on these findings we propose a novel replicative mechanism for DNA amplification that allows the de novo formation of hairpin structures. According to this model, an obstruction of the replication fork may cause an overturning of the DNA polymerase, followed by a template switch that leads to the use of the newly replicated strand as a template. This mode of replication results in the generation of hairpin structures which can function as precursors for the duplicated inverted repeats which are commonly observed in amplified genomes. This model is supported by our in vitro and in vivo studies. The relevance of this model for the amplification of cellular sequences is discussed.
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PMID:The mechanism of carcinogen-induced DNA amplification: in vivo and in vitro studies. 137 26