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)

Alkylatio of Escherichia coli DNA that have been made permeable to nucleotides by toluene treatment results in the expression of DNA polymerase I-directed repair synthesis. The system only permits measurement of DNA polymerase I-directed repair synthesis. The latter is not observed in mutant cells deficient in this polymerase. DNA ligation is intentionally prevented by the addition of the inhibitor, nicotinamide mononucleotide. MNU, ENU and MMS elicit DNA polymerase I-directed repair synthesis. MNU and MMS are especially potent in this regard, while EMS is a poor inducer of DNA polymerase I activity in permeabilized cells. The natural compound para-aminobenzoic acid itself (0,0002 mM - 20 mM) doesn't induce DNA polymerase I-directed repair synthesis. However, when PABA is used in complex with alkylating agents as the inducers, the repair synthesis increased 2,0, 1,2 and 2,8 times for MNU, ENU and EMS, respectively, as compared to that elicited by "pure" mutagens. The increasing of DNA repair synthesis in permeabilized bacteria in the experiments with PABA may serve as the foundation for its reparagenic activity. The latter was discovered previously by the authors in experiments on mutagenesis of bacterial cells.
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PMID:[Genetic activity of para-aminobenzoic acid. The intensification of DNA polymerase I-dependent repair induced by chemical mutagens in toluene-treated Escherichia coli cells]. 704 62

Genistein, the main isoflavone in soy, has received considerable attention for its potential anti-carcinogenic properties. In a previous report, we investigated the possible role of genistein in anti-mutagenesis, using an Escherichia coli reversion assay system. Genistein reduced ENU-induced mutagenesis in a dose-dependent manner and the reduction of mutation frequency was differential among several categories of mutation. Most notable was a loss of transversion mutations, which require SOS functions. In this report, we further investigated the anti-mutagenic effect of genistein using a genetic approach. E. coli strains having alterations in genes involved in SOS-mutagenesis were examined, as were strains having defects in proteins that might serve as potential targets for genistein. The results showed that ENU-induced mutations produced in recA730 and lexA(Def) strains, both expressing a constitutive SOS response, were reduced by genistein to a lesser extent than in the wild-type strain. The effect of genistein was not entirely abolished, however. ENU mutagenesis in a umuC derivative, which reflects predominantly transition mutations, was unaffected by genistein. ENU-induced mutations in strains having defects in topA, gyrA, typA or uspA were not different than the wild-type, suggesting that these gene products were not involved in genistein's anti-mutagenic effect. In addition, we determined the distribution of genistein in various cellular fractions using HPLC. These studies revealed that genistein could be recovered from E. coli cells grown on agar media containing genistein; the intracellular concentration was similar to that in the agar plates. Further, most of the genistein recovered was associated with proteins in the cytosolic fraction and little partitioned in the membrane fraction. In vitro studies showed that genistein could be precipitated from a protein (BSA) containing solution. Finally, we examined the effect of genistein on formation of the RecA filament on ssDNA in vitro and observed an inhibition at high concentrations of genistein. In total, these results suggested that genistein may reduce SOS-dependent mutagenesis by reducing the interaction of RecA protein with ssDNA. As a consequence, genistein could cause a reduction in (1) the overall SOS response (confirmed using beta-galactosidase assays) and (2) trans-lesion DNA synthesis by DNA polymerase V.
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PMID:Genetic analysis of the anti-mutagenic effect of genistein in Escherichia coli. 1687 40