Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.1.30.2 (endonuclease)
 18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A series of cell lines derived from Chinese hamster V79 cells by selection in increasing concentrations of Adriamycin (ADRM) was developed to study the mechanisms of drug resistance and its relationship to radiation response. Survival studies revealed that selection in increasingly higher concentrations of ADRM positively correlated with increased cellular drug resistance. Increased cellular resistance correlated positively with amplification of the hamster multidrug-resistance gene (pgp 1) as detected with dot blot analysis using the pCHP1 probe. Southern blot analysis of restriction endonuclease digested DNA (Eco RI, Hind III, Pst I, or Bam HI) showed that (1) some fragments were preferentially amplified compared to others in the ADRM-resistant lines; and (2) no major gene rearrangement appeared to have occurred during the selection for greater ADRM resistance. Levels of pgp 1 gene expression assayed with dot blot and Northern analysis showed a parallel increase of mRNA with gene amplification and increased ADRM resistance. The amounts of the pgp 1 gene product, P-glycoprotein (P-gp), in the cell membrane of the ADRM-resistant cells correlated with the amount of gene amplification/expression. However, levels of P-gp only correlated with degree of drug resistance as measured by cell survival in earlier selection stages (77A and LZ-3). In later selection stages (LZ-8 and LZ-24), higher levels of ADRM resistance were achieved but levels of P-gp did not increase beyond approximately 20% of plasma membrane proteins. These results suggest that (1) the LZ cell plasma membrane may have a physical limit as to the amount of P-gp it can accommodate and/or there is a cellular mechanism for regulating the amount of P-gp in the plasma membrane, and (2) additional resistance mechanisms are present in LZ-8 and LZ-24 cells. Microscopic observations of intracellular drug distribution in these cell lines revealed that (1) ADRM appeared to be sequestered in cytoplasmic vesicles, and (2) the amount of sequestration (number of vesicles) exhibited correlated with the degree of drug resistance attained by the cell lines. These results suggest that drug sequestration is another mechanism of resistance in LZ cells in addition to P-gp-mediated drug efflux.
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PMID:Characterization of adriamycin-resistant and radiation-sensitive Chinese hamster cell lines. 136 Feb 13

The anthracycline antineoplastic agents Adriamycin and N-trifluoroacetyl-Adriamycin-14-valerate were assayed in vivo and in vitro for ability to produce DNA lesions recognized by the UVRABC endonuclease, a DNA repair enzyme of Escherichia coli which recognizes large, bulky lesions in DNA. We found that, while both drugs produce DNA lesions, only the lesions produced by Adriamycin were toxic. Hence, anthracycline antineoplastic activity may be related to production of large, bulky lesions in DNA, while toxicity may correlate with toxicity measured in a simple E. coli DNA repair mutant test system.
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PMID:Interactions of the UVRABC endonuclease in vivo and in vitro with DNA damage produced by antineoplastic anthracyclines. 637 70

The p53 tumor suppressor protein is involved in apoptosis and cell cycle checkpoints. We have shown recently that p53 also facilitates base excision repair (BER). To further examine p53 involvement in the regulation of BER we chose to focus on 3-methyladenine DNA glycosylase (3-MeAde DNA glycosylase), the first enzyme acting in the BER pathway. 3-MeAde DNA glycosylase activity was found to be modulated by the p53 protein. This modulation was dependent on the type of genotoxic stress used. Gamma-irradiation damage resulted in activation of glycosylase, which was enhanced by p53. Doxorubicin and hydrogen peroxide (H2O2) treatment, although inducing p53 stabilization, did not cause the activation of glycosylase. Nitric oxide (NO) resulted in activation of 3-MeAde DNA glycosylase. Surprisingly this activation was down regulated by wild-type p53. The down regulation of 3-MeAde DNA glycosylase activity was due to trans repression of glycosylase mRNA by p53. Furthermore, we found that AP endonuclease (APE) activity was not altered by NO. Our study provides evidence for a possible antimutagenic role for p53 following exposure of cells to NO species. In the absence of p53, NO exposure results in elevation of 3-MeAde DNA glycosylase activity that results in elevation in the number of AP sites in DNA. At the same time, APE activity does not rise and removal of the AP sites is not further processed resulting in a mutator phenotype. When p53 is present, it down regulates the transcription of 3-MeAde DNA glycosylase. This provides a new model by which p53 prevents the creation of a mutator phenotype.
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PMID:The role of p53 in base excision repair following genotoxic stress. 1455 12

Multidrug resistance following initial chemotherapy is commonly associated with MDR1 gene encoding for P-glycoprotein (P-gp). RNA interference of MDR1 gene expression was used as a strategy to reverse MDR1-mediated multidrug resistance phenotypes. Here we report that endonuclease-prepared small interfering RNA (esiRNA) at concentrations as low as 10 ng/ml (about 0.7 nM) can decrease MDR1 expression and increase chemosensitivity in the Adriamycin-induced resistant MCF-7/R cells. When MCF-7/R cells were transiently transfected with esiRNA of MDR1 (esiMDR1), the MDR1 mRNA was reduced by about 50%, drug accumulation increased by about 30%, and the IC50 for daunorubicin was reduced from 4.5 to 1.2 microM. These results provide evidence that esiRNA of MDR1 could be an alternative to P-gp inhibitors with the advantage of avoiding non-specific suppression with a lower effective dosage than using a single siRNA duplex, offering a potential therapeutic application of siRNA.
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PMID:Reversal of MDR1 gene-dependent multidrug resistance using low concentration of endonuclease-prepared small interference RNA. 1656 22

In this study, Cas9 system was employed to down-regulate mdr1 gene for overcoming multidrug resistance of cancer cells. Disruption of the MDR1 gene was achieved by delivery of the Cas9-sgRNA plasmid or the Cas9-sgRNA ribonucleoprotein complex using a conventional gene transfection agent and protein transduction domain (PTD). Doxorubicin showed considerable cytotoxicity to the drug-resistant breast cancer cells pre-treated with the RNA-guided endonuclease (RGEN) systems, whereas virtually non-toxic to the untreated cells. The potency of drug was enhanced in the cells treated with the protein-RNA complex as well as in those treated with plasmids, suggesting that mutation of the mdr1 gene by intracellular delivery of Cas9-sgRNA complex using proper protein delivery platforms could recover the drug susceptibility. Therefore, Cas9-mediated disruption of the drug resistance-related gene can be considered as a promising way to overcome multidrug resistance in cancer cells.
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PMID:Overcoming doxorubicin resistance of cancer cells by Cas9-mediated gene disruption. 2696 1