Yasunori Funayama scite author profile

Taxol is a novel anticancer agent with activity against a broad range of tumors. It has a unique ability to stabilize polymerized tubulin into microtubule bundles within the cell. We have established a taxol‐resistant human small‐cell lung cancer cell line (H69/Txl) by exposing H69 cells to stepwise increases in taxol concentration. The resistance of H69/Txl cells to taxol was 4.7‐fold that of the original H69 cells: the IC50 values for H69 and H69/Txl were 113.7 ± 56.54 nM and 538.7 ± 214.7 nM by the tetrazolium dye assay, respectively. Removal of the drug from the medium resulted in a 38% decrease in the growth rate of H69/Txl as compared with that in the presence of 30 nM taxol, suggesting that the growth of H69/Txl was partially dependent on taxol. H69/Txl showed higher sensitivity to vinca alkaloids such as vindesine, vincristine and vinblastine than the parental H69. There was no significant difference in intracellular [3H]taxol content between H69 and H69/Txl cells. No MDR‐1 mRNA was detected in H69/Txl by the reverse transcription polymerase chain reaction. There was no significant difference of total and polymerized tubulin content between H69 and H69/Txl cells. Altered mobility of one of the α‐tubulin isoforms in H69/Txl was revealed by using isoelectric focusing and Western blotting with anti‐α‐tubulin antibody. In H69, two α‐tubulin isoforms were observed, whereas three were evident in H69/Txl, two of them comigrating with the isoforms of H69 and the other being more acidic. We observed the increased acetylation of α‐tubulin in H69/Txl cells as compared with that in H69 cells. The acetylation of α‐tubulin may be responsible for the taxol resistance and/or taxol‐dependent growth of H69/Txl.

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A Novel Antitumor Antibiotic, KW‐2189 Is Activated by Carboxyl Esterase and Induces DNA Strand Breaks in Human Small Cell Lung Cancer Cells

Ogasawara

Nishio

Takeda

et al. 1994

Japanese Journal of Cancer Research

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KW‐2189 has been selected as a lead compound for clinical trial among duocarmycin derivatives with structural similarity to CC‐1065, a cyclopropylpyrroloindole. The purpose of this study was to examine the DNA‐binding potency and the mechanisms of cytotoxicity of KW‐2189. In order to analyze DNA‐binding activity of KW‐2189, plasmid pBR322 was treated with KW‐2189 with or without pretreatment with carboxyl esterase, which we demonstrated to be an activating enzyme, and the products were examined by agarose gel electrophoresis and restriction enzyme analysis. Cytotoxic activity was examined by exposing a human small cell lung cancer cell line, NCI‐H69 to KW‐2189 with or without carboxyl esterase. Alkaline elution was performed to examine whether KW‐2189 induces DNA strand breaks. DNA treated with KW‐2189 and carboxyl esterase migrated faster than KW‐2189‐treated DNA, which migrated at the same rate as untreated DNA. In addition DNA treated with esterase‐activated KW‐2189 was protected from digestion by some restriction enzymes. KW‐2189 showed concentration‐ and time‐dependent growth inhibitory effect with IC50 values (drug concentration required for 50% growth inhibition) of 58 nM (96 h) to 1900 nM (1 h) in H69 cells. The IC50 values of 4‐h exposure of H69 to KW‐2189 with 0, 26, 130, 650 mU/ml carboxyl esterase were 460, 120, 30, and 7 nM, respectively. Time‐dependent enhancement of cytotoxicity by carboxyl esterase was also observed. KW‐2189 induced DNA strand breaks in H69 cells in a concentration‐dependent manner around the IC50 value. We conclude that 1) KW‐2189 is activated by carboxyl esterase to its active form(s), 2) activated KW‐2189 has a stronger DNA‐binding activity and cytotoxicity than KW‐2189, 3) DNA cleavage is one of the major mechanisms of KW‐2189‐mediated cytotoxicity.

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High-level aminoglycoside resistance in Enterococcus faecalis and Enterococcus faecium causing invasive infection: Twelve-year surveillance in the Minami Ibaraki Area

Osuka

Nakajima

Oishi

et al. 2016

Journal of Infection and Chemotherapy

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