Parental H1299 Research Articles

The Quinoline-Based Drug,N-{4-[1-hydroxy-2-(dibutylamino)ethyl] quinolin-8-yl}-4-azidosalicylamide, Photoaffinity Labels the Multidrug Resistance Protein (MRP) at a Biologically Relevant Site

MRP is a member of the ABC trafficking proteins thought to mediate the transport of glutathione S-conjugates and amphiphilic natural products. However, unlike P-glycoprotein, the biochemical mechanism by which MRP mediates the resistance to cytotoxic drugs is not clear. In this report, we describe the interactions of a quinoline-based drug, N-{4-[1-hydroxy-2-(dibutylamino)ethyl] quinolin-8-yl}-4-azidosalicylamide (IAAQ), with MRP. Our results demonstrate the ability of IAAQ to photoaffinity label a 190 kDa protein in resistant Small Cell Lung Cancer cells (H69/AR) but not in the parental H69 cells. The photoaffinity labeling of the 190 kDa protein with IAAQ was both saturable and specific. The identity of the 190 kDa protein, as MRP, was confirmed by immunoprecipitation with the monoclonal antibody, QCRL-1. Furthermore, a molar excess of LTC4, MK 571 or vinblastine inhibited the photoaffinity labeling of MRP with IAAQ in intact cells and plasma membranes. Cell growth and drug transport studies showed H69/AR cells to be less sensitive to and to accumulate less IAAQ than the parental H69 cells. In addition, MK 571 and doxorubicin increased the sensitivity to and the accumulation of IAAQ in H69/AR cells. Together, the results of this study show for the first time the direct binding of unaltered cytotoxic drug to MRP. Moreover, given the structural similarities between IAAQ and MK 571, we suggest that MK 571 modulates MRP-mediated resistance by direct binding to MRP.

Characterization of a taxol-resistant human small-cell lung cancer cell line.

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.

Reduced levels of topoisomerase II alpha and II beta in a multidrug-resistant lung-cancer cell line.

We have previously shown that the doxorubicin-selected multidrug-resistant small-cell lung-cancer cell line H69AR is resistant to VP-16-induced single-strand DNA breaks as compared with its parental H69 cell line. Levels of immunoreactive topoisomerase II alpha are also reduced in H69AR cells. In the present study, we found that cleaved complex formation in the presence of VP-16 was decreased in H69AR cells as compared with H69 cells. In addition, the resistant cells contained lower levels of both topoisomerase II alpha and topoisomerase II beta protein and mRNA. However, these changes were not accompanied by a decrease in the P4-unknotting (strand-passing) activity of 0.67 M NaCl nuclear extracts of H69AR cells, nor was there any difference in VP-16 inhibition of unknotting activity in the H69 and H69AR nuclear extracts. These data suggest that reduced levels of topoisomerase II alpha and II beta may contribute to the resistance of H69AR cells to VP-16 and other drugs that target these isoenzymes.