Diazenes as modificators of drug-resistance in tumor cells.

To overcome the drug resistance, which is the major obstacle in the successful treatment of cancer patients, various compounds have been tested. Glutathione is one of the most promising targets for modulation. In the present study, we examined the influence of five new synthesized compounds--diazenes on the reduction of the intracellular level of GSH. Further, we investigated their ability to increase the cytotoxicity of cisplatin, vincristine and doxorubicin. In experiments human parental cervical (HeLa) and laryngeal (HEp2) carcinoma cells and their drug-resistant cell sublines (HeLaCA and CK2, respectively) were used. Intracellular GSH content was examined spectrophotometrically by the procedure developed by Tietze. The cell sensitivity to drugs was determined using a modified colorimetric MTT assay. Results showed that the rate of reduction of GSH concentration was dependent on the cell type and the type of diazenes. We did not find a correlation between the reduction in GSH level and increased cytotoxicity to selected anticancer drugs. Nevertheless, we found that: a) diazenes LV-35 and VZ-19 increased the cytotoxicity of cisplatin in HEp2 cells, b) diazene MG-19 potentiated the cytotoxicity of vincristine in HEp2 cells, and c) diazene VZ-19 in HeLaCA cells. These data suggest that specific combination of diazene and anticancer drug may be useful in the treatment of certain tumor types.

Diazenes: modificators of tumor cell resistance to cisplatin.

Most studies indicate that modulation of glutathione metabolism may be one of the most promising means of reversing clinical drug resistance. Five new diazene compounds have been synthesized: JK-279, JK-835, JK-913, JK-925 and LV-57 that should, according to their structure and biochemical properties, lower the GSH concentration. In the present study, we examined the influence of diazenes on cisplatin resistance in human cervical (HeLa) and laryngeal carcinoma (HEp2) cells as well as in their cisplatin-resistant sublines (HeLaCA and CK2, respectively). Intracellular GSH content was examined spectrophotometrically by the procedure developed by Tietze. The cell sensitivity to drugs was determined using a modified colorimetric MTT assay. Results show that all examined diazenes lowered GSH concentration. This decrease was insignificant for JK-835 and JK-925 in HeLa and HeLaCA cells, and JK-925 in CK2 cells. In human cervical carcinoma HeLa and HeLaCA cells, JK-279 was mostly active in sensitizing the cells to cisplatin, especially in drug-resistant cells. JK-913, JK-835 and LV-57 reverted partially resistance to cisplatin in HEp2 cells, while none of the diazenes was active in CK2 cells. In conclusion, diazene JK-279 may be useful in the combined treatment (cisplatin + diazene) for the certain type of cancer.

Diazene JK-279: potential anticancer drug.

The aim of this study was to examine the cytotoxic effect of 10 newly synthesized diazenecarboxamides (diazenes). Using a modified colorimetric MTT assay, their cytotoxicity was determined on 10 human cell lines: cervical carcinoma parental and cisplatin-resistant cells, laryngeal carcinoma parental and cisplatin- and vincristine-resistant cells, glioblastoma parental and cisplatin-resistant cells, breast adenocarcinoma parental and doxorubicin-resistant cells, and mammary carcinoma cells. Results show that diazene JK-279 was most effective, reducing significantly the cell survival of all 10 cell lines examined, including five drug-resistant cell lines. A cytotoxic effect was observed also on nine from 10 cell lines for diazene JK-835. A small reduction in cell survival was obtained (mainly for highest drug concentrations) for diazenes LV-57 and MG-19 on two cell lines, and JK-429 and JK-913 on one cell line. Other diazenes did not demonstrate any cytotoxic activity. The results encourage further research on diazene JK-279 as a potential anticancer drug.