Learn about the flu shot, COVID-19 vaccine, and our masking policy »
New to MyHealth?
Manage Your Care From Anywhere.
Access your health information from any device with MyHealth. You can message your clinic, view lab results, schedule an appointment, and pay your bill.
ALREADY HAVE AN ACCESS CODE?
DON'T HAVE AN ACCESS CODE?
NEED MORE DETAILS?
MyHealth for Mobile
Get the iPhone MyHealth app »
Get the Android MyHealth app »
Abstract
The cyanomorpholino analog of doxorubicin (MRA-CN) is a potent cytotoxic agent which is known to cross-link DNA. A human ovarian carcinoma cell line, ES-2, was grown in increasing concentrations of MRA-CN from 0.1 to 0.5 nM. The resultant resistant subline, ES-2R, was 4-fold resistant to MRA-CN. DNA damage and repair in response to MRA-CN were compared in the parental and resistant cell lines using alkaline elution. DNA cross-links were detectable after 3-h incubation of the cells at 37 degrees C in MRA-CN at concentrations greater than or equal to 1.0 nM. Paradoxically, 2-fold more cross-links were detected in the ES-2R cells as compared with the ES-2 cells. This paradoxical difference in cross-links between the 2 cell lines was observed to increase with time of exposure to 2.5 nM of MRA-CN. Non-protein-associated DNA strand breaks were also detected in the 2 cell lines after exposure to 2.5 nM of the drug. The ES-2 cells consistently showed twice as many breaks as the ES-2R cells, which could explain the paradoxical higher apparent DNA cross-linking observed with the ES-2R cells after exposure to MRA-CN. Studies of the time course of cross-link repair after exposure to MRA-CN revealed that 75% of the DNA cross-links disappeared in the ES-2R cells by the end of 8 h in drug-free medium. In contrast, cross-links in the ES-2 cells were undetectable after 4 h, which coincided with a progressive increase in DNA strand breaks. The topoisomerase II level in the ES-2 cells was 2- to 4-fold higher than that in the ES-2R cells. However, proteinase K treatment of the lysed cells did not increase the number of apparent strand breaks produced by MRA-CN, suggesting that topoisomerase II may not be involved. These findings indicate that, in addition to DNA cross-linking, MRA-CN causes DNA strand breakage. Resistance to MRA-CN in the ES-2R cells is associated with more apparent DNA cross-linking and less DNA strand breakage, which may be a consequence of differences in DNA repair and/or nonspecific DNA degradation between the resistant and the sensitive cell lines.
View details for Web of Science ID A1990DK78300043
View details for PubMedID 2162251