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Vol. 60, Issue 3, 559-567, September 2001
B
Department of Pharmacology, The George Washington University
Medical Center, Washington, DC
Physiological stress conditions associated with the tumor
microenvironment play a role in resistance to anticancer therapy. In
this study, treatment of EMT6 mouse mammary tumor cells with hypoxia or
the chemical stress agents brefeldin A (BFA) or okadaic acid (OA)
causes the development of resistance to the topoisomerase II inhibitor
etoposide. The mechanism of physiological stress-induced drug
resistance may involve the activation of stress-responsive proteins and
transcription factors. Our previous work shows that treatment with BFA
or OA causes activation of the nuclear transcription factor NF-
B.
Pretreatment with the proteasome inhibitor
carbobenzyoxyl-leucinyl-leucinyl-leucinal inhibits stress-induced
NF-B activation and reverses BFA-induced drug resistance. To test
whether NF-B specifically mediates stress-induced drug resistance,
an inducible phosphorylation site-deficient mutant of IB
(IBM, S32/36A) was introduced into EMT6 cells. In this study, we
show that IBM expression inhibits stress-induced NF-B activation and prevents BFA-, hypoxia-, and OA-induced resistance to
etoposide. These results indicate that NF-B activation mediates both
chemical and physiological drug resistance to etoposide. Furthermore,
they imply that coadministration of agents that inhibit NF-B may
enhance the efficacy of topoisomerase II inhibitors in clinical cancer chemotherapy.
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