Topoisomerase II in multiple drug resistance

Abstract

Topoisomerase II is a target of alkaloid, anthracycline and related antitumor agents. Two types of multiple drug resistance are associated with these enzymes. In classical (typical) multidrug resistance, inhibitors are actively effluxed from cells by P-glycoprotein. In atypical multidrug resistance, topoisomerase II is either reduced in cellular content or mutated to a form that does not interact with inhibitors. Because cytotoxicity of most antineoplastic topoisomerase II inhibitors is directly related to the number of active topoisomerase II molecules, a reduction in this number leads to resistance. In the topoisomerase II mechanism, through which the DNA linking number is altered, DNA double strands are cleaved, and the termini transiently bound covalently (5′) or noncovalently (3′) to the enzyme while a second double strand is passed through the break in the first. This transition state complex then decays to enzyme and DNA of altered linking number. Most cytotoxic topoisomerase II inhibitors stabilize these reaction intermediates as ternary complexes, which are converted to lethal lesions when cells attempt to utilize the damaged DNA as templates. Toxicity is related to topoisomerase II content as well as to drug concentration. Thus, multidrug resistance results from either 1) decreasing cellular content of the inhibitor by P-glycoprotein (typical) or 2) decreasing cellular content and/or activity of the target, topoisomerase II, as, for example, when its content or activity is modulated downward by decreased expression, deactivation, or by mutations to the TopII gene, producing an enzyme that reacts poorly with inhibitors (atypical). Mixed types,i.e., both typical and atypical, are known. Attempts to abrogate or prevent both typical and atypical multidrug resistance to topoisomerase II inhibitors have been described.