The catalytic activities of DNA topoisomerase II are most closely associated with the DNA cleavage/religation steps.

DNA topoisomerase II regulates the three-dimensional organisation of DNA and is the principal target of many important anticancer and antimicrobial agents. These drugs usually act on the DNA cleavage/religation steps of the catalytic cycle resulting in accumulation of covalent DNA-topoisomerase II complexes. We have studied the different steps of the catalytic cycle as a function of salt concentration, which is a classical way to evaluate the biochemical properties of proteins. The results show that the catalytic activity of topoisomerase II follows a bell-shaped curve with optimum between 100 and 225 mM KCl. No straight-forward correlation exists between DNA binding and catalytic activity. The highest levels of drug-induced covalent DNA-topoisomerase II complexes are observed between 100 and 150 mM KCl. Remarkably, at salt concentrations between 150 mM and 225 mM KCl, topoisomerase II is converted into a drug-resistant form with greatly reduced levels of drug-induced DNA-topoisomerase II complexes. This is due to efficient religation rather than to absence of DNA cleavage as witnessed by relaxation of the supercoiled DNA substrate. In the absence of DNA, ATP hydrolysis is strongest at low salt concentrations. Unexpectedly, the addition of DNA stimulates ATP hydrolysis at 100 and 150 mM KCl, but has little or no effect below 100 mM KCl in spite of strong non-covalent DNA binding at these salt concentrations. Therefore, DNA-stimulated ATP hydrolysis appears to be associated with covalent rather than non-covalent binding of DNA to topoisomerase II. Taken together, the results suggest that it is the DNA cleavage/religation steps that are most closely associated with the catalytic activities of topoisomerase II providing a unifying theme for the biological and pharmacological modulation of this enzyme.