Abstract
We have prepared full-length Drosophila and human topoisomerase II and truncation constructs containing the amino-terminal ATPase domain, and we have analyzed their biochemical properties. The ATPase activity of the truncation proteins, similar to that of the full-length proteins, is greatly stimulated by the presence of DNA. This activity of the truncation proteins is also sensitive to the inhibition by the drug bisdioxopiperazine, ICRF-193, albeit at a much lower level than the full-length protein. Therefore, bisdioxopiperazine can directly interact with the NH(2)-terminal ATPase domain, but the drug-enzyme interaction may involve other domains as well. The ATPase activity of the ATPase domain protein showed a quadratic dependence on enzyme concentration, suggesting that dimerization of the NH(2)-terminal domain is a rate-limiting step. Using both protein cross-linking and sedimentation equilibrium analysis, we showed that the ATPase domain exists as a monomer in the absence of cofactors but can readily dimerize in the presence of a nonhydrolyzable analog of ATP, 5'-adenylyl-beta,gamma-imidodiphosphate. More interestingly, both ATP and ADP can also promote protein dimerization. This result thus suggests that the protein clamp, mediated through the dimerization of ATPase domain, remains closed after ATP hydrolysis and opens upon the dissociation of ADP.
Highlights
Type II DNA topoisomerases1 are ubiquitous enzymes that catalyze DNA topological changes by transporting one double strand DNA segment through another [1,2,3,4]
The 46-kDa fragment of ATPase domain of human topo II, HsATPD, contains the first 6 amino acid residues of Saccharomyces cerevisiae topo II followed by Ser-29 to Lys-425 of human topo II and a hexahistidine tag (Fig. 1D)
To further investigate the inhibition of eukaryotic topo II by bisdioxopiperazine drugs, we studied the effect of ICRF-193 on the ATPase activities of both human and Drosophila topo II holoenzymes, DmGyrB, and both human and Drosophila ATPase domain fragments
Summary
INHIBITION OF ATPase ACTIVITY BY THE ANTI-CANCER DRUG BISDIOXOPIPERAZINE AND ATP/ADP-INDUCED DIMERIZATION*. The ATPase activity of the ATPase domain protein showed a quadratic dependence on enzyme concentration, suggesting that dimerization of the NH2-terminal domain is a rate-limiting step Using both protein cross-linking and sedimentation equilibrium analysis, we showed that the ATPase domain exists as a monomer in the absence of cofactors but can readily dimerize in the presence of a nonhydrolyzable analog of ATP, 5-adenylyl-,␥-imidodiphosphate. A previous study on a member of this drug family, ICRF-193, has shown that in the presence of ATP, the drug inhibits yeast topo II activities by trapping the enzyme in a closed clamp form [20]. A recent study on the ATPase domain of yeast topo II has shown that ICRF-193 can inhibit the ATP hydrolysis, indicating a direct interaction between the drug and ATPase domain [24].
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