Regulation of catalysis by the smallpox virus topoisomerase

The poxvirus type IB topoisomerases catalyze relaxation of supercoiled DNA by cleaving and rejoining DNA strands via a pathway involving a covalent phosphotyrosine intermediate. Recently we determined structures of the smallpox virus topoisomerase bound to DNA in covalent and non-covalent DNA complexes using x-ray crystallography. Here we analyzed the effects of twenty-two amino acid substitutions on the topoisomerase activity in vitro in assays of DNA relaxation, single cycle cleavage, and equilibrium cleavage-religation. Alanine substitutions at 14 positions impaired topoisomerase function, marking a channel of functionally important contacts along the protein-DNA interface. Unexpectedly, alanine substitutions at two positions (D168A and E124A) accelerated the forward rate of cleavage. These findings and further analysis indicate that Asp(168) is a key regulator of the active site that maintains an optimal balance among the DNA cleavage, religation, and product release steps. Finally, we report that high level expression of the D168A topoisomerase in Escherichia coli, but not other alanine-substituted enzymes, prevented cell growth. These findings help elucidate the amino acid side chains involved in DNA binding and catalysis and provide guidance for designing topoisomerase poisons for use as smallpox antivirals.