Interaction between DNA gyrase and quinolones: effects of alanine mutations at GyrA subunit residues Ser(83) and Asp(87).

DNA gyrase is a target of quinolone antibacterial agents, but the molecular details of the quinolone-gyrase interaction are not clear. Quinolone resistance mutations frequently occur at residues Ser(83) and Asp(87) of the gyrase A subunit, suggesting that these residues are involved in drug binding. Single and double alanine substitutions were created at these positions (Ala(83), Ala(87), and Ala(83) Ala(87)), and the mutant proteins were assessed for DNA supercoiling, DNA cleavage, and resistance to a number of quinolone drugs. The Ala(83) mutant was fully active in supercoiling, whereas the Ala(87) and the double mutant were 2.5- and 4- to 5-fold less active, respectively; this loss in activity may be partly due to an increased affinity of these mutant proteins for DNA. Supercoiling inhibition and cleavage assays revealed that the double mutant has a high level of resistance to certain quinolones while the mutants with single alanine substitutions show low-level resistance. Using a drug-binding assay we demonstrated that the double-mutant enzyme-DNA complex has a lower affinity for ciprofloxacin than the wild-type complex. Based on the pattern of resistance to a series of quinolones, an interaction between the C-8 group of the quinolone and the double-mutant gyrase in the region of residues 83 and 87 is proposed.

The interaction of drugs with DNA gyrase: a model for the molecular basis of quinolone action.

DNA gyrase supercoils DNA in bacteria. The fact that it is essential in all bacteria and absent from eukaryotes makes it an ideal drug target. We discuss the action of coumarin and quinolone drugs on gyrase. In the case of coumarins, the drugs are known to be competitive inhibitors of the gyrase ATPase reaction. From a combination of structural and biochemical studies, the molecular details of the gyrase-coumarin complex are well established. In the case of quinolones, the drugs are thought to act by stabilising a cleavage complex between gyrase and DNA that arrests polymerases in vivo. The exact nature of the gyrase-quinolone-DNA complex is not known; we propose a model for this complex based on structural and biochemical data.