Interactions of aryloxyphenoxypropionic acids with sensitive and resistant acetyl-coenzyme a carboxylase by homology modeling and molecular dynamic simulations.

Acetyl-coenzyme A carboxylase (ACCase) has been identified as one of the most important targets of herbicides. In the present study, we constructed homology models of the carboxyl-transferase (CT) domain of ACCase from sensitive and resistant foxtail and used these models as templates to study the molecular mechanism of herbicide resistance and stereochemistry-activity relationships of aryloxyphenoxypropionates (APPs). In the homology modeling structures, the dimer of the CT domain was formed by the side-to-side arrangement of the two monomers, in such a way that the N domain of one molecule is placed next to the C domain of the other. The dimeric association of sensitive foxtail CT was found to differ from that of resistant foxtail CT, and the spatial orientation of two key residues, Leu-695 and Ile-695, in these dimers also differed. The mutation of Ile to Leu may perturb the conformation of the dimeric interface, which may account for the molecular mechanism of herbicide resistance. Further docking analysis indicated that the binding model of high-active compounds is similar to that in the crystal structure of the enzyme-ligand complex. The different spatial orientations of ester groups of the isomers of APPs may explain the stereochemistry-activity relationship. Ser-698 formed a H-bonding interaction with all of the docked ligands, while Tyr-728 formed a pi-pi stacking interaction with some of the APPs. These findings may enhance our understanding of the molecular mechanism of herbicide resistance and stereochemistry-activity relationships, which may provide a new starting point for the identification of more potent inhibitors against both sensitive and resistant ACCase.