Molecular basis of enrofloxacin translocation through OmpF, an outer membrane channel of Escherichia coli--when binding does not imply translocation.

The molecular pathway of enrofloxacin, a fluoroquinolone antibiotic, through the outer membrane channel OmpF of Escherichia coli is investigated. High-resolution ion current fluctuation analysis reveals a strong affinity for enrofloxacin to OmpF, the highest value ever recorded for an antibiotic-channel interaction. A single point mutation in the constriction zone of OmpF, replacing aspartic acid at the 113 position with asparagine (D113N), lowers the affinity to a level comparable to other antibiotics. All-atom molecular dynamics simulations allow rationalizing the translocation pathways: wild-type OmpF has two symmetric binding sites for enrofloxacin located at each channel entry separated by a large energy barrier in the center, which inhibits antibiotic translocation. In this particular case, our simulations suggest that the ion current blockages are caused by molecules occupying either one of these peripheral binding sites. Removal of the negative charge on position 113 removes the central barrier an...