Development mechanism of resistant population post-exposure to tigecycline in tigecycline-heteroresistant Acinetobacter baumannii strain.

Tigecycline heteroresistance is highly prevalent in Acinetobacter baumannii clinical isolates, reducing the efficacy of tigecycline treatment. This study investigated the population dynamics of A. baumannii with tigecycline heteroresistance to determine the origin of resistance that occurs over time after antibiotic exposure. Tigecycline heteroresistance was imitated by mixing tigecycline-susceptible and -resistant A. baumannii isolates in a 1:10 ratio, and confirmed using population analysis profiling. Growth curves and an in-vitro competition assay found no difference in bacterial fitness between tigecycline-resistant and -susceptible populations. The green fluorescent protein (GFP) expression system and flow cytometry were used to monitor the population dynamics of the heteroresistant population, while differentiating the resistant population from the susceptible population. The mimicked tigecycline heteroresistance was confirmed to be reproducible and stable without tigecycline. The GFP-expressing population (i.e. the resistant population) nearly went undetected because it only represented approximately 10 of the entire population. However, when the mimicked tigecycline-heteroresistant strain was treated with tigecycline, most subpopulations expressing GFP were detected. The surviving A. baumannii population, upon exposure to tigecycline, exhibited a high minimum inhibitory concentration for tigecycline, equivalent to that of tigecycline-resistant isolates that were used to mimic heteroresistance. These results indicate that the development of resistance in tigecycline-heteroresistant A. baumannii strains, resulting in decreased antibiotic efficacy, may depend on the selection of a pre-existing resistant subpopulation.