Evolutionary escape of Escherichia coli from Bdellovibrio bacteriovorus

Antimicrobial resistance (AMR) is a threat to modern medicine. To combat AMR pathogens, natural predators like bacteriophages and predatory bacteria have gained interest recently. Predatory bacterium Bdellovibrio bacteriovorus is ubiquitous and has a broad prey range. It is particularly potent at killing many AMR Gram-negative bacterial pathogens featured on the WHO priority list. However, it is currently unclear whether prey bacteria can evolve genetically-determined resistance against predation by B. bacteriovorus. Here, we show that the model bacterium Escherichia coli K-12 consistently evolves resistance against B. bacteriovorus during experimental evolution. Selection for resistance scaled positively with predation pressure and was widespread after two cycles of predator exposure. Similar to antibiotics, predation resistance was costly, manifesting in a trade-off between predation resistance and fitness in the absence of predators. Genetic analysis combined with proteomics identified mutations that lead to the down-regulation of the outer membrane porin OmpF as a common resistance mechanism. In addition, a rarer mutation in cell envelope lipopolysaccharide-modifying enzyme WaaF also conferred predation resistance, likely by a pleiotropic effect, which included OmpF down regulation. While our study uncovers evolutionary and mechanistic aspects of prey escape from predation, it also highlights that the high cost of resistance reflects a handicap for the pathogen and can thus be exploited to increase treatment sustainability. Altogether, our work generates essential knowledge in ecologically important predator-prey interactions and can advance predatory bacteria as “living antibiotics” to combat AMR.