Filamentous cheater phages drive bacterial and phage populations to lower fitness.

Many bacteria carry phage genome(s) in their chromosome, which intertwines the fitness of the bacterium and the phage. Most Pseudomonas aeruginosa strains carry filamentous phages called Pf that establish chronic infections and do not require host lysis to spread. However, spontaneous mutations in the Pf repressor gene (pf5r) can allow extreme phage production that slows bacterial growth and increases cell death, violating an apparent détente between bacterium and phage. We observed this paradoxical outcome in an evolution experiment with P. aeruginosa in media simulating nutrients from the cystic fibrosis airway. Bacteria containing pf5r mutant phage grow to a lower density but directly outcompete their ancestor and convert them into pf5r mutants via phage superinfection. Reduced fitness therefore spreads throughout the bacterial population, driven by weaponized Pf. Yet, high intracellular phage replication facilitates another evolutionary conflict: "cheater miniphages" lacking capsid genes and the superinfection exclusion gene (pfsE) invade populations of full-length phages within cells. Although bacteria containing both full-length phages and miniphages become mostly immune to superinfection by limiting the Pf receptor, this hybrid vigor is extremely unstable; a classic "tragedy of the commons" scenario ensues that causes complete prophage loss. The entire cycle-from phage hyperactivation to miniphage invasion to prophage loss-can occur within 24 h, showcasing rapid coevolution between bacteria and their filamentous phages. This study demonstrates that P. aeruginosa, and potentially many other bacterial species that carry filamentous prophages, risk being exploited by these phages in a runaway process that reduces fitness of both host and virus.