Trade-offs between phage resistance and conjugative ability shape the ecological and evolutionary response of a multidrug resistance plasmid to plasmid-dependent phage

Phage therapy is a promising alternative to antibiotics to treat multidrug resistant infections. Plasmid dependent phages (PDPs) are particularly attractive as therapeutics because they can both kill targeted pathogen cells, whilst also potentially preventing the further spread of antibiotic resistance genes encoded by plasmids. However, we lack experimental studies of the ecological and evolutionary response of multidrug resistance plasmids against plasmid dependent phage treatment under ecologically relevant scenarios allowing plasmid conjugation. We experimentally evolved populations of E. coli carrying the multidrug resistance RP4 plasmid with the PRD1 PDP under conditions where conjugation was associated with either strong or weak benefits. When opportunities for conjugation were rare, PRD1 only transiently suppressed the conjugative plasmid population due to the rapid evolution of PRD1 resistant plasmids that lacked conjugative ability. Increasing the ecological opportunity for conjugation enhanced plasmid suppression and delayed the evolution of PRD1 resistant plasmids. PRD1 resistance was associated with reduced conjugative ability, but this trade-off was complex due to the heterogeneous impacts of resistance mutations on pilus production and conjugative ability. Mutations and IS element insertions in conjugation genes caused a wide range of PRD1 resistance phenotypes, ranging from complete resistance ( virB4 ) to partial resistance ( trbB , trbL ). Bioinformatic analysis of publicly available IncP plasmid sequences showed that truncated variants of VirB4 protein are common in natural populations, suggesting that plasmid-dependent phages are an important selective pressure in microbial communities. Our results demonstrate an evolutionary trade-off between conjugative ability and phage resistance that cannot be easily circumvented by plasmids. Targeting multidrug resistance plasmids with PDPs is likely to drive loss of conjugation limiting the transfer of antibiotic resistance genes in bacterial communities.