Abstract
Plasmids are autonomous genetic elements that can be exchanged between microorganisms via horizontal gene transfer (HGT). Despite the central role they play in antibiotic resistance and modern biotechnology, our understanding of plasmids’ natural ecology is limited. Recent experiments have shown that plasmids can spread even when they are a burden to the cell, suggesting that natural plasmids may exist as parasites. Here, we use mathematical modeling to explore the ecology of such parasitic plasmids. We first develop models of single plasmids and find that a plasmid’s population dynamics and optimal infection strategy are strongly determined by the plasmid’s HGT mechanism. We then analyze models of co-infecting plasmids and show that parasitic plasmids are prone to a “tragedy of the commons” in which runaway plasmid invasion severely reduces host fitness. We propose that this tragedy of the commons is averted by selection between competing populations and demonstrate this effect in a metapopulation model. We derive predicted distributions of unique plasmid types in genomes—comparison to the distribution of plasmids in a collection of 17,725 genomes supports a model of parasitic plasmids with positive plasmid–plasmid interactions that ameliorate plasmid fitness costs or promote the invasion of new plasmids.
Highlights
Plasmids are autonomous genetic elements that utilize the replication machinery of a host to replicate
Plasmids play a significant role in bacterial evolution and the spread of antibiotic resistance, but their ecology is not well understood
By analyzing models across multiple population scales, we developed a mechanistic framework to provide insight into the forces shaping the natural ecology of plasmids
Summary
Plasmids are autonomous genetic elements that utilize the replication machinery of a host to replicate. They come in a variety of forms, ranging from plasmids of only a few kilobases that contain no discernible genes [1], to large, chromosome-like plasmids that encode genes essential to host survival [2]. Plasmids can transfer between hosts by a variety of mechanisms, including conjugation, by which cells directly exchange plasmids [3], and transformation, in which free plasmids infect cells [4]. Plasmids are important vehicles of horizontal gene transfer (HGT) in bacteria and archaea, being one of the mechanisms that allow these
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
