Abstract

Mobile genetic elements (MGEs) and the interactions between them are a major source of evolutionary innovation. Insertion sequences, the simplest MGEs usually encoding only the necessary genes for transposition and maintenance, are widespread in bacterial genomes, and are particularly common in plasmids. Plasmids, self-replicating extrachromosomal DNA elements, often exist in multiple copies imparting a stochastic barrier to the fixation of an insertion sequence by limiting the proportion of the plasmid population harboring the IS. In this work we demonstrate that to overcome this, the IS200/605 family of insertion sequences utilizes programmable RNA guided nucleases as gene drive to spread the IS through the plasmid population. TnpB, the likely ancestor of Cas12, records the specific insertion site of the IS in its RNA guide to prevent loss of the IS during transposition. When introduced to a plasmid TnpB will be reprogrammed to target and cleave IS- plasmids, resulting in biased replication of only those IS+ plasmids. Furthermore, the gene drive activity is critical for the IS to invade high copy plasmid populations. Because TnpB can only be mobilized between microbes on other mobile genetic elements, this advantage to fixing in plasmids may help explain the prevalence of TnpB across the tree of life. More generally, the unique pressures arising from movement between genetic contexts with different multiplicities shapes the evolution of strategies for MGE spread.

Competing Interest Statement

The authors have declared no competing interest.