Multileveled Selection on Plasmid Replication

Multileveled Selection on Plasmid Replication

Johan Paulsson^a
^a Department of Molecular Biology, Princeton University, Princeton, New Jersey 08544

Corresponding author: Johan Paulsson, Princeton University, Washington Rd., Princeton, NJ 08544., paulsson{at}princeton.edu (E-mail)

Communicating editor: M. W. FELDMAN

The replication control genes of bacterial plasmids face selectionat two conflicting levels. Plasmid copies that systematicallyoverreplicate relative to their cell mates have a higher chanceof fixing in descendant cells, but these cells typically havea lower chance of fixing in the population. Apart from identifyingthe conflict, this mathematical discussion characterizes theefficiency of the selection levels and suggests how they drivethe evolution of kinetic mechanisms. In particular it is hypothesizedthat: (1) tighter replication control is more vulnerable toselfishness; (2) cis-acting replication activators are relicsof a conflict where a plasmid outreplicated its intracellularcompetitors by monopolizing activators; (3) high-copy plasmidswith sloppy replication control arise because intracellularselection favors overreplication, thereby relieving intercellularselection for lower loss rates; (4) the excessive synthesisof cis-acting replication activators and trans-acting inhibitorsis the result of an arms race between cis selfishness and transretaliations; (5) site-specific recombination of plasmid dimersis equivalent to self-policing; and (6) plasmids modify theirhorizontal transfer to spread without promoting selfishness.It is also discussed how replication control may be subjectto a third level of selection acting on the entire populationof plasmid-containing cells.

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