Bacteria contain a primary chromosome and, frequently, either essential secondary chromosomes or dispensable megaplasmids of plasmid origin. Incoming plasmids are often poorly adapted to their hosts and their stabilization requires integration with the host's cellular mechanisms in a process termed domestication. All Vibrio, including pathogenic species, carry a domesticated secondary chromosome (Chr2) where replication is coordinated with that of the primary chromosome (Chr1). Chr2 replication is triggered by the replication of an intergenic sequence (crtS) located on Chr1. Yet, the molecular mechanisms by which crtS replication controls the initiation of Chr2 replication are still largely unknown. In this study, we show that crtS not only regulates the timing of Chr2 initiation but also controls Chr2 copy number. We observed and characterized the direct binding of the Chr2 initiator (RctB) on crtS. RctB binding to crtS is independent of its methylation state. RctB molecules, which naturally form dimers, preferentially bind to crtS as monomers, with DnaK/J protein chaperones shown to stimulate binding of additional RctB monomers on crtS. In this study, we addressed various hypothesis of how replication of crtS could trigger Chr2 replication and provide new insights into its mode of action.
In bacteria, the FtsK/Xer/dif (chromosome dimer resolution site) system is essential for faithful vertical genetic transmission, ensuring the resolution of chromosome dimers during their segregation to daughter cells. This system is also targeted by mobile genetic elements that integrate into chromosomal dif sites. A central question is thus how Xer/dif recombination is tuned to both act in chromosome segregation and stably maintain mobile elements. To explore this question, we focused on pathogenic Neisseria species harboring a genomic island in their dif sites. We show that the FtsK DNA translocase acts differentially at the recombination sites flanking the genomic island. It stops at one Xer/dif complex, activating recombination, but it does not stop on the other site, thus dismantling it. FtsK translocation thus permits cis discrimination between an endogenous and an imported Xer/dif recombination complex.
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