Vibrio cholerae harbours a primary chromosome derived from the monochromosomal ancestor of the Vibrionales (ChrI) and a secondary chromosome derived from a megaplasmid (ChrII). The choreography of segregation of the replication terminus of ChrI and ChrII, TerI and TerII, determines when and where cell division occurs. ChrI encodes for a homolog of Escherichia coli MatP. Using a combination of deep sequencing and fluorescence microscopy techniques, we show that MatP structures TerI and TerII into macrodomains, targets them to mid-cell in the course of replication and delays their segregation, demonstrating that ChrII behaves as a bona fide chromosome. We further show that the extent of the segregation delay mediated by MatP depends on the number and local density of matS sites, and is independent of its assembly into tetramers and any interaction with a cell division protein, in contrast to what has been observed in E. coli.

Vibrio cholerae harbours a primary chromosome derived from the monochromosomal ancestor of the Vibrionales (ChrI) and a secondary chromosome derived from a megaplasmid (ChrII). The choreography of segregation of the replication terminus of ChrI and ChrII, TerI and TerII, determines when and where cell division occurs. ChrI encodes for a homolog of Escherichia coli MatP. Using a combination of deep sequencing and fluorescence microscopy techniques, we show that MatP structures TerI and TerII into macrodomains, targets them to mid-cell in the course of replication and delays their segregation, demonstrating that ChrII behaves as a bona fide chromosome. We further show that the extent of the segregation delay mediated by MatP depends on the number and local density of matS sites, and is independent of its assembly into tetramers and any interaction with a cell division protein, in contrast to what has been observed in E. coli.