How genomes rearrange: genome comparison within bacteria Neisseria suggests roles for mobile elements in formation of complex genome polymorphisms.

Comparison of closely related genome sequences can provide a clue as to how macroscopic genome polymorphisms were formed through various events of recombination. However, this approach has been limited to relatively simple polymorphisms such as insertion, deletion and inversion. In the present study, we tried to extend this approach to more complex genome polymorphisms that were observed when four genome sequences of bacterial genus Neisseria were compared. The first polymorphism was an apparent translocation (ab-cd to cd-ba; a region 'ab' was translocated). The second one was a re-ordering of adjacent regions (ab-cd-ef-gh to ef-cd-ab-gh; ab, cd and ef were in reverse order). The third one was a translocation of two adjacent regions with permutation of their order (ab-cd to cd-ab elsewhere in the genome). The fourth one was a genome-wide inversion associated with a genome-specific insertion into the joints (-ab-cd- to -y-ba-x-cd-). We were able to explain their formation by only a few steps of plausible events of recombination that involved linked IS copies and prophages. Our approach would help to reconstruct a history of apparently complex genome polymorphisms in any forms of organisms and to understand genome rearrangements in the natural environments in non-model organisms.

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