Abstract
Inversion of many predetermined segments of the Escherichia coli chromosome was attempted by using a system for in vivo selection of genomic rearrangements. Two types of constraints on these inversions were observed: (i) a sensitivity to rich medium when the distance between oriC and the 86- to 91-min region (which carries loci essential for transcription and translation) is increased; (ii) a poor viability or inviability of inversions having at least one endpoint in the one-third of the chromosome around replication terminators (with an exception for some inversions ending between these terminators). Although the first constraint is simply explained by a decreased dosage of the region involved, the second one may result from disruption of two long-range chromosomal organizations. The nondivisible zones thus disclosed coincide remarkably well with the two zones that we have previously described, which are polarized with respect to their replication. It is proposed that the two phenomena result from a sequence-dependent and polarized organization of the terminal region of the chromosome, which defines chromosome replication arms and may participate in nucleoid organization.
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