Left-handed Z-DNA and in vivo supercoil density in the Escherichia coli chromosome.

A system for studying Z-DNA formation in the Escherichia coli chromosome was developed. Prior investigations in recombinant plasmids showed that alternating (Pur-Pyr) sequences can adopt a left-handed Z-DNA conformation both in vitro and in vivo. We constructed mobile, transposon-based cassettes carrying cloned (Pur-Pyr) sequences containing an EcoRI site in the center. These cassettes were subsequently inserted into different locations in the E. coli chromosome in a random fashion. A number of stable insertions were characterized by Southern analysis and pulsed-field gel electrophoresis mapping. A cloned temperature-sensitive MEcoRI methylase was expressed in trans as the probe to study Z-DNA formation in vivo. In this system, the control EcoRI sites were quickly methylated when cells were placed at the permissive temperature. Strong inhibition of the methylation was observed, however, only for the EcoRI sites embedded in a 56-bp run of (C-G). In contrast, the shorter sequence of 32 bp did not show this behavior. Prior in vitro determinations revealed that the longer tract required less energy to stabilize the Z-helix than the shorter block. We conclude that the observed inhibition of methylation is due to Z-DNA formation in the E. coli chromosome. In vitro, these sequences undergo the B- to Z-DNA transition at a supercoil density of -0.026 for the 56-bp insert and -0.032 for the 32-bp block. Since only the longer (C-G) tract but not the shorter run adopted the left-handed conformation in the chromosome, we propose that these densities establish the boundaries in the different chromosomal loci investigated; these boundaries are in good agreement with the extremes found in plasmids.