Mechanisms of deletion formation in Escherichia coli plasmids. II. Deletions mediated by short direct repeats.

Summary A set of plasmids containing 42, 21 and 13 bp direct repeats was used to analyze the effect of repeat length on the frequencies of deletion formation and the structure of the deleted derivatives of different recombination-deficient Escherichia coli strains. Agarose gel electrophoresis of plasmid DNA demonstrated that the formation of deletions in these plasmids was associated with dimerization of plasmid DNA. Restriction analysis of the dimers showed that deletions at short direct repeats arose non-conservatively, that is, the formation of a deletion in one monomeric plasmid unit was not associated with a duplication in the other. Mutations in the recA, recF, recJ and recO genes had no marked effect on either the frequencies of deletion formation or the structure of dimers. In contrast, recB recC mutations greatly increased the frequencies of deletion formation, 6-fold for 42 bp, and 115-fold for 21 by direct repeats. Conversion of DNA replication to the rolling circle mode in a recB recC strain, resulting in the formation of double-stranded ends, is suggested as the stimulatory effector.     

Molecular mechanisms of deletion formation in Escherichia coli plasmids. I. Deletion formation mediated by long direct repeats.

Summary Derivatives of plasmid pBR327 with the tet gene interrupted by 165 pb or 401 by direct repeats were constructed. In cells harboring these plasmids, deletions which restored the wild-type tet gene gave rise to tetracycline-resistant colonies, thereby allowing a simple phenotypic test for deletion formation. The frequencies of deletions in these plasmids were measured in Escherichia coli strains proficient or deficient in general recombination. The structure of plasmid DNA isolated from tetracycline-resistant transformants was analyzed by agarose gel electrophoresis, restriction mapping and sequencing. The data presented here demonstrate that deletion formation is always associated with dimerization of plasmid DNA. Dimeric plasmids were of two types. Those which carried both a deletion and a compensating duplication were the major type in a Rec⁺ background and were rare in recA, recF, recJ and recO backgrounds. Dimers of the second type contained deletions, but no compensating duplications, and their formation was RecA-independent. The data presented demonstrate that deletion formation mediated by long direct repeats is mainly the result of unequal crossing-over between two plasmid molecules.     

Duplications between direct repeats stabilized by DNA secondary structure occur preferentially in the leading strand during DNA replication

To ascertain a leading or lagging strand preference for duplication mutations, several short DNA sequences, i.e. mutation inserts, were designed that should demonstrate an asymmetric propensity for duplication mutations in the two complementary DNA strands during replication. The design of the mutation insert involved a 7-bp quasi inverted repeat that forms a remarkably stable hairpin in one DNA strand, but not the other. The inverted repeat is asymmetrically placed between flanking direct repeats. This sequence was cloned into a modified chloramphenicol acetyltransferase (CAT) gene containing a −1 frameshift mutation. Duplication of the mutation insert restores the reading frame of the CAT gene resulting in a chloramphenicol resistant phenotype. The mutation insert showed greater than a 200-fold preference for duplication mutations during leading strand, compared with lagging strand, replication. This result suggests that misalignment stabilized by DNA secondary structure, leading to duplication between direct repeats, occurred preferentially during leading strand synthesis.