Integrative compatibility: stable coexistence of chromosomally integrated and autonomous derivatives of plasmid RP4

Replication control of IncP plasmids

Clones of Escherichia coli with a chromosomally integrated RP4-prime plasmid were isolated and characterized. Chromosome transfer was increased about 50-fold and the Hfr still carried an autonomous plasmid indistinguishable from the original RP4-prime. This could be eliminated by pRP64 or R751, two distinguishably marked incompatible plasmids, giving rise to strains which stably retained the resistance patterns of both plasmids and which continued to transfer the chromosome at enhanced levels. In both cases, however, the copy number of the autonomous plasmid was reduced by the presence of a chromosomal RP4 such that the total number of P plasmid genomes (integrated and autonomous) remained constant. The results are consistent with the idea that copy number is controlled by diffusible inhibitors or initiators of replication.

Replication defective RP4 plasmids recovered after chromosomal integration

pHH6000 is a composite replicon made by the in vitro ligation of the IncP plasmid RP4 to a fragment of bacteriophage lambda capable of autonomous replication. Derivatives were selected in which it had integrated into the Escherichia coli chromosome by homologous recombination with the resident lambda prophage, and plasmids were subsequently regenerated from the integrated molecules. Although of the same molecular size as pHH6000, all had altered properties: those recovered from the chromosome of cells simultaneously carrying a distinguishable autonomous IncP plasmid showed a 100- to 1000-fold reduction in their ability to become established in a lambda lysogen; those regenerated from cells with no autonomous IncP plasmid were no longer RP4 replicons, now being dependent on replication functions encoded by the lambda DNA they carry and therefore unable to form a plasmid in a lambda lysogen. This second class of plasmids still exhibited normal RP4 incompatibility and stability even though neither property is encoded by the lambda replicator DNA. It was concluded that expression of RP4 incompatibility and partitioning control do not require an intact RP4 replicon. The data also suggest that the presence in the chromosome of a normal RP4 molecule may be deleterious to the host, although the manner in which the integrated molecules were obtained allows other explanations. The composite plasmids replicating from cloned lambda genes should be useful in analysis of the regulated distribution of RP4 molecules at cell division.

Formation of Escherichia coli Hfr strains by integrative suppression with the P group plasmid RP1

Hfr strains of Escherichia coli were obtained by integrative suppression of a dnaA(Ts) mutation by the Inc P-1 plasmid RP1 without prior creation of an unnatural homology between the plasmid and the E. coli chromosome. Unmodified RP1 mobilized the polarized transfer of the chromosome in a counterclock-wise direction from a distinct origin between 81 min (pyrE) and 82 min (dnaA) with pyrE as a leading marker. Inheritance of RP1-Hfr chromosomal and antibiotic resistance genes was due to recombination with the recipient chromosome, as shown by the need for a functional recA system. The acquisition of temperature resistance and donor ability was accompanied by the disappearance of free plasmid when the selection pressure for integration was maintained (growth at 41 degrees C); the loss of temperature resistance and donor ability was accompanied by the reappearance of autonomous RP1 when the selection pressure was removed (growth at 30 degrees C).