High-efficiency gene inactivation and replacement system for gram-positive bacteria

Abstract

A system for high-efficiency single- and double-crossover homologous integration in gram-positive bacteria has been developed, with Lactococcus lactis as a model system. The system is based on a thermosensitive broad-host-range rolling-circle plasmid, pG+host5, which contains a pBR322 replicon for propagation in Escherichia coli at 37 degrees C. A nested set of L. lactis chromosomal fragments cloned onto pG+host5 were used to show that the single-crossover integration frequency was logarithmically proportional to the length of homology for DNA fragments between 0.35 and 2.5 kb. Using random chromosomal 1-kb fragments, we showed that homologous integration can occur along the entire chromosome. We made use of the reported stimulatory effect of rolling-circle replication on intramolecular recombination to develop a protocol for gene replacement. Cultures were first maintained at 37 degrees C to select for a bacterial population enriched for plasmid integrants; activation of the integrated rolling-circle plasmid by a temperature shift to 28 degrees C resulted in efficient plasmid excision by homologous recombination and replacement of a chromosomal gene by the plasmid-carried modified copy. More than 50% of cells underwent replacement recombination when selection was applied for the replacing gene. Between 1 and 40% of cells underwent replacement recombination when no selection was applied. Chromosomal insertions and deletions were obtained in this way. These results show that gene replacement can be obtained at an extremely high efficiency by making use of the thermosensitive rolling-circle nature of the delivery vector. This procedure is applicable to numerous gram-positive bacteria.