The classic strategy to achieve gene deletion variants is based on double-crossover integration of nonreplicating vectors into the genome. In addition, recombination systems such as Cre-lox have been used extensively, mainly for eukaryotic organisms. This study presents the construction of a Cre-lox-based system for multiple gene deletions in Lactobacillus plantarum that could be adapted for use on gram-positive bacteria. First, an effective mutagenesis vector (pNZ5319) was constructed that allows direct cloning of blunt-end PCR products representing homologous recombination target regions. Using this mutagenesis vector, doublecrossover gene replacement mutants could be readily selected based on their antibiotic resistance phenotype. In the resulting mutants, the target gene is replaced by a lox66-P 32 -cat-lox71 cassette, where lox66 and lox71 are mutant variants of loxP and P 32 -cat is a chloramphenicol resistance cassette. The lox sites serve as recognition sites for the Cre enzyme, a protein that belongs to the integrase family of site-specific recombinases. Thus, transient Cre recombinase expression in double-crossover mutants leads to recombination of the lox66-P 32 -cat-lox71 cassette into a double-mutant loxP site, called lox72, which displays strongly reduced recognition by Cre. The effectiveness of the Cre-lox-based strategy for multiple gene deletions was demonstrated by construction of both single and double gene deletions at the melA and bsh1 loci on the chromosome of the gram-positive model organism Lactobacillus plantarum WCFS1. Furthermore, the efficiency of the Cre-lox-based system in multiple gene replacements was determined by successive mutagenesis of the genetically closely linked loci melA and lacS2 in L. plantarum WCFS1. The fact that 99.4% of the clones that were analyzed had undergone correct Cre-lox resolution emphasizes the suitability of the system described here for multiple gene replacement and deletion strategies in a single genetic background.The development of tools for genetic engineering of grampositive bacteria is highly valuable for research applications. The classic strategy for obtaining gene deletion variants is based on homologous recombination, using double-crossover integration of heterologous nonreplicating vectors such as pUC (34,36,37,42), pACYC184 (6,48,50), or their derivatives in the genome. Several convenient systems that derive from this strategy use conditionally replicating vectors, such as the thermosensitive pG ϩ host system (40) and the RepA-dependent lactococcal pORI system (originating from pWV01) (12, 33, 51) and its broad-host-range derivative (42,51).In addition to systems that derive from the classic strategy, various site-specific recombination systems such as Flp-FRT (52), Gateway (Invitrogen), ParA-res (31), TnpR-res (13), and Cre-lox are used in mutational strategies. To date, however, these systems have not been available for construction of an unlimited number of mutations in the same genetic background in gram-positive bacteria. For this purpo...
