Abstract
Genome engineering without leaving foreign DNA behind requires an efficient counter-selectable marker system. Here, we developed a genome engineering method in Bacillus subtilis using a synthetic gene circuit as a counter-selectable marker system. The system contained two repressible promoters (B. subtilis xylA (Pxyl) and spac (Pspac)) and two repressor genes (lacI and xylR). Pxyl-lacI was integrated into the B. subtilis genome with a target gene containing a desired mutation. The xylR and Pspac–chloramphenicol resistant genes (cat) were located on a helper plasmid. In the presence of xylose, repression of XylR by xylose induced LacI expression, the LacIs repressed the Pspac promoter and the cells become chloramphenicol sensitive. Thus, to survive in the presence of chloramphenicol, the cell must delete Pxyl-lacI by recombination between the wild-type and mutated target genes. The recombination leads to mutation of the target gene. The remaining helper plasmid was removed easily under the chloramphenicol absent condition. In this study, we showed base insertion, deletion and point mutation of the B. subtilis genome without leaving any foreign DNA behind. Additionally, we successfully deleted a 2-kb gene (amyE) and a 38-kb operon (ppsABCDE). This method will be useful to construct designer Bacillus strains for various industrial applications.
Highlights
Bacillus species are spore-forming Gram-positive bacteria and are the most frequently used bacteria for industrial enzyme production
About 60% of commercially available enzymes are produced from Bacillus species
An effective method for genome engineering that is free of any antibiotic resistance markers is needed
Summary
Bacillus species are spore-forming Gram-positive bacteria and are the most frequently used bacteria for industrial enzyme production. About 60% of commercially available enzymes are produced from Bacillus species. Bacillus strains have been used to produce nucleotides, vitamins, ribose and poly-␥ -glutamic acid and as expression hosts to produce foreign recombination proteins [1,2,3]. Industrial-scale production of commercial enzymes or metabolites requires strain engineering because wild-type Bacillus strains have not been adapted for overproducing specific enzymes or metabolites. Strain engineering often requires multiple mutations in the genome. The number of antibiotic selection markers available for use in Bacillus subtilis is limited. An effective method for genome engineering that is free of any antibiotic resistance markers is needed. The method must be usable to construct food-grade recombinant strains
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