Studies in bacterial genome engineering and its applications

Many different approaches exist for engineering bacterial genomes. The most common current methods include transposons for random mutagenesis, recombineering for specific modifications in Escherichia coli, and targetrons for targeted knock-outs. Site-specific recombinases, which can catalyze a variety of large modifications at high efficiency, have been relatively underutilized in bacteria. Employing these technologies in combination could significantly expand and empower the toolkit available for modifying bacteria.

Targetrons can be adapted to carry functional genetic elements to defined genomic loci. For instance, we re-engineered targetrons to deliver lox sites, the recognition target of the site-specific recombinase, Cre. We used this system on the E. coli genome to delete over 100 kilobases, invert over 1 megabase, insert a 12-kilobase polyketide-synthase operon, and translocate a 100 kilobase section to another site over 1 megabase away. We further used it to delete a 15-kilobase pathogenicity island from Staphylococcus aureus, catalyze an inversion of over 1 megabase in Bacillus subtilis, and simultaneously deliver nine lox sites to the genome of Shewanella oneidensis. This represents a powerful, versatile, and broad-host-range solution for bacterial genome engineering.

We also placed lox sites on mariner transposons, which we leveraged to create libraries of millions of strains harboring rearranged genomes. The resulting data represents the most thorough search of the space of potential genomic rearrangements to date. While simple insertions were often most adaptive, the most successful modification found was an inversion that significantly improved fitness in minimal media. This approach could be pushed further to examine swapping or cutting and pasting regions of the genome, as well.

As potential applications, we present work towards implementing and optimizing extracellular electron transfer in E. coli, as well as mathematical models of bacteria engineered to adhere to the principles of the economic concept of comparative advantage, which indicate that the approach is feasible, and furthermore indicate that economic cooperation is favored under more adverse conditions. Extracellular electron transfer has applications in bioenergy and biomechanical interfaces, while synthetic microbial economics has applications in designing consortia-based industrial bioprocesses. The genomic engineering methods presented above could be used to implement and optimize these systems.