Abstract
AbstractMaking targeted gene deletions is essential for studying organisms, but is difficult in many prokaryotes due to the inefficiency of homologous recombination based methods. Here, I describe an easily modifiable, single-plasmid system that can be used to make rapid, sequence targeted, markerless knockouts in both a Gram-negative and a Gram-positive organism. The system is comprised of targeted DNA cleavage by Cas9 and error-prone repair by Non-Homologous End Joining (NHEJ) proteins. I confirm previous results showing that Cas9 and NHEJ can make knockouts when NHEJ is expressed before Cas9. Then, I show that Cas9 and NHEJ can be used to make knockouts when expressed simultaneously. I term the new method Potentially Organism-Agnostic Knockout (POAK) system and characterize its function in Escherichia coli and Weissella confusa. First, I develop a novel transformation protocol for W. confusa. Next, I show that, as in E. coli, POAK can create knockouts in W. confusa. Characterization of knockout efficiency across galK in both E. coli and W. confusa showed that while all gRNAs are effective in E. coli, only some gRNAs are effective in W. confusa, and cut site position within a gene does not determine knockout efficiency for either organism. I examine the sequences of knockouts in both organisms and show that POAK produces similar edits in both E. coli and W. confusa. Finally, as an example of the importance of being able to make knockouts quickly, I target W. confusa sugar metabolism genes to show that two sugar importers are not necessary for metabolism of their respective sugars. Having demonstrated that simultaneous expression of Cas9 and NHEJ is sufficient for making knockouts in two minimally related bacteria, POAK represents a hopeful avenue for making knockouts in other under-utilized bacteria.
Publisher
Cold Spring Harbor Laboratory