Using Cupriavidus necator H16 to Provide a Roadmap for Increasing Electroporation Efficiency in Nonmodel Bacteria

Bacteria are a treasure trove of metabolic reactions, but most industrial biotechnology applications rely on a limited set of established host organisms. In contrast, adopting nonmodel bacteria for the production of various chemicals of interest is often hampered by their limited genetic amenability coupled with their low transformation efficiency. In this study, we propose a series of steps that can be taken to increase electroporation efficiency in nonmodel bacteria. As a test strain, we use Cupriavidus necator H16, a lithoautotrophic bacterium that has been engineered to produce a wide range of products from CO2 and hydrogen. However, its low electroporation efficiency hampers the high-throughput genetic engineering required to develop C. necator into an industrially relevant host organism. Thus, conjugation has often been the method of choice for introducing exogenous DNA, especially when introducing large plasmids or suicide plasmids. We first propose a species-independent technique based on natively methylated DNA and Golden Gate assembly to increase one-pot cloning and electroporation efficiency by 70-fold. Second, bioinformatic tools were used to predict defense systems and develop a restriction avoidance strategy that was used to introduce suicide plasmids by electroporation to obtain a domesticated strain. The results are discussed in the context of metabolic engineering of nonmodel bacteria.