Some of the largest scale chemical processes for the production of important commodity chemicals and fuels involve an H2-containing gas mixture as an intermediate [e.g. ammonia, urea, methanol, Fischer-Tropsch (F-T) diesel, and hydrotreatment of crude petroleum to refined fuels]. The successful development of a model H2-oxidizing chemoautotrophic host could expand the range of fuels and chemicals produced from H2 and CO2 intermediates in the chemical, oil, and gas sectors in the near term, as well as from renewable and waste-derived sources of these gases that are expected to greatly expand in coming years. Among non-photosynthetic bacteria that can utilize H2 and CO2, Cupriavidus necator (C. necator, formerly Ralstonia eutropha), is the best studied. C. necator is an excellent microbial host for the production of a variety of chemicals because it grows extremely quickly to very high cell densities autotrophically on H2 and CO2, is genetically tractable, and has the ability to accumulate polymers, such as polyhydroxybutyrate, at industrial levels.
Despite having great potential as a platform bioproduction host, genetic tools are limited, making metabolic engineering of this organism slow and laborious. In this CRADA project, we developed a number of genetic tools for C. necator:
1) Improvement of C. necator genetic transformation efficiency
2) Integration of heterologous genes into the C. necator chromosome and development of promoter library
3) Development of graded RBSs to control heterologous protein expression
4) Use of RBSs to demonstrate fatty alcohol production in C. necator
5) Demonstration of CRISPR-Cas9 gene editing in C. necator