Stepwise optimization of genetic RuBisCO-equipped Escherichia coli for low carbon-footprint protein and chemical production

Abstract

Bio-mitigation of carbon dioxide has recently attracted more research focus because it is a sustainable and ecofriendly way of carbon conversion to a variety of indispensable chemicals. However, studies regarding the recombinant strain development toward simultaneous chemical production and CO₂ assimilation in E. coli are limited and the reported studies are challenged with critically low efficiency. In this context, we first expressed ribulose-1,5-bisphosphate carboxylase/oxygenases (RuBisCOs) and phosphoribulokinases (PRKs) from the Calvin cycle to optimize the CO₂ assimilation capability in E. coli with a value of −4.9 g-CO₂ per g-DCW. To enhance the CO₂ assimilation capability and broaden the applicability of RuBisCO-equipped E. coli, we conducted stepwise integration of the recombinant genes (RuBisCO and PRK) as well as introduced the CRISPRi system for redirecting the carbon flux to the RuBisCO pathway. The final strain, SSCI with CRISPRi targeted on zwf and pfkAB, enhanced the CO₂ assimilation capability to −1.58 g-CO₂ per g-DCW. Finally, RuBisCO-equipped E. coli was applied for simultaneous CO₂ recycling and production of high-value molecules from various proteins, including 5-aminoleuvinic acid (ALA) by ALA synthetase, carbon dioxide sequestration via carbonic anhydrase (CA), and 1,5-diaminopentane (DAP) through lysine decarboxylase. This genomic RuBisCO-equipped E. coli neutralizer is denoted as a GREEN workhorse, with the great opportunity to be a low-carbon footprint microbial cell factory.