Multidimensional engineering of Rhodobacter sphaeroides for enhanced photo-fermentative hydrogen production

Abstract

The photo-fermentative hydrogen production by purple non-sulfur photosynthetic bacteria (PNSB) is regarded as a promising approach for sustainable hydrogen production. In PNSB, biohydrogen synthesis is catalyzed by nitrogenase which requires two essential cofactors of adenosine triphosphate (ATP) and electron. To avoid the insufficient ATP supply that limits the nitrogenase activity for hydrogen production, we systematically engineered Rhodobacter sphaeroides to improve the hydrogen production by manipulating the light harvesting (LH) complexes, the electron transfer chain (ETC), the adenosine diphosphate (ADP) synthetic pathway, the F0F1-ATPase expression, and the nitrogenase expression. To improve the photosynthetic efficiency, we engineered the LH complexes by eliminating pucBA and overexpressing pufQ and spbA. Then, the ETC was boosted by deleting qxt-type oxidase and integrating the electron carrier cytochrome cy at the site of cyt cbb3 oxidase. In addition, we increased the supply of precursor ADP by overexpressing adk, and the abundance of F0F1-ATPase was efficiently enhanced through overexpressing atpXF. Further transposon engineering with the integration of nifHDK and atpXF resulted in a mutant YH27 with a substantial improvement of performance over the base strain, and its nitrogenase activity and hydrogen production were enhanced by 404 % and 93 %, respectively. Taken together, the multidimensional strategies enabled the engineered R. sphaeroides with a hydrogen productivity of 61.2 mL/(Lh) and a yield of 3.0 mol/mol acetate under the fed-batch condition, which represents one of the most efficient biohydrogen-producing strains.