Engineering Nitrogen Fixation Activity in an Oxygenic Phototroph.

Biological nitrogen fixation is catalyzed by nitrogenase, a complex metalloenzyme found only in prokaryotes. N fixation is energetically highly expensive, and an energy-generating process such as photosynthesis can meet the energy demand of N fixation. However, synthesis and expression of nitrogenase are exquisitely sensitive to the presence of oxygen. Thus, engineering nitrogen fixation activity in photosynthetic organisms that produce oxygen is challenging. Cyanobacteria are oxygenic photosynthetic prokaryotes, and some of them also fix N Here, we demonstrate a feasible way to engineer nitrogenase activity in the nondiazotrophic cyanobacterium sp. PCC 6803 through the transfer of 35 nitrogen fixation () genes from the diazotrophic cyanobacterium sp. ATCC 51142. In addition, we have identified the minimal cluster required for such activity in 6803. Moreover, nitrogenase activity was significantly improved by increasing the expression levels of genes. Importantly, the O tolerance of nitrogenase was enhanced by introduction of uptake hydrogenase genes, showing this to be a functional way to improve nitrogenase enzyme activity under micro-oxic conditions. To date, our efforts have resulted in engineered 6803 strains that, remarkably, have more than 30% of the N fixation activity of 51142, the highest such activity established in any nondiazotrophic oxygenic photosynthetic organism. This report establishes a baseline for the ultimate goal of engineering nitrogen fixation ability in crop plants. Application of chemically synthesized nitrogen fertilizers has revolutionized agriculture. However, the energetic costs of such production processes and the widespread application of fertilizers have raised serious environmental issues. A sustainable alternative is to endow to crop plants the ability to fix atmospheric N One long-term approach is to transfer all genes from a prokaryote to plant cells and to express nitrogenase in an energy-producing organelle, chloroplast, or mitochondrion. In this context, 6803, the nondiazotrophic cyanobacterium utilized in this study, provides a model chassis for rapid investigation of the necessary requirements to establish diazotrophy in an oxygenic phototroph.