Development of an efficient algal H{sub 2}-producing system

Green algae have the potential to efficiently photoevolve H{sub 2} from water using the photosynthetic O{sub 2} evolving apparatus and the reversible hydrogenase enzyme when CO{sub 2} is not present. Unfortunately algal hydrogenases are very sensitive to inactivation by O{sub 2}, the by-product of the water-splitting process. This problem has been one of the major practical factors limiting the commercial utilization of green algae for H{sub 2} production. The other major limitation, saturation of H{sub 2} production by algae at light intensities much lower than normal solar levels, is being addressed by ORNL. The objectives of this project are to generate O{sub 2}-tolerant, H{sub 2}-producing mutants of the green alga Chlamydomonas reinhardtti, to test them in a laboratory-scale system for continuous production of H{sub 2} under aerobic conditions; and to collaborate with ORNL to improve the overall efficiency of H{sub 2} production in intact and cell-free systems. The ultimate goal of the work is to configure a photobiological water-splitting process that will lead to a H{sub 2}-producing system that is cost effective, scalable, non-polluting, and renewable. The approach to obtain O{sub 2}-tolerant mutants of Chlamydomonas involves two types of selection techniques. The first depends on the survival of cells under photoreductive conditions, where H{sub 2} utilization is required, and the second requires the survival of the organisms under H{sub 2}-producing conditions. As part of this collaboration, the authors have independently confirmed that two of the Chlamydomonas mutants lacking photosystem I used by ORNL do in fact produce O{sub 2} in the light and also evolve H{sub 2}. Not unexpectedly, they do the latter with the same O{sub 2}-sensitivity as the WT cells. This observation is crucial for the credibility of the important ORNL work, since it confirms the potential for doubling the quantum efficiency for H{sub 2} production in these mutants.