Light-dependent hydrogen evolution by Scenedesmus

Abstract

The effect of glucose and the uncoupler Cl-CCP upon hydrogen production was studied in adapted cells of Scenedesmus obliquus D₃. Cl-CCP at 10^-5M concentration completely inhibited the evolution of H₂ in the dark and increased the apparent rate of H₂ evolution in the light. At 10^-5M Cl-CCP, photosynthesis and photoreduction by anaerobically adapted algae were only temporarily inhibited; O₂ evolution reappeared after approximately 1 hr of illumination if CO₂ was present. Increasing the Cl-CCP concentration to 5 x 10^-5M led to a maximum rate of photohydrogen production and fully inhibited H₂ evolution, photoreduction and dark H₂ evolution. H₂ evolution was accompanied by a release of varying amounts of CO₂ in the light, as well as in the dark. Dark CO₂ production was stimulated by Cl-CCP. H₂ evolution in the light was stimulated by adding glucose to autotrophically grown cells or by growing the cells heterotrophically with glucose; starvation had an opposite effect. Adapted cells released ¹⁴CO₂ from the 3 and/or 4 position of specifically labeled glucose, indicating that degradation occurred via the Embden-Meyerhof pathway. The amount of H₂ released by autotrophically grown cells was the same either with continuous illumination or with short periods of light, followed by darkness. Scenedesmus mutant No. 11, which is unable to evolve O₂ was not inhibited in its capacity to evolve H₂ in the light. These data indicate that the evolution of H₂ in the light by adapted Scenedesmus depends upon the degradation of organic material and does not require the production of free O₂ by photosystem II.