The effects of phosphorus (P) limitation on growth, toxicity, and variable chl fluorescence of Alexandrium minutum were examined in batch culture experiments. Cell division was greatly impaired in P‐limited cultures, but P spiking of these cultures after 9 days stimulated high levels of cell division equivalent to P‐replete cultures. The cellular concentration of paralytic shellfish toxins was consistent over the growth cycle of control cultures from lag phase into logarithmic growth phase, with toxins repeatedly lost to daughter cells during division. The low level of cell division in P‐limited cultures resulted in a 10‐fold increase of cellular toxin compared with controls, but this dropped upon P spiking due to increased rates of cell division. The history of phosphorus supply had an important effect on toxin concentration, with the P‐limited and the P‐spiked cultures showing values 2‐fold higher than the P‐replete cultures. Toxin profiles of the A. minutum strain used in these experiments were dominated by the N1‐hydroxy toxins, gonyautoxins (GTX) GTX1 and GTX4, which were approximately 40 times more abundant than their analogues, GTX2 and GTX3, in P‐limited cultures. The dominance of the N1‐hydroxy toxins increased significantly in control cultures as they advanced through logarithmic growth. In‐line measurements of the variable chl fluorescence of light‐adapted cells indicated consistent photochemical efficiency under P‐replete conditions. P limitation induced a drop in fluorescence‐based photochemical efficiency that was reversible by P spiking. There was an inverse linear relationship between in‐line fluorescence and cell toxin quota (r = −0.88). Monitoring fluorescence in‐line may be valuable in managing efficient biotechnological production of toxins.
Photobiological hydrogen production by the unicellular green alga Chlamydomonas reinhardtii has been studied under laboratory conditions to a vast extend but has not been investigated under outdoor conditions yet. Because the hydrogen-producing hydrogenase is very sensitive to oxygen, the production must be performed in a two-stage process: generation of the required algal biomass under oxygenic photosynthesis, followed by hydrogen biosynthesis under anaerobic conditions. In order to design a sustainable process, cultivation and subsequent hydrogen production under cost-free sunlight was investigated in this work for the first time. First, cells were grown in closed photobioreactors under simulated outdoor conditions according to the light intensities of an idealized summer day (up to 2,000 μmol photons m −2 s −1 ) in order to achieve results independent of varying, and therefore not reproducible, weather conditions. The following outdoor experiments showed comparable growth characteristics and similar cell densities. However, the use of cells grown under outdoor, simulated outdoor, or high light conditions generally resulted in significantly lower hydrogen yields compared to the use of cells cultivated under low and continuous irradiance. In order to lower cultivation costs during the growth phase, the use of 10% CO 2 corresponding to the CO 2 content of flue gas was investigated. By supplying additional CO 2 during growth under the light profile corresponding to an idealized summer day, no significant increase of cell densities could be achieved, but the subsequent hydrogen production increased compared to hydrogen production of cells grown under atmospheric CO 2 .
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