1999, 2002) Furthermore, state transitions in C reinhardtii are

1999, 2002). Furthermore, state transitions in C. reinhardtii are substantially affected by anaerobiosis. The PQ pool, whose reduction

state is one of the key signals for state transitions (see more Wollman 2001), is maximally reduced in the absence of O2, probably because PRIMA-1MET purchase the plastidic terminal oxidase as a part of the chlororespiratory pathway cannot function (Wollman and Delepelaire 1984). In addition, oxidation of exogenously provided acetate tends to cause reduction of the PQ-pool and can result in state transitions toward state 2 in the dark (Endo and Asada 1996). Having this in mind, one has to be careful not to let the algal sample become anoxic in the dark incubation prior to the measurement, unless this is desired. On the other hand, if one takes samples from the culture container to analyze S-deprived and H2-producing C. reinhardtii cells, this might result in some aeration

of the cells, causing a change in the bioenergetic status of the latter. Again, on-line measurements within a bioreactor are much better suited for the monitoring of the bioenergetic status of the photosynthetic apparatus and the cells themselves. Screening systems for the targeted isolation of mutants with an altered H2 metabolism this website Basic research on H2 metabolism and efforts to increase yields of H2 production by the microalgae make use of well-established techniques allowing forward Pregnenolone and reverse genetics in C. reinhardtii (Galván et al. 2007). To identify genes whose products are involved in the H2 metabolism of C. reinhardtii or to create strains with optimized phenotypes regarding H2 yields, transformant libraries are created by DNA insertional mutagenesis. This is an easy and well-established method to mutagenize C. reinhardtii and tag the affected genes simultaneously (Kindle 1990). However, to identify the strains of interest, a powerful screening system must be at hand. Here, research on both algal

hydrogenases and H2 metabolism has profited from the coupling of these processes with photosynthesis. Three screening systems with different objectives have been established, all of these relying on photosynthetic activity. The first screening protocol aims at identifying algal mutant strains with any defect affecting H2 production by making use of the fact that dark-adapted and anaerobic Chlamydomonas cells show a transient but high H2-production activity after a sudden dark–light shift. This screening utilizes the characteristics of tungsten oxide, which changes its color after being reduced by hydrogen. The second screening system has been established both for biotechnological reasons and optimizing the analysis of photosynthetic H2 production. It selectively screens for C.

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