4 to 3 9 was observed Upon the onset of dark exposure,

v

4 to 3.9 was observed. Upon the onset of dark exposure,

values remained stable for approximately 1 min, declined thereafter, and established a quasi steady state for 20 min at a lower CH5183284 supplier ratio of 2.9 indicating an increase in the absorption cross section of PSI. After 30 min of dark incubation, the PSII:PSI ratio increased again and reached an F 685/F 715 ratio close to values of that of far-red-light-treated samples (4.22 ± 0.34 vs. 3.83 ± 0.56 for far-red light, and 1 h dark-acclimated cells, respectively; Fig. 5). Our results suggest that state-transitions are limited to 25% of the PSII-antenna when the PQ pool is completely reduced by PSI-light (ratio changes from 4.2 to 3.4). Interestingly, PSII:PSI ratios were different after 1 h dark acclimation prior to light exposure (t = 0 in Fig. 5), and after the block light treatment. In the first case, cells were dark-acclimated after exposure to the growth PF, while the experimental light treatment was approximately three times as high. Fig. 5 Low-temperature PSII/PSI fluorescence emission ratios (F 685/F 715 nm). Samples were collected during block light treatment of 660 μmol photons m−2 s−1 (open circles) and darkness (closed circles). Dark acclimation was 1 h prior to illumination. Far-red light treatment for 15 min after 1 h darkness showed highest values (dashed line). Data represent

mean of three independent measurements (±SD). Considerable higher cell densities than during FRRF measurements were required for analysis in this experiment. To account for package effects of the denser medium, photon flux BMS-907351 chemical structure was elevated compared to experiments where FRRF measurements were taken CCCP To further investigate the extent/GF120918 mw occurrence

of qE we added the protonophore uncoupler CCCP, which should collapse Fenbendazole the ΔpH gradient and thus qE. After addition of CCCP the F′ signal increased within about 1 min to maximal levels (+50 ± 13% of F′(pre-CCCP)), with an exponential decline thereafter to values of 120 ± 13% greater than those of F′(pre-CCCP) (Fig. 6). This demonstrates the existence of a pH-driven qE process. However, after the initial rise in F′ as a result of the collapse of the pH gradient, F′ decreased again and a steady state was established within 10 min after CCCP addition, presumably due to a state-transition to the low fluorescent state. When actinic light was switched off, the F 0 signal increased (by +31 ± 12% of F′(pre-CCCP)). During the first 18 min no saturation pulses were given. But when they were applied (indicated by the double arrowhead) considerable oscillation in F′ was observed. Fig. 6 Continuous fluorescence at room temperature using a Diving-PAM. Data show one representative fluorescence trace during block light treatment of 660 μmol photons m−2 s−1 and darkness (downward arrow). Cells were poisoned with 200 μM CCCP (double arrowhead) after a light acclimated state was established.

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