Abstract
Photoacoustics (PA) allows the determination of enthalpy and volume changes of photoreactions in photosynthetic reaction centers on the 0.1–10 μs time scale. These include the bacterial centers from Rb. sphaeroides, PS I and PS II centers from Synechocystis and in whole cells. In vitro and in vivo PA data on PS I and PS II revealed that both the volume change (–26 A3) and reaction enthalpy (–0.4 eV) in PS I are the same as those in the bacterial centers. However the volume change in PS II is small and the enthalpy far larger, –1 eV. Assigning the volume changes to electrostriction allows a coherent explanation of these observations. One can explain the large volume decrease in the bacterial centers with an effective dielectric coefficient of ∼4. This is a unique approach to this parameter so important in estimation of protein energetics. The value of the volume contraction for PS I can only be explained if the acceptor is the super- cluster (Fe4S4)(Cys4) with charge change from –1 to –2. The small volume change in PS II is explained by sub-μs electron transfer from YZ anion to P680 cation, in which charge is only moved from the YZ anion to the QA with no charge separation or with rapid proton transfer from oxidized YZ to a polar region and thus very little change in electrostriction. At more acid pH equally rapid proton transfer from a neighboring histidine to a polar region may be caused by the electric field of the P680 cation.
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Mauzerall, D., Hou, JM. & Boichenko, V.A. Volume changes and electrostriction in the primary photoreactions of various photosynthetic systems: estimation of dielectric coefficient in bacterial reaction centers and of the observed volume changes with the Drude–Nernst equation. Photosynthesis Research 74, 173–180 (2002). https://doi.org/10.1023/A:1020903525973
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DOI: https://doi.org/10.1023/A:1020903525973