Cooperative binding of oxygen to the water-splitting enzyme in the filamentous cyanobacterium Oscillatoria chalybea

In the filamentous cyanobacterium Oscillatoria chalybea photolysis of water does not take place in the complete absence of oxygen. A catalytic oxygen partial pressure of 15×10 −6 Torr has to be present for effective water splitting to occur. By means of mass spectrometry we measured the photosynthet...

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Bibliographic Details
Published in:Biochimica et biophysica acta 2000-01, Vol.1456 (2), p.108-120
Main Authors: Bader, Klaus P., Schmid, Georg H.
Format: Article
Language:English
Subjects:
Cooperativity
Cyanobacteria - enzymology
Cyanobacterium
Enzymes - metabolism
Mass Spectrometry
Oxygen - metabolism
Oxygen isotope
Photosynthesis
Protein Binding
Water - metabolism
Water splitting
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Summary:In the filamentous cyanobacterium Oscillatoria chalybea photolysis of water does not take place in the complete absence of oxygen. A catalytic oxygen partial pressure of 15×10 −6 Torr has to be present for effective water splitting to occur. By means of mass spectrometry we measured the photosynthetic oxygen evolution in the presence of H 2 18O in dependence on the oxygen partial pressure of the atmosphere and analysed the liberations of 16O 2, 16O 18O and 18O 2 simultaneously. The observed dependences of the light-induced oxygen evolution on bound oxygen yield sigmoidal curves. Hill coefficient values of 3.0, 3.1 and 3.2, respectively, suggest that the binding is cooperative and that four molecules of oxygen have to be bound per chain to the oxygen evolving complex. Oxygen seems to prime the water-splitting reaction by redox steering of the S-state system, putting it in the dark into the condition from which water splitting can start. It appears that in O. chalybea an interaction of oxygen with S 0 and S 1 leads to S 2 and S 3, thus yielding the typical oxygen evolution pattern in which even after extensive dark adaptation substantial amounts of Y 1 and Y 2 are found. The interacting oxygen is apparently reduced to hydrogen peroxide. Mass spectrometry permits to distinguish this highly specific oxygen requirement from the interaction of bulk atmospheric oxygen with the oxygen evolving complex of the cyanobacterium. This interaction leads to the formation H 2O 2 which is decomposed under O 2 evolution in the light. The dependence on oxygen-partial pressure and temperature is analysed. Structural peculiarities of the cyanobacterial reaction centre of photosystem II referring to the extrinsic peptides might play a role.
ISSN:0005-2728
0006-3002
1879-2650
DOI:10.1016/S0005-2728(99)00108-5