Abstract
The water-soluble chemical modifier, diazonium benzene-sulfonic acid, significantly inhibited photosystem II-dependent water oxidation (oxygen evolution) when the compound was reacted with chloroplast membranes in the light but not in the dark. The photochemistry of photosystem II was not affected by the diazonium treatment, shown by complete restoration of photosystem II-dependent electron flow from the alternate electron donor diphenylcarbazide. Paralleling the inhibition of oxygen evolution the illuminated chloroplasts bound significantly more diazonium reagent than did chloroplasts treated in the dark. Both the inhibition of oxygen evolution and the increased binding of the diazonium to the membranes were dependent on photosystem II electron flux, which could not be replaced by photosystem I cyclic electron flow. A dark base to acid or acid to base transition resulted in a similar inhibition of water oxidation and increased diazonium binding. The results suggest a membrane conformational change associated with photosystem II electron flow that exposes otherwise buried diazo reactive groups at the external grana membrane surface.
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