CHROMATIC REGULATION OF QUANTUM YIELDS FOR PHOTOSYSTEM II CHARGE SEPARATION, OXYGEN EVOLUTION, AND CARBON FIXATION IN HETEROCAPSA PYGMAEA (PYRROPHYTA)

Operational and maximum quantum yields for system (PSII) charge separation, oxygen evolution, and carbon fixation were quantified and compared for Heterocapsa pygmaea Loeblich, Schmidt et Sherley populations chromatically adapted to white, green, blue, and red light. Significant variability in quantum yields was induced by chromatic adaptation alone or when chromatically adapted cells were suddenly exposed to biased light fields (i.e. white light). Results indicated a close coupling between the variability in quantum yields for PSII charge separation and oxygen evolution, but not between quantum yields for oxygen evolution and carbon fixation. But not between quantum yields for oxygen evolution and carbon fixation. The ability to regrlate and optimize light energy distribution between PSII and photosystem I (PSI) appears to be the mechanism underlying chromatic adaptation for PSII charge separation and oxygen evolution. Conceptually, the resulting impacts on PSI cyclic electron transport rates could account for observed variability in quantum yields for oxygen evolution and some variability in quantum yields for carbon fixation. Similarly, enzymatic processes associated with organic carbon synthesis appeared to be variably dependent on spectral growth irradiances and contributing to the observed variability in quantum yields for carbon fixation. The relevance of these findings to the in situ primary production is discussed.