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Metabolism and Enzymology

Chlorophyll a Fluorescence Predicts Total Photosynthetic Electron Flow to CO₂ or NO₃^–/NO₂^– under Transient Conditions ¹

Department of Biology, Queen's University, Kingston, Ontario, Canada, K7L 3N6

A model which predicts total photosynthetic electron flow from a linear regression of the relationship between corrected steady-state quantum yield and nonphotochemical quenching (E Weis, JA Berry [1987] Biochem Biophys Acta 894: 198-208) was formulated for N-limited cells of the green alga Selenastrum minutum. Unlike other models based on net CO₂ fixation, our model is based on total photosynthetic electron flow measured as gross O₂ evolution. This allowed for the prediction of total photosynthetic electron flow from water to both CO₂ fixation and NO₃^–/NO₂^– reduction. The linear regression equation predicting electron flow is of the form: J = I · Q_q[0.4777-0.3282 Q_NP] (where J = gross photosynthetic electron flow, I = incident PAR, Q_q = photochemical quenching, Q_NP = nonphotochemical quenching). During steady-state photosynthesis, over a range of irradiance, the model predicted a photosynthetic light saturation curve which was well correlated with that observed. Although developed under steady-state conditions, the model was tested during nonsteady-state photosynthesis induced by transient nitrogen assimilation. The model predicted transient rates of gross O₂ evolution which were in excellent agreement with the rates observed under a variety of conditions regardless of whether CO₂ or NO₃^–/NO₂^– served as the physiological electron acceptor. The fluorescence transients resulting from ammonium and nitrate assimilation are discussed with respect to metabolic demands for reductant and ATP.

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