Quantification of the rate of CO2 formation in the periplasmic space of microalgae during photosynthesis. A comparison of whole‐cell rate constants for CO2 and HCO3– uptake among three species of the green alga Chlorella

Abstract

As previously described, the absolute rate of photosynthesis due to a limited concentration of dissolved inorganic carbon at alkaline pH, where the rate of CO₂ formation is strictly limited, plotted as a function of chlorophyll (Chl) concentration, will take the form of a rectangular hyperbola combined with a linear rate directly proportional to [Chl], which are, respectively, due to the contribution of CO₂ and HCO₃^– to photosynthesis. This model represents that the mathematical asymptote of absolute rate of photosynthesis versus cell density is described by the whole‐cell rate constant for HCO₃^– uptake and the maximum rate of CO₂ formation in the extracellular space. This means that any trace modification of the CO₂ formation rate outside the cell will alter the photosynthetic rate and should be detectable experimentally. In air‐grown Chlorella ellipsoidea and C. kessleri and in high CO₂‐grown C. saccharophila, the graph of the absolute rate of photosynthesis against [Chl] clearly followed the mathematical model described above and the actual CO₂ formation rates outside the cells were not significantly different from the calculated rates. It also indicated that the whole‐cell rate constants for CO₂ and HCO₃^– uptake in air‐grown C. ellipsoidea and C. saccharophila were similar at ≈ 300 and 2·0 mm³μg^–1 Chl min^–1, respectively, whereas those in air‐grown C. kessleri were ≈ 550 and 15 mm³μg^–1 Chl min^–1. These results indicate that no acidification of the periplasmic space occurs, and there is no trace activity of external carbonic anhydrase in these microalgae.