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Metabolism and Enzymology

Alternative Methods of Photosynthetic Carbon Assimilation in Marine Macroalgae ¹

Department of Botany, and the Center for Aquatic Plants, University of Florida, Gainesville, Florida 32611

Two green macroalgae, Codium decorticatum and Udotea flabellum, differ photosynthetically. Codium had high O₂-sensitive, and Udotea low O₂-insensitive, CO₂ compensation points; Codium showed a Warburg effect at seawater dissolved inorganic carbon levels and had photorespiratory CO₂ release, whereas Udotea did not. Seawater dissolved inorganic carbon levels did not saturate photosynthesis. For Codium, but not Udotea, the Warburg effect was increased by ethoxyzolamide, a carbonic anhydrase inhibitor, at high but not low pH. Isolated chloroplasts from both macroalgae showed a Warburg effect that was ethoxyzolamide-insensitive. In both macroalgae, chloroplastic and extrachloroplastic carbonic anhydrase activity was present. P-enolpyruvate carboxykinase (PEPCK) carboxylating activity in Udotea extracts was equivalent to that of ribulose bisphosphate carboxylase, and enzyme activities for C₄ acid metabolism and P-enolpyruvate regeneration were sufficient to operate a limited C₄-like system. In Udotea, malate and aspartate were early-labeled photosynthetic products that turned over within 60 seconds. Photorespiratory compounds were much less labeled in Udotea. Low dark fixation rates ruled out Crassulacean acid metabolism. A limited C₄-like system, based on PEPCK, is hypothesized to be the mechanism reducing photorespiration in Udotea. Codium showed no evidence of photosynthetic C₄ acid metabolism. Marine macroalgae, like terrestrial angiosperms, seem to have diverse photosynthetic modes.

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