Abstract
The influence of elevated CO2 concentrations on growth and photosynthesis ofGracilaria sp. andG. chilensis was investigated in order to procure information on the effective utilization of CO2. Growth of both was enhanced by CO2 enrichment (air + 650 ppm CO2, air + 1250 ppm CO2, the enhancement being greater inGracilaria sp. Both species increased uptake of NO3 − with CO2 enrichment. Photosynthetic inorganic carbon uptake was depressed inG. chilensis by pre-culture (15 days) with CO2 enrichment, but little affected inGracilaria sp. Mass spectrometric analysis showed that O2 uptake was higher in the light than in the dark for both species and in both cases was higher inGracilaria sp. The higher growth enhancement inGracilaria sp. was attributed to greater depression of photorespiration by the enrichment of CO2 in culture.
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References
Asada K (1981) Biological carboxylations. In Inoue S, Yamaguchi N (eds), Organic and Bio-organic Chemistry of Carbon Dioxide. Kodansha, Tokyo, 193–199.
Bidwell RGS, McLachlan J (1985) Carbon nutrition of seaweeds: photosynthesis, photorespiration and respiration. J. exp. mar. Biol. Ecol. 86: 15–46.
Bird CJ, McLachlan J (1986)Gracilaria chilensis sp. nov. (Rhodophyta, Gigartinales, from Pacific South America.) Can. J. Bot. 64: 2928–2934.
Bjork M, Haglund K, Ramazanov Z, Pedersen M (1993) Inducible mechanisms for HCO3 − utilization and repression of photorespiration in protoplasts and thalli of three species of Ulva (Chlorophyta). J. Phycol. 29: 166–173.
Coleman JR (1991) The molecular and biochemical analyses of CO2 concentrating mechanisms in cyanobacteria and microalgae. Plant Cell Environ. 14: 861–867.
FAO (1990) Training Manual onGracilaria Culture and Seaweed Processing in China. Regional Seafarming Development and Demonstration Project. Training Manual 6.
Gao K (1992) Technical Report: Studies on CO2 Fixation by Seaweeds. Kansai Environmental Engineering Center (Osaka) (in Japanese).
Gao K, Nakahara H (1990) Effects of nutrients on the photosynthesis ofSargassum thunbergii. Bot. Mar. 33: 375–383.
Gao K, Aruga Y, Asada K, Ishihara T, Akano T, Kiyohara M (1991) Enhanced growth of the red algaPorphyra yezoensis Ueda in high CO2 concentrations. J. appl. Phycol. 3: 355–362.
Gao K, Aruga Y, Asada K, Ishihara T, Akano T, Kiyohara M (1992) Photorespiration and CO2 fixation in the red algaPorphyra yezoensis Ueda. Jpn. J. Phycol. 40: 373–377.
Giordano M, Maberly SC (1989) Distribution of carbonic anhydrase in British marine macroalgae. Oecologia 81: 534–539.
Graham D, Smillie RM (1976) Carbonate dehydrase in marine organisms of the Great Barrier Reef. Aust. J. Plant Physiol. 3: 113–119.
Haglund K, Pedersen M (1992) Growth of the red algaGracilaria tenuistipitata at high pH. Influence of some environmental factors and correlation to an increased carbonicanhydrase activity. Bot. Mar. 35: 579–587.
Hanelt D (1992) Photoinhibition of photosynthesis in marine macrophytes of the South China Sea. Mar. Ecol. Progr. Ser. 82: 199–206.
Israel A & Beer S (1992) Photosynthetic carbon acquisition in the red algaGracilaria conferta. II. Rubisco carboxylase kinetics, carbonic anhydrase and HCO3 − uptake. Mar. Biol. 112: 697–200.
Iwamoto K (ed.) (1985) Manual of city water analysis (Josui-Shiken Hoho). Japan Waterworks Association. (in Japanese).
Johnston AM, Raven JA (1990) Effects of culture in high CO2 on the photosynthetic physiology ofFucus serratus. Br. Phycol. J. 25: 75–82.
Lapointe BE (1987) Phosphorus and nitrogen limited photosynthesis and growth ofGracilaria tikvahiae. Mar. Biol. 93: 561–568.
Levavasseur G, Edwards GE, Osmond CB, Ramus J (1991) Inorganic carbon limitation of photosynthesis inUlva rotundata (Chlorophyta). J. Phycol. 27: 667–672.
Lignell A, Pedersen M (1989). Effects of pH and inorganic carbon concentration on growth ofGracilaria secundata. Br. phycol. J. 24: 83–89.
Maberly SC (1990) Exogenous sources of inorganic carbon for photosynthesis by marine macroalgae. J. Phycol. 26: 439–449.
Oresso CA (1989) Ecophysiological Study ofGracilaria species in Tosa Bay, Southern Japan. Master Thesis, Kochi University.
Provasoli L (1966) Media and prospects for the cultivation of marine algae. In Watanabe A, Hattori A (eds), Cultures and Collections of Algae (Proc. U.S.-Japan Conf. Hokone, Sept. 1966). Jap. Soc. Plant Physiol, 63–75.
Quay PK, Tilbrook B, Wong CS (1992) Oceanic uptake of fossil fuel CO2: carbon-13 evidence. Science 256: 74–79.
Radmer R, Ollinger O (1980) Measurement of the oxygen cycle: the mass spectrometric analysis of gases dissolved in a liquid. Methods in Enzymology 69: 547–560.
Raven JA (1991) Physiology of inorganic C acquisition and implications for resource use efficiency by marine phytoplankton: relation to increased CO2 and temperature. Plant Cell Environ. 14: 779–794.
Smith RG, Bidwell RGS (1987) Carbonic anhydrase-dependent inorganic carbon uptake by the red macroalga,Chondrus crispus. Plant Physiol. 83: 735–738.
Stumm W, Morgan JJ (1981) Aquatic Chemistry. Wiley, New York.
Surif MB, Raven JA (1989) Exogenous inorganic carbon sources for photosynthesis in seawater by members of the Fucales and the Laminariales (Phaeophyta): ecological and taxonomic implications. Oecologia 78: 97–105.
Tsuzuki M, Miyachi S (1989) The function of carbonic anhydrase in aquatic photosynthesis. Aquat. Bot. 34: 85–104.
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Gao, K., Aruga, Y., Asada, K. et al. Influence of enhanced CO2 on growth and photosynthesis of the red algaeGracilaria sp. andG. chilensis . J Appl Phycol 5, 563–571 (1993). https://doi.org/10.1007/BF02184635
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DOI: https://doi.org/10.1007/BF02184635