Photosynthetic use of inorganic carbon in deep-water kelps from the Strait of Gibraltar

详细信息    查看全文

• 作者：María Jesús García-Sánchez ; Antonio Delgado-Huertas…
• 关键词：Carbonic anhydrase ; CO2 concentration mechanism ; Kelps ; HCO3 − ; Laminaria ochroleuca ; Phyllariopsis brevipes ; Phyllariopsis purpurascens ; Saccorhiza polyschides ; δ13C
• 刊名：Photosynthesis Research
• 出版年：2016
• 出版时间：March 2016
• 年：2016
• 卷：127
• 期：3
• 页码：295-305
• 全文大小：688 KB
• 参考文献：Axelsson L (1988) Changes in pH as a measure of photosynthesis by marine macroalgae. Mar Biol 97:287–294. doi:10.​1007/​BF00391314 CrossRef
  Axelsson L, Uusitalo J (1988) Carbon acquisition strategies for marine macroalgae. I. Utilization of proton exchanges visualized during photosynthesis in a closed system. Mar Biol 97:295–300. doi:10.​1007/​BF00391315 CrossRef
  Axelsson L, Larsson C, Ryberg H (1999) Affinity, capacity and oxygen sensitivity of two different mechanisms for bicarbonate utilization in Ulva lactuca L. (Chlorophyta). Plant, Cell Environ 22:969–978. doi:10.​1046/​j.​1365-3040.​1999.​00470.​x CrossRef
  Axelsson L, Mercado JM, Figueroa FL (2000) Utilization of HCO3 − at high pH by the brown macroalga Laminaria saccharina. Eur J Phycol 35:53–59. doi:10.​1080/​0967026001000173​5621 CrossRef
  Björk M, Haglund K, Ramazanov Z, García-Reina G, Pedersén M (1992) Inorganic-carbon assimilation in the green seaweed Ulva rigida C. Ag. (Chlorophyceae). Planta 187:152–156. doi:10.​1007/​BF00201637 CrossRef PubMed
  Connell SD, Russell BD (2010) The direct effects of increasing CO2 and temperature on non-calcifying organisms: increasing the potential for phase shifts in kelp forests. Proc Biol Sci 277:1409–1415. doi:10.​1098/​rspb.​2009.​2069 PubMedCentral CrossRef PubMed
  Cornwall C, Hepburn CD, Pritchard D, McGraw C, Hunter K, Hurd CL (2012) Carbon-use strategies in macroalgae: differential responses to lowered pH and implications for ocean acidification. J Phycol 48:137–144. doi:10.​1111/​j.​1529-8817.​2011.​01085.​x CrossRef
  Drechsler Z, Sharkia R, Cabantchik ZI, Beer S (1993) Bicarbonate uptake in the marine macroalga Ulva sp. is inhibited by classical probes of anion exchange by red blood cells. Planta 191:34–40CrossRef
  Edwards G, Walker DA (1983) C3, C4. Molecular, cellular and environmental regulation of photosynthesis. Blackwell Science, Oxford
  Fernández P, Hurd CL, Roleda M (2014) Bicarbonate uptake via an anion exchange protein is the main mechanism of inorganic carbon acquisition by the giant kelp Macrocystis pyrifera (Laminariales, Phaeophyceae) under variable pH. J Phycol 50:998–1008. doi:10.​1111/​jpy.​12247 CrossRef
  Fernández P, Roleda M, Hurd CL (2015) Effects of ocean acidification on the photosynthetic performance, carbonic anhydrase activity and growth of the giant kelp Macrocystis pyrifera. Photosynth Res 124:293–304. doi:10.​1007/​s11120-015-0138-5 CrossRef PubMed
  Flores-Moya A (1997) Changes in reproductive effort, lamina area index and standing crop with depth in the deep water brown alga Phyllariopsis purpurascens (Laminariales). Phycologia 36:32–37. doi:10.​2216/​i0031-8884-36-1-32.​1 CrossRef
  Flores-Moya A (2012) Warm temperate communities: a case study of deep water kelp forests from the Alborán Sea (SW Mediterranean Sea) and the Strait of Gibraltar. In: Wiencke C, Bischof K (eds) Seaweed biology. Ecological studies 219. Springer, Berlin, pp 315–328
  Flores-Moya A, Fernández JA (1998) The role of external carbonic anhydrase in the photosynthetic use of inorganic carbon in the deep-water alga Phyllariopsis purpurascens (Laminariales, Phaeophyta). Planta 207:115–119. doi:10.​1007/​s004250050462 CrossRef
  Flores Moya A, Fernández JA, Niell FX (1995) Seasonal variations of photosynthetic pigments, total C, N, and P content, and photosynthesis in Phyllariopsis purpurascens (Phaeophyta) from the Strait of Gibraltar. J Phycol 31:867–874. doi:10.​1111/​j.​0022-3646.​1995.​00867.​x CrossRef
  Gaitián-Espitia JD, Hancock JR, Padilla-Gamiño JL, Rivest EB, Blanchette CA, Reed DC, Hofmann GE (2014) Interactive effects of elevated temperature and pCO2 on early–life–history stages of the giant kelp Macrocystis pyrifera. J Exp Mar Biol Ecol 457:51–58. doi:10.​1016/​j.​jembe.​2014.​03.​018 CrossRef
  Giordano M, Beardall J, Raven JA (2005) CO2 concentrating mechanisms in algae. Mechanisms, environmental modulation, and evolution. Annu Rev Plant Biol 56:99–131. doi:10.​1146/​annurev.​arplant.​56.​032604.​144052 CrossRef PubMed
  Haglund K, Björk M, Ramazanov Z, García-Reina G, Pedersén M (1992a) Role of carbonic anhydrase in photosynthesis and inorganic-carbon assimilation in the red alga Gracilaria tenuistipitata. Planta 187:275–281. doi:10.​1007/​BF00201951 CrossRef PubMed
  Haglund K, Ramazanov Z, Mtolera M, Pedersén M (1992b) Role of external carbonic anhydrase in light-dependent alkalization by Fucus serratus L. and Laminaria saccharina (L.) Lamour. (Phaeophyta). Planta 188:1–6. doi:10.​1007/​BF01160705 CrossRef PubMed
  Hammer Ø, Harpe DAT, Ryan PD (2001) PAST: paleontological statistics software package for education and data analysis. Palaeontol Electron 4:1–9. http://​palaeo-electronica.​org/​2001_​1/​past/​issue1_​01.​htm
  Hellblom F, Beer S, Björk M, Axelsson L (2001) A buffer sensitive inorganic carbon utilization system in Zostera marina. Aquat Bot 69:55–62. doi:10.​1016/​S0304-3770(00)00132-7 CrossRef
  Hepburn DC, Pritchard DW, Cornwall CE, McLeod RJ, Beardall J, Raven JA, Hurd CL (2011) Diversity of carbon use strategies in a kelp forest community: implications for a high CO2 ocean. Glob Change Biol 17:2488–2497. doi:10.​1111/​j.​1365-2486.​2011.​02411.​x CrossRef
  Hurd CL (2000) Water motion, marine macroalgal ecophysiology and production. J Phycol 36:453–472. doi:10.​1046/​j.​1529-8817.​2000.​99139.​x CrossRef
  Johnson KS (1982) Carbon dioxide hydration and dehydration kinetics in seawater. Limnol Oceanogr 27:849–855CrossRef
  Johnston AM (1991) The acquisition of inorganic carbon by marine macroalgae. Can J Bot 69:1123–1132. doi:10.​1139/​b91-144 CrossRef
  Klenell M, Snoeijs P, Pedersén M (2002) The involvement of a membrane H+-ATPase in the blue-light enhancement of photosynthesis in Laminaria digitata (Phaeophyta). J Phycol 38:1143–1149. doi:10.​1046/​j.​1529-8817.​2002.​02063.​x CrossRef
  Klenell M, Snoeijs P, Pedersén M (2004) Active carbon uptake in Laminaria digitata and L. saccharina (Phaeophyta) is driven by a proton pump in the plasma membrane. Hydrobiologia 514:41–53. doi:10.​1007/​978-94-017-0920-0_​4 CrossRef
  Kübler JE, Raven JA (1994) Consequences of light limitation for inorganic carbon acquisition in three rhodophytes. Mar Ecol Prog Ser 110:203–209CrossRef
  Maberly SC (1990) Exogenous sources of inorganic carbon for photosynthesis by marine macroalgae. J Phycol 26:439–449. doi:10.​1111/​j.​0022-3646.​1990.​00439.​x CrossRef
  Maberly SC, Raven JA, Johnston AM (1992) Discrimination between 12C and 13C by marine plants. Oecologia 91:481–492. doi:10.​1007/​BF00650320 CrossRef
  Marconi M, Giordano M, Raven JA (2011) Impact of taxonomy, geography, and depth on δ13C and δ15N variation in a large collection of macroalgae. J Phycol 47:1023–1025. doi:10.​1111/​j.​1529-8817.​2011.​01045.​x CrossRef
  Mercado JM, Gordillo FJL (2011) Inorganic carbon acquisition in algal communities: are the laboratory data relevant to the natural ecosystems? Photosynth Res 109:257–267. doi:10.​1007/​s11120-011-9646-0 CrossRef PubMed
  Mercado JM, Niell FX, Figueroa FL (1996) Regulation of the mechanism for HCO3 − use by the inorganic carbon level in Porphyra leucosticta Thur. in Le Jolis (Rhodophyta). Planta 201:319–325. doi:10.​1007/​s004250050073 CrossRef
  Mercado JM, Gordillo FJL, Figueroa FL, Niell FX (1998) External carbonic anhydrase and affinity for inorganic carbon in intertidal macroalgae. J Exp Mar Biol Ecol 221:209–220. doi:10.​1016/​S0022-0981(97)00127-5 CrossRef
  Mercado JM, Andría JR, Pérez-Llorens JL, Vergara JJ, Axelsson L (2006) Evidence for a plasmalemma-based CO2 concentrating mechanism in Laminaria saccharina. Photosynth Res 88:259–268. doi:10.​1007/​s11120-006-9039-y CrossRef PubMed
  Mercado JM, de los Santos CB, Pérez-Llorens JL, Vergara JJ (2009) Carbon isotopic fractionation in macroalgae from Cádiz Bay (Southern Spain): comparison with other bio-geographic regions. Estuar Coast Shelf Sci 85:449–458. doi:10.​1016/​j.​ecss.​2009.​09.​005 CrossRef
  Meyer M, Griffiths H (2013) Origins and diversity of eukaryotic CO2-concentrating mechanisms: lessons for the future. J Exp Bot 64:769–786. doi:10.​1093/​jxb/​ers390 CrossRef PubMed
  Moulin P, Andría JR, Axelsson L, Mercado JM (2011) Different mechanisms of inorganic carbon acquisition in red macroalgae (Rhodophyta) revealed by the use of TRIS buffer. Aquat Bot 95:31–38. doi:10.​1016/​j.​aquabot.​2011.​03.​007 CrossRef
  Murru M, Sandgren CD (2004) Habitat matters for inorganic carbon acquisition in 38 species of red macroalgae (Rhodophyta) from Puget Sound, Washington, USA. J Phycol 40:837–845. doi:10.​1111/​j.​1529-8817.​2004.​03182.​x CrossRef
  Park PK (1969) Oceanic CO2 system: an evaluation of ten methods of investigation. Limnol Oceanogr 14:179–186CrossRef
  Price GD, Badger MR (1985) Inhibition by proton buffers of photosynthetic utilization of bicarbonate in Chara corallina. Aust J Plant Physiol 12:257–267. doi:10.​1071/​PP9850257 CrossRef
  Rautenberger R, Fernández PA, Strittmatter M, Heesch S, Cornwall CE, Hurd CL, Roleda MY (2015) Saturating light and not increasing carbon dioxide under ocean acidification drives photosynthesis and growth in Ulva rigida (Chlorophyta). Ecol Evol 5:874–888. doi:10.​1002/​ece3.​1382 PubMedCentral CrossRef PubMed
  Raven JA (1997) Inorganic carbon acquisition by marine photoautrophs. Adv Bot Res 27:86–209
  Raven JA, Beardall J (2003) Carbon acquisition mechanisms of algae: carbon dioxide diffusion and carbon dioxide concentration mechanisms. In: Larkum WD, Douglas SE, Raven JA (eds) Photosynthesis in Algae. Kluwer Academic Publishers, Dordrecht, pp 225–244CrossRef
  Raven JA, Farquhar GD (1990) The influence of N-metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants. New Phytol 116:505–529. doi:10.​1111/​j.​1469-8137.​1990.​tb00536.​x CrossRef
  Raven JA, Walker DI, Johnston AM, Handley LL, Kübler JE (1995) Implications of 13C natural abundances measurements for photosynthetic performance by marine macrophytes in their natural environment. Mar Ecol Prog Ser 123:193–205. doi:10.​3354/​meps123193 CrossRef
  Raven JA, Johnston AM, Kübler JE, Korb RE, McInroy SG, Handley LL, Scrimgeour CM, Walker DI, Beardall J, Vanderklift M, Fredriksen S, Dunton KH (2002a) Mechanistic interpretation of carbon isotope discrimination by marine macroalgae and seagrasses. Funct Plant Biol 29:355–378. doi:10.​1071/​PP01201 CrossRef
  Raven JA, Johnston AM, Kübler JE, Korb RE, McInroy SG, Handley LL, Scrimgeour CM, Walker DI, Beardall J, Clayton MN, Vanderklift M, Fredriksen S, Dunton KH (2002b) Seaweeds in cold seas: evolution and carbon acquisition. Ann Bot 90:525–536. doi:10.​1093/​aob/​mcf171 PubMedCentral CrossRef PubMed
  Raven JA, Ball LA, Beardall J, Giordano M, Maberly SC (2005) Algae lacking carbon concentrating mechanisms. Can J Bot 83:879–890. doi:10.​1139/​b05-074 CrossRef
  Roleda MY, Morris JN, McGraw CM, Hurd CL (2012) Ocean acidification and seaweed reproduction: increased CO2 ameliorates the negative effect of lowered pH on meiospore germination in the giant kelp Macrocystis pyrifera (Laminariales, Phaeophyceae). Glob Change Biol 18:854–864. doi:10.​1111/​j.​1365-2486.​2011.​02594.​x CrossRef
  Royal Society (2005) Ocean acidification due to increasing atmospheric carbon dioxide. Policy document 12/05. The Royal Society, London
  Runcie JW, Gurgel CFD, McDermid KJ (2008) In situ photosynthetic rates of tropical marine macroalgae at their lower depth limit. Eur J Phycol 43:377–388. doi:10.​1080/​0967026080197930​3 CrossRef
  Sand-Jensen K, Gordon DM (1984) Differential ability of marine and freshwater macrophytes to utilize HCO3 − and CO2. Mar Biol 80:247–253CrossRef
  Scrimgeour CM, Robinson D (2003) Stable isotope analysis and applications. In: Smith KA, Cresser MS (eds) Soil and environmental analysis: modern instrumental techniques. Marcel Dekker, London, pp 381–431
  Snoeijs P, Klenell M, Choo KS, Comhaire I, Ray S, Pedersén M (2002) Strategies for carbon acquisition in the red marine macroalga Coccotylus truncatus from the Baltic Sea. Mar Biol 140:435–444. doi:10.​1007/​s00227-001-0729-x CrossRef
  Surif MB, Raven JA (1989) Exogenous inorganic carbon sources for photosynthesis in seawater by members of the Fucales and Laminariales (Phaeophyta): ecological and taxonomic implications. Oecologia 78:97–105. doi:10.​1007/​BF00377203 CrossRef
  Wiencke C, Fischer G (1990) Growth and stable carbon isotope composition of cold-water macroalgae in relation to light and temperature. Mar Ecol Prog Ser 65:283–292CrossRef
  Wiencke C, Gómez I, Pakker H, Flores-Moya A, Altamirano M, Hanelt D, Bischof K, Figueroa FL (2000) Impact of UV radiation on viability, photosynthetic characteristics and DNA of brown algal zoospores: implications for depth zonation. Mar Ecol Prog Ser 197:217–229. doi:10.​3354/​meps197217 CrossRef
  Yool A, Shepherd JG, Bryden HL, Oschlies A (2009) Low efficiency of nutrient translocation for enhancing oceanic uptake of carbon dioxide. J Geophys Res 114:C08009. doi:10.​1029/​2008JC004792
  Zar JH (1999) Biostatistical analysis, 4th edn. Prentice Hall, Upper Saddle River
  Zou D, Gao K (2010) Acquisition of inorganic carbon by Endarachne binghamiae (Scytosiphonales, Phaeophyceae). Eur J Phycol 45:117–126. doi:10.​1080/​0967026090338390​9 CrossRef
  Zou DH, Gao KS, Xia JR (2003) Photosynthetic utilization of inorganic carbon in the economic brown alga, Hizikia fusiforme (Sargassaceae) from the South China Sea. J Phycol 36:1095–1100. doi:10.​1111/​j.​1529-8817.​2010.​00929.​x CrossRef
  Zou D, Gao K, Chen W (2011) Photosynthetic carbon acquisition in Sargassum henslowianum (Fucales, Phaeophyta), with special reference to the comparison between the vegetative and reproductive tissues. Photosynth Res 107:159–168. doi:10.​1007/​s11120-010-9612-2 CrossRef PubMed
  
• 作者单位：María Jesús García-Sánchez (1)
  Antonio Delgado-Huertas (2)
  José Antonio Fernández (1)
  Antonio Flores-Moya (3)
  
  1. Departamento de Biología Vegetal (Fisiología Vegetal), Facultad de Ciencias, Universidad de Málaga, Campus de Teatinos s/n, 29071, Málaga, Spain
  2. Instituto Andaluz de Ciencias de la Tierra, Consejo Superior de Investigaciones Científicas-Universidad de Granada, 18100, Armilla, Spain
  3. Departamento de Biología Vegetal (Botánica), Facultad de Ciencias, Universidad de Málaga, Campus de Teatinos s/n, 29071, Málaga, Spain
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Plant Physiology
  
• 出版者：Springer Netherlands
• ISSN：1573-5079

文摘

Mechanisms of inorganic carbon assimilation were investigated in the four deep-water kelps inhabiting sea bottoms at the Strait of Gibraltar; these species are distributed at different depths (Saccorhiza polysiches at shallower waters, followed by Laminaria ochroleuca, then Phyllariopsis brevipes and, at the deepest bottoms, Phyllariopsis purpurascens). To elucidate the capacity to use HCO₃ − as a source of inorganic carbon for photosynthesis in the kelps, different experimental approaches were used. Specifically, we measured the irradiance-saturated gross photosynthetic rate versus pH at a constant dissolved inorganic carbon (DIC) concentration of 2 mM, the irradiance-saturated apparent photosynthesis (APS) rate versus DIC, the total and the extracellular carbonic anhydrase (CA_ext), the observed and the theoretical photosynthetic rates supported by the spontaneous dehydration of HCO₃ − to CO₂, and the δ13C signature in tissues of the algae. While S. polyschides and L. ochroleuca showed photosynthetic activity at pH 9.5 (around 1.0 µmol O₂ m−2 s−1), the activity was close to zero in both species of Phyllariopsis. The APS versus DIC was almost saturated for the DIC values of natural seawater (2 mM) in S. polyschides and L. ochroleuca, but the relationship was linear in P. brevipes and P. purpurascens. The four species showed total and CA_ext activities but the inhibition of the CA_ext originated the observed photosynthetic rates at pH 8.0 to be similar to the theoretical rates that could be supported by the spontaneous dehydration of HCO₃ −. The isotopic 13C signatures ranged from −17.40 ± 1.81 to −21.11 ± 1.73 ‰ in the four species. Additionally, the δ13C signature was also measured in the deep-water Laminaria rodriguezii growing at 60–80 m, showing even a more negative value of −26.49 ± 1.25 ‰. All these results suggest that the four kelps can use HCO₃ − as external carbon source for photosynthesis mainly by the action of external CA_ext, but they also suggest that the species inhabiting shallower waters show a higher capacity than the smaller kelps living in deeper waters. In fact, the photosynthesis in the two Phyllariopsis species could be accomplished by the spontaneous dehydration of HCO₃ − to CO₂. These differences in the capacity to use HCO₃ − in photosynthesis among species could be important considering the increasing levels of atmospheric CO₂ predicted for the near future.