SEARCH

SEARCH BY CITATION

References

  • Ainsworth EA, Long SP (2005) What have we learned from 15 years of free-air CO2 enrichment (FACE)? A meta-analytic review of the responses of photosynthesis, canopy properties and plant production to rising CO2. New Phytol 165: 351372
  • Allen SE (1989) Chemical Analysis of Ecological Materials, 2nd Edn. Blackwell Scientific Publications, Oxford, UK
  • Bernacchi CJ, Calfapietra C, Davey PA, Wittig VE, Scarascia-Mugnozza GE, Raines CA, Long SP (2003) Photosynthesis and stomatal conductance responses of poplars to free-air CO2 enrichment (PopFACE) during the first growth cycle and immediately following coppice. New Phytol 159: 609621
  • Blaschke L, Schulte M, Raschi A, Slee N, Rennenberg H, Polle A (2001) Photosynthesis, soluble and structural carbon compounds in two Mediterranean oak species (Quercus pubescens and Q. ilex) after life time growth at naturally elevated CO2 concentrations. Plant Biol 3: 288298
  • Bunce J (1992) Stomatal conductance, photosynthesis and respiration of temperature deciduous tree seedlings grown outdoors at an elevated concentration of carbon dioxide. Plant Cell Environ 15: 541549
  • Ceulemans R (1997) Direct impacts of CO2 and temperature on physiological processes in trees. In: MohrenGMJ, KramerK, SabatéS (eds), Impacts of Global Change on Tree Physiology and Forest Ecosystems Forestry Sciences, Vol. 52. Kluwer Academic Publishers, Dordrecht, the Netherlands, pp 314
  • Ceulemans R, Mousseau M (1994) Effects of elevated atmospheric CO2 on woody plants. New Phytol 127: 425446
  • Ceulemans R, Jiang XN, Shao BY (1995) Growth and physiology of one-year old poplar (Populus) under elevated atmospheric CO2 levels. Ann Bot 75: 609617
  • Chaves MM, Pereira JS, Cerasoli S, Clifton-Brown J, Miglietta F, Raschi A (1995) Leaf metabolism during summer drought in Quercus ilex trees with lifetime exposure to elevated CO2. J Biogeogr 22: 255259
  • Coûteaux MM, Kurz C, Bottner P, Raschi A (1999) Influence of increased atmospheric CO2 concentration on quality of plant material and litter decomposition. Tree Physiol 19: 301311
  • Curtis PS, Klus DJ, Kalisz S, Tonsor SJ (1996) Intraspecific variation in CO2 response in Raphanus raphanistrum and Plantago lanceolata: assessing the potential for evolutionary change with rising atmospheric CO2. In: KörnerC, BazzazFA (eds), Carbon Dioxide, Populations, and Communities. Academic Press, New York, pp 1322
  • Davis FW, Michaelsen J (1995) Sensitivity of fire regime in chaparral ecosystems to climate change. In: MorenoJM (ed), Global Change and Mediterranean Type Ecosystems. Ecological Studies, Vol. 117. Springer Verlag, Berlin, Germany, pp 435456
  • Dijkstra P, Hymus G, Colavito D, Vieglais DA, Cundari CM, Johnson DP, Hungate BA, Hinkle CR, Drake BG (2002) Elevated atmospheric CO2 stimulates aboveground biomass in a re-regenerated scrub-oak ecosystem. Glob Change Biol 8: 90103
  • Drake BG, Gonzàlez-Meler MA, Long SP (1997) More efficient plants: a consequence of rising atmospheric CO2? Annu Rev Plant Physiol Mol Biol 48: 609639
  • El Omari B, Fleck I, Aranda X, Abadía A, Cano A, Arnao MB (2003) Total antioxidant activity in Quercus ilex resprouts after fire. Plant Physiol Biochem 41: 4147
  • Faria T, Wilkins D, Besford RT, Vaz M, Pereira JS, Chaves MM (1996) Growth at elevated CO2 leads to down regulation of photosynthesis and altered to high temperature in Quercus suber L. J Exp Bot 47: 17551761
  • Farrar J (1993) Carbon partitioning. In: HallDO, ScurlockJMO, Bolhar-NordenkampfHR, LeegoodRC, LongSP (eds), Photosynthesis and Production in a Changing Environment. A Field and Laboratory Manual. Chapman & Hall, London, UK, pp 232246
  • Fleck I, Grau D, Sanjosé M, Vidal D (1996) Influence of fire and tree-fell on physiological parameters in Quercus ilex resprouts. Ann Sci For 53: 337346
  • Fleck I, Hogan KP, Llorens L, Abadía A, Aranda X (1998) Photosynthesis and photoprotection in Quercus ilex resprouts after fire. Tree Physiol 18: 607614
  • Griffin KL, Tissue DT, Turnbull MH, Whitehead D (2000) The onset of photosynthetic acclimation to elevated CO2 partial pressure in field-grown Pinus radiata D. Don. after 4 years. Plant Cell Environ 23: 10891098
  • Gunderson CA, Norby RJ, Wullscheler SD (1993) Foliar gas exchange responses of two deciduous hardwoods during 3 years of growth in elevated CO2: no loss of photosynthetic enhancement. Plant Cell Environ 16: 797807
  • Hättenschwiler S, Miglietta F, Raschi A, Körner C (1997) Thirty years of in situ tree growth under elevated CO2: a model for future forest responses? Glob Change Biol 3: 463471
  • Hogan KP, Fleck I, Bungard R, Cheeseman JM, Whitehead D (1997) Effect of elevated CO2 on the utilization of light energy in Nothofagus fusca and Pinus radiata. J Exp Bot 48: 12891297
  • Houghton JT, Ding Y, Griggs DJ, Noguer M, Van Der Linden PJ, Drai X, Maskell K, Johnson CA (2001) Climate Change: The Scientific Basis. Contribution of Working Group I in the Third Assessment Report of Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK
  • Joffre R, Gillon D, Dardenne P, Agneessens R, Biston R (1992) The use of near-infrared reflectance spectroscopy in litter decomposition studies. Ann For Sci 49: 481488
  • Karnosky DF (2003) Impacts of elevated atmospheric CO2 on forest trees and forest ecosystems: knowledge gaps. Environ Int 29: 161169
  • Körner C (2000) Biosphere responses to CO2 enrichment. Ecol Appl 10: 15901619
  • Körner C (2003) Carbon limitation in trees. J Ecol 91: 417
  • Körner C, Miglietta F (1994) Long term of naturally elevated CO2 on the Mediterranean grassland and forest effects. Oecologia 99: 343351
  • Körner C, Asshoff R, Bignucolo O, Hättenschwiler S, Keel SG, Pelaez-Riedl S, Pepin S, Siegwolf RTW, Zotz G (2005) Carbon flux and growth in mature deciduous forest trees exposed to elevated CO2. Science 309: 13601362
  • Krall JP, Edwards GE (1992) Relationship between photosystem II activity and CO2 fixation in leaves. Physiol Plant 86: 180187
  • Langley JA, Drake BG, Hungate BA (2002) Extensive belowground carbon storage supports and mycorrhizae in regenerating scrub oaks. Oecologia 131: 542548
  • Li JH, Dijkstra P, Hinkle CR, Wheeler RM, Drake BG (1999) Photosynthetic acclimation to elevated CO2 concentration in the Florida scrub-oak species Quercus germinata and Quercus myrtifolia growing in their native environment. Tree Physiol 19: 229234
  • Lichtenthaler HK (1987) Chlorophylls and carotenoids, the pigments of the photosynthetic biomembranes. In: DouceR, PackerL (eds), Methods in Enzymology. Academic Press, New York, pp 350382
  • Marek MV, Sprtová M, De Angelis P, Scarascia-Mugnozza G (2001) Spatial distribution of photosynthetic response to long-term influence of elevated CO2 in a Mediterranean macchia mini-ecosystem. Plant Sci 160: 11251136
  • Martens H, Naes T (1989) Multivariate Calibration. John Wiley & Sons, Chichester, UK
  • McMurtrie RE, Wang YP (1993) Mathematical models of the photosynthetic response of tree stands to rising CO2 concentrations and temperatures. Plant Cell Environ 16: 113
  • Medlyn BE, Barton CVM, Broadmeadow MSJ, Ceulemans R, DeAngelis P, Forstreuter M (2001) Stomatal conductance of forest species after long-term exposure to elevated CO2 concentrations: a synthesis. New Phytol 149: 247264
  • Melillo JM, McGuire AD, Kicklighter DW, Moore, B, III, Vorosmarty CJ, Schloss AL (1993) Global climate change and terrestrial net primary production. Nature 363: 234240
  • Meuret M, Dardenne P, Biston R, Poty O (1993) The use of NIR in predicting nutritive value of Mediterranean tree and shrub foliage. J Near Infrared Spectrosc 1: 4554
  • Moore BD, Cheng SH, Sims D, Seemann JR (1999) The biochemical and molecular basis for photosynthetic acclimation to elevated atmospheric CO2. Plant Cell Environ 22: 567582
  • Mouillot F, Rambal S, Joffre R (2002) Simulating climate change impacts on fire frequency and vegetation dynamics in a Mediterranean-type ecosystem. Glob Change Biol 8: 423437
  • Nowak RS, Ellsworth DS, Smith SD (2004) Functional responses of plants to elevated atmospheric and productivity data from FACE experiments support earlier predictions? New Phytol 162: 253280
  • Oxborough K, Baker NR (1997) Resolving chlorophyll a fluorescence images of photosynthetic efficiency into photochemical and non-photochemical components–calculation of qP and F′v/F′m without measuring F′o. Photosynth Res 54: 135142
  • Peña-Rojas K, Aranda X, Fleck I (2004) Stomatal limitation to CO2 assimilation and down-regulation of photosynthesis in Quercus ilex resprouts in response to slowly imposed drought. Tree Physiol 24: 813822
  • Peñuelas J, Estiarte M (1998) Can elevated CO2 affect secondary metabolism and ecosystem function? Trees 13: 2024
  • Peñuelas J, Castells E, Joffre R, Tognetti R (2002) Carbon-based secondary and structural compounds in Mediterranean shrubs growing near a natural CO2 spring. Glob Change Biol 8: 281288
  • Saurer M, Cherubini P, Bonani G, Siegwolf R (2003) Tracing carbon uptake from a natural CO2 spring into tree rings: an isotope approach. Tree Physiol 23: 9971004
  • Scarascia-Mugnozza G, De Angelis P, Mateaucci G, Valentini R (1996) Long term exposure to elevated [CO2] in a natural Quercus ilex L. community: net photosynthesis and photochemical efficiency of PSII at different levels of water stress. Plant Cell Environ 19: 643654
  • Seneweera SP, Ghannoum O, Conroy JP, Ishimaru K, Okada M, Lieffering M, Kim HY, Kobayashi K (2002) Changes in source–sink relations during development influence photosynthetic acclimation of rice to free air CO2 enrichment (FACE). Funct Plant Biol 29: 947955
  • Staudt M, Joffre R, Rambal S, Kesselmeier J (2001) Effect of elevated CO2 on monoterpene emission of young Quercus ilex trees and its relation to structural and ecophysiological parameters. Tree Physiol 21: 437445
  • Taub DR, Seemann JR, Coleman JS (2000) Growth in elevated CO2 protects photosynthesis against high temperature damage. Plant Cell Environ 23: 649656
  • Tissue DT, Thomas RB, Strain BR (1997) Atmospheric CO2 enrichment increases growth and photosynthesis and rubisco in loblolly pine seedlings. Plant Cell Environ 16: 859865
  • Tognetti R, Johnson JD (1999) Responses of growth, nitrogen and carbon partitioning to elevated atmospheric CO2 concentration in live oak (Quercus virginiana Mill.) seedlings in relation to nutrient supply. Ann For Sci 56: 91105
  • Van Soest P, Robertson J (1985) Analysis of Forages and Fibrous Foods: A Laboratory Manual for Animal Science. Cornell University Publications, Ithaca, New York.
  • Ward JK, Strain BR (1999) Elevated CO2 studies: past, present and future. Tree Physiol 19: 211220
  • Ward JK, Kelly JK (2004) Scaling up evolutionary responses to elevated CO2: lessons from Arabidopsis. Ecol Lett 7: 427440
  • Williams M, Robertson EJ, Leech RM, Harwood JL (1998) Lipid metabolism in leaves from young wheat (Triticum aestivum cv. Hareward) plants grown at two carbon dioxide levels. J Exp Bot 49: 511520
  • Wittig VE, Bernacchi CJ, Zhu X-G, Calapietra C, Ceulemans R, Deangelis P, Gielen B, Miglietta F, Morgan PB, Long SP (2005) Gross primary production is stimulated for three Populus species grown under free-air CO2 enrichment from planting through canopy closure. Glob Change Biol 11: 644656
  • Wolfe DW, Gifford RM, Hilbert D, You YQ (1998) Integration of photosynthetic acclimation tom CO2 at the whole plant level. Glob Change Biol 4: 879893
  • Woodward FI (2002) Potential impacts of global elevated CO2 concentrations in plants. Curr Opin Plant Biol 5: 207211
  • Wullschleger SD, Tschaplinski TJ, Norby RJ (2002) Plant water relations at elevated CO2–implications for water-limited environments. Plant Cell Environ 25: 319331
  • Yin X (2002) Responses of leaf nitrogen concentration and specific leaf area to atmospheric CO2 enrichment: a retrospective synthesis across 62 species. Glob Change Biol 8: 631642