Changes in leaf morphology and composition with future increases in CO2 and temperature revisited: Wheat in field chambers

Journal of Plant Growth Regulation

Volumn 28, Issue 4, 2009, Pages 349-357

  Gutiérrez, Elena ^a   Gutiérrez, Diego ^a   Morcuende, Rosa ^a   Verdejo, Angel L ^a   Kostadinova, Svetla ^a,b   Martinez Carrasco, Rafael ^a   Pérez, Pilar ^a  

^a INSTITUTO DE RECURSOS NATURALES Y AGROBIOLOGÍA DE SALAMANCA   (Spain)

^b AGRICULTURAL UNIVERSITY   (Bulgaria)

Author keywords

Carbohydrates; Elevated CO2; Elevated temperature; Leaf composition; Leaf mass per area; Leaf morphology; Nitrogen; Photosynthesis; Water content; Wheat

Indexed keywords

TRITICUM AESTIVUM;

EID: 70450222537     PISSN: 07217595     EISSN: 14358107     Source Type: Journal    
DOI: 10.1007/s00344-009-9102-y     Document Type: Article

References (57)

1. Aranjuelo I, Irigoyen JJ, Pérez P, Martínez-Carrasco R, Sánchez-Díaz M (2005) The use of temperature gradient tunnels for studying the combined effect of CO2, temperature and water availability in N2 fixing alfalfa plants. Ann Appl Biol 146: 51-60.
2. Arnon DI (1949) Copper enzymes in isolated chloroplasts. Polyphenol oxidase in Beta vulgaris. Plant Physiol 24: 1-15.
3. Bernacchi CJ, Morgan PB, Ort DR, Long SP (2005) The growth of soybean under free air [CO2] enrichment (FACE) stimulates photosynthesis while decreasing in vivo Rubisco capacity. Planta 220: 434-446.
4. Cawse P (1967) Determination of NO3- in soil by UV-spectrophotometry. Analyst 92: 311-315.
5. Curtis PS (1996) A meta-analysis of leaf gas exchange and nitrogen in trees grown under elevated carbon dioxide. Plant Cell Environ 19: 127-137.
6. Davey PA, Hunt S, Hymus GJ, DeLucia EH, Drake BG, Karnosky DF, Long SP (2004) Respiratory oxygen uptake is not decreased by an instantaneous elevation of [CO2], but is increased with long-term growth in the field at elevated [CO2]. Plant Physiol 134: 1-8.
7. Del Pozo A, Pérez P, Morcuende R, Alonso A, Martínez-Carrasco R (2005) Acclimatory responses of stomatal conductance and photosynthesis to elevated CO2 and temperature in wheat crops grown at varying levels of N supply, in a Mediterranean environment. Plant Sci 169: 908-916.
8. Del Pozo A, Pérez P, Gutierrez D, Alonso A, Morcuende R, Martínez-Carrasco R (2007) Gas exchange acclimation to elevated CO2 in upper-sunlit and lower-shaded canopy leaves in relation to nitrogen acquisition and partitioning in wheat grown in field chambers. Environ Exp Bot 59: 371-380.
9. Dermody O, Long SP, DeLucia EH (2006) How does elevated CO2 or ozone affect the leaf-area index of soybean when applied independently? New Phytol 169: 145-155.
10. Drake BG, Gonzalez-Meler MA, Long SP (1997) More efficient plants: a consequence of rising atmospheric CO2? Annu Rev Plant Physiol Plant Mol Biol 48: 609-639.
11. Dwyer SA, Ghannoum O, Nicotra A, von Caemmerer S (2007) High temperature acclimation of C4 photosynthesis is linked to changes in photosynthetic biochemistry. Plant Cell Environ 30: 53-66.
12. Eguchi N, Fukatsu E, Funada R, Tobita H, Kitao M, Maruyama Y, Koike T (2004) Changes in morphology, anatomy, and photosynthetic capacity of needles of Japanese larch (Larix kaempferi) seedlings grown in high CO2 concentrations. Photosynthetica 42: 173-178.
13. Evans JR, Pooter H (2001) Photosynthetic acclimation of plants to growth irradiance: the relative importance of specific leaf area and nitrogen partitioning in maximizing carbon gain. Plant Cell Environ 24: 755-767.
14. Farage P, McKee I, Long SP (1998) Does a low nitrogen supply necessarily lead to acclimation of photosynthesis to elevated CO2? Plant Physiol 118: 573-580.
15. Frak E, Le Roux X, Millard P, Dreyer E, Jaquen G, Saint-Joanis B, Wendler R (2001) Changes in total leaf nitrogen and partitioning of leaf nitrogen drive photosynthetic acclimation to light in fully developed walnut leaves. Plant Cell Environ 24: 1279-1288.
16. Geiger M, Haake V, Ludewig F, Sonnewald U, Stitt M (1999) The nitrate and ammonium nitrate supply have a major influence on the response of photosynthesis, carbon metabolism, nitrogen metabolism and growth to elevated carbon dioxide in tobacco. Plant Cell Environ 22: 1177-1199.
17. Groot JCJ, Lantinga EA, Neuteboom JH, Deinum B (2003) Analysis of the temperature effect on the components of plant digestibility in two populations of perennial ryegrass. J Sci Food Agric 83: 320-329.
18. Hare PE (1977) Subnanomole-range amino acid analysis. Method Enzymol 47: 3-18.
19. Hikosaka K, Terashima I (1996) Nitrogen partitioning among photosynthetic components and its consequence in sun and shade plants. Funct Ecol 10: 335-343.
20. Hirose T (1984) Nitrogen use efficiency in growth of Polygonum cuspidatum Sieb. et Zucc. Ann Bot 54: 695-704.
21. Ishizaki S, Hikosaka K, Hirose T (2003) Increase in leaf mass per area benefits plant growth at elevated CO2 concentration. Ann Bot 91: 1-10.
22. Jahnke S, Krewitt M (2002) Atmospheric CO2 concentration may directly affect leaf respiration measurement in tobacco, but not respiration itself. Plant Cell Environ 25: 641-651.
23. Krapp A, Hofmann B, Schäfer C, Stitt M (1993) Regulation of the expression of rbcS and other photosynthetic genes by carbohydrates: a mechanism for the 'sink' regulation of photosynthesis? Plant J 3: 817-828.
24. Long SP (1991) Modification of the response of photosynthetic productivity to rising temperature by atmospheric CO2 concentrations: has its importance been underestimated? Plant Cell Environ 14: 729-739.
25. Long SP, Ainsworth EH, Rogers A, Ort DR (2004) Rising atmospheric carbon dioxide: plants FACE the future. Annu Rev Plant Biol 55: 591-628.
26. Lowry OH, Rosebrough NJ, Farr AL, Randall RJ (1951) Protein measurement with the folin phenol reagent. J Biol Chem 193: 265-275.
27. Luo Y, Field CB, Mooney HA (1994) Predicting responses of photosynthesis and root fraction to elevated [CO2]: interactions among carbon, nitrogen, and growth. Plant Cell Environ 17: 1195-1204.
28. Luo Y, Sims DA, Griffin KL (1998) Nonlinearity of photosynthetic responses to growth in rising atmospheric CO2: an experimental and modelling study. Glob Change Biol 4: 173-183.
29. Luo ZB, Calfapietra C, Liberloo M, Scarascia-Mugnozza G, Polle A (2006) Carbon partitioning to mobile and structural fractions in poplar wood under elevated CO2 (EUROFACE) and N fertilization. Glob Change Biol 12: 272-283.
30. Martínez-Carrasco R, Thorne GN (1979) Physiological factors limiting grain size in wheat. J Exp Bot 30: 669-679.
31. Martínez-Carrasco R, Pérez P, Morcuende R (2005) Interactive effects of elevated CO2, temperature and nitrogen on photosynthesis of wheat grown under temperature gradient tunnels. Environ Exp Bot 54: 49-59.
32. Masle J (2000) The effects of elevated CO2 concentrations on cell division rates, growth patterns, and blade anatomy in young wheat plants are modulated by factors related to leaf position, vernalization, and genotype. Plant Physiol 122: 1399-1415.
33. 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: 567-582.
34. Morcuende R, Krapp A, Hurry V, Stitt M (1998) Sucrose-feeding leads to increased rates of nitrate assimilation, increased rates of a-oxoglutarate synthesis, and increased synthesis of a wide spectrum of amino acids in tobacco leaves. Planta 206: 394-409.
35. Morcuende R, Kostadinova S, Pérez P, Martín del Molino IM, Martínez-Carrasco R (2004) Nitrate is a negative signal for fructan synthesis, and the fructosyltransferase-inducing trehalose inhibits nitrogen and carbon assimilation, in excised barley leaves. New Phytol 161: 749-759.
36. Morison JIL (1998) Stomatal response to increased CO2 concentration. J Exp Bot 49: 443-452.
37. Mott KA (1988) Do stomata respond to CO2 concentrations other than intercellular. Plant Physiol 86: 200-203.
38. Nakano H, Makino A, Mae T (1997) The effect of elevated partial pressures of CO2 on the relationship between photosynthetic capacity and N content in rice leaves. Plant Physiol 115: 191-198.
39. Nie G, Hendrix DL, Webber AN, Kimball BA, Long SP (1995) Increased accumulation of carbohydrates and decreased photosynthetic gene transcript levels in wheat grown at an elevated CO2 concentration in the field. Plant Physiol 108: 975-983.
40. Pérez P, Morcuende R, Martín del Molino I, Martínez-Carrasco R (2005) Diurnal changes of Rubisco in response to elevated CO2, temperature and nitrogen in wheat grown under temperature gradient tunnels. Environ Exp Bot 53: 13-27.
41. Peterson GL (1977) A simplification of the protein assay method of Lowry et al which is more generally applicable. Anal Biochem 83: 346-356.
42. Peterson AG, Ball JT, Luo Y, Field CB, Curtis PS, Griffin KL, Gunderson CA, Norby RJ, Tissue DT, Forstreuter M, Rey A, Vogel CS, CMEAL participants (1999) Quantifying the response of photosynthesis to changes in leaf nitrogen content and leaf mass per area in plants grown under atmospheric CO2 enrichment. Plant Cell Environ 22: 1109-1119.
43. Pitre FE, Cooke JEK, Mackay JJ (2007) Short-term effects of nitrogen availability on wood formation and fibre properties in hybrid poplar. Trees Struct Funct 21: 249-259.
44. Poorter H, van Berkel Y, Baxter B, Den Hertog J, Dijkstra P, Gifford RM, Griffin KL, Roumet C, Roy J, Wong SC (1997) The effect of elevated CO2 on the chemical composition and construction costs of leaves of 27 C3 species. Plant Cell Environ 20: 474-482.
45. Rademacher IF, Nelson CJ (2001) Nitrogen effects on leaf anatomy within the intercalary meristems of tall fescue leaf blades. Ann Bot 88: 893-903.
46. Radoglou KM, Jarvis PG (1992) The effects of CO2 enrichment and nutrient supply on growth morphology and anatomy of Phaseolus vulgaris L. seedlings. Ann Bot 70: 245-256.
47. Rawson HM, Gifford RM, Condon BN (1995) Temperature gradient chambers for research on global environment change. Part I. Portable chambers for research on short-stature vegetation. Plant Cell Environ 18: 1048-1054.
48. Reich PB, Walters MB, Ellsworth DS (1997) From tropics to tundra: global convergence in plant functioning. Proc Natl Acad Sci USA 94: 13730-13734.
49. Riviere-Rolland H, Contard P, Betsche T (1996) Adaptation of pea to elevated atmospheric CO2: Rubisco, phosphoenolpyruvate carboxylase and chloroplast phosphate translocator at different levels of nitrogen and phosphorus nutrition. Plant Cell Environ 19: 109-117.
50. Roderick ML, Berry SL, Noble IR (1999a) The relationship between leaf composition and morphology at elevated CO2 concentrations. New Phytol 143: 63-72.
51. Roderick ML, Berry SL, Noble IR, Farquhar GD (1999b) A theoretical approach to linking the composition and morphology with the function of leaves. Funct Ecol 13: 683-695.
52. Roderick ML, Berry SL, Saunders AR, Noble IR (1999c) On the relationship between the composition, morphology and function of leaves. Funct Ecol 13: 696-710.
53. Sheen J (1990) Metabolic repression of transcription in higher plants. Plant Cell 2: 1027-1038.
54. Sims DA, Seemann JR, Luo Y (1998) Elevated CO2 concentration has independent effects on expansion rates and thickness of soybean leaves across light and nitrogen gradients. J Exp Bot 49: 583-591.
55. Thomas JF, Harvey CN (1983) Leaf anatomy of four species grown under continuous CO2 enrichment. Bot Gazette 144: 303-309.
56. Wong SC (1990) Elevated atmospheric partial pressure of CO2 and plant growth. II. Non-structural carbohydrate content in cotton plants and its effect on growth parameters. Photosynth Res 23: 171-180.
57. Yin X (2002) Response of leaf nitrogen concentration and specific leaf area to atmospheric CO2 enrichment: a retrospective synthesis across 62 species. Glob Change Biol 8: 631-642.