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Acta Agron Sin ›› 2009, Vol. 35 ›› Issue (6): 1115-1121.doi: 10.3724/SP.J.1006.2009.01115

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Relationships among Water Use Efficiency,Carbon Isotope Discrimination,and Specific Leaf Area in Maize

ZHANG Cong-Zhi12,ZHANG Jia-Bao1,ZHAO Bing-Zi1,ZHANG Hui12,HUANG Ping12,LI Xiao-Peng12,ZHU Qiang-Gen1   

  1. 1State Experimental Station of Agro-Ecosystem in Fengqiu,State Key Laboratory of Soil and Sustainable Agriculture,Institute of Soil Science,Chinese Academy of Sciences,Nanjing 210008,China;2Graduate School of the Chinese Academy of Sciences,Beijing 100049,China
  • Received:2008-08-20 Revised:2008-12-13 Online:2009-06-12 Published:2009-04-16
  • Contact: ZHANG Jia-Bao,E-mail:jbzhang@issas.ac.cn

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Abstract:

Plant fractionates heavy carbon isotopes during photosynthesis, which usually occurs when CO2 diffuses to the carboxylation site, and during carboxylation reaction. On account of CO2 fixation process is coupled with water transpiration during the photosynthesis, it is possible to apply stable carbon isotope to study crop water use efficiency (WUE). At present, stable carbon isotope techniques have been widely studied and applied in C3 plants, however, the relative studies are less reported in C4 plants. In this way, a pot experiment was conducted from June 9 to September 25 in 2007 to study the variation of leaf area (LA), specific leaf area (SLA), water use efficiency (WUE), and carbon isotope discrimination (Δ13C) in maize (Zea mays L.) under different water deficit conditions. The objective was to understand the relationship among WUE, Δ13C and SLA. Maize were subjected to four water treatments, that is: 75–100% (W1), 50%–75% (W2), 30%–50% (W3), and 0–30% (W4) of field water-holding capacity of the soil. The WUE, SLA, and Δ13C values were measured at seedling, jointing, booting, tasseling, filling, and mature stages. The dry matter accumulation at jointing was obviously affected by W2 and W3 treatments, and decreased significantly in W4 treatment after booting. WUE increased with water stress during all growth stages in W2 and W3 treatments, but decreased significantly in W4 treatment after booting. SLA reached maximal value at booting. Leaf Δ13C decreased in W1, W2, and W3 treatments from jointing to mature, whereas leaf Δ13C value was greater in W4 treatment than in W2 and W3 treatments. Stem Δ13C significantly and positively correlated and presented no significant difference with leaf Δ13C, which indicated that carbon isotope was not fractionated during photosynthate transport from leaves to stems. Maize Δ13C was negatively correlated with WUE; SLA and Δ13C presented positive correlation and both negatively correlated with WUE.

Key words: Water stress, Maize,Growth stage, Water use efficiency, Carbon isotope discrimination, Specific leaf area

[1] Yepez E A, Williams D G, Scott R L, Lin G. Partitioning overstory and understory evapotranspiration in a semiarid savanna woodland from the isotope composition of water vapor. Agric For Meteorol, 2003, 119: 53-68
[2] Williams D G, Cable W, Hultine K, Hoedjes J C B, Yepez E A, Simonneaux V, Er-Raki S, Boulet G, de Bruin H A R, Chehbouni A, Hartogensis O K, Timouk F. Evapotranspiration components determined by stable isotope, sap flow and eddy covariance techniques. Agrci For Meteorol, 2004, 125: 241-258
[3] Nier A O, Gulbransen E A. Variations in the relative abundance of the carbon isotopes. J Am Chem Soc, 1939, 61: 697-698
[4] O’leary M H. Carbon isotope fractionation in plants. Phytochemistry, 1981, 20:553-567
[5] Farquhar G D. On the nature of carbon isotope discrimination in C4 species. Aust J Plant Physiol, 1983, 10: 205-226
[6] Wright G C, Hubick K T, Farquhar G D. Discrimination in carbon isotopes of leaves correlates with water use efficiency of field grown peanut cultivars. Aust J Plant Physiol, 1988, 15: 815-825
[7] Wright G C, Nageswara R C, Farquhar G D. Water-use efficiency and carbon isotope discrimination in peanut under water deficit conditions. Crop Sci, 1994, 34: 92-97
[8] Hubick K T, Shorter R, Farquhar G D. Heritability and genotype × environment interactions of carbon isotope discrimination and transpiration efficiency in peanut (Arachis hypogaea L). Aust J Plant Physiol, 1988, 15: 799-813
[9] Ehleringer J R, Klassen S, Clayton C, Sherrili D, Fuller H M, Qing N F, Cooper T A. Carbon isotope discrimination and transpiration efficiency in common bean. Crop Sci, 1991, 31: 1161-1615
[10] Ehdaie B, Waines J G. Variation in water-use efficiency and its components in wheat: I. Well-watered pot experiment. Crop Sci, 1993, 33: 294-299
[11] Knight J D, Livingston N J, van Kessel C. Carbon isotope discrimination and water-use efficiency of six crops under wet and dryland conditions. Plant, Cell Environ, 1994, 17: 173-179
[12] Condon A G, Richards R A, Farquhar G D. Relationship between carbon isotope discrimination, water use efficiency and transpiration efficiency for dryland wheat. Aust J Agric Res, 1993, 44: 1693-1671
[13] Wall F L, Matus A, Lafond G P, van Kessel C. Water-use efficiency and carbon isotopic composition in reduced tillage system. Soil Sci Soc Am J, 1999, 63: 356-361

[14] Farquhar G D, Ehleringer J R, Hubick K T. Carbon isotope discrimination and photosynthesis. Ann Rev Plant Physiol, 1989, 40: 503-537
[15] Voltas J, Serrano L, Hernández M, Pemán J. Carbon isotope discrimination, gas exchange and stem growth of four Euramerican hybrid poplars under different watering regimes.New For, 2006, 31: 435-451
[16] Chaves M M, Pereira J S, Maroco J, Rodriques M L, Ricardo C P, Osório M L, Carvalho I, Faria T, Pinheiro C. How plants cope with water stress in the field. Photosynthesis and growth. Ann Bot, 2002, 89: 907-916
[17] Sun Z J, Livingston N J, Guy R D, Ethier G J. Stable carbon isotopes as indicators of increased water use efficiency and productivity in white spruce
[Picea glauca (Moench) Voss] seedlings. Plant Cell Environ, 1996, 19: 887-894
[18] Saranga Y, Flash I, Paterson A H, Yakir D. Carbon isotope ratio in cotton varies with growth stage and plant organ. Plant Sci, 1999, 142: 47-56
[19] Chen Y-H(陈英华), Hu J(胡俊), Li Y-H(李裕红), Xue B(薛博), Yan C-L(严重玲). Application of stable carbon isotope techniques to research into water stress. Acta Ecol Sin(生态学报), 2004, 24 (5): 1027-1033 (in Chinese with English abstract)
[20] Ebukanson G J. Retardation of chloroplast ATPase activity in maize seedlings by drought stress. J Plant Physiol, 1987, 129: 187-189
[21] Gimenez C, Mitchell V G, Lawlor D W. Regulation of photosynthetic rate of two sunflower hybrids under water stress. Plant Physio1, 1992, 98: 516-524
[22] Zhao B Z, Kondo M, Maeda M, Ozaki Y, Zhang J. Water-use efficiency and carbon isotope discrimination in two cultivars of upland rice during different developmental stages under three water regimes. Plant Soil, 2004, 261: 61-75
[23] FarquharG D, Richards R A. Isotopic composition of plant carbon correlates with water-use efficiency of wheat genotypes. Aust J Plant Physiol, 1984, 11: 539-552
[24] Hubick K T, Farquhar G D. Carbon isotope discrimination and the ratio of carbon gained to water lost in barley cultivars. Plant, Cell Environ, 1989, 12: 795-804
[25] Hall A E, Richards R A, Condon A G, Wright G C, Farquhar G D. Carbon isotope discrimination and plant breeding. Plant Breed Rev, 1994, 12: 81-113
[26] Meinzer F C, Rundel P W, Goldstein G, Sharifi M R. Carbon isotope composition in relation to leaf gas exchange and environmental conditions in Hawaiian Metrosideros polymorpha populations. Oecologia, 1992, 91: 305-311
[27] Bagnall D J, King R W, FarquharG D. Temperature dependent feedback inhibition of photosynthesis in peanut. Planta, 1988, 175: 348-354
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