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Journal of Integrative Agriculture
Journal of Integrative Agriculture  2019, Vol. 18 Issue (12): 2732-2743    DOI: 10.1016/S2095-3119(19)62693-6
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Diurnal variation of gas exchange, chlorophyll fluorescence, and photosynthetic response of six parental lines of maize released in three eras
LI Cong-feng1, DONG Shu-ting2, LIU Rui-xian3, REN Hong1, DING Zai-song1, ZHAO Ming1  
1 Institute of Crop Sciences, Chinese Academy of Agricultural Sciences/Key Laboratory of Crop Physiology and Ecology, Ministry of Agriculture and Rural Affairs, Beijing 100081, P.R.China
2 College of Agriculture, Shandong Agricultural University/State Key Laboratory of Crop Biology, Tai’an 271018, P.R.China
3 Jiangsu Academy of Agricultural Sciences, Nanjing 210014, P.R.China
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Abstract  
Over the past seven decades, the grain yield of maize (Zea mays L.) has increased continuously in China, mostly due to hybridization innovations, particularly recent genetic improvements in photosynthesis.  In order to reveal photosynthetic characters of elite inbred lines in different ears, a field experiment was conducted at the North China Plain of Shandong Province in China.  Six parental lines of maize introduced in three eras (the 1960s, 1980s, and 2000s) were investigated diurnal variation of gas exchange, chlorophyll fluorescence, and photosynthetic response characteristic at the grain filling stage.  Compared to earlier parental lines, the 2000s parental lines always had higher net photosynthetic rate (Pn) throughout the day, especially at noon, and a mid-day depression in Pn did not occur in all hybrids parental lines.  Moreover, the stomatal conductance (Gs) and water use efficiency (WUE) of the 2000s’ lines showed higher value than those of the 1960s’ and 1980s’ lines.  The inbred lines differences in photosynthetic parameters were partly owing to their different quantum carboxylation efficiencies and light synthase activities.  Simultaneously, the 2000s parental lines exhibited lower light and CO2 compensation points, and their higher apparent quantum yield, and carboxylation efficiency.  These suggested that the modern parental lines required lower light intensity and less CO2 to maintain a relatively high photosynthetic capacity, substantially increasing leaf physical quality and stress resistance.  It provided crucial information of high photo-efficiency and stress-resistance breeding in maize.
Keywords:  maize ')" href="#">  
Received: 23 August 2018   Accepted:
Fund: This research was funded by the National Key Research and Development Program of China (2016YFD0300103) and the earmarked fund for China Agriculture Research System (CARS-02-12).
Corresponding Authors:  Correspondence ZHAO Ming, Tel: +86-10-82108752, E-mail: zhaoming@caas.cn   
About author:  LI Cong-feng, Tel: +86-10-82106042, E-mail: licongfeng@caas.cn;
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LI Cong-feng
DONG Shu-ting
LIU Rui-xian
REN Hong
DING Zai-song
ZHAO Ming

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LI Cong-feng, DONG Shu-ting, LIU Rui-xian, REN Hong, DING Zai-song, ZHAO Ming. 2019. Diurnal variation of gas exchange, chlorophyll fluorescence, and photosynthetic response of six parental lines of maize released in three eras. Journal of Integrative Agriculture, 18(12): 2732-2743.

Allen M T, Pearcy R W. 2000. Stomatal behavior and photosynthetic performance under dynamic light regimes in a seasonally dry tropical rain forest. Oecologia, 122, 470–478.
Arnozis P A, Nelemans J A, Findenegg G R. 1988. Phosphoenolpyruvate carboxylase activity in plants grown with either NO3– or NH4+ as inorganic nitrogen source. Journal of Plant Physiology, 132, 23–27.
Bradford M M. 1976. A rapid and sensitive method for the quantification of microgram quantities of protein, utilizing the principle of protein-dye landing. Analytical Biochemistry, 72, 248–254.
Chen G Y, Yu G L, Chen R, Xu D Q. 2006. Exploring the observation methods of photosynthetic responses to light and carbon dioxide. Journal of Plant Physiology and Molecular Biology, 32, 691–696. (in Chinese)
Chen X C, Chen F J, Chen Y L, Gao Q, Yang X L, Yuan L X, Zhang F S, Mi G H. 2013. Modern maize hybrids in Northeast China exhibit increased yield potential and resource use efficiency despite adverse climate change. Global Change Biology, 19, 923–936.
Demmig-Adams B, Adams W W. 1992. Photoprotection and other responses of plants to high light stress. Annual Review of Plant Physiology and Plant Molecular Biology, 43, 599–626.
Demmig-Adams B, Adams W W, Barker D H, Logan B A, Bowling D R, Verhoeven A S. 1996. Using chlorophyll fluorescence to assess the fraction of absorbed light allocated to thermal dissipation of excess excitation. Physiologia Plantarum, 98, 253–264.
Ding L, Wang K J, Jiang G M, Biswas D K, Xu H, Li L F, Li Y H. 2005a. Effects of nitrogen deficiency on photosynthetic traits of maize hybrids released in different years. Annals of Botany, 96, 925–930.
Ding L, Wang K J, Jiang G M, Liu M Z, Jiang C D, Liu M Z, Niu S L, Peng Y. 2006. Diurnal variation of gas exchange, chlorophyll fluorescence, and xanthophyll cycle components of maize hybrids released in different years. Photosynthetica, 44, 26–31.
Ding L, Wang K J, Jiang G M, Liu M Z, Niu S L, Gao L M. 2005b. Post-anthesis changes in photosynthetic traits of maize hybrids released in different years. Field Crops Research, 93, 108–115.
Duncan W G, Hesketh J D. 1968. Net photosynthetic rates, relative leaf growth rates, and leaf numbers of 22 races of maize grown at eight temperatures. Crop Science, 8, 670–674.
Duvick D N. 2005. The contribution of breeding to yield advances in maize (Zea mays L.). Advances in Agronomy, 86, 83–145.
Dwyer L M, Tollenaar M. 1989. Genetic improvement in photosynthetic response of hybrid maize cultivars, 1959 to 1988. Canadian Journal of Plant Science, 69, 81–91.
Geiger D R, Servarites J C. 1994. Diurnal regulation of photosynthetic carbon metabolism in C3 plant. Annual Review of Plant Physiology and Plant Molecular Biology, 45, 235–256.
Harbinson J, Genty B, Baker N R. 1990. The relationship between CO2 assimilation and electron transport in leaves. Photosynthesis Research, 25, 313–324.
Hirasawa T, Iida Y, Ishihara K. 1989. Dominant factors in reduction of photosynthetic rate affected by air humidity and leaf water potential in rice plants. Japanese Journal of Crop Science, 58, 383–389.
Hola D, Kocova M, Kornerova M, Sofrova D, Sopko B. 1999. Genetically based differences in photochemical activities of isolated maize (Zea mays L.) mesophyll chloroplasts. Photosynthetica, 36, 187–197.
Huang Y, Zhao Z. 2001. Studies on several physiological indexes of the drought resistance of crossbreed corn and its comprehensive evaluation. Seed, 1, 12–14.
Jack S A, Silvere R M, Tracy L. 2017. Diurnal variation in gas exchange: The balance between carbon fixation and water Loss. Plant Physiology, 174, 614–623.
Jiang G M, Hao N B, Bai K Z, Zhang Q D, Sun J Z, Guo R J, Ge Q Y, Kuang T Y. 2000. Chain correlation between variables of gas exchange and yield potential in different winter wheat cultivars. Photosynthetica, 38, 227–232.
Krebs D, Synková H, Avratovšěuková N, Koěová M, Šesták Z. 1996. Chorophyll fluorescence measurements for genetic analysis of maize hybrids. Photosynthetica, 32, 505–608.
Leverenz J W, Falk S, Pilström C M, Samuelsson G. 1990. The effects of photoinhibition on the photosynthetic light-response curve of green plant cells (Chlamydomonas reinhardtii). Planta, 182, 161–168.
Li C F, Tao Z Q, Liu P, Zhang J W, Zhuang K Z, Dong S T, Zhao M. 2015. Increased grain yield with improved photosynthetic characters in modern maize parental lines. Journal of Integrative Agriculture, 14, 1735–1744.
Li C F, Zhao M, Liu P, Zhang J W, Yang J S, Liu J G, Wang K J, Dong S T. 2013. Responses of main traits of maize hybrids and their parents to density in different eras of China. Scientia Agricultura Sinica, 46, 2421–2429. (in Chinese)
Li L, Zhang X X, Zheng R, Guo J Q. 2016. Photosynthetic characteristics and photosynthesis-light response curve models of summer maize. Chinese Journal of Plant Ecology, 40, 1310–1318. (in Chinese)
Li Y B, Song H, Zhou L, Xu Z Z, Zhou G S. 2019. Tracking chlorophyll fluorescence as an indicator of drought and rewatering across the entire leaf lifespan in a maize field. Agricultural Water Management, 211, 190–201.
Lilley R M, Walker D A. 1974. An improved spectrophotometric assay for ribulose bisphosphate carboxylase. Biochimica et Biophysica Acta, 358, 226–229.
Long S P, Zhu X G, Naidu S L, Ort D R. 2006. Can improved photosynthesis increase crop yields? Plant, Cell and Environment, 29, 315–330.
Olsson T, Leverenz J. 1994. Non-uniform stomatal closure and the apparent convexity of the photosynthetic photon Xux density response curve. Plant, Cell and Environment, 17, 701–710.
Peng Y F, Li C J, Fritschi F B. 2014. Diurnal dynamics of maize leaf photosynthesis and carbohydrate concentrations in response to differential N availability. Environmental and Experimental Botany, 99, 18–27.
Prioul J, Chartier P. 1977. Partitioning of transfer and carboxylation components of intracellular resistance to photosynthetic CO2 fxation: A critical analysis of the methods used. Annals of Botany, 41, 789–800.
Roberts D R, Thompson J E, Dumbroff E B, Gepstein S, Mattoo A K. 1987. Differential changes in the synthesis and steady-state levels of thylakoid protein during bean leaf senescence. Plant Molecular Biology, 9, 343–354.
Sangoi L. 2001. Understanding plant density effects on maize growth and development: An important issue to maximize grain yield. Ciência Rural, 31, 159–168.
Schreiber U, Bilger W, Neubauer C. 1994. Chlorophyll fluorescence as a non-invasive indicator for rapid assessment o in vivo photosynthesis. In: Schulzem E D, Calswell M M, eds., Ecophysiology of Photosynthesis. Springer Verlag, Berlin. pp. 49–70.
Serageldin I. 1999. Biotechnology and food security in the 21st century. Science, 285, 387–389.
Shirley L, Li L L, Xie J H, Zhang R Z, Stephen Y, Diogenes L. 2017. Photosynthetic response of maize to nitrogen fertilization in the semiarid western Loess Plateau of China. Crop Science, 57, 2739–2752.
Tollenaar M. 1989. Genetic improvement in grain yield of commercial maize hybrids grown in Ontario from 1959 to 1988. Crop Science, 29, 1365–1371.
Zeng X M, Yuan L, Shen Y G. 2002. Response of photosynthesis to light intensity in intact and detached leaves of Arabidopsis thaliana. Plant Physiology Communications, 38, 25–28. (in Chinese)
Zhang Q D, Lu C M, Feng L J, Lin S Q, Kuang T Y, Bai K Z. 1996. Effect of elevated CO2 on the primary conversion of light energy of alfafa photosynthesis. Acta Botanica Sinica, 38, 77–82.
 
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