Abstract
The high-yielding indica rice variety, ‘Takanari’, has the high rate of leaf photosynthesis compared with the commercial japonica varieties. Among backcrossed inbred lines from a cross between ‘Takanari’ and a japonica variety, ‘Koshihikari’, two lines, BTK-a and BTK-b, showed approximately 20% higher photosynthetic rate than that of ‘Takanari’ for a flag leaf at full heading. This is a highest recorded rate of rice leaf photosynthesis. Here, the timing and cause of the increased leaf photosynthesis in the BTK lines were investigated by examining the photosynthesis and related parameters, as well as mesophyll cell anatomy during ontogenesis. Their photosynthetic rate was greater than that of ‘Takanari’ in the 13th leaf, as well as the flag leaf, but there were no differences in the 7th and 10th leaves. There were no consistent differences in the stomatal conductance, or the leaf nitrogen and Rubisco contents in the 13th and flag leaves. The total surface area of mesophyll cells per leaf area (TAmes) in the 13th and flag leaves increased significantly in the BTK lines due to the increased number and developed lobes of mesophyll cells compared with in ‘Takanari’. The mesophyll conductance (g m) became greater in the BTK lines compared with ‘Takanari’ in the flag leaves but not in the 10th leaves. A close correlation was observed between TAmes and g m. We concluded that the increased mesophyll conductance through the development of mesophyll cells during the reproductive period is a probable cause of the greater photosynthetic rate in the BTK lines.
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References
Adachi S, Nito N, Kondo M, Yamamoto T, Arai-Sanoh Y, Ando T, Ookawa T, Yano M, Hirasawa T (2011a) Identification of chromosomal regions involving in the rate of photosynthesis of rice leaves by using a progeny from japonica and high-yielding indica varieties. Plant Prod Sci 14:118–127
Adachi S, Tsuru Y, Nito N, Murata K, Yamamoto T, Ebitani T, Ookawa T, Hirasawa T (2011b) Identification and characterization of genomic regions on chromosomes 4 and 8 that control the rate of photosynthesis in rice leaves. J Exp Bot 62:1927–1938
Adachi S, Nakae T, Uchida M, Soda K, Takai T, Oi T, Yamamoto T, Ookawa T, Miyake H, Yano M, Hirasawa T (2013) The mesophyll anatomy enhancing CO2 diffusion is a key trait for improving rice photosynthesis. J Exp Bot 64:1061–1072
Brooks A, Farquhar G (1985) Effect of temperature on the CO2/O2 specificity of ribulose-1,5-bisphosphate carboxy/oxygenase and the rate of respiration in the light. Planta 165:397–406
Chonan N (1967) Studies on the photosynthetic tissues in leaves of cereal crops. III. The mesophyll structure of rice leaves inserted at different levels of the shoot. Proc Crop Sci Soc Jpn 36:291–296 [In Japanese with English summary]
Cook MG, Evans LT (1983) Some physiological aspects of the domestication and improvement of rice. Field Crops Res 6:219–238
Evans JR (1989) Photosynthesis and nitrogen relationships in leaves of C3 plants. Oecologia 78:9–19
Evans JR, Poorter 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
Evans JR, Kaldenhoff R, Genty B, Terashima I (2009) Resistances along the CO2 diffusion pathway inside leaves. J Exp Bot 60:2235–2248
FAOSTAT. http://faostat.fao.org/site/567/default.aspx#ancor. Accessed 10 July 2016
Farquhar GD, Sharkey TD (1982) Stomatal conductance and photosynthesis. Annu Rev Plant Physiol 33:317–345
Farquhar GD, von Caemmerer S, Berry JA (1980) A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species. Planta 149:78–90
Flood PJ, Harbinson J, Aarts MGM (2011) Natural genetic variation in plant photosynthesis. Trend Plant Sci 16:327–335
Gilbert ME, Pou A, Zwieniecki MA, Holblook NM (2012) On measuring the response of mesophyll conductance to carbon dioxide with the variable J method. J Exp Bot 63:413–425
Giuliani R, Koteyeva N, Voznesenskaya E, Evans MA, Cousins AB, Edwards GE (2013) Coordination of leaf photosynthesis, transpiration, and structural traits in rice and wild relatives (Genus Oryza). Plant Physiol 162:1632–1651
Harley PC, Loreto F, Di Marco G, Sharkey TD (1992) Theoretical considerations when estimating the mesophyll conductance to CO2 flux by analysis of the response of photosynthesis to CO2. Plant Physiol 98:1426–1436
Hirasawa T, Ozawa S, Taylaran RD, Ookawa T (2010) Varietal differences in photosynthetic rates in rice plants, with special reference to the nitrogen content of leaves. Plant Prod Sci 13:53–57
Horton P (2000) Prospects for crop improvement through the genetic manipulation of photosynthesis: morphological and biochemical aspects of light capture. J Exp Bot 51:475–485
Hubbart S, Peng S, Horton P, Chen Y, Murchie EH (2007) Trends in leaf photosynthesis in historical rice varieties developed in the Philippines since 1966. J Exp Bot 58:3429–3438
Ito J-I, Nonomura K-I, Ikeda K, Yamaki S, Inukai Y, Yamagishi H, Kitano H, Nagato Y (2005) Rice plant development: from zygote to spikelet. Plant Cell Physiol 46:23–47
Jahn CE, Mckay JK, Mauleon R, Stephens J, McNally KL, Bush DR, Leung H, Leach JE (2011) Genetic variation in biomass traits among 20 diverse rice varieties. Plant Physiol 155:157–168
Kanemura T, Homma K, Ohsumi A, Shiraiwa T, Horie T (2007) Evaluation of genotypic variation in leaf photosynthetic rate and its associated factors by using rice diversity research set of germplasm. Photosynth Res 94:23–30
Kebeish R, Niessen M, Thiruveedhi K et al (2007) Chloroplastic photorespiratory bypass increases photosynthesis and biomass production in Arabidopsis thaliana. Nature Biotechnol 25:593–599
Khush GS (1999) Green revolution: preparing for the 21st century. Genome 42:646–855
Kumagai E, Araki T, Kubota F (2009) Correlation of chlorophyll meter reading with gas exchange and chlorophyll fluorescence in flag leaves of rice (Oryza sativa L.) plants. Plant Prod Sci 12:50–53
Kuroda E, Kumura A (1990) Difference in single-leaf photosynthesis between old and new rice varieties: III. Physiological bases of varietal difference in single-leaf photosynthesis between varieties viewed from nitrogen content and the nitrogen-photosynthesis relationship. Jpn J Crop Sci 59:298–302 [Japanese with English abstract]
Li Y, Gao YX, Xu XM, Shen QR, Guo SW (2009) Light-saturated photosynthetic rate in high-nitrogen rice (Oryza sativa L.) leaves is related to chloroplastic CO2 concentration. J Exp Bot 60:2351–2236
Long SP, Marshall-Colon A, Zhu X-G (2015) Meeting the global food demand of the future by engineering crop photosynthesis and yield potential. Cell 161:56–66
Loriaux SD, Avenson TJ, Welles JM, Mcdermitt DK, Eckles RD, Riensche B, Genty B (2013) Closing in on maximum yield of chlorophyll fluorescence using a single multiphase flash of sub-saturating insensity. Plant Cell Environ 36:1755–1770
Makino A (2011) Photosynthesis, grain yield, and nitrogen utilization in rice and wheat. Plant Physiol 155:125–129
Makino A, Mae T, Ohira K (1984) Changes in photosynthetic capacity in rice leaves from emergence through senescence. Analysis from ribulose-1,5-bisphosphate carboxylase and leaf conductance. Plant Cell Physiol 25:511–521
Mann CC (1999) Crop scienctists seek a new revolution. Science 283:310–314
Manter DK, Kerrigan J (2004) A/Ci curve analysis across a range of woody plant species: influence of regression analysis parameters and mesophyll conductance. J Exp Bot 55:2581–2588
Masumoto C, Ishii T, Kataoka S, Hatanaka T, Uchida N (2004) Enhancement of rice leaf photosynthesis by crossing between cultivated rice, Oryza sativa and wild rice species, Oryza rufipogon. Plant Prod Sci 7:252–259
Matsushima S, Manaka T (1956) Crop-scientific studies on the yield-forecast of lowland rice. (XXX) Tracing up developmental processes of young panicles on all individual tillers (4). Proc Crop Sci Soc Jpn 24:299–302 [In Japanese with English summary]
Nishimura A, Ito M, Kamiya N, Matsuoka M (2002) OsPNH1 regulates leaf development and maintenance of the shoot apical meristem in rice. Plant J 30:189–201
Nobel PS (2005) Physiochemical and environmental plant physiology. Academic Press, Amesterdam
Ohsumi A, Hamasaki A, Nakagawa H, Yoshida H, Shiraiwa T, Horie T (2007) A model explaining genotypic and ontogenetic variation of leaf photosynthetic rate in rice (Oryza sativa L.) based on leaf nitrogen content and stomatal conductance. Ann Bot 99:265–273
OokawaT, Naruoka Y, Yamazaki T, Suga J, Hirasawa T (2003) A comparison of the accumulation and partitioning of nitrogen in plants between two rice cultivars, Akenohoshi and Nipponbare, at the ripening stage. Plant Prod Sci 6:172–178
Ort DR, Merchant SS, Alric J et al (2015) Redesigning photosynthesis to sustainably meet global food and bioenergy demand. Proc Natl Acad Sci 112:8529–8536
Qi L, Qian Q, Bu Q, Li S et al (2008) Mutation of the rice Narrow leaf1 gene, which encodes a novel protein, affects vein patterning and polar auxin transport. Plant Physiol 147:1947–1959
Raines CA (2010) Increasing photosynthetic carbon assimilation in C3 plants to improve crop yield: current and future strategies. Plant Physiol 155:36–42
Sage TL, Sage RF (2009) The functional anatomy of rice leaves: implications for refixation of photorespiratory CO2 and efforts to engineer C4 photosynthesis into rice. Plant Cell Physiol 50:756–772
Sage RF, Zhu XG (2011) Exploiting the engine of C4 photosynthesis. J Exp Bot 62:2989–3000
Sasaki H, Ishii R (1992) Cultivar differences in leaf photosynthesis of rice bred in Japan. Photosynth Res 32:139–146
Sasaki H, Samejima M, Ishii R (1996) Analysis by δ13C measurement on mechanism of cultivar difference in leaf photosynthesis of rice (Oryza sativa L.). Plant Cell Physiol 37:1161–1166
Scafaro AP, von Caemmerer S, Evans JR, Atwell BJ (2011) Temperature response of mesophyll conductance in cultivated and wild Oryza species with contrasting mesophyll cell wall thickness. Plant Cell Environ 34:1999–2008
Sheehy JE, Mitchell PL (2011) Developments in rice research: visions and pragmatism. World Agric 2:1–19
Simkin AJ, McAusland L, Headland LR, Lawson T, Raines CA (2015) Multigene manipulation of photosynthetic carbon assimilation increases CO2 fixation and biomass yield in tabacco. J Exp Bot 66:4075–4090
Smillie IRA, Pyke KA, Murchie EH (2012) Variation in vein density and mesophyll cell architecture in a rice deletion mutant population. J Exp Bot 63:4563–4570
Sudo E., Makino A, Mae T (2003) Differences between rice and wheat in ribulose-1,5 bisphosphate regeneration capacity per unit of leaf-N content. Plant Cell Environ 26:255–263
Sugiyama T, Hirayama Y (1983) Correlation of the activities of phosphoenolpyruvate carboxylase and pyruvate, orthophosphate dikinase with biomass in maize seedling. Plant Cell Physiol 24:783–787
Takai T, Adachi S, Taguchi-Shiobara F et al (2013) A natural variant of NAL1, selected in high-yield rice breeding programs, pleiotropically increases photosynthesis rate. Sci Rep. doi:10.1038/srep02149
Taylaran RD, Adachi S, Ookawa T, Usuda H, Hirasawa T (2011) Hydraulic conductance as well as nitrogen accumulation plays a role in the higher rate of leaf photosynthesis of the most productive variety of rice in Japan. J Exp Bot 62:4067–4077
Terashima I, Hanba YT, Tholen D, Niinemets Ü (2011) Leaf functional anatomy in relation to photosynthesis. Plant Physiol 155:108–116
Thain JF (1983) Curvature correction factors in the measurement of cell surface areas in plant tissues. J Exp Bot 34:87–94
Warren CR, Dreyer E (2006) Temperature response of photosynthesis and internal conductance to CO2: results from two independent approachs. J Exp Bot 57:3057–3067
Xiong D, Yu T, Zhong T, Li Y, Peng S, Huang J (2015) Leaf hydraulic conductance is coordinated with leaf morpho-anatomical traits and nitrogen status in the genus Oryza. J Exp Bot 66:741–748
Yamaguchi T, Nagasawa N, Kawasaki S, Matsuoka M, Nagato Y, Hirano H-Y (2004) The YABBY gene DROOPING LEAF regulates carpel specification and midrib development in Oryza sativa. Plant Cell 16:500–509
Zhu X-G, Long SP, Ort DR (2008) What is the maximum efficiency with which photosynthesis can convert solar energy into biomass? Curr Opin Biotechnol 19:153–159
Zhu X-G, Long SP, Ort DR (2010) Improving photosynthetic efficiency for greater yield. Annu Rev Plant Biol 61:235–261
Acknowledgements
This work was supported in part by Grants-in-Aid from the Ministry of Education, Culture, Sports, Science, and Technology of Japan (Grant No. 26660013), the Ministry of Agriculture, Forestry, and Fisheries, Japan (Genomics-based Technology for Agricultural Improvement, Grant No. QTL-1002) and the National Natural Science Foundation of China (Grant No. 61070130). The authors are thankful to graduate and undergraduate students of Tokyo University of Agriculture and Technology, Toru T. Nakae, Naoto Ichihara, and Takayuki Ochiai, for their kind help.
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He, W., Adachi, S., Sage, R.F. et al. Leaf photosynthetic rate and mesophyll cell anatomy changes during ontogenesis in backcrossed indica × japonica rice inbred lines. Photosynth Res 134, 27–38 (2017). https://doi.org/10.1007/s11120-017-0403-x
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DOI: https://doi.org/10.1007/s11120-017-0403-x