Adachi S, Yoshikawa K, Yamanouchi U, Tanabata T, Sun J, Ookawa T, Yamamoto T, Sage RF, Hirasawa T, Yonemaru J. (2017). Fine mapping of carbon assimilation rate 8, a quantitative trait locus for flag leaf nitrogen content, stomatal conductance and photosynthesis in rice. Frontiers in Plant Science 8: 60
Adachi S, Yamamoto T, Nakae T, Yamashita M, Uchida M, Karimata R, Ichihara N, Soda K, Ochiai T, Ao R, Otsuka C, Nakano R, Takai T, Ikka T, Kondo K, Ueda T, Ookawa T, Hirasawa T (2019) Genetic architecture of leaf photosynthesis in rice revealed by different types of reciprocal mapping populations. J Exp Bot 70: 5131-5144
Bailey-Serres J, Parker JE, Ainsworth EA, Oldroyd GED, Schroeder JI (2019) Genetic strategies for improving crop yields. Nature 575: 109-118
Carmo-Silva E, Andralojc PJ, Scales JC, Driever SM, Mead A, Lawson T, Raines CA, Parry MAJ (2017) Phenotyping of field-grown wheat in the UK highlights contribution of light response of photosynthesis and flag leaf longevity to grain yield. J Exp Bot 68: 3473–3486
Canfield DE, Glazer AN, Falkowski PG (2010) The evolution and future of Earth’s nitrogen cycle. Science 330: 192–196
Cook MG, Evans LT (1983) Some physiological aspects of the domestication and improvement of rice (Oryza spp). Field Crops Res 6: 219–238
Cock JH, Yoshida S (1972) Accumulation of 14C-labelled carbohydrate before flowering and its subsequent redistribution and respiration in the rice plant. Proc Crop Sci Soc Jpn 41: 226-234
Evans LT (1998) Feeding the Ten Billion. Plants and Population Growth (Cambridge University Press, Cambridge)
Good AG, Beatty PH (2011) Fertilizing nature: a tragedy of excess in the commons. PLoS Biol 9: e1001124
Gu J, Yin X, Struik PC, Stomph TJ, Wang H (2012) Using chromosome introgression lines to map quantitative trait loci for photosynthesis parameters in rice (Oryza sativa L.) leaves under drought and well-watered field conditions. J Exp Bot 63: 455–469
Honda S, Ohkubo S, San NS, Nakkasame A, Tomisawa K, Katsura K, Ookawa T, Nagano AJ, Adachi S (2021) Maintaining higher leaf photosynthesis after heading stage could promote biomass accumulation in rice. 11: 7579
Hoshikawa K (1989) The growing rice plant (Nosan Gyoson Bunka Kyokai)
Hossain MZ, Shibuya Z, Saigusa M (2000) No-tillage transplanting system of rice with controlled availability fertilizer in the nursery box. 1. Growth characteristics and yield of rice in these representative paddy soil. Tohoku J Agric Res 50: 71-86
Long SP (2012) Mechanisms of plant response to global atmospheric change. Plant Cell Environ 35: 1705-1706
Long SP (2020) Photosynthesis engineered to increase rice yield. Nature Food 1: 105
Nagata K, Fukuta Y, Shimizu H, Yagi T, Terao T. (2002) Quantitative trait loci for sink size and ripening traits in rice (Oryza sativa L.). Breed Sci 52: 259-273.
Long SP, Marshall-Colon A, Zhu XG (2015) Meeting the global food demand of the future by engineering crop photosynthesis and yield potential. Cell 161: 56-66
Mae T, Ohira, K (1981) The remobilization of nitrogen related to leaf growth and senescence in rice plants (Oryza sativa L.). Plant Cell Physiol 22: 1067–1074
Mae T, Inaba A, Kaneta Y, Masaki S, Sasaki M, Aizawa M, Okawa S, Hasegawa S, Makino (2006) A large-grain rice cultivar, Akita 63, exhibits high yields with high physiological N-use efficiency. Field Crops Res 97: 227–237
Makino A (2011) Photosynthesis, grain yield, and nitrogen utilization in rice and wheat. Plant Physiol 155: 125–129
Makino A (2021) Photosynthesis improvement for enhancing productivity in rice. Soil Sci Plant Nutr Doi; https://doi.org/10.1080/00380768.2021.1966290
Makino A, Kaneta Y, Obara M, Ishiyama K, Kanno K, Kondo E, Suzuki Y, Mae T (2020) High yielding ability of a large-grain rice cultivar, Akita 63. Sci Rep 10: 12231
Makino A, Mae T, Ohira K (1985) Photosynthesis and ribulose-1,5-bisphosphate carboxylase oxygenase in rice leaves from emergence through senescence – quantitative analysis by carboxylation oxygenation and regeneration of ribulose 1,5-bisphosphate. Planta 166: 414–420
Makino A, Nakano H, Mae T (1994) Responses of ribulose-1,5-bisphosphate carboxylase, cytochrome f, and sucrose synthesis enzymes in rice leaves to leaf nitrogen and their relationships to photosynthesis. Plant Physiol 105: 173–179
San-oh Y, Kondo M, Okawa T, Hirasawa T (2004) Comparison of dry matter production and associated characters between direct-sown and transplanted rice plants in a submerged paddy field and relationships to planting patterns. Field Crops Res 42:79-89
Sinclair TR, Rufty TW, Lewis RS (2019) Increasing photosynthesis: Unlikely solution for world food problem. Trends Plant Sci 24:1032-1039
Sudo E, Suzuki Y, Makino A (2014) Whole-plant growth and N utilization in transgenic rice plants with increased or decreased Rubisco content under different CO2 partial pressures. Plant Cell Physiol 55: 1905–1911
Suzuki Y, Ohkubo M, Hatakeyama H, Ohashi K, Yoshizawa R, Kojima S, Hayakawa T, Yamaya T, Mae T, Makino A (2007) Increased Rubisco content in transgenic rice transformed with the ‘Sense’ rbcs Gene. Plant Cell Physiol 48: 626-637
Takai T, Adachi S, Taguchi-Shiobara F, Sanoh-Arai Y, Iwasawa N, Yoshinaga S, Hirose S, Taniguchi Y, Yamanouchi U, Wu J, Matsumoto T, Sugimoto K, Kondo K, Ikka T, Ando T, Kono I, Ito S, Shomura A, Ookawa T, Hirasawa T, Yano M, Kondo M, Yamamoto T (2013) A natural variant of NAL1, selected in high-yield rice breeding programs, pleiotropically increases photosynthesis rate. Sci Rep 3: 2149
von Caemmerer S, Evans JR (2010) Enhancing C3 photosynthesis. Plant Physiol 154: 589-592
Yoon D-K, Ishiyama K, Suganami M, Tazoe Y, Watanabe M, Imaruoka S, Ogura M, Ishida H, Suzuki Y, Obara M, Mae T, Makino A (2020) Transgenic rice overproducing Rubisco exhibits increased yields with improved nitrogen-use efficiency in an experimental paddy field. Nature Food 1: 134-139
Yoshida S (1981) Fundamentals of rice crop science (The International Rice Research Institute)