References
Burnett AC, Rogers A, Rees M, Osborne CP . 2016. Carbon
source-sink limitations differ between two species with contrasting
growth strategies: Source-sink limitations vary with growth strategy.
Plant, Cell & Environment 39 , 2460–2472.
Cai C, Li G, Di L, et al. 2020. The acclimation of leaf
photosynthesis of wheat and rice to seasonal temperature changes in
T-FACE environments. Global Change Biology 26 , 539–556.
Dingkuhn M, Luquet D, Fabre D, Muller B, Yin X, Paul MJ . 2020.
The case for improving crop carbon sink strength or plasticity for a
CO2-rich future. Current Opinion in Plant Biology 56 , 259–272.
Fabre D, Adriani DE, Dingkuhn M, Ishimaru T, Punzalan B, Lafarge
T, Clément-Vidal A, Luquet D . 2016. The qTSN4 Effect on Flag Leaf Size,
Photosynthesis and Panicle Size, Benefits to Plant Grain Production in
Rice, Depending on Light Availability. Frontiers in Plant Science7 .
Fabre D, Dingkuhn M . 2022. Why is rice Amax (at saturating CO2)
more heritable than Asat (at ambient CO2)? A commentary on Acevedo-Siaca
et al. (2021). Plant Breeding 141 , 542–545.
Fabre D, Dingkuhn M, Yin X, Clément‐Vidal A, Roques S, Soutiras
A, Luquet D . 2020. Genotypic variation in source and sink traits
affects the response of photosynthesis and growth to elevated
atmospheric CO2. Plant, Cell & Environment 43 , 579–593.
Fabre D, Yin X, Dingkuhn M, Clément-Vidal A, Roques S, Rouan L,
Soutiras A, Luquet D . 2019. Is triose phosphate utilization involved in
the feedback inhibition of photosynthesis in rice under conditions of
sink limitation? Journal of Experimental Botany 70 , 5773–5785.
Gao B, Hu S, Jing L, Niu X, Wang Y, Zhu J, Wang Y, Yang L .
2021. Alterations in Source-Sink Relations Affect Rice Yield Response to
Elevated CO2: A Free-Air CO2 Enrichment Study. Frontiers in Plant
Science 12 .
Hasegawa T, Sakai H, Tokida T, et al. 2013. Rice
cultivar responses to elevated CO2 at two free-air CO2 enrichment (FACE)
sites in Japan. Functional Plant Biology 40 , 148.
Hasegawa T, Sakai H, Tokida T, Usui Y, Yoshimoto M, Fukuoka M,
Nakamura H, Shimono H, Okada M . 2016. Rice Free-Air Carbon Dioxide
Enrichment Studies to Improve Assessment of Climate Change Effects on
Rice Agriculture. Advances in Agricultural Systems Modeling. Improving
Modeling Tools to Assess Climate Change Effects on Crop Response.
Madison, WI: American Society of Agronomy, Crop Science Society of
America, and Soil Science Society of America, Inc., 45–68.
Huber SC, Huber JL . 1992. Role of Sucrose-Phosphate Synthase in
Sucrose Metabolism in Leaves. Plant Physiology 99 , 1275–1278.
Iglesias DJ, Lliso I, Tadeo FR, Talon M . 2002. Regulation of
photosynthesis through source: sink imbalance in citrus is mediated by
carbohydrate content in leaves. Physiologia Plantarum 116 ,
563–572.
Impa SM, Raju B, Hein NT, Sandhu J, Prasad PVV, Walia H,
Jagadish SVK . 2021. High night temperature effects on wheat and rice:
Current status and way forward. Plant, Cell & Environment 44 ,
2049–2065.
Jagadish SVK, Bahuguna RN, Djanaguiraman M, Gamuyao R, Prasad
PVV, Craufurd PQ . 2016. Implications of High Temperature and Elevated
CO2 on Flowering Time in Plants. Frontiers in Plant Science 7 .
Jagadish SVK, Murty MVR, Quick WP . 2015. Rice responses to
rising temperatures – challenges, perspectives and future directions.
Plant, Cell & Environment 38 , 1686–1698.
Kadam NN, Jagadish KSV, Struik PC, van der Linden GC, Yin X. 2019.
Incorporating genome-wide association into eco-physiological simulation
to identify markers for improving rice yields. J. Exp. Bot. 70,
2575-2586.
Kölling K, Thalmann M, Müller A, Jenny C, Zeeman SC . 2015.
Carbon partitioning in Arabidopsis thaliana is a dynamic process
controlled by the plants metabolic status and its circadian clock.
Plant, Cell & Environment 38 , 1965–1979.
Kumagai E, Aoki N, Masuya Y, Shimono H. 2015. Phenotypic Plasticity
Conditions the Response of Soybean Seed Yield to Elevated Atmospheric
CO2 Concentration. Plant Physiol . 169,
2021–2029.
Kumar U, Quick WP, Barrios M, Sta Cruz PC, Dingkuhn M . 2017.
Atmospheric CO2 concentration effects on rice water use and biomass
production. PLoS ONE 12 .
Lemoine R, Camera SL, Atanassova R, et al. 2013.
Source-to-sink transport of sugar and regulation by environmental
factors. Frontiers in Plant Science 4 , 272.
Liu S, Waqas MA, Wang S, Xiong X, Wan Y . 2017. Effects of
increased levels of atmospheric CO2 and high temperatures on rice growth
and quality. PLOS ONE 12 , e0187724.
Liu H, Yang L, Wang Y, Huang J, Zhu J, Yunxia W, Dong G, Liu G .
2008. Yield formation of CO2-enriched hybrid rice cultivar Shanyou 63
under fully open-air field conditions. Field Crops Research108 , 93–100.
Lv C, Huang Y, Sun W, Yu L, Zhu J . 2020. Response of rice yield
and yield components to elevated [CO2]: A synthesis of updated data
from FACE experiments. European Journal of Agronomy 112 ,
125961.
Mai W, Abliz B, Xue X . 2021. Increased Number of Spikelets per
Panicle Is the Main Factor in Higher Yield of Transplanted vs.
Direct-Seeded Rice. Agronomy 11 , 2479.
McClain AM, Cruz JA, Kramer DM, Sharkey TD . 2023. The time
course of acclimation to the stress of triose phosphate use limitation.
Plant, Cell & Environment 46 , 64–75.
Moore BD, Cheng S-H, Sims D, Seemann JR . 1999. The biochemical
and molecular basis for photosynthetic acclimation to elevated
atmospheric CO2. Plant, Cell & Environment 22 , 567–582.
Nakano H, Yoshinaga S, Takai T, et al. 2017.
Quantitative trait loci for large sink capacity enhance rice grain yield
under free-air CO2 enrichment conditions. Scientific Reports 7 ,
1827.
Paul MJ, Pellny TK . 2003. Carbon metabolite feedback regulation
of leaf photosynthesis and development. Journal of Experimental Botany54 , 539–547.
Pomeranz Y, Meloan CE . 1994. Enzymatic Methods. In: Pomeranz
Y,, In: Meloan CE, eds. Food Analysis: Theory and Practice. Boston, MA:
Springer US, 506–531.
Rebolledo MC, Peña AL, Duitama J, Cruz DF, Dingkuhn M, Grenier
C, Tohme J . 2016. Combining Image Analysis, Genome Wide Association
Studies and Different Field Trials to Reveal Stable Genetic Regions
Related to Panicle Architecture and the Number of Spikelets per Panicle
in Rice. Frontiers in Plant Science 7 , 1384.
Rohde, M.M. Floods and droughts are intensifying globally. Nat
Water 1 , 226–227 (2023).
https://doi.org/10.1038/s44221-023-00047-y
Sadok W, Jagadish SVK . 2020. The Hidden Costs of Nighttime
Warming on Yields. Trends in Plant Science 25 , 644–651.
Seneweera S, Makino A, Hirotsu N, Norton R, Suzuki Y . 2011. New
insight into photosynthetic acclimation to elevated CO2: The role of
leaf nitrogen and ribulose-1,5-bisphosphate carboxylase/oxygenase
content in rice leaves. Environmental and Experimental Botany71 , 128–136.
Sharkey TD . 2019. Is triose phosphate utilization important for
understanding photosynthesis? Journal of Experimental Botany70 , 5521–5525.
Sheehy JE, Dionora MJA, Mitchell PL . 2001. Spikelet numbers,
sink size and potential yield in rice. Field Crops Research 71 ,
77–85.
Sonnewald U, Fernie AR . 2018. Next-generation strategies for
understanding and influencing source-sink relations in crop plants.
Current opinion in plant biology 43 , 63–70.
Wang D, Rianti W, Gálvez F, van der Putten PEL, Struik PC, Yin
X . 2022. Estimating photosynthetic parameter values of rice, wheat,
maize and sorghum to enable smart crop cultivation. Crop and
Environment.
White AC, Rogers A, Rees M, Osborne CP . 2016. How can we make
plants grow faster? A source–sink perspective on growth rate. Journal
of Experimental Botany 67 , 31–45.
Xiong D, Yu T, Liu X, Li Y, Peng S, Huang J . 2015.
Heterogeneity of photosynthesis within leaves is associated with
alteration of leaf structural features and leaf N content per leaf area
in rice. Functional Plant Biology 42 , 687–696.
Yin X, Busch FA, Struik PC, Sharkey TD . 2021. Evolution of a
biochemical model of steady-state photosynthesis. Plant, Cell &
Environment 44 , 2811–2837.
Ziska LH, Tomecek MB, Gealy DR. 2013. Assessment of cultivated and wild,
weedy rice lines to concurrent changes in CO2concentration and air temperature: determining traits for enhanced seed
yield with increasing atmospheric CO2. Functional
Plant Biology 41 , 236-243.