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Functional Plant Biology Functional Plant Biology Society
Plant function and evolutionary biology
RESEARCH ARTICLE

Modelling photosynthesis in flag leaves of winter wheat (Triticum aestivum) considering the variation in photosynthesis parameters during development

Jingsong Sun A , Jindong Sun B and Zhaozhong Feng A C
+ Author Affiliations
- Author Affiliations

A State Key Laboratory of Urban and Regional Ecology, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China.

B DuPont Pioneer, Johnston, IA 50131, USA.

C Corresponding author. Emails: fzz@rcees.ac.cn; zhzhfeng201@hotmail.com

Functional Plant Biology 42(11) 1036-1044 https://doi.org/10.1071/FP15140
Submitted: 13 January 2015  Accepted: 10 August 2015   Published: 8 September 2015

Abstract

The Farquhar–von Caemmerer–Berry (FvCB) model of photosynthesis has been widely used to estimate the photosynthetic C flux of plants under different growth conditions. However, the seasonal fluctuation of some photosynthesis parameters (e.g. the maximum carboxylation rate of Rubisco (Vcmax), the maximum electron transport rate (Jmax) and internal mesophyll conductance to CO2 transport (gm)) is not considered in the FvCB model. In this study, we investigated the patterns of the FvCB parameters during flag leaf development based on measured photosynthesis–intercellular CO2 curves in two cultivars of winter wheat (Triticum aestivum L.). Parameterised seasonal patterns of photosynthesis parameters in the FvCB model have subsequently been applied in order to predict the photosynthesis of flag leaves. The results indicate that the Gaussian curve characterises the dynamic patterns of Vcmax, Jmax and gm well. Compared with the model with fixed photosynthesis parameter values, updating the FvCB model by considering seasonal changes in Vcmax and Jmax during flag leaf development slightly improved predictions of photosynthesis. However, if the updated FvCB model incorporated the seasonal patterns of Vcmax and Jmax, and also of gm, predictions of photosynthesis was improved a lot, matching well with the measurements (R2 = 0.87, P < 0.0001). This suggests that the dynamics of photosynthesis parameters, particularly gm, play an important role in estimating the photosynthesis rate of winter wheat.

Additional keywords: Farquhar–von Caemmerer–Berry model, maximum carboxylation rate of Rubisco, maximum electron transport rate; internal conductance to CO2 transport.


References

Abbad H, El Jaafari S, Bort J, Araus JL (2004) Comparison of flag leaf and ear photosynthesis with biomass and grain yield of durum wheat under various water conditions and genotypes. Agronomie 24, 19–28.
Comparison of flag leaf and ear photosynthesis with biomass and grain yield of durum wheat under various water conditions and genotypes.Crossref | GoogleScholarGoogle Scholar |

Adachi M, Hasegawa T, Fukayama H, Tokida T, Sakai H, Matsunami T, Nakamura H, Sameshima R, Okada M (2014) Soil and water warming accelerates phenology and down-regulation of leaf photosynthesis of rice plants grown under free-air CO2 enrichment (FACE). Plant & Cell Physiology 55, 370–380.
Soil and water warming accelerates phenology and down-regulation of leaf photosynthesis of rice plants grown under free-air CO2 enrichment (FACE).Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC2cXitFWls7k%3D&md5=727d1b41ec81780350beb33291f349d8CAS |

Archontoulis SV, Yin X, Vos J, Danalatos NG, Struik PC (2012) Leaf photosynthesis and respiration of three bioenergy crops in relation to temperature and leaf nitrogen: how conserved are biochemical model parameters among crop species? Journal of Experimental Botany 63, 895–911.
Leaf photosynthesis and respiration of three bioenergy crops in relation to temperature and leaf nitrogen: how conserved are biochemical model parameters among crop species?Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC38Xos1ClsA%3D%3D&md5=f68d5b8c9c14f33b3bac1342d2fa2cabCAS | 22021569PubMed |

Bernacchi CJ, Portis AR, Nakano H, von Caemmerer S, Long SP (2002) Temperature response of mesophyll conductance. Implications for the determination of Rubisco enzyme kinetics and for limitations to photosynthesis in vivo. Plant Physiology 130, 1992–1998.
Temperature response of mesophyll conductance. Implications for the determination of Rubisco enzyme kinetics and for limitations to photosynthesis in vivo.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXktlOj&md5=3bbb903dadee0537f3d33223524684faCAS | 12481082PubMed |

Boote KJ, Jones JW, Hoogenboom G, Pickering NB (1998) The CROPGRO model for grain legumes. In ‘Understanding options for agricultural production. Vol. 7’. (Eds G Tsuji, G Hoogenboom, P Thornton.) pp. 99–128. (Springer: Berlin)

Borjigidai A, Hikosaka K, Hirose T, Hasegawa T, Okada M, Kobayashi K (2006) Seasonal changes in temperature dependence of photosynthetic rate in rice under a free-air CO2 enrichment. Annals of Botany 97, 549–557.
Seasonal changes in temperature dependence of photosynthetic rate in rice under a free-air CO2 enrichment.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28Xkt1OisL8%3D&md5=f746a09093c38fc2844d3640022c8332CAS | 16399793PubMed |

Bunce JA (2010) Variable responses of mesophyll conductance to substomatal carbon dioxide concentration in common bean and soybean. Photosynthetica 48, 507–512.
Variable responses of mesophyll conductance to substomatal carbon dioxide concentration in common bean and soybean.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXjs1Gmug%3D%3D&md5=8da8b7db4a53d9c5a4be54eb958e489cCAS |

Centritto M, Loreto F, Chartzoulakis K (2003) The use of low [CO2] to estimate diffusional and non-diffusional limitations of photosynthetic capacity of salt-stressed olive saplings. Plant, Cell & Environment 26, 585–594.
The use of low [CO2] to estimate diffusional and non-diffusional limitations of photosynthetic capacity of salt-stressed olive saplings.Crossref | GoogleScholarGoogle Scholar |

Chen CP, Zhu XG, Long SP (2008) The effect of leaf-level spatial variability in photosynthetic capacity on biochemical parameter estimates using the Farquhar model: a theoretical analysis. Plant Physiology 148, 1139–1147.
The effect of leaf-level spatial variability in photosynthetic capacity on biochemical parameter estimates using the Farquhar model: a theoretical analysis.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXht1GmtLnP&md5=dfd8a30f1bb665e9b98f2080ebc3de9eCAS | 18715955PubMed |

Delfine S, Alvino A, Villani MC, Loreto F (1999) Restrictions to carbon dioxide conductance and photosynthesis in spinach leaves recovering from salt stress. Plant Physiology 119, 1101–1106.
Restrictions to carbon dioxide conductance and photosynthesis in spinach leaves recovering from salt stress.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1MXhvFymu7w%3D&md5=2332bffe1209404b636455ab5401a118CAS | 10069849PubMed |

Dillen SY, Op de Beeck M, Hufkens K, Buonanduci M, Phillips NG (2012) Seasonal patterns of foliar reflectance in relation to photosynthetic capacity and color index in two co-occurring tree species, Quercus rubra and Betula papyrifera. Agricultural and Forest Meteorology 160, 60–68.
Seasonal patterns of foliar reflectance in relation to photosynthetic capacity and color index in two co-occurring tree species, Quercus rubra and Betula papyrifera.Crossref | GoogleScholarGoogle Scholar |

Ethier GJ, Livingston NJ (2004) On the need to incorporate sensitivity to CO2 transfer conductance into the Farquhar–von Caemmerer–Berry leaf photosynthesis model. Plant, Cell & Environment 27, 137–153.
On the need to incorporate sensitivity to CO2 transfer conductance into the Farquhar–von Caemmerer–Berry leaf photosynthesis model.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2cXisFKru7Y%3D&md5=82b58a4e67f359be9ddb6cc51bff01d4CAS |

Evans L, Rawson H (1970) Photosynthesis and respiration by the flag leaf and components of the ear during grain development in wheat. Australian Journal of Biological Sciences 23, 245–254.

Farquhar GD, Wong SC (1984) An empirical model of stomatal conductance. Australian Journal of Plant Physiology 11, 191–209.
An empirical model of stomatal conductance.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaL2cXks12ltrk%3D&md5=76bb8145a460ac8782872fad55ff80feCAS |

Farquhar GD, Caemmerer SV, Berry JA (1980) A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species. Planta 149, 78–90.
A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaL3cXksVWrt7w%3D&md5=580ad8465ff46edd49bd8f41674c5486CAS | 24306196PubMed |

Feng ZZ, Pang J, Kobayashi K, Zhu JG, Ort DR (2011) Differential responses in two varieties of winter wheat to elevated ozone concentration under fully open-air field conditions. Global Change Biology 17, 580–591.
Differential responses in two varieties of winter wheat to elevated ozone concentration under fully open-air field conditions.Crossref | GoogleScholarGoogle Scholar |

Flexas J, Bota J, Escalona JM, Sampol B, Medrano H (2002) Effects of drought on photosynthesis in grapevines under field conditions: an evaluation of stomatal and mesophyll limitations. Functional Plant Biology 29, 461–471.
Effects of drought on photosynthesis in grapevines under field conditions: an evaluation of stomatal and mesophyll limitations.Crossref | GoogleScholarGoogle Scholar |

Flexas J, Barbour MM, Brendel O, Cabrera HM, Carriqui M, Diaz-Espejo A, Douthe C, Dreyerc E, Ferrio JP, Gago J, Galle A, Galmes J, Kodama N, Medrano H, Niinemets U, Peguero-Pina JJ, Poua A, Ribas-Carbo M, Tomas M, Tosens T, Warren CR (2012) Mesophyll diffusion conductance to CO2: an unappreciated central player in photosynthesis. Plant Science 193-194, 70–84.
Mesophyll diffusion conductance to CO2: an unappreciated central player in photosynthesis.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC38XhtVeksrzL&md5=c1bc08ac8d54969b8a0faa63e31d692cCAS | 22794920PubMed |

Frank AB (1981) Effect of leaf age and position on photosynthesis and stomata1 conductance of forage grasses. Journal of Agronomy 73, 70–80.
Effect of leaf age and position on photosynthesis and stomata1 conductance of forage grasses.Crossref | GoogleScholarGoogle Scholar |

Gardiner ES, Schweitzer CJ, Stanturf JA (2001) Photosynthesis of Nuttall oak (Quercus nuttallii Palm.) seedlings interplanted beneath an eastern cottonwood (Populus deltoides Bartr. ex Marsh.) nurse crop. Forest Ecology and Management 149, 283–294.
Photosynthesis of Nuttall oak (Quercus nuttallii Palm.) seedlings interplanted beneath an eastern cottonwood (Populus deltoides Bartr. ex Marsh.) nurse crop.Crossref | GoogleScholarGoogle Scholar |

Gielen B, Calfapietra C, Lukac M, Wittig VE, De Angelis P, Janssens IA, Moscatelli MC, Grego S, Cotrufo MF, Godbold DL, Hoosbeek MR, Long SP, Miglietta F, Polle A, Bernacchi CJ, Davey PA, Ceulemans R, Scarascia-Mugnozza GE (2005) Net carbon storage in a poplar plantation (POPFACE) after three years of free-air CO2 enrichment. Tree Physiology 25, 1399–1408.
Net carbon storage in a poplar plantation (POPFACE) after three years of free-air CO2 enrichment.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXht1CmtbzF&md5=1676e9828caa50436b91f3a024d7e4c0CAS | 16105807PubMed |

Grassi G, Vicinelli E, Ponti F, Cantoni L, Magnani F (2005) Seasonal and interannual variability of photosynthetic capacity in relation to leaf nitrogen in a deciduous forest plantation in northern Italy. Tree Physiology 25, 349–360.
Seasonal and interannual variability of photosynthetic capacity in relation to leaf nitrogen in a deciduous forest plantation in northern Italy.Crossref | GoogleScholarGoogle Scholar | 15631983PubMed |

Grossman-Clarke S, Kimball BA, Hunsaker DJ, Long SP, Garcia RL, Kartschall T, Wall GW, Printer PJ, Wechsung F, LaMorte RL (1999) Effects of elevated atmospheric CO2 on canopy transpiration in senescent spring wheat. Agricultural and Forest Meteorology 93, 95–109.
Effects of elevated atmospheric CO2 on canopy transpiration in senescent spring wheat.Crossref | GoogleScholarGoogle Scholar |

Gu LH, Pallardy SG, Tu K, Law BE, Wullschleger SD (2010) Reliable estimation of biochemical parameters from C3 leaf photosynthesis–intercellular carbon dioxide response curves. Plant, Cell & Environment 33, 1852–1874.
Reliable estimation of biochemical parameters from C3 leaf photosynthesis–intercellular carbon dioxide response curves.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXhsFaisbfI&md5=ee08f4c8e8dac751634e9c981b2ef569CAS |

Han QM, Kawasaki T, Nakano T, Chiba Y (2008) Leaf-age effects on seasonal variability in photosynthetic parameters and its relationships with leaf mass per area and leaf nitrogen concentration within a Pinus densiflora crown. Tree Physiology 28, 551–558.
Leaf-age effects on seasonal variability in photosynthetic parameters and its relationships with leaf mass per area and leaf nitrogen concentration within a Pinus densiflora crown.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXltl2gs7g%3D&md5=1bbfbe553dad341adb17b03ab9e2acd6CAS |

Harley PC, Loreto F, Dimarco G, Sharkey TD (1992a) Theoretical considerations when estimating the mesophyll conductance to CO2 flux by analysis of the response of photosynthesis to CO2. Plant Physiology 98, 1429–1436.
Theoretical considerations when estimating the mesophyll conductance to CO2 flux by analysis of the response of photosynthesis to CO2.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK38XisFagu7o%3D&md5=ea18929283f91c7ea3f9421be0a0a193CAS | 16668811PubMed |

Harley PC, Thomas RB, Reynolds JF, Strain BR (1992b) Modeling photosynthesis of cotton grown in elevated CO2. Plant, Cell & Environment 15, 271–282.
Modeling photosynthesis of cotton grown in elevated CO2.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK38XksVCkuro%3D&md5=962734dc3fa2e3631200b9eef5f9f11cCAS |

Heichel GH, Turner NC (1983) CO2 assimilation of primary and regrowth foliage of red maple (Acer rubrum L.) and red oak (Quercus rubra L.): response to defoliation. Oecologia 57, 14–19.
CO2 assimilation of primary and regrowth foliage of red maple (Acer rubrum L.) and red oak (Quercus rubra L.): response to defoliation.Crossref | GoogleScholarGoogle Scholar |

Jahan E, Amthor JS, Farquhar GD, Trethowan R, Barbour MM (2014) Variation in mesophyll conductance among Australian wheat genotypes. Functional Plant Biology 41, 568–580.
Variation in mesophyll conductance among Australian wheat genotypes.Crossref | GoogleScholarGoogle Scholar |

June T, Evans JR, Farquhar GD (2004) A simple new equation for the reversible temperature dependence of photosynthetic electron transport: a study on soybean leaf. Functional Plant Biology 31, 275–283.
A simple new equation for the reversible temperature dependence of photosynthetic electron transport: a study on soybean leaf.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2cXjt1ejurs%3D&md5=69d74c04e4531bc5d74a0dc0df5d5aafCAS |

Kicklighter DW, Bondeau A, Schloss AL, Kaduk J, McGuire AD, participants of the Potsdam NPP Model Intercomparison (1999) Comparing global models of terrestrial net primary productivity (NPP): global pattern and differentiation by major biomes. Global Change Biology 5, 16–24.
Comparing global models of terrestrial net primary productivity (NPP): global pattern and differentiation by major biomes.Crossref | GoogleScholarGoogle Scholar |

Lenz KE, Host GE, Roskoski K, Noormets A, Sober A, Karnosky DF (2010) Analysis of a Farquhar–von Caemmerer–Berry leaf-level photosynthetic rate model for Populus tremuloides in the context of modeling and measurement limitations. Environmental Pollution 158, 1015–1022.
Analysis of a Farquhar–von Caemmerer–Berry leaf-level photosynthetic rate model for Populus tremuloides in the context of modeling and measurement limitations.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXjt1Cjt7c%3D&md5=19c840132ea8f63796baca4c6464db1bCAS | 19766365PubMed |

Llano-Sotelo JM, Alcaraz-Melendez L, Villegas AEC (2010) Gas exchange in Paulownia species growing under different soil moisture conditions in the field. Journal of Environmental Biology 31, 497–502.

Loreto F, Centritto M, Chartzoulakis K (2003) Photosynthetic limitations in olive cultivars with different sensitivity to salt stress. Plant, Cell & Environment 26, 595–601.
Photosynthetic limitations in olive cultivars with different sensitivity to salt stress.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXjsl2rurg%3D&md5=6b84e8336b7dd93c6477e71a492a8904CAS |

Lu CM, Lu QT, Zhang JH, Kuang TY (2001) Characterization of photosynthetic pigment composition, Photosystem II photochemistry and thermal energy dissipation during leaf senescence of wheat plants grown in the field. Journal of Experimental Botany 52, 1805–1810.
Characterization of photosynthetic pigment composition, Photosystem II photochemistry and thermal energy dissipation during leaf senescence of wheat plants grown in the field.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3MXms12ks7w%3D&md5=75580457b0f8f1c17f799954aeab9101CAS |

Maherali H, Moura CF, Caldeira MC, Willson CJ, Jackson RB (2006) Functional coordination between leaf gas exchange and vulnerability to xylem cavitation in temperate forest trees. Plant, Cell & Environment 29, 571–583.
Functional coordination between leaf gas exchange and vulnerability to xylem cavitation in temperate forest trees.Crossref | GoogleScholarGoogle Scholar |

Misson L, Tu KP, Boniello RA, Goldstein AH (2006) Seasonality of photosynthetic parameters in a multi-specific and vertically complex forest ecosystem in the Sierra Nevada of California. Tree Physiology 26, 729–741.
Seasonality of photosynthetic parameters in a multi-specific and vertically complex forest ecosystem in the Sierra Nevada of California.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XlvFars7c%3D&md5=a58ec8c5cb319f8bf6ca3c0246f6fb28CAS | 16510388PubMed |

Onoda Y, Hikosaka K, Hirose T (2005) Seasonal change in the balance between capacities of RuBP carboxylation and RuBP regeneration affects CO2 response of photosynthesis in Polygonum cuspidatum. Journal of Experimental Botany 56, 755–763.
Seasonal change in the balance between capacities of RuBP carboxylation and RuBP regeneration affects CO2 response of photosynthesis in Polygonum cuspidatum.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXhtV2ru78%3D&md5=21d7040d460fed41d2fd1bb734bf44a7CAS | 15596479PubMed |

Osman AM, Milthorpe FL (1971) Photosynthesis of wheat leaves in relation to age, illuminance and nutrient supply. II. Results. Photosynthetica 5, 61–70.

Qiao YH, Yu ZY, Driessen PM (2002) Dynamic changes and quantification of winter wheat leaf area. Chinese Journal of Eco-Agriculture 10, 83–85.

Rawson H, Hackett C (1974) Exploration of the carbon economy of the tobacco plant. III. Gas exchange of leaves in relation to position on the stem, ontogeny and nitrogen content. Australian Journal of Plant Physiology 1, 551–600.
Exploration of the carbon economy of the tobacco plant. III. Gas exchange of leaves in relation to position on the stem, ontogeny and nitrogen content.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaE2MXotlahtQ%3D%3D&md5=4954ba367e553610ef8e9ab9e00f0fb7CAS |

Rawson H, Hindmarsh J, Fischer R, Stockman Y (1983) Changes in leaf photosynthesis with plant ontogeny and relationships with yield per ear in wheat cultivars and 120 progeny. Australian Journal of Plant Physiology 10, 503–514.
Changes in leaf photosynthesis with plant ontogeny and relationships with yield per ear in wheat cultivars and 120 progeny.Crossref | GoogleScholarGoogle Scholar |

Reich PB, Kloeppel BD, Ellsworth DS, Walters MB (1995) Different photosynthesis–nitrogen relations in deciduous hardwood and evergreen coniferous tree species. Oecologia 104, 24–30.
Different photosynthesis–nitrogen relations in deciduous hardwood and evergreen coniferous tree species.Crossref | GoogleScholarGoogle Scholar |

Reynolds RF, Bauerle WL, Wang Y (2009) Simulating carbon dioxide exchange rates of deciduous tree species: evidence for a general pattern in biochemical changes and water stress response. Annals of Botany 104, 775–784.
Simulating carbon dioxide exchange rates of deciduous tree species: evidence for a general pattern in biochemical changes and water stress response.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXhtF2ktbnN&md5=5ac0b9953960520c7d009cd1af888e88CAS | 19567419PubMed |

Roupsard O, Gross P, Dreyer E (1996) Limitation of photosynthetic activity by CO2 availability in the chloroplasts of oak leaves from different species and during drought. Annales des Sciences Forestieres 53, 243–254.
Limitation of photosynthetic activity by CO2 availability in the chloroplasts of oak leaves from different species and during drought.Crossref | GoogleScholarGoogle Scholar |

Schuller A, Kehr J, Ludwig-Muller J (2014) Laser microdissection coupled to transcriptional profiling of Arabidopsis roots inoculated by Plasmodiophora brassicae indicates a role for brassinosteroids in clubroot formation. Plant & Cell Physiology 55, 392–411.
Laser microdissection coupled to transcriptional profiling of Arabidopsis roots inoculated by Plasmodiophora brassicae indicates a role for brassinosteroids in clubroot formation.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC2cXitFWls78%3D&md5=24317d8fe84b05d587197e26c84e8dadCAS |

Sellers PJ, Berry JA, Collatz GJ, Field CB, Hall FG (1992) Canopy reflectance, photosynthesis, and transpiration. 3. A reanalysis using improved leaf models and a new canopy integration scheme. Remote Sensing of Environment 42, 187–216.
Canopy reflectance, photosynthesis, and transpiration. 3. A reanalysis using improved leaf models and a new canopy integration scheme.Crossref | GoogleScholarGoogle Scholar |

Sellers PJ, Dickinson RE, Randall DA, Betts AK, Hall FG, Berry JA, Collatz GJ, Denning AS, Mooney HA, Nobre CA, Sato N, Field CB, Henderson-Sellers A (1997) Modeling the exchanges of energy, water, and carbon between continents and the atmosphere. Science 275, 502–509.
Modeling the exchanges of energy, water, and carbon between continents and the atmosphere.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2sXnvVSgsg%3D%3D&md5=f0f29383db0b20072fc78710d74d0863CAS | 8999789PubMed |

Su YH, Zhu GF, Miao ZW, Feng Q, Chang ZQ (2009) Estimation of parameters of a biochemically based model of photosynthesis using a genetic algorithm. Plant, Cell & Environment 32, 1710–1723.
Estimation of parameters of a biochemically based model of photosynthesis using a genetic algorithm.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXhsFKrsrvK&md5=ddf41775403f88ebf82b54221ee73049CAS |

Suzuki S, Nakamoto H, Ku MSB, Edwards GE (1987) Influence of leaf age on photosynthesis, enzyme activity, and metabolite levels in wheat. Plant Physiology 84, 1244–1248.
Influence of leaf age on photosynthesis, enzyme activity, and metabolite levels in wheat.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaL2sXlsFWnt7w%3D&md5=c108ad245c0c96bec2945aa8fcc6ef82CAS | 16665591PubMed |

Van Goethem D, Potters G, De Smedt S, Gu LH, Samson R (2014) Seasonal, diurnal and vertical variation in photosynthetic parameters in Phyllostachys humilis bamboo plants. Photosynthesis Research 120, 331–346.
Seasonal, diurnal and vertical variation in photosynthetic parameters in Phyllostachys humilis bamboo plants.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC2cXjtlylt7s%3D&md5=29937847aa9b43854e709f7b23729474CAS | 24585025PubMed |

von Caemmerer S (2000) ‘Biochemical models of leaf photosynthesis.’ (CSIRO: Collingwood, Vic.)

Vos J, van der Putten PEL, Birch CJ (2005) Effect of nitrogen supply on leaf appearance, leaf growth, leaf nitrogen economy and photosynthetic capacity in maize (Zea mays L.). Field Crops Research 93, 64–73.
Effect of nitrogen supply on leaf appearance, leaf growth, leaf nitrogen economy and photosynthetic capacity in maize (Zea mays L.).Crossref | GoogleScholarGoogle Scholar |

Wang Q, Iio A, Tenhunen J, Kakubari Y (2008) Annual and seasonal variations in photosynthetic capacity of Fagus crenata along an elevation gradient in the Naeba Mountains, Japan. Tree Physiology 28, 277–285.
Annual and seasonal variations in photosynthetic capacity of Fagus crenata along an elevation gradient in the Naeba Mountains, Japan.Crossref | GoogleScholarGoogle Scholar | 18055438PubMed |

Weng XY, Xu HX, Jiang DA (2005) Characteristics of gas exchange, chlorophyll fluorescence and expression of key enzymes in photosynthesis during leaf senescence in rice plants. Journal of Integrative Plant Biology 47, 560–566.
Characteristics of gas exchange, chlorophyll fluorescence and expression of key enzymes in photosynthesis during leaf senescence in rice plants.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XosVygsQ%3D%3D&md5=c1d805b0880a871069ae6c36990188f4CAS |

Wilson KB, Baldocchi DD, Hanson PJ (2001) Leaf age affects the seasonal pattern of photosynthetic capacity and net ecosystem exchange of carbon in a deciduous forest. Plant, Cell & Environment 24, 571–583.
Leaf age affects the seasonal pattern of photosynthetic capacity and net ecosystem exchange of carbon in a deciduous forest.Crossref | GoogleScholarGoogle Scholar |

Wullschleger SD (1993) Biochemical limitations to carbon assimilation in C3 plants – a retrospective analysis of the A–C i curves from 109 species. Journal of Experimental Botany 44, 907–920.
Biochemical limitations to carbon assimilation in C3 plants – a retrospective analysis of the A–C i curves from 109 species.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK3sXkvFWnurk%3D&md5=24e68b2afb4a2b47e9a5ce9e910c0b5fCAS |

Xu LK, Baldocchi DD (2003) Seasonal trends in photosynthetic parameters and stomatal conductance of blue oak (Quercus douglasii) under prolonged summer drought and high temperature. Tree Physiology 23, 865–877.
Seasonal trends in photosynthetic parameters and stomatal conductance of blue oak (Quercus douglasii) under prolonged summer drought and high temperature.Crossref | GoogleScholarGoogle Scholar |

Yadav S, Irfan M, Ahmad A, Hayat S (2011) Causes of salinity and plant manifestations to salt stress: a review. Journal of Environmental Biology 32, 667–685.

Yang XS, Chen GX, Yuan ZY (2013) Photosynthetic decline in ginkgo leaves during natural senescence. Pakistan Journal of Botany 45, 1537–1540.

Ye ZP, Robakowski P, Suggett DJ (2013a) A mechanistic model for the light response of photosynthetic electron transport rate based on light harvesting properties of photosynthetic pigment molecules. Planta 237, 837–847.
A mechanistic model for the light response of photosynthetic electron transport rate based on light harvesting properties of photosynthetic pigment molecules.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXjtVWqtL8%3D&md5=4988250d06e6e6820b959f580138eb44CAS | 23138268PubMed |

Ye ZP, Suggett DJ, Robakowski P, Kang HJ (2013b) A mechanistic model for the photosynthesis–light response based on the photosynthetic electron transport of Photosystem II in C3 and C4 species. New Phytologist 199, 110–120.
A mechanistic model for the photosynthesis–light response based on the photosynthetic electron transport of Photosystem II in C3 and C4 species.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXosFart7Y%3D&md5=37de4cc080e4eaf301ab3b869e64e355CAS | 23521402PubMed |