[1] Flexas J, Brugnoli E, Warren CR. Mesophyll conductance to CO2// Flexas J, Loreto F, Medrano H, eds, Terrestrial Photosynthesis in a Changing Environment: A Molecular, Physiological and Ecological Approach. Cambridge: Cambridge University Press, 2012: 169-185 [2] Flexas J, Ribas-Carbó M, Diaz-Espejo A, et al. Mesophyll conductance to CO2: Current knowledge and future prospects. Plant, Cell & Environment, 2008, 31: 602-621 [3] Farquhar GD, von Caemmerer S, Berry JA. A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species. Planta, 1980, 149: 78-90 [4] Han J-M (韩吉梅), Zhang W-F (张旺锋), Xiong D-L (熊栋梁), et al. Mesophyll conductance and its limiting factors in plant leaves. Chinese Journal of Plant Ecology (植物生态学报), 2017, 41(8): 914-924 (in Chinese) [5] Loreto F, Centritto M, Chartzoulakis K. Photosynthetic limitations in olive cultivars with different sensitivity to salt stress. Plant, Cell & Environment, 2003, 26: 595-601 [6] Bernacchi CJ, Morgan PB, Ort DR, et al. The growth of soybean under free air [CO2] enrichment (FACE) stimulates photosynthesis while decreasing in vivo Rubisco capacity. Planta, 2005, 220: 434-446 [7] Flexas J, Ribas-Carb M, Bota J. Decreased Rubisco activity during water stress is not induced by decreased relative water content but related to conditions of low stomatal conductance and chloroplast CO2 concentration. New Phytologist, 2006, 172: 73-82 [8] Galmés J, Medrano H, Flexas J. Acclimation of Rubisco specificity factor to drought in tobacco: Discrepancies between in vitro and in vivo estimations. Journal of Experimental Botany, 2006, 57: 3659-3667 [9] Galmés J, Medrano H, Flexas J. Photosynthetic limitations in response to water stress and recovery in Mediterranean plants with different growth forms. New Phytologist, 2007, 175: 81-93 [10] Flowers MD, Fiscus EL, Burkey KO, et al. Photosynthesis, chlorophyll fluorescence, and yield of snap bean (Phaseolus vulgaris L.) genotypes differing in sensitivity to ozone. Environmental and Experimental Botany, 2007, 61: 190-198 [11] Warren CR, Löw M, Matyssek R, et al. Internal conductance to CO2 transfer of adult Fagus sylvatica: Variation between sun and shade leaves and due to free-air ozone fumigation. Environmental and Experimental Botany, 2007, 59: 130-138 [12] Diaz-Espejo A, Nicolás E, Fernández JE. Seasonal evolution of diffusional limitations and photosynthetic capacity in olive under drought. Plant, Cell & Environment, 2007, 30: 922-933 [13] Warren CR. Does growth temperature affect the temperature response of photosynthesis and internal conductance to CO2? A test with Eucalyptus regnans. Tree Physiology, 2008, 28: 11-19 [14] Warren CR, Livingston NJ, Turpin DH. Water stress decreases the transfer conductance of Douglas-fir (Pseudotsuga menziesii) seedlings. Tree Physiology, 2004, 24: 971-979 [15] Evans JR, Sharkey TD, Berry JA, et al. Carbon isotope discrimination measured concurrently with gas exchange to investigate CO2 diffusion in leaves of higher plants. Australian Journal of Plant Physiology, 1986, 13: 281-292 [16] Evans JR, Terashima I. Photosynthetic characteristics of spinach leaves grown with different treatments. Plant and Cell Physiology, 1988, 29: 157-165 [17] Ren B (任 博), Li J (李 俊), Tong X-J (同小娟), et al. Simulation on photosynthetic-CO2 response of Quercus variabilis and Robinia pseudoacacia in the southern foot of the Taihang Mountain, China. Chinese Journal of Applied Ecology (应用生态学报), 2018, 29(1): 1-10 (in Chinese) [18] Monteith JL. Solar radiation and productivity in tropical ecosystem. Journal of Applied Ecology, 1972, 9: 747-766 [19] Monteith JL, Moss CJ. Climate and the Efficiency of Crop Production in Britain. Philosophical Transactions of the Royal Society of London B, 1977, 281: 277-294 [20] Yu Q (于 强), Ren B-H (任保华), Wang T-D (王天铎), et al. Simulations of diurnal variation of photosynthesis in C3 Plants. Chinese Journal of Atmospheric Sciences (大气科学), 1998, 22(6): 867-880 (in Chinese) [21] Di Marco G, Manes F, Tricoli D, et al. Fluorescence parameters measured concurrently with net photosynthesis to investigate chloroplastic CO2 concentration in leaves of Quercus ilex L. Journal of Plant Physiology, 1990, 136: 538-543 [22] Sharkey TD, Bernacchi CJ, Farquhar GD, et al. Fitting photosynthetic carbon dioxide response curves for C3 leaves. Plant, Cell & Environment, 2007, 30: 1035-1040 [23] Sharkey TD, Vassey TL, Vanderveer PJ, et al. Carbon metabolism enzymes and photosynthesis in transgenic tobacco (Nicotiana tabacum L.) having excess phytochrome. Planta, 1991, 185: 287-296 [24] Loreto F, Harley PC, Marco GD, et al. Estimation of mesophyll conductance to CO2 flux by three different methods. Plant Physiology, 1992, 98: 1437-1443 [25] Sage RF. A model describing the regulation of ribulose-1,5-bisphosphate carboxylase, electron transport, and triose phosphate use in response to light intensity and CO2 in C3 plants. Plant Physiology, 1990, 94: 1728-1734 [26] Manter DK, Kerrigan J. A/Ci curve analysis across a range of woody plant species: Influence of regression analysis parameters and mesophyll conductance. Journal of Experimental Botany, 2004, 55: 2581-2588 [27] Li Y (李 勇), Peng S-B (彭少兵), Huang J-L (黄见良), et al. Components and magnitude of mesophyll conductance and its responses to environmental variations. Plant Physiology Journal (植物生理学报), 2013, 49(11): 1143-1154 (in Chinese) [28] Guo S-W (郭世伟), Ran W (冉 伟), Zhou Y (周毅), et al. On carbon and nitrogen metabolism of rice plants under elevated CO2 conditions. Chinese Journal of Rice Science (中国水稻科学), 2006, 20(5): 560-566 (in Chinese) [29] von Caemmerer S, Evans JR, Hudson GS, et al. The kinetics of ribulose-1,5-bisphosphate carboxylase/oxygenase in vivo inferred from measurements of photosynthesis in leaves of transgenic tobacco. Planta, 1994, 195: 88-97 [30] von Caemmerer S. Biochemical Models of Leaf Photosynthesis. Collingwood, Victoria, Australia: CSIRO Publishing, 2000 [31] Long SP, Bernacchi CJ. Gas exchange measurements, what can they tell us about the underlying limitations to photosynthesis? Procedures and sources of error. Journal of Experimental Botany, 2003, 54: 2393-2401 [32] Warren C. Estimating the internal conductance to CO2 movement. Functional Plant Biology, 2006, 33: 431-442 [33] Pons TL, Flexas J, von Caemmerer S, et al. Estimating mesophyll conductance to CO2: Methodology, potential errors, and recommendations. Journal of Experimental Botany, 2009, 60: 2217-2234 [34] Genty B, Briantais JM, Baker NR. The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. Biochimica et Biophysica Acta, 1989, 990: 87-92 [35] Laisk A, Loreto F. Determining photosynthetic parameters from leaf CO2 exchange and chlorophyll fluorescence. Ribulose-1,5-bisphosphate carboxylase/oxygenase specificity factor, dark respiration in the light, excitation distribution between photosystems, alternative electron transport rate, and mesophyll diffusion resistance. Plant Physiology, 1996, 110: 903-912 [36] Harley PC, Loreto F, Di Marco G, et al. Theoretical considerations when estimating the mesophyll conductance to CO2 flux by the analysis of the response of photosynthesis to CO2. Plant Physiology, 1992, 98: 1429-1436 [37] Pons TL, Westbeek MHM. Analysis of differences in photosynthetic nitrogen-use efficiency between four contrasting species. Physiologia Plantarum, 2004, 122: 68-78 [38] Seaton GGR, Walker DA. Chlorophyll fluorescence as a measure of photosynthetic carbon assimilation. Proceedings of the Royal Society B: Biological Science, 1990, 242: 29-35 [39] Pons TL, Welschen RAM. Midday depression of net photosynthesis in the tropical rainforest tree Eperua grandiflora: Contributions of stomatal and internal conductances, respiration and Rubisco functioning. Tree Physiology, 2003, 23: 937-947 [40] Flexas J, Diaz-Espejo A, Galmes J, et al. Rapid variations of mesophyll conductance in response to changes in CO2 concentration around leaves. Plant, Cell & Environment, 2007, 30: 1284-1298 [41] Bongi G, Loreto F. Gas-exchange properties of salt-stressed olive (Olea europea L) leaves. Plant Physiology, 1989, 90: 1408-1416 [42] Hassiotou F, Ludwig M, Renton M, et al. Influence of leaf dry mass per area, CO2 and irradiance on mesophyll conductance in sclerophylls. Journal of Experimental Botany, 2009, 60: 2303-2314 [43] Flexas J, Barón M, Bota J, et al. Photosynthesis limitations during water stress acclimation and recovery in the drought-adapted Vitis hybrid Richter-110 (V. berlandieri × V. rupestris). Journal of Experimental Botany, 2009, 60: 2361-2377 [44] Vrabl D, Vaskova M, Hronkova M, et al. Mesophyll conductance to CO2 transport estimated by two independent methods: Effect of ambient CO2 concentration and abscisic acid. Journal of Experimental Botany, 2009, 60: 2315-2323 [45] Yin X, Struik PC, Romero P, et al. Using combined measurements of gas exchange and chlorophyll fluorescence to estimate parameters of a biochemical C3 photosynthesis model: A critical appraisal and a new integrated approach applied to leaves in a wheat (Triticum aestivum) canopy. Plant, Cell & Environment, 2009, 32: 448-464 [46] Martins SCV, Galmés J, Molins A, et al. Improving the estimation of mesophyll conductance to CO2: On the role of electron transport rate correction and respiration. Journal of Experimental Botany, 2013, 64: 3285-3298 [47] Ehleringer J, Pearcy RW. Variation in quantum yield for CO2 uptake among C3 and C4 plants. Plant Physiology, 1983, 73: 555-559 [48] Evans JR, Loreto F. Acquisition and diffusion of CO2 in higher plant leaves//Leegood RC, Sharkey TD, von Caemmerer S, eds, Photosynthesis: physiology and metabolism. Advances in photosynthesis. Dordrecht, The Netherlands: Kluwer Academic Publishers, 2000: 321-351 [49] Flexas J, Bota J, Escalona JM, et al. Effects of drought on photosynthesis in grapevines under field conditions: An evaluation of stomatal and mesophyll limitations. Functional Plant Biology, 2002, 29: 461-471 [50] Grassi G and Magnani F. Stomatal, mesophyll conductance and biochemical limitations to photosynthesis as affected by drought and leaf ontogeny in ash and oak trees. Plant, Cell & Environment, 2005, 28: 834-849 [51] Valentini R, Epron D, Angelis PDE, et al. In situ estimation of net CO2 assimilation, photosynthetic electron flow and photorespiration in Turkey oak (Q. cerris L.) leaves: Diurnal cycles under different levels of water supply. Plant, Cell & Environment, 1995, 18: 631-640 [52] Evans JR, Poorter H. Photosynthetic acclimation of plants to growth irradiance: the relative importance of SLA and nitrogen partitioning in maximising carbon gain. Plant, Cell & Environment, 2001, 24: 755-768 [53] Laisk AK. Kinetics of photosynthesis and photorespiration in C3 plants. Moscow, Russia: Nauka Publishing, 1977 [54] von Caemmerer S, Evans JR. Determination of the average partial pressure of CO2 in chloroplasts from leaves of several C3 plants. Australian Journal Plant Physiology, 1991, 18: 287-305 [55] Peisker M, Apel H. Inhibition by light of CO2 evolution from dark respiration: Comparison of two gas exchange methods. Photosynthesis Research, 2001, 70: 291-298 [56] Sun JW, Guan DX, Wu JB, et al. Day and night respiration of three tree species in a temperate forest of northeastern China. iForest: Biogeosciences and Forestry, 2015, 8: 25-32 [57] Bernacchi CJ, Singsaas EL, Pimentel C, et al. Improved temperature response functions for models of Rubisco-limited photosynthesis. Plant, Cell & Environment, 2001, 24: 253-259 [58] Bernacchi CJ, Portis AR, Nakano H, et al. Temperature response of mesophyll conductance. Implications for the determination of Rubisco enzyme kinetics and for limitations to photosynthesis in vivo. Plant Physiology, 2002, 130: 1992-1998 [59] Atkin OK, Scheurwater I, Pons TL. High thermal acclimation potential of both photosynthesis and respiration in two lowland Plantago species in contrast to an alpine congeneric. Global Change Biology, 2006, 12: 500-515 [60] Théroux-Rancourt G, Éthier G, Pepin S. Threshold response of mesophyll CO2 conductance to leaf hydraulics in highly transpiring hybrid poplar clones exposed to soil drying. Journal of Experimental Botany, 2014, 65: 741-753 [61] Théroux-Rancourt G, Éthier G, Pepin S. Greater efficiency of water use in poplar clones having a delayed response of mesophyll conductance to drought. Tree Physiology, 2015, 35: 172-184 [62] Galmés J, Flexas J, Keys AJ, et al. Rubisco specificity factor tends to be larger in plant species from drier habitats and in species with persistent leaves. Plant, Cell & Environment, 2005, 28: 571-579 [63] Ethier GH, Livingston NJ. On the need to incorporate sensitivity to CO2 transfer conductance into the Farquhar-von Caemmerer-Berry leaf photosynthesis model. Plant, Cell & Environment, 2004, 27: 137-153 [64] Ethier GH, Livingston NJ, Harrison DL, et al. Low stomatal and internal conductance to CO2 versus Rubisco de activation as determinants of the photosynthetic decline of ageing evergreen leaves. Plant, Cell & Environment, 2006, 29: 2168-2184 [65] von Caemmerer S, Evans JR. Determination of the average partial pressure of CO2 in chloroplasts of several C3 species. Australian Journal of Plant Physiology, 1991, 18: 287-305 [66] Lloyd J, Syvertsen JP, Kriedeman PE, et al. Low conductances for CO2 diffusion from stomata to the sites of carboxylation in leaves of woody species. Plant, Cell & Environment, 1992, 15: 873-899 [67] Bowling DR, Sargent SD, Tanner BD, et al. Tunable diode laser absorption spectroscopy for stable isotope studies of ecosystem-atmosphere CO2 exchange. Agricultural and Forest Meteorology, 2003, 118: 1-19 [68] Farquhar GD, O’Leary MH, Berry JA. On the relationship between carbon isotope discrimination and the intercellular carbon dioxide concentration in leaves. Australian Journal of Plant Physiology, 1982, 9: 121-137 [69] Gillon JS, Griffiths H. The influence of photorespiration on carbon isotope discrimination in plants. Plant, Cell & Environment, 1997, 20: 1217-1230 [70] Ghashghaie J, Badeck F, Lanigan G, et al. Carbon isotope fractionation during dark respiration and photorespiration in C3 plants. Phytochemistry Reviews, 2003, 2: 145-161 [71] Igamberdiev AU, Mikkelsen TN, Ambus P, et al. Photorespiration contributes to stomatal regulation and carbon isotope fractionation: A study with barley, potato and Arabidopsis plants deficient in glycine decarboxylase. Photosynthesis Research, 2004, 81: 139-152 [72] Lanigan G, Betson N, Griffiths H, et al. Carbon isotope fractionation during photorespiration and carboxylation in Senecio. Plant Physiology, 2008, 148: 2013-2020 [73] Brooks A, Farquhar GD. Effect of temperature on the CO2/O2 specificity of ribulose-1,5-bisphosphate carboxylase/oxygenase and the rate of respiration in the light. Planta, 1985, 165: 397-406 [74] Lin G, Ehleringer JR. Carbon isotope fractionation does not occur during dark respiration in C3 and C4 plants. Plant Physiology, 1997, 114: 391-394 [75] Shi Z-M (史作民), Feng Q-H (冯秋红), Cheng R-M (程瑞梅), et al. The research progress of mesophyll conductance. Acta Ecologica Sinica (生态学报), 2010, 30(17): 4792-4803 (in Chinese) [76] Warren C. Temperature response of photosynthesis and internal conductance to CO2: Results from two independent approaches. Journal of Experimental Botany, 2006, 57: 3057-3067 [77] Xiong DL, Xi L, Liu LM, et al. Rapid responses of mesophyll conductance to changes of CO2 concentration, temperature and irradiance are affected by N supplements in rice. Plant, Cell & Environment, 2015, 38: 2541-2550 [78] Wang XX, Du TT, Huang JL, et al. Leaf hydraulic vulnerability triggers the decline in stomatal and mesophyll conductance during drought in rice. Journal of Experimental Botany, 2018, 16: 4033-4045 |