Changes in photosynthetic capacity during leaf senescence of Liquidambar formosana

doi:10.13287/j.1001-9332.201610.008

Abstract

Abstract: In this study, the photosynthetic light response curves were measured for Liquidambar formosana during the leaf senescence from October to December in 2014. The measurements were simulated by a photosynthetic light response model (Ye model) and the conventional non-rectangular hyperbola model, in order to understand the photosynthetic capacity of senescing leaves of L. formosana. The results showed that the light sensitivity of the net photosynthetic rate decreased gra-dually during the leaf senescence. The measured maximum net photosynthetic rate was about 2.88 μmol CO₂·m^-2·s^-1 when the leaf color just turned yellow, and dropped to 0.95 μmol CO₂·m^-2·s^-1 in the later stage of leaf senescence (8th December). The two photosynthetic light-response models performed well in fitting the observation data, with Ye model being slightly better. Parameters estimated from the two models, such as the maximum net photosynthetic rate, the appa-rent quantum yield, the quantum yield at the light compensation point and the dark respiration rate, all gradually decreased with time, quantitatively describing the decrease in the photosynthetic capacity during the leaf senescence for L. formosana. The senescing leaves of L. formosana maintained positive net photosynthesis rates during the whole senescence, which had positive impact on carbon assimilation in the study area.

LUO Zi-dong, GUAN Hua-de, ZHANG Xin-ping, LIU Na. Changes in photosynthetic capacity during leaf senescence of Liquidambar formosana[J]. Chinese Journal of Applied Ecology, 2016, 27(10): 3129-3136.

References

[1] Sharp RE, Matthews MA, Boyer JS. Kok effect and the quantum yield of photosynthesis: Light partially inhibits dark respiration. Plant Physiology, 1984, 75: 95-101
[2] Zeng X-M (曾小美), Yuan L (袁琳), Shen Y-G (沈允钢). Response of photosynthesis to light intensity in intact and detached leaves of Arabidopsis thaliana. Plant Physiology Communications (植物生理学通讯), 2002, 38(1): 25-26 (in Chinese)
[3] Ye Z-P (叶子飘), Yu Q (于强). Comparison of new and several classical models of photosynthesis in response to irradiance. Chinese Journal of Plant Ecology (植物生态学报), 2008, 32(6): 1356-1361 (in Chinese)
[4] Ye Z-P (叶子飘). A new model of light-response of photosynthesis and its application. Journal of Biomathematics (生物数学学报), 2008, 23(4): 710-716 (in Chinese)
[5] Bassman JH, Zwier JC. Gas exchange characteristics of Populus trichocarpa, Populus deltoides and Populus tri-chocarpa × P. deltoides clones. Tree Physiology, 1991, 8: 145-159
[6] Kubiske ME, Pregitzer KS. Effects of elevated CO₂ and light availability on the photosynthetic light response of trees of contrasting shade tolerance. Tree Physiology, 1996, 16: 351-358
[7] Silva J, Santos R, Serodio J, et al. Light response curves for Gelidium sesquipedale from different depths, determined by two methods: O₂ evolution and chlorophyll fluorescence. Journal of Applied Phycology, 1998, 10: 295-301
[8] Dias-Filho MB. Photosynthetic light response of the C₄ grasses Brachiaria brizantha and B. humidicola under shade. Scientia Agricola, 2002, 59: 65-68
[9] Ye ZP. A new model for relationship between irradiance and the rate of photosynthesis in Oryza sativa. Photosynthetica, 2007, 45: 637-640
[10] Xu J-Z (徐俊增), Peng S-Z (彭世彰), Wei Z (魏征), et al. Characteristics of rice leaf photosynthetic light response curve with different water and nitrogen regulation. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2012, 28(2): 72-76 (in Chinese)
[11] Zhang M (张弥), Wu J-B (吴家兵), Guan D-X (关德新), et al. Light response curve of dominant tree species photosynthesis in broad leaved Korean pine forest of Changbai Mountain. Chinese Journal of Applied Ecology (应用生态学报), 2006, 17(9): 1575-1578 (in Chinese)
[12] Guan M (管铭), Jin Z-X (金则新), Wang Q (王强), et al. Response of photosynthesis traits of dominant plant species to different light regimes in thesecon-dary forest in the area of Qiandao Lake, Zhejiang, China. Chinese Journal of Applied Ecology (应用生态学报), 2014, 25(6): 1615-1622 (in Chinese)
[13] Posada JM, Lechowicz MJ, Kitajima K. Optimal photosynthetic use of light by tropical tree crowns achieved by adjustment of individual leaf angles and nitrogen content. Annals of Botany, 2009, 103: 795-805
[14] Mayoral C, Calama R, Sánchez-González M, et al. Modelling the influence of light, water and temperature on photosynthesis in young trees of mixed Mediterranean forests. New Forests, 2015, 46: 485-506
[15] Yu Q, Zhang YQ, Liu YF, et al. Simulation of the stomatal conductance of winter wheat in response to light, temperature and CO₂changes. Annals of Botany, 2004, 93: 435-441
[16] Steele JH. Environmental control of photosynthesis in the sea. Limnology and Oceanography, 1962, 7: 137-150
[17] Dos Santos Junior UM, de Carvalho GonŞalves JF, Fearnside PM. Measuring the impact of flooding on Amazonian trees: Photosynthetic response models for ten species flooded by hydroelectric dams. Trees, 2013, 27: 193-210
[18] Gao J (高峻), Meng P (孟平), Wu B (吴斌), et al.Photosynthesis and transpiration of Salvia miltiorrhiza in tree-herb system of Prunus dulcis and Salvia miltiorrhiza. Journal of Beijing Forestry University (北京林业大学学报), 2006, 28(2): 64-67 (in Chinese)
[19] Leng H-B (冷寒冰), Qin J (秦俊), Ye K (叶康), et al. Comparison of light response models of photosynthesis in Nelumbo nucifera leaves under different light conditions. Chinese Journal of Applied Ecology (应用生态学报), 2014, 25(10): 2855-2860 (in Chinese)
[20] Liu Q (刘强), Li F-R (李凤日), Xie L-F (谢龙飞). Optimal models of photosynthesis-light response curve in canopy of planted Larix olgensis forest. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(8): 2420-2428 (in Chinese)
[21] Lang Y (郎莹), Zhang G-C (张光灿), Zhang Z-K (张征坤), et al. Light response of photosynthesis and its simulation in leaves of Prunus sibirica L. under diffe-rent soil water conditions. Acta Ecologica Sinica (生态学报), 2011, 31(16): 4499-4508 (in Chinese)
[22] Xia J-B (夏江宝), Zhang G-C (张光灿), Sun J-K (孙景宽), et al. Threshold effects of photosynthetic and physiological parameters in Prunus sibirica to soil moisture and light intensity. Chinese Journal of Plant Ecology (植物生态学报), 2011, 35(3): 322-329 (in Chinese)
[23] Fang LD, Zhang SY, Zhang GC, et al. Application of five light-response models in the photosynthesis of Populus × Euramericana cv.‘Zhonglin46’ leaves. Applied Biochemistry and Biotechnology, 2015, 176: 86-100
[24] Rodríguez-López NF, Martins SCV, Cavatte PC, et al. Morphological and physiological acclimations of coffee seedlings to growth over a range of fixed or changing light supplies. Environmental and Experimental Botany, 2014, 102: 1-10
[25] Keeling CD, Chin JFS, Whorf TP. Increased activity of northern vegetation inferred from atmospheric CO₂ mea-surements. Nature, 1996, 382: 146-149
[26] Yuan J-W (袁婧薇), Ni J (倪健). Plant signals and ecological evidences of climate change in China. Arid Land Geography (干旱区地理), 2007, 30(4): 465-473 (in Chinese)
[27] Wang L-X (王连喜), Chen H-L (陈怀亮), Li Q (李琪), et al. Research advances in plant phenology and climate. Acta Ecologica Sinica (生态学报), 2010, 30(2): 447-454 (in Chinese)
[28] Wu C, Gough CM, Chen JM, et al. Evidence of autumn phenology control on annual net ecosystem productivity in two temperate deciduous forests. Ecological Enginee-ring, 2013, 60: 88-95
[29] Zhang YJ, Yang QY, Lee DW, et al. Extended leaf senescence promotes carbon gain and nutrient resorption: Importance of maintaining winter photosynthesis in subtropical forests. Oecologia, 2013, 173: 721-730
[30] Shen C-G (沈成国), Zhang F-S (张福锁), Mao D-R (毛达如). Advances in degradation metabolism of chlorophyll during plant leaf senescence. Chinese Bulletin of Botany (植物学通报), 1998, 15(suppl.): 42-47 (in Chinese)
[31] Oda-Yamamizo C, Mitsuda N, Sakamoto S, et al. The NAC transcription factor ANAC046 is a positive regulator of chlorophyll degradation and senescence in Arabidopsis leaves. Scientific Reports, 2016, 6: 23609
[32] Keskitalo J. A cellular timetable of autumn senescence. Plant Physiology, 2005, 139: 1635-1648
[33] Moy A, Le S, Verhoeven A. Different strategies for photoprotection during autumn senescence in maple and oak. Physiologia Plantarum, 2015, 155: 205-216
[34] Zhu X-W (朱晓文), Zhang K-R (张克荣), Liu K-M (刘克明), et al. The quantitative classification of plant communities in Yuelu Mountain. Journal of Natural Science of Hunan Normal University (湖南师范大学自然科学学报), 2009, 32(3): 89-94 (in Chinese)
[35] Ye Z-P (叶子飘). Application of light-response model in estimating the photosynthesis of super-hybrid rice combination-Ⅱ Youming 86. Chinese Journal of Ecology (生态学杂志), 2007, 26(8): 1323-1326 (in Chinese)
[36] Marshall B, Biscoe P. A model for C₃ leaves describing the dependence of net photosynthesis on irradiance. Journal of Experimental Botany, 1980, 31: 29-39
[37] Wu W-B (吴伟斌), Hong T-S (洪添胜), Wang X-P (王锡平), et al. Advance in ground-based LAI mea-surement methods. Journal of Huazhong Agricultural University (华中农业大学学报), 2007, 26(2): 270-275 (in Chinese)
[38] Cheng W-X (程武学), Pan K-Z (潘开志), Yang C-J (杨存建). Research progress in the determination methods of leaf area index (LAI). Journal of Sichuan Forestry Science and Technology (四川林业科技), 2010, 31(3): 51-54 (in Chinese)
[39] Pekin B, Macfarlane C. Measurement of crown cover and leaf area index using digital cover photography and its application to remote sensing. Remote Sensing, 2009, 1: 1298-1320
[40] Xiong C-Y (熊彩云), Zeng W (曾伟), Xiao F-M (肖复明), et al. An analysis of photosynthetic parameters among Schima superba provenances. Acta Ecologica Sinica (生态学报), 2012, 32(11): 3628-3634 (in Chinese)
[41] Jiang D-Y (蒋冬月), Qian Y-Q (钱永强), Liu J-X (刘俊祥), et al. Evaluation of radiation use efficiency of superior clones of Salix based on photosynthetic light-response characteristics. Journal of Beijing Forestry University (北京林业大学学报), 2015, 37(5): 49-61 (in Chinese)
[42] Ye Z-P (叶子飘), Yu Q (于强). Comparison of a new model of light response of photosynthesis with traditional models. Journal of Shenyang Agricultural University (沈阳农业大学学报), 2007, 38(6): 771-775 (in Chinese)
[43] Zhang HS, Zhou CJ. Signal transduction in leaf senescence. Plant Molecular Biology, 2013, 82: 539-545
[44] Panchen ZA, Primack RB, Gallinat AS, et al. Substantial variation in leaf senescence times among 1360 temperate woody plant species: Implications for phenology and ecosystem processes. Annals of Botany, 2015, 116: 865-873
[45] Ma L (马林). Advances in studies on physiological and biochemical changes during plant senescence. Journal of Biology (生物学杂志), 2007, 24(3): 12-15 (in Chinese)
[46] Holaday AS, Martindale W, Alred R, et al. Changes in activities of enzymes of carbon metabolism in leaves du-ring exposure of plants to low temperature. Plant Physio-logy, 1992, 98: 1105-1114
[47] Yang S-S (杨淑慎), Gao J-F (高俊凤), Li X-J (李学俊). Leaf senescence in higher plant. Acta Botanica Boreali-Occidentalia Sinica (西北植物学报), 2001, 21(6): 223-229 (in Chinese)
[48] Mayoral C, Calama R, Sánchez-González M, et al. Modelling the influence of light, water and temperature on photosynthesis in young trees of mixed Mediterranean forests. New Forests, 2015, 46: 485-506
[49] Ye ZP, Suggett DJ, Robakowski P, et al. A mechanistic model for the photosynthesis-light response based on the photosynthetic electron transport of photosystem Ⅱ in C3 and C4 species. New Phytologist, 2013, 199: 110-120