Response of photosynthetic capacity of Larix gmelinii needles to climate warming

doi:10.13287/j.1001-9332.202508.020

Abstract

Abstract: Larix gmelinii seedlings were transplanted from Tahe, Songling, Heihe and Dailing to a common garden in Mao’ershan, near the southern edge of its natural distribution range in China. Two decades after the transplantation, we measured the photosynthetic capacity of needles in four transplanting locations (control) and common garden (climate warming treatment) simultaneously, and analyzed the response mechanism of needle photosynthetic capacity to climate warming. The results showed that climate warming significantly increased the maximum net photosynthetic rate (P_{n max}), total nitrogen content (N_area), chlorophyll content (Chl_m), the activities of ribulose-1,5-diphosphate carboxylase/oxygenase (Rubisco) and phosphoenolpyruvate carboxylase (PEPC), as well as the content and proportion of nitrogen in photosynthetic system. Climate warming significantly increased P_{n max} by 23.5%, 34.4%, 37.5% and 45.8%, increased Rubisco activity by 11.1%, 30.1%, 36.3% and 56.7%, and increased nitrogen content in photosynthetic system by 19.0%, 51.0%, 67.8% and 70.4% for Dailing, Heihe, Songling and Tahe, respectively. The P_{n max} was significantly positively associated with Rubisco activity, PEPC activity and the content of nitrogen in photosynthetic system. Climate warming did not affect photosynthetic nitrogen use efficiency. The significant increase in photosynthetic capacity of L. gmelinii needles under climate warming was resulted from the interaction of increased nitrogen content in the photosynthetic system and enhanced photosynthetic enzyme activity.

Key words: photosynthetic rate, leaf nitrogen allocation, climate change, common garden, photosynthetic nitrogen use efficiency

WANG Jingjing, CAI Ruijia, ZHANG Rui, WANG Chuankuan, QUAN Xiankui. Response of photosynthetic capacity of Larix gmelinii needles to climate warming[J]. Chinese Journal of Applied Ecology, 2025, 36(8): 2297-2306.

References

[1] Reich PB, Sendall KM, Rice K, et al. Geographic range predicts photosynthetic and growth response to warming in co-occurring tree species. Nature Climate Change, 2015, 5: 148-152
[2] Sendall KM, Reich PB, Zhao CM, et al. Acclimation of photosynthetic temperature optima of temperate and boreal tree species in response to experimental forest warming. Global Change Biology, 2015, 21: 1342-1357
[3] Varhammar A, Wallin G, McLean CM, et al. Photosynthetic temperature responses of tree species in Rwanda: Evidence of pronounced negative effects of high tempe-rature in montane rainforest climax species. New Phyto-logist, 2015, 206: 1000-1012
[4] Streit K, Siegwolf RTW, Hagedorn F, et al. Lack of photosynthetic or stomatal regulation after 9 years of elevated CO₂ and 4 years of soil warming in two conifer species at the alpine treeline. Plant, Cell & Environment, 2014, 37: 315-326
[5] Farquhar GD, von Caemmerer S, Berry JA. A biochemical model of photosynthetic CO₂ assimilation in leaves of C3 species. Planta, 1980, 149: 78-90
[6] Quan XK, Wang CK. Acclimation and adaptation of leaf photosynthesis, respiration and phenology to climate change: A 30-year Larix gmelinii common-garden experiment. Forest Ecology and Management, 2018, 411: 166-175
[7] Ju YL, Wang CK, Wang N, et al. Transplanting larch trees into warmer areas increases the photosynthesis and its temperature sensitivity. Tree Physiology, 2022, 42: 2521-2533
[8] Wright IJ, Reich PB, Cornelissen JHC, et al. Assessing the generality of global leaf trait relationships. New Phytologist, 2005, 166: 485-496
[9] Liu T, Ren T, White PJ, et al. Storage nitrogen co-ordinates leaf expansion and photosynthetic capacity in winter oilseed rape. Journal of Experimental Botany, 2018, 69: 2995-3007
[10] Togashi HF, Prentice IC, Atkin OK, et al. Thermal acclimation of leaf photosynthetic traits in an evergreen woodland, consistent with the coordination hypothesis. Biogeosciences, 2018, 15: 3461-3474
[11] Wang H, Atkin OK, Keenan TF, et al. Acclimation of leaf respiration consistent with optimal photosynthetic capacity. Global Change Biology, 2020, 26: 2573-2583
[12] Kurepin LV, Stangl ZR, Ivanov AG, et al. Contrasting acclimation abilities of two dominant boreal conifers to elevated CO₂ and temperature. Plant, Cell & Environment, 2018, 41: 1331-1345
[13] Kumarathunge DP, Medlyn BE, Drake JE, et al. Acclimation and adaptation components of the temperature dependence of plant photosynthesis at the global scale. New Phytologist, 2019, 222: 768-784
[14] Dusenge ME, Warren JM, Reich PB, et al. Boreal conifers maintain carbon uptake with warming despite failure to track optimal temperatures. Nature Communications, 2023, 14: 4667
[15] Crous KY, Uddling J, De Kauwe MG. Temperature responses of photosynthesis and respiration in evergreen trees from boreal to tropical latitudes. New Phytologist, 2022, 234: 353-374
[16] Tian RP, Li LY, Zhang DJ, et al. Response of photosynthetic capacity to climate warming and its variation among 11 provenances of Dahurian larch (Larix gmelinii). Forests, 2024, 15: 1024
[17] Hikosaka K. Mechanisms underlying interspecific variation in photosynthetic capacity across wild plant species. Plant Biotechnology, 2010, 27: 223-229
[18] Wu CC, Peng GQ, Zhang YB, et al. Physiological responses of Abies faxoniana seedlings to different non-growing-season temperatures as revealed by reciprocal transplantations at two contrasting altitudes. Canadian Journal of Forest Research, 2011, 41: 599-607
[19] Khaliq I, Hof C, Prinzinger R, et al. Global variation in thermal tolerances and vulnerability of endotherms to climate change. Proceedings of the Royal Society B-Biologi-cal Sciences, 2014, 281: 20141097
[20] 乌佳美, 唐敬超, 史作民, 等. 巴郎山糙皮桦叶片光合氮利用效率的海拔响应. 应用生态学报, 2019, 30(3): 751-758
[21] Kositsup B, Montpied P, Kasemsap P, et al. Photosynthetic capacity and temperature responses of photosynthesis of rubber trees (Hevea brasiliensis Mull. Arg.) acclimate to changes in ambient temperatures. Trees-Structure and Function, 2009, 23: 357-365
[22] Wu T, Tissue DT, Li X, et al. Long-term effects of 7-year warming experiment in the field on leaf hydraulic and economic traits of subtropical tree species. Global Change Biology, 2020, 26: 7144-7157
[23] Yamori W, Hikosaka K, Way DA. Temperature response of photosynthesis in C3, C4, and CAM plants: Temperature acclimation and temperature adaptation. Photosynthesis Research, 2014, 119: 101-117
[24] Sage RF, Kubien DS. The temperature response of C3 and C4 photosynthesis. Plant, Cell & Environment, 2007, 30: 1086-1106
[25] 梁逸娴, 王传宽, 臧妙涵, 等. 落叶松径向生长和生物量分配对气候暖化的响应. 植物生态学报, 2024, 48(4): 459-468
[26] 臧妙涵, 王传宽, 梁逸娴, 等. 基于纬度移栽的落叶松叶、枝、根生态化学计量特征对气候变暖的响应. 植物生态学报, 2024, 48(4): 469-482
[27] Sharkey TD, Bernacchi CJ, Farquhar GD, et al. Fitting photosynthetic carbon dioxide response curves for C3 leaves. Plant, Cell & Environment, 2007, 30: 1035-1040
[28] Harley PC, Loreto F, Di Marco G, et al. Theoretical considerations when estimating the mesophyll conduc-tance to CO₂ flux by analysis of the response of photosynthesis to CO₂. Plant Physiology, 1992, 98: 1429-1436
[29] Jordan DB, Ogren WL. The CO₂/O₂ specificity of ribulose 1,5-bisphosphate carboxylase/oxygenase: Depen-dence on ribulosebisphosphate concentration, pH and temperature. Planta, 1984, 161: 308-313
[30] Niinemets, Tenhunen JD. A model separating leaf structural and physiological effects on carbon gain along light gradients for the shade-tolerant species Acer saccharum. Plant, Cell & Environment, 2010, 20: 845-866
[31] Du XL, Huang JX, Xiong DC, et al. Effects of air warming and soil warming on ecophysiological processes of leaves and fine roots of Cunninghamia lanceolata saplings. Forest Ecology and Management, 2024, 561: 121889
[32] 叶旺敏, 熊德成, 杨智杰, 等. 模拟增温对杉木幼树生长和光合特性的影响. 生态学报, 2019, 39(7): 2501-2509
[33] Singh J, Garai S, Das S, et al. Role of C4 photosynthe-tic enzyme isoforms in C3 plants and their potential applications in improving agronomic traits in crops. Photosynthesis Research, 2022, 154: 233-258
[34] He XR, Long FY, Li YJ, et al. Comparative transcriptome analysis revealing the potential mechanism of low-temperature stress in Machilus microcarpa. Frontiers in Plant Science, 2022, 13: 900870
[35] 上官虹玉, 王传宽, 全先奎. 兴安落叶松叶化学计量特征与光合性状的权衡及其种源差异. 应用生态学报, 2023, 34(6): 1483-1490
[36] Tenkanen A, Suprun S, Oksanen E, et al. Strategy by latitude? Higher photosynthetic capacity and root mass fraction in northern than southern silver birch (Betula pendula Roth) in uniform growing conditions. Tree Physiology, 2021, 41: 974-991
[37] Dusenge ME, Madhavji S, Way DA. Contrasting acclimation responses to elevated CO₂ and warming between an evergreen and a deciduous boreal conifer. Global Change Biology, 2020, 26: 3639-3657
[38] Aspinwall MJ, Vårhammar A, Blackman CJ, et al. Adap-tation and acclimation both influence photosynthetic and respiratory temperature responses in Corymbia calophylla. Tree Physiology, 2017, 37: 1095-1112
[39] Lee JY, Marotzke J, Bala G, et al. Future global climate: Scenario-based projections and near-term information// IPCC. Climate Change 2021: The Physical Science Basis. Working Group Ⅰ Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge Univer-sity, 2021: 553-672
[40] 刘梅朔, 王传宽, 全先奎. 兴安落叶松叶光合与氮代谢对环境变化响应的转录组分析. 应用生态学报, 2022, 33(4): 957-962
[41] Wright IJ, Reich PB, Westoby M, et al. Least-cost input mixtures of water and nitrogen for photosynthesis. American Naturalist, 2003, 161: 98-111
[42] Dong N, Prentice IC, Wright IJ, et al. Components of leaf-trait variation along environmental gradients. New Phytologist, 2020, 228: 16558
[43] Wang H, Prentice IC, Keenan TF, et al. Towards a universal model for carbon dioxide uptake by plants. Nature Plants, 2017, 3: 734-741