Changes of non-structural carbohydrates and nitrogen contents of needles and twigs in Pinus sylvestris var. mongolica plantations along an aridity gradient

doi:10.13287/j.1001-9332.202206.005

Abstract

Abstract: With six Pinus sylvestris var. mongolica plantations (Huinan, Xifeng, Fujia, Zhanggutai, Naiman and Wulanaodu) along an aridity gradient in the Horqin sandy land, we examined the changes in non-structural carbohydrates (NSCs) and nitrogen (N) contents of current and one-year-old needles and twigs, to explore the carbon supply and demand status as well as the nutrient accumulation strategies of P. sylvestris var. mongolica under drought. The results showed that the contents of NSCs and soluble sugars in needles and twigs of P. sylvestris var. mongolica plantations significantly decreased with increasing aridity. From the most humid site (Huinan) to the most aridity site (Wulanaodu), the soluble sugar contents in current and one-year old needles of P. sylvestris var. mongolica decreased from 12.8% and 12.5% to 9.0% and 9.5%, respectively. The soluble sugar contents in current-year old twigs decreased from 15.6% to 9.2%. With increasing aridity, the starch contents in needles and twigs remained relatively stable, soluble sugars/starch ratio in current and one-year old needles decreased, the N contents in current and one-year old twigs significantly increased. The P. sylvestris var. mongolica plantations in the Horqin sandy land consumed soluble sugar storage under drought, resulting in a risk of mortality from ‘carbon starvation’. P. sylvestris var. mongolica tended to maintain stable starch storage and accumulate N in twigs to cope with long-term drought stress.

Key words: drought, non-structural carbohydrate, nitrogen, carbon starvation, Pinus sylvestris var. mongolica

ZHAI Pei-feng, GUAN Jia-xin, HE Peng, LIU He-yong, MAN Liang, JIANG Yong, MA Cheng-cang. Changes of non-structural carbohydrates and nitrogen contents of needles and twigs in Pinus sylvestris var. mongolica plantations along an aridity gradient[J]. Chinese Journal of Applied Ecology, 2022, 33(6): 1518-1524.

References

[1] Choat B, Jansen S, Brodribb TJ, et al. Global convergence in the vulnerability of forests to drought. Nature, 2012, 491: 752-755
[2] 朴世龙, 张新平, 陈安平, 等. 极端气候事件对陆地生态系统碳循环的影响. 中国科学: 地球科学, 2019, 49(9): 1321-1334
[3] Adams HD, Guardiola-Claramonte M, Barron-Gafford GA, et al. Temperature sensitivity of drought-induced tree mortality portends increased regional die-off under global-change-type drought. Proceedings of the National Academy of Sciences of the United States of America, 2009, 106: 7063-7066
[4] Allen CD, Macalady AK, Chenchouni H, et al. A global overview of drought and heat-induced treemortality reveals emerging climate change risks for forests. Forest Ecology and Management, 2010, 259: 660-684
[5] 安玉艳, 梁宗锁. 植物应对干旱胁迫的阶段性策略. 应用生态学报, 2012, 23(10): 2907-2915
[6] McDowell N, Pockman WT, Allen CD, et al. Mechanisms of plant survival and mortality during drought: Why do some plants survive while others succumb to drought? New Phytologist, 2008, 178: 719-739
[7] 董蕾, 李吉跃. 植物干旱胁迫下水分代谢、碳饥饿与死亡机理. 生态学报, 2013, 33(18): 5477-5483
[8] Dickman LT, McDowell NG, Sevanto S, et al. Carbohydrate dynamics and mortality in a pinon-juniper woodland under three future precipitation scenarios. Plant, Cell & Environment, 2015, 38: 729-739
[9] Hartmann H, Trumbore S. Understanding the roles of nonstructural carbohydrates in forest trees: From what we can measure to what we want to know. New Phytologist, 2016, 211: 386-403
[10] Adams HD, Zeppel MJ, Anderegg WR, et al. A multi-species synthesis of physiological mechanisms in drought-induced tree mortality. Nature Ecology & Evolution, 2017, 1: 1285-1291
[11] Zhang PP, Zhou XH, Fu YL, et al. Differential effects of drought on nonstructural carbohydrate storage in seedlings and mature trees of four species in a subtropical forest. Forest Ecology and Management, 2020, 469: 118-159
[12] 潘庆民, 韩兴国, 白永飞, 等. 植物非结构性贮藏碳水化合物的生理生态学研究进展. 植物学报, 2002, 19(1): 30-38
[13] Körner C. Carbon limitation in trees. Journal of Ecology, 2003, 91: 4-17
[14] Hoch G, Richter A, Körner C. Non-structural carbon compounds in temperate forest trees. Plant, Cell & Environment, 2003, 26: 1067-1081
[15] 郑云普, 王贺新, 娄鑫, 等. 木本植物非结构性碳水化合物变化及其影响因子研究进展. 应用生态学报, 2014, 25(4): 1188-1196
[16] Li MH, Xiao WF, Wang SG, et al. Mobile carbohydrates in Himalayan treeline trees. Ⅰ. Evidence for carbon gain limitation but not for growth limitation. Tree Physiology, 2008, 28: 1287-1296
[17] 杜建会, 邵佳怡, 李升发, 等. 树木非结构性碳水化合物含量多时空尺度变化特征及其影响因素研究进展. 应用生态学报, 2020, 31(4): 1378-1388
[18] 王凯, 沈潮, 曹鹏, 等. 沙地樟子松幼苗干旱致死过程中非结构性碳水化合物的变化. 应用生态学报, 2018, 29(11): 3513-3520
[19] 钱杨, 孙洪刚, 董汝湘, 等. 针叶树碳水化合物分配研究进展. 林业科学, 2018, 54(1): 141-153
[20] Hao B, Hartmann H, Li Y, et al. Precipitation gradient drives divergent relationship between non-structural carbohydrates and water availability in Pinus tabuliformis of Northern China. Forests, 2021, 12: 133
[21] 上官淮亮, 刘鸿雁, 胡国铮, 等. 干旱林线区不同树种非结构性碳水化合物的季节格局及其主导因子. 北京大学学报: 自然科学版, 2019, 55(3): 553-560
[22] Millard P, Grelet GA. Nitrogen storage and remobilization by trees: Ecophysiological relevance in achanging world. Tree Physiology, 2010, 30: 1083-1095
[23] Gessler A, Schaub M, McDowell NG. The role of nutrients in drought-induced tree mortality and recovery. New Phytologist, 2017, 214: 513-520
[24] Yuan Z, Chen HY. Decoupling of nitrogen and phosphorus in terrestrial plants associated with global changes. Nature Climate Change, 2015, 5: 465-469
[25] 朱教君, 康宏樟, 许美玲. 科尔沁沙地南缘樟子松(Pinus sylvestris var. mongolica) 人工林天然更新障碍. 生态学报, 2007, 24(10): 4086-4095
[26] 褚建民, 邓东周, 王琼, 等. 降雨量变化对樟子松生理生态特性的影响. 生态学杂志, 2011, 30(12): 2672-2678
[27] Song LN, Zhu JJ, Li MC, et al. Sources of water used by Pinus sylvestris var. mongolica trees based on stable isotope measurements in a semiarid sandy region of Northeast China. Agricultural Water Management, 2016, 164: 281-290
[28] 赵姗宇, 黎锦涛, 孙学凯, 等. 樟子松人工林原产地与不同自然降水梯度引种地土壤和植物叶片生态化学计量特征. 生态学报, 2018, 38(20): 7189-7197
[29] He P, Fontana S, Sardans J, et al. The biogeochemical niche shifts of Pinus sylvestris var. mongolica along an environmental gradient. Environmental and Experimental Botany, 2019, 167: 103825
[30] 李露露, 李丽光, 陈振举, 等. 辽宁省人工林樟子松径向生长对水热梯度变化的响应. 生态学报, 2015, 35(13): 4508-4517
[31] Remus P, Adrian P, Bogdan R, et al. Spatio-temporal changes of the climatic water balance in Romania as a response to precipitation and reference evapotranspiration trends during 1961-2013. Catena, 2019, 172: 295-312
[32] Sala A, Mencuccini M. Plump trees win under drought. Nature Climate Change, 2014, 4: 666
[33] 王宗琰, 王凯, 姜涛, 等. 油松幼苗非结构性碳水化合物对干旱胁迫的阶段性响应. 植物研究, 2018, 8(3): 460-466
[34] Maguire AJ, Kobe RK. Drought and shade deplete nonstructural carbohydrate reserves in seedlings of five temperate tree species. Ecology and Evolution, 2015, 5: 5711-5721
[35] 杜尧, 韩轶, 王传宽. 干旱对兴安落叶松枝叶非结构性碳水化合物的影响. 生态学报, 2014, 34(21): 6090-6100
[36] 马玥, 苏宝玲, 韩艳刚, 等. 岳桦幼苗光合特性和非结构性碳水化合物积累对干旱胁迫的响应. 应用生态学报, 2021, 32(2): 513-520
[37] Martínez-Vilalta J, Sala A, Asensio D, et al. Dynamics of non-structural carbohydrates in terrestrial plants: A global synthesis. Ecological Monographs, 2016, 86: 495-516
[38] Piper FI, Fajardo A, Hoch G. Single-provenance mature conifers show higher non-structural carbohydrate storage and reduced growth in a drier location. Tree Physiology, 2017, 37: 1001-1010
[39] 王凯, 赵成姣, 林婷婷, 等. 水分处理对榆树幼苗不同器官非结构性碳水化合物的影响. 干旱区研究, 2019, 36(1): 113-121
[40] Adams HD, Germino MJ, Breshears DD, et al. Nonstructural leaf carbohydrate dynamics of Pinus edulis during drought-induced tree mortality reveal role for carbon metabolism in mortality mechanism. New Phytologist, 2013, 197: 1142-1151
[41] 曾德慧, 陈广生, 陈伏生, 等. 不同林龄樟子松叶片养分含量及其再吸收效率. 林业科学, 2005, 41(5): 21-27