隔离降水对杉木幼苗细根生物量和功能特征的影响

doi:10.13287/j.1001-9332.201609.023

应用生态学报 ›› 2016, Vol. 27 ›› Issue (9): 2807-2814.doi: 10.13287/j.1001-9332.201609.023

隔离降水对杉木幼苗细根生物量和功能特征的影响

钟波元^1,2, 熊德成^1,2*, 史顺增^1,2, 冯建新^1,2, 许辰森^1,2, 邓飞^1,2, 陈云玉^1,2, 陈光水^1,2

1福建师范大学地理科学学院, 福州 350007;
2湿润亚热带山地生态国家重点实验室培育基地, 福州 350007

收稿日期:2016-04-12 发布日期:2016-09-18
通讯作者: * E-mail: xdc104@163.com
作者简介:钟波元,男,1991年生,硕士研究生. 主要从事森林生态学研究. E-mail: 402106145@qq.com
基金资助:
国家自然科学基金优秀青年科学基金项目(31422012)、国家重点基础研究发展计划前期专项(2014CB460602)、国家自然科学基金项目(31500408)和福建省杰出青年科学基金项目(2014J07005)资助

Effects of precipitation exclusion on fine-root biomass and functional traits of Cunninghamia lanceolata seedlings.

ZHONG Bo-yuan^1,2, XIONG De-cheng^1,2*, SHI Shun-zeng^1,2, FENG Jian-xin^1,2, XU Chen-sen^1,2, DENG Fei^1,2, CHEN Yun-yu^1,2, CHEN Guang-shui^1,2

1College of Geographical Sciences, Fujian Normal University, Fuzhou 350007, China;
2Cultivation Base of State Key Laboratory of Humid Subtropical Mountain Ecology, Fuzhou 350007, China

Received:2016-04-12 Published:2016-09-18
Contact: * E-mail: xdc104@163.com
Supported by:
This work was supported by the National Natural Science Foundation for Excellent Young Scholars of China (31422012), the Special Pre-Project of National Basic Research Program of China (2014CB460602), the National Natural Science Foundation of China (31500408) and the Rolling Project of Natural Science Foundation for Distinguished Young Scholars of Fujian Province (2014J07005)

摘要/Abstract

摘要： 在福建三明陈大国有采育场杉木幼苗小区,采用土钻法和内生长环法,以非隔离降水为对照,对隔离降水50%处理一年的杉木幼苗细根生物量和形态、化学计量学、比根呼吸、非结构性碳水化合物等功能特征进行研究.结果表明: 与对照相比,隔离降水处理0～1 mm细根生物量显著降低,1～2 mm细根生物量差异不显著;隔离降水导致细根在形态上发生了适应性变化,0～1 mm和1～2 mm细根比根长分别增加21.1%和30.5%,0～1 mm细根组织密度显著降低,而比表面积显著增加.隔离降水导致细根氮的富集,但限制了对磷的吸收,氮磷比升高,导致营养失衡;隔离降水没有显著改变细根比根呼吸和非结构性碳水化合物含量,但导致1～2 mm细根可溶性糖、糖淀比显著降低,淀粉含量增加33.3%,表明其通过增加非结构性碳水化合物贮存比例以应对降水减少.

Abstract: A precipitation exclusion experiment was set up in Cunninghamia lanceolata seedling plots in Chenda State-Owned Forest Farm, Sanming, Fujian Province, which included 50% precipi-tation reduction and ambient precipitation (control). Using soil coring and in-growth core me-thods, changes in fine-root functional traits of C. lanceolata seedlings, including fine-root biomass, morphology, stoichiometry, specific root respiration, and nonstructural carbohydrates, were exa-mined after 1 year’s precipitation exclusion. The results showed that precipitation exclusion significantly decreased biomass of 0-1 mm diameter roots but had no effect on 1-2 mm diameter roots. However, adaptive morphological changes occurred in the precipitation exclusion treatment. The specific root length (SRL) of the 0-1 and 1-2 mm diameter roots increased by 21.1% and 30.5%, respectively, and root tissue density (RTD) significantly decreased and specific root surface area (SRA) significantly increased in the 0-1 mm diameter roots. Precipitation exclusion led to increase in nitrogen concentration in fine roots, but the absorption capacity for phosphorus was impeded, resulting in increased root N:P, which implied a nutritional imbalance in fine roots. Precipitation exclusion did not significantly change fine root specific respiration rate and nonstructural carbohydrate (NSC) content. However, the soluble sugar content and the ratio of soluble sugar to starch were significantly decreased, and the starch content was increased by 33.3% in the 1-2 mm diameter roots, indicating an adaptation response of C. lanceolata seedlings to reduced precipitation by increasing the storage of nonstructural carbohydrate in fine roots.

钟波元, 熊德成, 史顺增, 冯建新, 许辰森, 邓飞, 陈云玉, 陈光水. 隔离降水对杉木幼苗细根生物量和功能特征的影响[J]. 应用生态学报, 2016, 27(9): 2807-2814.

ZHONG Bo-yuan, XIONG De-cheng, SHI Shun-zeng, FENG Jian-xin, XU Chen-sen, DENG Fei, CHEN Yun-yu, CHEN Guang-shui. Effects of precipitation exclusion on fine-root biomass and functional traits of Cunninghamia lanceolata seedlings.[J]. Chinese Journal of Applied Ecology, 2016, 27(9): 2807-2814.

参考文献

[1] IPCC. Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group Ⅱ to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, 2014
[2] Dai A. Increasing drought under global warming in observations and models. Nature Climate Change, 2013, 3: 52-58
[3] Zhou GY, Wei XH, Wu YP, et al. Quantifying the hydrological responses to climate change in an intact fore-sted small watershed in Southern China. Global Change Biology, 2011, 17: 3736-3746
[4] Anderegg WRL, Berry JA, Smith DD, et al. The roles of hydraulic and carbon stress in a widespread climate-induced forest die-off. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109: 233-237
[5] Brunner I, Herzog C, Dawes MA, et al. How tree roots respond to drought. Frontiers in Plant Science, 2015, 6: 547
[6] Brando PM, Nepstad DC, Davidson EA, et al. Drought effects on litterfall, wood production and belowground carbon cycling in an Amazon forest: Results of a throughfall reduction experiment. Philosophical Transactions of the Royal Society of London B: Biological Sciences, 2008, 363: 1839-1848
[7] Hamanishi ET, Campbell MM. Genome-wide responses to drought in forest trees. Forestry, 2011, 84: 273-283
[8] Tian H-Q (田汉勤), Xu X-F (徐小锋), Song X (宋霞). Drought impacts on terrestrial ecosystem producti-vity. Chinese Journal of Plant Ecology (植物生态学报), 2009, 31(2): 231-241 (in Chinese)
[9] Chen GS, Yang ZJ, Gao R, et al. Carbon storage in a chronosequence of Chinese fir plantations in southern China. Forest Ecology and Management, 2013, 300: 68-76
[10] Chen G-S (陈光水), He Z-M (何宗明), Xie J-S (谢锦升), et al. Comparision on fine root production, distribution and turnover between plantations of Fokienia hodginsii and Cunninghamia lanceolata. Scientia Silvae Sinicae (林业科学), 40(4): 15-21 (in Chinese)
[11] Gaul D, Hertel D, Borken W, et al. Effects of experimental drought on the fine root system of mature Norway spruce. Forest Ecology and Management, 2008, 256: 1151-1159
[12] Hertel D, Strecker T, Müller-Haubold H, et al. Fine root biomass and dynamics in beech forests across a precipitation gradient: Is optimal resource partitioning theory applicable to water-limited mature trees? Journal of Ecology, 2013, 101: 1183-1200
[13] Metcalfe DB, Meir P, Aragão LEOC, et al. The effects of water availability on root growth and morphology in an Amazon rainforest. Plant and Soil, 2008, 311: 189-199
[14] Leuschner C, Hertel D, Schmid I, et al. Stand fine root biomass and fine root morphology in old-growth beech forests as a function of precipitation and soil fertility. Plant and Soil, 2004, 258: 43-56
[15] Meier IC, Leuschner C. Belowground drought response of European beech: Fine root biomass and carbon partitioning in 14 mature stands across a precipitation gra-dient. Global Change Biology, 2008, 14: 2081-2095
[16] Zang U, Goisser M, Häberle KH, et al. Effects of drought stress on photosynthesis, rhizosphere respiration, and fine-root characteristics of beech saplings: A rhizotron field study. Journal of Plant Nutrition and Soil Science, 2014, 177: 168-177
[17] Zhou YM, Tang JW, Melillo JM, et al. Root standing crop and chemistry after six years of soil warming in a temperate forest. Tree Physiology, 2011, 31: 707-717
[18] Hong J-T (洪江涛), Wu J-B (吴建波), Wang X-D (王小丹). Effects of global climate change on the C, N, and P stoichiometry of terrestrial plants. Chinese Journal of Applied Ecology (应用生态学报), 2013, 24(9): 2658-2665 (in Chinese)
[19] Ryan MG. Tree responses to drought. Tree Physiology, 2011, 31: 237-239
[20] Cleveland CC, Wieder WR, Reed SC, et al. Experimental drought in a tropical rain forest increases soil carbon dioxide losses to the atmosphere. Ecology, 2010, 91: 2313-2323
[21] Clark NM, Apple ME, Nowak RS. The effects of eleva-ted CO₂ on root respiration rates of two Mojave Desert shrubs. Global Change Biology, 2010, 16: 1566-1575
[22] Buysse JAN, Merckx R. An improved colorimetric me-thod to quantify sugar content of plant tissue. Journal of Experimental Botany, 1993, 44: 1627-1629
[23] Yu L-M (于丽敏), Wang C-K (王传宽), Wang X-C (王兴昌). Allocation of nonstructural carbohydrates for three temperate tree species in Northeast China. Chinese Journal of Plant Ecology (植物生态学报), 2011, 35(12): 1245-1255 (in Chinese)
[24] Beyer F, Hertel D, Leuschner C. Fine root morphological and functional traits in Fagus sylvatica and Fraxinus excelsior saplings as dependent on species, root order and competition. Plant and Soil, 2013, 373: 143-156
[25] Bloom AJ, Chapin FS, Mooney HA. Resource limitation in plants: An economic analogy. Annual Review of Ecology and Systematics, 1985, 16: 363-392
[26] Markesteijn L, Poorter L. Seedling root morphology and biomass allocation of 62 tropical tree species in relation to drought-and shade-tolerance. Journal of Ecology, 2009, 97: 311-325
[27] Knutzen F, Meier IC, Leuschner C. Does reduced precipitation trigger physiological and morphological drought adaptations in European beech (Fagus sylvatica L.)? Comparing provenances across a precipitation gradient. Ocean Dynamics, 2015, 35: 1719-1741
[28] Moser G, Schuldt B, Hertel D, et al. Replicated throughfall exclusion experiment in an Indonesian perhumid rainforest: Wood production, litter fall and fine root growth under simulated drought. Global Change Biology, 2014, 20: 1481-1497
[29] Chen GS, Yang YS, Robinson D. Allocation of gross primary production in forest ecosystems: Allometric constraints and environmental responses. New Phytologist, 2013, 200: 1176-1186
[30] Ruehr NK, Offermann CA, Arthur G, et al. Drought effects on allocation of recent carbon: From beech leaves to soil CO₂ efflux. New Phytologist, 2009, 184: 950-961
[31] Barthel M, Hammerle A, Sturm P, et al. The diel imprint of leaf metabolism on the δ¹³C signal of soil respiration under control and drought conditions. New Phytolo-gist, 2011, 192: 925-38
[32] Coomes DA, Grubb PJ. Impacts of root competition in forests and woodlands: A theoretical framework and review of experiments. Ecological Monographs, 2000, 70: 171-207
[33] Ostonen I, Püttsepp Ü, Biel C, et al. Specific root length as an indicator of environmental change. Plant Biosystems, 2007, 141: 426-442
[34] Olmo M, Lopez-Iglesias B, Villar R. Drought changes the structure and elemental composition of very fine roots in seedlings of ten woody tree species: Implications for a drier climate. Plant and Soil, 2014, 384: 113-129
[35] Meier IC, Leuschner C. Genotypic variation and phenotypic plasticity in the drought response of fine roots of European beech. Tree Physiology, 2008, 28: 297-309
[36] Eissenstat DM, Wells CE, Yanai RD, et al. Building roots in a changing environment: Implications for root longevity. New Phytologist, 2000, 147: 33-42
[37] Steudle E. Water uptake by roots: Effects of water deficit. Journal of Experimental Botany, 2000, 51: 1531-1542
[38] Sardans J, Peñuelas J, Ogaya R. Drought-induced changes in C and N stoichiometry in a Quercus ilex Mediterranean forest. Forest Science, 2008, 54: 513-522
[39] Sardans J, Rivas-Ubach A, Peñuelas J. The C:N:P stoichiometry of organisms and ecosystems in a changing world: A review and perspectives. Perspectives in Plant Ecology, Evolution and Systematics, 2012, 14: 33-47
[40] McCormack ML, Adams TS, Smithwick EAH, et al. Predicting fine root lifespan from plant functional traits in temperate trees. New Phytologist, 2012, 195: 823-831
[41] Koerselman W, Meuleman AFM. The vegetation N:P ratio: A new tool to detect the nature of nutrient limitation. Journal of Applied Ecology, 1996, 33: 1441-1450
[42] Bais HP, Weir TG, Perry LG, et al. The role of root exu-dates in rhizosphere interactions with plants and other organisms. Annual Review of Plant Biology, 2006, 57: 233-266
[43] Sims SE, Hendricks JJ, Mitchell RJ, et al. Nitrogen decreases and precipitation increases ectomycorrhizal extramatrical mycelia production in a longleaf pine forest. Mycorrhiza, 2007, 17: 299-309
[44] Wei L-L (韦莉莉), Zhang X-Q (张小全), Hou Z-H (侯振宏), et al. Effects of water stress on photosynthesis and carbon allocation in Cunninghamia lanceolata seedlings. Acta Phytoecologica Sinica (植物生态学报), 2005, 29(3): 394-402 (in Chinese)
[45] Burton AJ, Pregitzer KS, Zogg GP, et al. Drought reduces root respiration in sugar maple forests. Ecological Applications, 1998, 8: 771-778
[46] Hasibeder R, Fuchslueger L, Richter A, et al. Summer drought alters carbon allocation to roots and root respiration in mountain grassland. New Phytologist, 2015, 205: 1117-1127
[47] Burton AJ, Pregitzer KS, Ruess RW, et al. Root respiration in North American forests: Effects of nitrogen concentration and temperature across biomes. Oecologia, 2002, 131: 559-568
[48] Jia S-X (贾淑霞), Zhao Y-L (赵妍丽), Ding G-Q (丁国泉), et al. Relationship among fine-root morpho-logy, anatomy, tissue nitrogen concentration and respiration in different branch root orders in Larix gmelinii and Fraxinus mandshurica. Chinese Bulletin of Botany (植物学报), 2010, 45(2): 174-181 (in Chinese)
[49] 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
[50] Galvez DA, Landhäusser SM, Tyree MT. Root carbon reserve dynamics in aspen seedlings: Does simulated drought induce reserve limitation? Tree Physiology, 2011, 31: 250-257
[51] Piper FI. Drought induces opposite changes in the concentration of non-structural carbohydrates of two evergreen Nothofagus species of differential drought resis-tance. Annals of Forest Science, 2011, 68: 415-424

隔离降水对杉木幼苗细根生物量和功能特征的影响

Effects of precipitation exclusion on fine-root biomass and functional traits of Cunninghamia lanceolata seedlings.

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics

本文评价