内蒙古草原不同基因组大小植物对氮水添加的响应

doi:10.13287/j.1001-9332.201908.018

应用生态学报 ›› 2019, Vol. 30 ›› Issue (8): 2675-2681.doi: 10.13287/j.1001-9332.201908.018

内蒙古草原不同基因组大小植物对氮水添加的响应

赵芳媛^1,2, 魏存争^3*, 吕晓涛¹, 韩兴国^2,3

¹中国科学院沈阳应用生态研究所, 沈阳 110016;
²中国科学院大学, 北京 100049;
³中国科学院植物研究所植被与环境变化国家重点实验室, 北京 100093

收稿日期:2019-04-30 出版日期:2019-08-15 发布日期:2019-08-15
通讯作者: * E-mail: weicunzheng@ibcas.ac.cn
作者简介:赵芳媛,女,1990年生,硕士研究生.主要从事生态系统生态学研究.E-mail:fangyuanyale@163.com
基金资助:
中国科学院科技服务网络计划项目(KFJ-STS-ZDTP-036)

Responses of plant species with different genome size to water and nitrogen addition in Inner Mongolia Grassland, China

ZHAO Fang-yuan^1,2, WEI Cun-zheng^3*, LYU Xiao-tao¹, HAN Xing-guo^2,3

¹Institute of Applied Ecology, Chinese Academy of Sciences, Shenyang 110016, China;
²University of Chinese Academy of Sciences, Beijing 100049, China;
³State Key Laboratory of Vegetation and Environmental Change, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China.

Received:2019-04-30 Online:2019-08-15 Published:2019-08-15
Contact: * E-mail: weicunzheng@ibcas.ac.cn

摘要/Abstract

摘要： 被子植物基因组大小的种间差异巨大,约为2400倍.基因组大小与植物从细胞核到个体水平的一系列性状密切相关,进而影响植物对环境变化的响应.作为水分和养分共同限制的生态系统,内蒙古草原植物群落对氮素、水分有效性变化的响应具有明显的种间差异,这种差异可能与种间基因组大小不同有关.本研究利用流式细胞术测定了内蒙古典型草原水分、氮素添加实验平台植物的基因组大小,研究了不同基因组大小植物地上净初级生产力(ANPP)和物种丰富度对水分、氮素添加及其交互作用的响应.结果表明: 基因组大小显著影响了不同植物ANPP对水分的响应,小基因组植物ANPP对氮水添加响应更敏感,加水和氮水共同添加显著增加了小基因组植物ANPP,而大基因组植物ANPP对所有处理响应均不显著.加氮对大小基因组植物ANPP都无显著影响.大小基因组植物的物种丰富度对氮水添加的响应也均不显著.基因组大小影响内蒙古草原不同植物ANPP对水分增加的响应.作为植物细胞核水平上十分稳定且种间差异巨大的物种性状,将基因组大小引入生态学研究将对全球变化背景下生态系统结构与功能变化研究起到重要作用.

Abstract: Plant genome size (GS) varies greatly over 2400-fold in angiosperms. Genome sizes are closely related to plant traits from cellular to individual level, which would have far-reaching ecolo-gical implications. Genome size may shape the interspecific responses of plants to changes of resource availability in Inner Mongolia grassland which is co-limited by water and nitrogen availabi-lity. We tested the role of genome size in structuring plant community composition after single and combined water (W) amd nitrogen (N) addition in a typical grassland of Inner Mongolia. Plant genome sizes were estimated by flow cytometry. We found that the response of plant aboveground net primary production (ANPP) to change in water availability was significantly affected by genome size. Water and NW addition significantly increased ANPP of small GS plants, instead of large GS species. Nitrogen addition had no effects on ANPP of both small and large GS plants. We found no effects of all the treatments on plant species richness. Results showed that GS modulated the response of grassland plant species to changes in water rather than nitrogen availability in Inner Mongolia. Since GS is a relatively constant trait with substantial interspecific variation, the application of GS in ecological studies would be of great significance to better understanding of ecosystem structure and function under global change.

赵芳媛, 魏存争, 吕晓涛, 韩兴国. 内蒙古草原不同基因组大小植物对氮水添加的响应[J]. 应用生态学报, 2019, 30(8): 2675-2681.

ZHAO Fang-yuan, WEI Cun-zheng, LYU Xiao-tao, HAN Xing-guo. Responses of plant species with different genome size to water and nitrogen addition in Inner Mongolia Grassland, China[J]. Chinese Journal of Applied Ecology, 2019, 30(8): 2675-2681.

参考文献

[1] Swift H. The constancy of desoxyribose nucleic acid in plant nuclei. Proceedings of the National Academy of Sciences of the United States of America, 1950, 36: 643-654
[2] Leitch IJ, Johnston E, Pellicer J, et al. Angiosperm DNA C-values database (Release 7.0) [EB/OL]. (2017-07) [2017-11-29]. http://data.kew.org/cvalues/
[3] Pellicer J, Hidalgo O, Dodsworth S, et al. Genome size diversity and its impact on the evolution of land plants. Genes, 2018, 9: 88
[4] Gregory TR. Genome size and developmental complexity. Genetica, 2002, 115: 131-146
[5] Knight CA, Ackerly D. Variation in nuclear DNA content across environmental gradients: A quantile regression analysis. Ecology Letters, 2002, 5: 66-76
[6] Bennett MD. The duration of meiosis. Proceedings of the Royal Society of London B: Biological Sciences, 1971, 178: 277-299
[7] Bennett MD. Variation in genomic form in plants and its ecological implications. New Phytologist, 2008, 106: 177-200
[8] Francis D, Davies MS, Barlow PW. A strong nucleoty-pic effect on the cell cycle regardless of ploidy level. Annals of Botany, 2008, 101: 747-757
[9] Vesely P, Bures P, Smarda P, et al. Genome size and DNA base composition of geophytes: The mirror of phenology and ecology? Annals of Botany, 2012, 109: 65-75
[10] Grime JP, Mowforth MA. Variation in genome size: An ecological interpretation. Nature, 1982, 299: 151-153
[11] Guignard MS, Nichols RA, Knell RJ, et al. Genome size and ploidy influence angiosperm species’ biomass under nitrogen and phosphorus limitation. New Phytolo-gist, 2016, 210: 1195-1206
[12] Šmarda P, Hejcman M, Brezinova A, et al. Effect of phosphorus availability on the selection of species with different ploidy levels and genome sizes in a long-term grassland fertilization experiment. New Phytologist, 2013, 200: 911-921
[13] Nacuteski JM, Bazzaz BA. Genome size and high CO₂. Nature, 1995, 376: 559-560
[14] Suda J, Meyerson LA, Leitch IJ, et al. The hidden side of plant invasions: The role of genome size. New Phyto-logist, 2015, 205: 994-1007
[15] Pyšek P, Skalova H, Cˇuda J, et al. Small genome separates native and invasive populations in an ecologically important cosmopolitan grass. Ecology, 2018, 99: 79-90
[16] Sterner R, Elser JJ. Ecological Stoichiometry: The Bio-logy of Elements from Molecules to the Biosphere. Princeton, NJ, USA: Princeton University Press, 2002
[17] Bai Y, Wu J, Xing Q, et al. Primary production and rain use efficiency across a precipitation gradient on the Mongolia Plateau. Ecology, 2008, 89: 2140-2153
[18] Clark CM, Tilman D. Loss of plant species after chronic low-level nitrogen deposition to prairie grasslands. Nature, 2008, 451: 712-715
[19] Lan Z, Bai Y. Testing mechanisms of N-enrichment-induced species loss in a semiarid Inner Mongolia grassland: Critical thresholds and implications for long-term ecosystem responses. Philosophical Transactions of the Royal Society B: Biological Sciences, 2012, 367: 3125-3134
[20] You C, Wu F, Gan Y, et al. Grass and forbs respond differently to nitrogen addition: A meta-analysis of global grassland ecosystems. Scientific Reports, 2017, 7: 1563-1572
[21] Galloway JN, Aber JD, Erisman JW, et al. The nitrogen cascade. BioScience, 2003, 53: 341-356
[22] Lu C, Tian H, Liu M, et al. Effect of nitrogen deposition on China’s terrestrial carbon uptake in the context of multifactor environmental changes. Ecological Applications, 2012, 22: 53-75
[23] Acquisti C, Elser JJ, Kumar S. Ecological nitrogen limitation shapes the DNA composition of plant genomes. Molecular Biology & Evolution, 2009, 26: 953-956
[24] Leitch AR, Leitch IJ, Trimmer M, et al. Impact of genomic diversity in river ecosystems. Trends in Plant Science, 2014, 19: 361-366
[25] Bennett MD, Leitch IJ. Nuclear DNA amounts in angiosperms: Targets, trends and tomorrow. Annals of Botany, 2011, 107: 467-590
[26] Hetherington AM, Woodward FI. The role of stomata in sensing and driving environmental change. Nature, 2003, 424: 901-908
[27] Bainard JD. Patterns and Biological Implications of DNA Content Variation in Land Plants. PhD Thesis. Guelph, ON, Canada: University of Guelph, 2011
[28] Sala OE, Gherardi LA, Reichmann L, et al. Legacies of precipitation fluctuations on primary production: Theory and data synthesis. Philosophical Transactions of the Royal Society B: Biological Sciences, 2012, 367: 3135-3144
[29] Lü X, Dijkstra FA, Kong D, et al. Plant nitrogen uptake drives responses of productivity to nitrogen and water addition in a grassland. Scientific Reports, 2014, 4: 4817
[30] Dolezel J, Bartoš J. Plant DNA flow cytometry and estimation of nuclear genome size. Annals of Botany, 2005, 95: 99-110
[31] Dolezel J, Greilhuber J, Suda J. Estimation of nuclear DNA content in plants using flow cytometry. Nature Protocols, 2007, 2: 2233-2244
[32] Ohri D, Fritsch RM, Hanelt P. Evolution of genome size in Allium (Alliaceae). Plant Systematics and Evolution, 1998, 210: 57-86
[33] Leitch IJ, Leitch AR. Genome size diversity and evolution in land plants// Greilhuber J, Dolezel J, Wendel JF, eds. Plant Genome Diversity. Volume 2: Physical Structure, Behaviour and Evolution of Plant Genomes. Vienna: Springer, 2013: 307-322
[34] Medici A, Marshall-Colon A, Ronzier E, et al. AtNIGT1/HRS1 integrates nitrate and phosphate signals at the Arabidopsis root tip. Nature Communications, 2015, 6: 6274
[35] Heineke D, Stitt M, Heldt HW. Effects of inorganic phosphate on the light dependent thylakoid energization of intact spinach chloroplasts. Plant Physiology, 1989, 91: 221-226
[36] Muller R, Morant M, Jarmer H, et al. Genome-wide analysis of the Arabidopsis leaf transcriptome reveals interaction of phosphate and sugar metabolism. Plant Physiology, 2007, 143: 156-171
[37] Beaulieu JM, Leitch IJ, Patel S, et al. Genome size is a strong predictor of cell size and stomatal density in angiosperms. New Phytologist, 2008, 179: 975-986
[38] Bucher SF, Auerswald K, Grün-Wenzel C, et al. Sto-matal traits relate to habitat preferences of herbaceous species in a temperate climate. Flora, 2017, 229: 107-115
[39] Franks PJ, Farquhar GD. The mechanical diversity of stomata and its significance in gas-exchange control. Plant Physiology, 2007, 143: 78-87
[40] Gindel I. Stomatal number and size as related to soil moisture in tree xerophytes in Israel. Ecology, 1969, 50: 263-267
[41] Grime JP. Evidence for the existence of three primary strategies in plants and its relevance to ecological and evolutionary theory. The American Naturalist, 1977, 111: 1169-1194

内蒙古草原不同基因组大小植物对氮水添加的响应

Responses of plant species with different genome size to water and nitrogen addition in Inner Mongolia Grassland, China

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