内蒙古典型草原主要物种-土壤互反馈初探

doi:10.11733/j.issn.1007-0435.2016.06.005

草地学报 ›› 2016, Vol. 24 ›› Issue (6): 1184-1191.DOI: 10.11733/j.issn.1007-0435.2016.06.005

内蒙古典型草原主要物种-土壤互反馈初探

达布希拉图, 彭菲, 林杉

中国农业大学资源与环境学院, 北京 100193

收稿日期:2015-07-07 修回日期:2016-05-03 出版日期:2016-12-15 发布日期:2017-03-18
通讯作者: 林杉
作者简介:达布希拉图(1989-),女,内蒙古赤峰人,硕士,研究方向为草原生态营养,E-mail:dabuxilatu8724@163.com
基金资助:
国家自然科学基金项目（41071207）资助

Plant-Soil Feedback of Main Species in Inner Mongolian Steppe

DA Bu-xi-la-tu, PENG Fei, LIN Shan

College of Resources and Environmental Sciences, China Agricultural University, Beijing 100193, China

Received:2015-07-07 Revised:2016-05-03 Online:2016-12-15 Published:2017-03-18

摘要/Abstract

摘要：

过度放牧不仅导致草地生产力下降，还会引起植物群落结构的改变，这可能与土壤理化性状和土壤生物组成的变化有关。探索土壤和植物的互反馈现象，对理解草原生态系统的稳定性具有重要意义。本研究选择内蒙古锡林郭勒草原相邻地块中度和过度放牧样地的2种土壤，在灭菌和不灭菌条件下，分别种植中度放牧样地优势物种大针茅（Stipa grandis）和过度放牧样地优势物种冷蒿（Artemisia frigida）2块样地共有物种冰草（Agropyron cristatum）和隐子草（Cleistogenes squarrosa），测定了植物生物量和水分利用效率。结果表明，中度放牧样地优势物种大针茅表现出显著的负反馈作用，而过度放牧样地优势物种冷蒿，则表现出显著的正反馈作用。与不灭菌处理相比，灭菌后，4个物种地上部生物量与水分利用效率都有增加趋势，其中冰草和隐子草生物量和水分利用效率增加显著。

关键词: 典型草原, 放牧强度, 生物量, 水分利用效率, 植物-土壤互反馈, 灭菌

Abstract:

Overgrazing resulted in productivity decrease of typical grassland and species composition change of plant community, which might be caused by the change of soil phy-chemial properties and soil microbes. Exploring plant-soil feedback has important implications for understanding the stability of grassland ecosystem. We sampled soil from two adjacent sites which were moderately grazed and overgrazed sites in Xilingol grassland. We used two sterilization treatments, and planted four species, the dominant species of moderately grazed site Stipa grandis, the dominant species of overgrazed site Artemisia frigida and the co-occurrence species Agropyron Cristatum and Cleistogenes squarrosa. Then we estimated shoot biomass and water use efficiency of the four species. Our results indicated that Stipa grandis showed negative feedback, while Artemisia frigida showed positive feedback. Compared with non-sterilized treatments, shoot biomass and water use efficiency of four species increased after sterilization, especially for Agropyron cristatum and Cleistogenes squarrosa, their shoot biomass and water use efficiency increased significantly.

Key words: Typical grassland, Grazing intensity, Shoot biomass, Water use efficiency, Plant-soil feedback, Sterilization

中图分类号:

S154.4

达布希拉图, 彭菲, 林杉. 内蒙古典型草原主要物种-土壤互反馈初探[J]. 草地学报, 2016, 24(6): 1184-1191.

DA Bu-xi-la-tu, PENG Fei, LIN Shan. Plant-Soil Feedback of Main Species in Inner Mongolian Steppe[J]. Acta Agrestia Sinica, 2016, 24(6): 1184-1191.

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参考文献

[1] Han J G, Zhang Y J, Wang C J. Rangeland degradation and restoration management in China[J]. The Rangeland Journal,2008,30(2):233-239
[2] Dakhah M, Gifford G F. Influence of vegetation, rock cover and trampling on infiltration rates and sediment production[J]. Water Resource Bull,1980,16:979-986
[3] Frissel M J. Cycling of mineral nutrients in agricultural ecosystems[J]. Agro-Ecosystems,1977,4(25):1-254
[4] Steffens M, Klbl A, Totsche K U, Kogel-Knabner I. Grazing effects on soil chemical and physical properties in a semiarid steppe of Inner Mongolia (PR China)[J]. Geoderma,2008,143(1):63-72
[5] 肖运峰,李世英. 羊草草原放牧退化演替及其退化原因分析[J]. 中国草地,1980(3):20-27
[6] Todd S W, Hoffman M T. A fence-line contrast reveals effects of heavy grazing on plant diversity and community composition in Namaqualand, South Africa[J]. Plant Ecology,1999,142(1-2):169-178
[7] 李永宏. 内蒙古草原草场放牧退化模式研究及退化监测专家系统雏议[J]. 植物生态学报,1994,18(1):68-79
[8] 王炜,刘钟龄,郝敦元,等.内蒙古典型草原退化群落恢复演替的研究1.退化草原的基本特征与恢复演替规律[J]. 植物生态学报,1996a(20):449-459
[9] 王炜,刘钟龄,郝敦元,等. 内蒙古典型草原退化群落恢复演替的研究.U.恢复演替时间进程的分析[J]. 植物生态报,1996b(20):460-471
[10] Van der Putten W H, Van D C, Troelstra S R. Biotic soil factors affecting the growth and development of Ammophila arenaria[J]. Oecologia,1988,76(2):313-320
[11] Kardol P, Cornips N J, Van Kempen M L, et al. Microbe mediated plant-soil feedback causes historical contingency effects in plant community assembly[J]. Ecological Monographs,2007,77(2):147-162
[12] Bever J D. Feedback between plants and their soil communities in an old-field community[J]. Ecology,1994,75(7):1965-1977
[13] Wardle D A. Communities and Ecosystems:Linking the Aboveground and Belowground Components[M]. Princeton:Princeton University Press,2002,56(3):35-41
[14] Ehrenfeld J G, Ravit B, Elgersma K. Feedback in the plant-soil system[J]. Annual Review of Environment and Resources,2005,30:75-115
[15] Mangla S, Inderjit & Callaway, R.M. Exotic invasive plant accumulates native soil pathogens which inhibit native plants[J]. Journal of Ecology,2008,96(1):58-67
[16] Bever J D, Westover K M, Antonovics J. Incorporating the soil community into plant population dynamics:the utility of the feedback approach[J]. Journal of Ecology,1997,(85):561-573
[17] Van der Putten W H. Plant defense belowground and spatiotemporal processes in natural vegetation[J]. Ecology,2003,84(9):2269-2280
[18] Grayston S, Wang S Q, Campbell C D, et al. Selective influence of plant species on microbial diversity in the rhizosphere[J]. Soil Biology and Biochemistry,1998,30(3):369-378
[19] Bonanomi G, Giannino F, Mazzoleni S. Negative plant-soil feedback and species coexistence[J]. Oikos,2005,11(2):311-321
[20] 陈佐忠,汪诗平.中国典型草原生态系统[M].北京:科学出版社,2000:1-57
[21] Berendse F. Litter decomposability-a neglected compound of plant finess[J]. Journal of Ecology,1994,82:187-190
[22] Bezemer T M, Lawson C S, Hedlund K, et al. Plant species and functional group effects on abiotic and microbial soil properties and plant-soil feedback responses in two grasslands[J]. Journal of Ecology,2006,94(5):893-904
[23] Giese M. Nitrogen dynamics as affected by grazing in semi-arid grasslands of Inner Mongolia[D]. Kiel:Christian Albrechts Universitaet,2007:72-77
[24] Gao Y, Giese M, Lin S. Belowground net primary productivity and biomass allocation of a grassland in Inner Mongolia is affected by grazing intensity[J]. Plant and Soil,2008,307(1-2):41-50
[25] Stevens C J, Dise N B, Mountford J O, et al. Impact of nitrogen deposition on the species richness of grasslands[J]. Science,2004,303(5665):1876-1879
[26] Bezemer T M, Wagenaar R, Van Dam N M, et al. Interactions between above-and belowground insect herbivores as mediated by the plant defense system[J]. Oikos,2003,101(3):555-562
[27] Klironomos J N. Feedback with soil biota contributes to plant rarity and invasiveness in communities[J]. Nature,2002,417(6884):67-70
[28] Bever J D. Soil community feedback and the coexistence of competitors:conceptual frameworks and empirical tests[J]. New Phytologist,2003,157(3):465-473
[29] Kulmatiski A, Beard K H, Stevens J R, et al. Plant-soil feedbacks:a meta-analytical review[J]. Ecology Letters,2008,11(9):980-992
[30] Wardle D A, Bonner K I, Barker G M, et al. Plant removals in perennial grassland:vegetation dynamics, decomposers, soil biodiversity, and ecosystem properties[J]. Ecological Monographs,1999,69(4):535-568
[31] Chapman S K, Langley J A, Hart S C, et al. Plants actively control nitrogen cycling:uncorking the microbial bottleneck[J]. New Phytologist,2005,169(1):27-34
[32] Kardol P, Bezemer T M, Van der Putten W H. Temporal variation in plant-soil feedback controls succession[J]. Ecology Letter,2006,9(9):1080-1088
[33] Aerts R, Chapin F S. The mineral nutrition of wild plants revisited:a re-evaluation of processes and patterns[J]. Advances in Ecological Research,2000,30:1-67
[34] Li J, Lin S, Taube F, et al. Above and belowground net primary productivity of grassland influenced by supplemental water and nitrogen in Inner Mongolia[J]. Plant and Soil,2011,340(1-2):253-264
[35] Pernilla Brinkman E, Van der Putten W H, Bakker E J, et al. Plant-soil feedback:experimental approaches, statistical analyses and ecological interpretations[J]. Journal of Ecology,2010,98(5):1063-1073
[36] Hendriks M, Mommer L, Caluwe H, et al. Independent variations of plant and soil mixtures reveal soil feedback effects on plant community overyielding[J]. Journal of Ecology,2013,101(2):287-297

内蒙古典型草原主要物种-土壤互反馈初探

Plant-Soil Feedback of Main Species in Inner Mongolian Steppe

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