三江源区高寒草甸植物多样性的海拔分布格局

doi:10.11686/cyxb2014347

摘要/Abstract

摘要：

三江源地区是我国受气候变化影响最大且最敏感的区域之一。研究高寒草甸植物多样性海拔分布格局及其与环境的关系,能为预测气候变化对植物多样性的影响和响应提供科学依据。本研究以青海三江源地区的6个样地/海拔梯度共78个样方的高寒草甸样地为研究对象,了解高寒草甸植物多样性和群落结构,分析海拔分布格局及其与环境的关系,旨在以空间替代时间的实验系统来揭示植物对气候变化的响应。统计分析发现,6个高寒草甸样地共有植物21科、51属、74种,且在中海拔和高海拔地区,高寒草甸以藏嵩草、高山嵩草、矮嵩草等莎草科植物占优势,低海拔地区高寒草甸则以针茅、早熟禾、垂穗披碱草等禾本科植物为优势种群。方差分析表明,随着海拔的降低,高寒草甸群落的物种多样性和物种丰富度均呈“单峰”分布格局,而均匀度指数逐渐升高。DCA分析发现,高寒草甸植物群落沿着海拔梯度呈现有规律的变化,具有从高寒草甸向高寒草原化草甸的逐渐过渡的特征,海拔梯度明显的影响了植物群落结构和多样性。此外,CCA结果表明,土壤pH值是影响高寒草甸植物群落分布格局的主要因素,土壤含水量、土壤温度、土壤有机碳、碱解氮含量与全钾含量是影响植物群落分布格局的关键因子。综上所述,我们推测气候变化极有可能影响三江源地区高寒草甸植物群落结构与分布格局。

Abstract:

The Three River Headwater region of Qinghai province, also known as the Qinghai-Tibetan Plateau is one of the regions in China likely to be most significantly affected by climate change. Hence, understanding the relationship between plant community distribution patterns and environment factors could afford scientific evidence for predicting the effect of climate change on plant diversity. In this research, six sites at a range of elevations and including 78 alpine meadow plots in the Three River Headwater region were surveyed to study the relationship between plant community structure and the environment. We aimed to explore the potential plant responses to climate change using a strategy of space-for-time substitution. At the six sites a total of 74 plant species belonging to 21 families and 51 genera were identified. Cyperaceous plants such as Kobresia schoenoides, Kobresia pygmaea and Kobresia humilis were the dominant species in the middle-high-elevation area, while plants of the Poaceae such as Stipa capillata, Poa annua and Elymus nutans covered the most of low elevation area. Species diversity index and richness index of the alpine meadow sites showed a unimodal pattern, and species evenness showed no significant differences along with the altitudinal gradient across the six sites. Detrended correspondence analysis indicated that species composition and diversity of plant communities changed continuously with decreasing elevation from alpine meadow to alpine steppe meadow. In addition, canonical correspondence analysis showed that soil pH was the main factor affect species diversity patterns in alpine meadow. Meanwhile, soil moisture, temperature, organic carbon content, available nitrogen content and total potassium content were key factors affect the distribution patterns of plant communities. On the basis of these observations, we predict that climate change is very likely to change plant community structure in the Three River Headwater Region.

卢慧, 丛静, 刘晓, 王秀磊, 唐军, 李迪强, 张于光. 三江源区高寒草甸植物多样性的海拔分布格局[J]. 草业学报, 2015, 24(7): 197-204.

LU Hui, CONG Jing, LIU Xiao, WANG Xiu-Lei, TANG Jun, LI Di-Qiang, ZHANG Yu-Guang. Plant diversity patterns along altitudinal gradients in alpine meadows in the Three River Headwater Region, China[J]. Acta Prataculturae Sinica, 2015, 24(7): 197-204.

参考文献

[1] Gaston K J. Global patterns in biodiversity. Nature, 2000, 405(6783): 220-227.

[2] He J S, Chen W L. A review of gradient changes in species diversity of land plant communities. Acta Ecologica Sinica, 1997, 17(1): 91-99.

[3] Tang Z Y, Fang J Y. A review on the elevational patterns of plant species diversity. Biodiversity Science, 2004, 12(1): 20-28.

[4] He Y H, Yan M, Zhang Q D. Altitudinal pattern of plant species diversity in the Wulu Mountain Nature Reserve, Shanxi, China. Acta Ecologica Sinica, 2013, 33(8): 2452-2462.

[5] Kong X H, Li Z J. Species diversity and altitudinal gradient patterns of evergreen broad-leaved forest in Meihuashan National Natural Reserve, Fujian Province. Plant Diversity and Resources, 2012, 34(2): 179-186.

[6] Marini L, Bona E, Kunin W E. Exploring anthropogenic and natural processes shaping fern species richness along elevational gradients. Journal of Biogeography, 2010, 38(1): 78-88.

[7] Ohlemuller R, Wilson J B. Vascular plant species richness along latitudinal and altitudinal gradients: a contribution from New Zealand temperate rainforests. Ecology Letters, 2000, 3(4): 262-266.

[8] Li G L, Cong J, Lu H, et al . Numerical classification and ordination of forest communities in habitat of Sichuan Snub-nosed Monkey in Hubei Shennongjia National Nature Reserve. Acta Ecologica Sinica, 2012, 32(23): 7501-7511.

[9] Liu H W, Cheng X Q, Kang F F. Changes of understory plant community in Pinus tabuliformis plantation and associated environmental explanations. Chinese Journal of Ecology, 2014, 33(2): 290-295.

[10] Chen B R, Li H S, Zhu Y X, et al . The spatial pattern and environmental interpretation of the plant community of Hulunber grassland. Acta Ecologica Sinica, 2010, 30(5): 1265-1271.

[11] Ren B. Analysis on the Typical Phytocoenoses and its Principle Factors of Distribution Patterns in East Dongting Lake Wetland[D]. Changsha: Hunan Agricultural University, 2012.

[12] Hu L, Wang C T, Wang G X, et al .Changes in the activities of soil enzymes and microbial community structure at different degradation successional stages of alpine meadows in the headwater region of Three Rivers, China. Acta Prataculturae Sinica, 2014, 23(3): 8-19.

[13] Liu Y S, Fan J W, Li Y Z, et al .Plant community productivity and diversity on alpine meadow steppe in the Three River Headwater Region, Qinghai Province under different denudation levels. Acta Prataculturae Sinica, 2014, 23(3): 1-7.

[14] Liu Y J, Shi G X, Mao L, et al . Direct and indirect influences of 8 yr of nitrogen and phosphorus fertilization on Glomeromycota in an alpine meadow ecosystem. New Phytologist, 2012, 194(2): 523-535.

[15] Rui Y C, Wang S P, Xu Z H, et al . Warming and grazing affect soil labile carbon and nitrogen pools differently in an alpine meadow of the Qinghai-Tibet Plateau in China. Journal of Soils and Sediments, 2011, 11(6): 903-914.

[16] Liu M C, Li D Q, Wen Y M, et al . The ecological function analysis and evaluation of ecosystem in Sanjiangyuan region. Acta Scientiae Circumstantiae, 2005, 25(9): 1280-1286.

[17] Li D Q, Li J W. Biodiversity: Scientific Investigation Report on Sanjiangyuan Natural Reserve[M]. Beijing: China Science and Technology Press, 2002.

[18] Duan M J, Gao Q Z, Guo Y Q, et al .Species diversity distribution pattern of alpine grassland communities along an altitudinal gradient in the Northern Tibet. Pratacultural Science, 2011, 28(10): 1845-1850.

[19] Bryant J A, Lamanna C, Morlon H, et al . Microbes on mountainsides: contrasting elevational patterns of bacterial and plant diversity. Proceedings of The National Academy of Sciences, 2008, 105(Supplement 1): 11505-11511.

[20] Wang K, Hong F Z, Zong J Y. Grassland resources and their sustainable utility in the “Three-River Headwaters” Region. Acta Agrestia Sinica, 2005,13(z1): 28-47.

[21] Fang J Y, Wang X P, Shen Z H, et al . Methods and protocols for plant community inventory. Biodiversity Science, 2009, 17(6): 533-548.

[22] Zhang Y G, Cong J, Lu H, et al . Community structure and elevational diversity patterns of soil Acidobacteria . Journal of Environmental Sciences, 2014, 26(8): 1717-1724.

[23] Ma K P, Liu Y M. Measurement of biotic community diversity I α diversity (Part 2). Biodiversity Science, 1994, 2(4): 231-239.

[24] Institute of Soil Science, Chinese Academy of Sciences. Soil Physical and Chemical Property Analysis[M]. Shanghai: Shanghai Science and Technology Press, 1983.

[25] Bao S D. Soil Agricultural Chemistry Analysis[M]. Beijing: China Agriculture Press, 2003.

[26] Xiao T, Shao Q Q, Sun W Y, et al . Grassland degradation characteristics of typical alpine meadow slopes in the Three-River Source Region of Qinghai province. Acta Agrestia Sinica, 2013, 21(3): 452-459.

[27] Wang G X, Li Y S, Wang Y B, et al . Effects of permafrost thawing on vegetation and soil carbon pool losses on the Qinghai-Tibet Plateau, China. Geoderma, 2008, 143(1): 143-152.

[28] Wang C T, Wang Q J, Long R J. Changes in plant species diversity and productivity along an elevation gradient in an alpine meadow. Acta Phytoecologica Sinica, 2004, 28(2): 240-245.

[29] Zhao Y K, Zhang W S, Wang Y N, et al . Research progress in physiology and molecular biology of plant responses to high pH. Chinese Journal of Eco-Agriculture, 2008, 16(3): 783-787.

[30] Zhao Z Y, Wang R H, Yin C H, et al . Species diversity and spatial heterogeneity of plant communities in piedmont plain of south slope of Tianshan Mountains. Acta Botanica Boreali-Occidentalia Sinica, 2007, 27(4): 784-790.

[31] Wang J B, Zhang D G, Cao G M, et al . Regional characteristics of the alpine meadow degradation succession on the Qinghai-Tibetan Plateau. Acta Prataculturae Sinica, 2013, 22(2): 1-10.

[32] Xu M H, Xue X. A research on summer vegetation characteristics & short-time responses to experimental warming of alpine meadow in the Qinghai-Tibetan Plateau. Acta Ecologica Sinica, 2013, 33(7): 2071-2083.

[33] Zhang Q, Niu J M, Buyantuyev A, et al . Ecological analysis and classification of Stipa breviflora communities in the Inner Mongolia region: the role of environmental factors. Acta Prataculturae Sinica, 2012, 21(1): 83-92.

[34] Tian H F, Liu H M, Wang W, et al . The distribution patterns of biodiversity and environmental interpretation in Daqingshan Mountain. Journal of Arid Land Resources and Environment, 2014, 28(8): 172-177.

[35] Cong J, Ying H Q, Lu H, et al . Species diversity and environmental interpretation of typical vegetation types in the Shennongjia Natural Reserve. Scientia Silvae Sinicae, 2013, 49(5): 30-35.

[2] 贺金生, 陈伟烈. 陆地植物群落物种多样性的梯度变化特征. 生态学报,1997,17(1): 91-99.

[3] 唐志尧, 方精云. 植物物种多样性的垂直分布格局. 生物多样性, 2004,12(1): 20-28.

[4] 何艳华, 闫明, 张钦弟. 五鹿山国家级自然保护区物种多样性海拔格局. 生态学报, 2013, 33(8): 2452-2462.

[5] 孔祥海, 李振基. 福建梅花山常绿阔叶林植物物种多样性及其海拔梯度格局. 植物分类与资源学报, 2012, 34(2): 179-186.

[8] 李广良, 丛静, 卢慧, 等. 神农架川金丝猴栖息地森林群落的数量分类与排序. 生态学报, 2012, 32(23): 7501-7511.

[9] 刘宏文, 程小琴, 康峰峰. 油松人工林林下植物群落变化及其环境解释. 生态学杂志, 2014, 33(2): 290-295.

[10] 陈宝瑞, 李海山, 朱玉霞, 等. 呼伦贝尔草原植物群落空间格局及其环境解释. 生态学报, 2010, 30(5): 1265-1271.

[11] 任勃. 东洞庭湖湿地典型植物群落及其格局主因子分析[M]. 长沙: 湖南农业大学, 2012.

[12] 胡雷, 王长庭, 王根绪, 等. 三江源区不同退化演替阶段高寒草甸土壤酶活性和微生物群落结构的变化. 草业学报, 2014, 23(3): 8-19.

[13] 刘艳书, 樊江文, 李愈哲, 等. 三江源地区不同剥蚀退化高寒草甸群落生物量与多样性特征. 草业学报, 2014, 23(3): 1-7.

[16] 刘敏超, 李迪强, 温琰茂, 等.三江源地区生态系统生态功能分析及其价值评估. 环境科学学报, 2005, 25(9): 1280-1286.

[17] 李迪强, 李建文. 三江源生物多样性: 三江源自然保护区科学考察报告[M]. 北京: 中国科学技术出版社, 2002.

[18] 段敏杰, 高清竹, 郭亚奇, 等.藏北高寒草地植物群落物种多样性沿海拔梯度的分布格局. 草业科学, 2011, 28(10): 1845-1850.

[20] 王堃, 洪绂曾, 宗锦耀.“三江源”地区草地资源现状及持续利用途径. 草地学报, 2005, 13(增刊): 28-47.

[21] 方精云, 王襄平, 沈泽昊, 等. 植物群落清查的主要内容, 方法和技术规范. 生物多样性, 2009, 17(6): 533-548.

[23] 马克平, 刘玉明. 生物群落多样性的测度方法Ⅰ.α多样性的测度方法(下). 生物多样性, 1994, 2(4): 231-239.

[24] 中国科学院南京土壤研究所. 土壤理化分析[M].上海: 上海科学技术出版社, 1983.

[25] 鲍士旦. 土壤农化分析[M]. 北京: 中国农业出版社, 2003.

[26] 肖桐, 邵全琴, 孙文义, 等. 三江源高寒草甸典型坡面草地退化特征综合分析. 草地学报, 2013, 21(3): 452-459.

[28] 王长庭, 王启基, 龙瑞军. 高寒草甸群落植物多样性和初级生产力沿海拔梯度变化的研究. 植物生态学报, 2004, 28(2): 240-245.

[29] 赵彦坤, 张文胜, 王幼宁, 等. 高pH对植物生长发育的影响及其分子生物学研究进展. 中国生态农业学报, 2008, 16(3): 783-787.

[30] 赵振勇, 王让会, 尹传华, 等. 天山南麓山前平原植物群落物种多样性及空间分异研究. 西北植物学报, 2007, 27(4): 784-790.

[31] 王建兵, 张德罡, 曹广民, 等.青藏高原高寒草甸退化演替的分区特征. 草业学报, 2013, 22(2): 1-10.

[32] 徐满厚, 薛娴. 青藏高原高寒草甸夏季植被特征及对模拟增温的短期响应. 生态学报, 2013, 33(7): 2071-2083.

[33] 张庆, 牛建明, Buyantuyev A, 等. 内蒙古短花针茅群落数量分类及环境解释. 草业学报, 2012, 21(1): 83-92.

[34] 田海芬, 刘华民, 王炜, 等. 大青山山地植物区系及生物多样性研究. 干旱区资源与环境, 2014, 28(8): 172-177.

[35] 丛静, 尹华群, 卢慧, 等. 神农架保护区典型植被的物种多样性和环境解释. 林业科学, 2013, 49(5): 30-35.