A comparative study of methods for monitoring plant diversity in montane shrub grassland in the Lhasa River Basin

doi:10.11686/cyxb2015199

Abstract

Abstract: Biodiversity is an important consideration in the monitoring and assessment of the ecological stability of rangelands in Tibet. Climate warming and grazing disturbance both threaten the stability of the Tibetan rangelands; hence, research into species succession, transition patterns and species diversity is important for the protection and utilization of grasslands in the region. A field survey was carried out to measure the community species composition and the species change along an altitudinal gradient in the Bailang village valley, Linzhou County in the Lhasa River Basin. Three conventional sampling methods, random square quadrats, repeat sampling lines and the Modified-Whittaker plots, were compared in this study. Key results were: (1) All three sampling methods indicated that α-diversity initially increased and then decreased with increasing altitude, though the line transect method using three 50 m transects detected more species than the other two methods. (2) The Sorensen similarity index and the Bray-Curtis index of β-diversity decreased with increasing altitude. (3) The intercept c and slope z of the relationship between species and sampling area showed unimodal patterns with increasing altitude as also did species richness. (4) In order to cover 80% of local plant species, the minimum sampling area should be up to 100 m². Future research should focus on the factors determining biodiversity distribution and community assembly in response to climate change and grazing disturbance.

LUO Li-Ming, WU Jian-Shuang, YU Cheng-Qun, PAN Ying, MIAO Yan-Jun, WU Jun-Xi, MING Sheng-Ping, GUO Ying-Jie. A comparative study of methods for monitoring plant diversity in montane shrub grassland in the Lhasa River Basin[J]. Acta Prataculturae Sinica, 2016, 25(3): 22-31.

References

[1] Jacquemyn H, Honnay O, Pailler T. Range size variation, nestedness and species turnover of orchid species along an altitudinal gradient on Re'union Island: Implications for conservation. Biological Conservation, 2007, 136: 388-397.
[2] Legendre P, Borcard D, Peresneto P R. Analyzing or explaining beta diversity? Comment. Ecology, 2008, 89(11): 3238-3244.
[3] Chen S B, Ou-Yang Z Y, Xu W H, et al . A review of beta diversity studies. Biodiversity Science, 2010, 18(4): 323-335.
[4] Jost L, Devries P, Walla T, et al . Partitioning diversity for conservation analyses. Diversity and Distributions, 2010, 16(1): 65-76.
[5] Liang J Y, Yu C T, Yang X H. Modified Whittaker: a multi scale nested vegetation sampling method. Research of Soil and Water Conservation, 2007, 14: 226-230.
[6] Zhang D Y, Wang G, Zhao S L. Study on the number of plant community succession in the abandoned farmland of the alpine meadow in South Gansu Ⅰ. The characteristic analysis of the succession of pioneer community. Chinese Grassland, 1988, 6: 14-18.
[7] Bashkin M, Stohlgren T J, Otsuki Y. Soil characteristics and plant exotic species invasions in the Grand Staircase-Escalante National Monument, Utah, USA. Applied Soil Ecology, 2002, 22: 67-77.
[8] Adler P B. Neutral models fail to reproduce observed species-time and species-area relationships in Kansas grasslands. Ecology, 2004, 85: 1265-1272.
[9] Wang L, Wang D L, Bai Y G, et al . Spatial distributions of multiple plant species affect herbivore foraging selectivity. Oikos, 2010, 119: 401-408.
[10] Stohlgren T J, Bull K A, Otsuki Y. Comparison of rangeland vegetation sampling techniques in the Central Grasslands. Journal of Range Manage, 1998, (51): 164-172.
[11] Wang S P, Li Y H, Wang Y F, et al . Influence of different stocking rates on plant diversity of Artemisia frigida community in Inner Mongolia Steppe. Acta Biotanica Sinica, 2001, 43(1): 89-96.
[12] Drakare S, Lennon J J, Hillebrand H. The imprint of geographical, evolutionary and ecological context on species-area relationships. Ecology Letters, 2006, 9(2): 215-227.
[13] Tang Z Y, Qiao X J, Fang J Y. Species-area relationship in biological communities. Biodiversity Science, 2009, 17(6): 549-559.
[14] Liu C R, Ma K P, Yu S L, et al . Plant community diversity in Donglingshan Mountain, Beijing, China: Ⅶ. The determination of critical sampling areas for several types of plant communities. Acta Ecology Sinica, 1998, 18(1): 15-23.
[15] Wang G P, Wang S P. Comparative study on the sampling methods of Leymus chinensis grassland of Inner Mongolia Autonomous Region. Acta Agrestia Sinica, 2003, 11(4): 283-288.
[16] Zhang R, Chen J Q, Hou Y C, et al . Relationships between plant species number and sampling area for sub-alpine meadow plant communities. Chinese Journal of Ecology, 2013, 32(9): 2268-2274.
[17] Zhao H X. Degradation status, causes and improving measures of Tibet grassland. Tibet's Science and Technology, 2007, 2: 48-51.
[18] Sun H L, Zheng D, Yao T D, et al . Protection and construction of the national ecological security shelter zone on Tibetan Plateau. Acta Geographica Sinica, 2012, 67(1): 3-12.
[19] Meng F D, Wang C S, Zhang Z H, et al . Comparative study of monitoring methods about plant diversity and above-ground biomass of alpine grasslands in the Tibetan Plateau. Acta Botanica Boreali-Occidentalia Sinica, 2013, 33(9): 1923-1929.
[20] Dong S K, Tang L, Wang X X, et al . Minimum plot size for estimating plant biodiversity of the alpine grasslands on the Qinghai-Tibetan Plateau. Biodiversity Science, 2013, 21(6): 651-657.
[21] Zhang G L, Ou-Yang H, Zhou C P, et al . Response of agricultural thermal resources to climate change in the region of the brahmaputra river and its two tributaries in Tibet during past 50 years. Resources Science, 2010, 32(10): 1943-1954.
[22] Stohlgren T J, Falkner M B, Schell L D. A Modified-Whittaker nested vegetation sampling method. Vegetation, 1995, 117: 113-121.
[23] Wu J S, Li X J, Shen Z X, et al . Species diversity distribution pattern of alpine grasslands communities along a precipitation gradient across Northern Tibetan Plateau. Acta Prataculturae Sinica, 2012, 21(3): 17-25.
[24] Feng J M, Wang X P, Xu C D, et al . Altitudinal patterns of plant species diversity and community structure on Yulong Mountains, Yunnan, China. Journal of Mountain Science, 2006, 24(1): 110-116.
[25] Gao X M, Ma K P, Huang J H, et al . Studies on plant community diversity in Donglingshan Mountain, Beijing, China: Ⅺ. The β diversity of mountain meadow. Acta Ecology Sinica, 1998, 18(1): 24-32.
[26] Zhang L M, Gao X, Dong K, et al . Study on community β diversity quantification structures and its measurements. Journal of Yunnan Agricultural University, 2014, 29(4): 578-585.
[27] Tjørve E. Shapes and functions of species-area curves: a review of possible models. Journal of Biogeography, 2003, 30(6): 827-835.
[28] Scheiner S M. Six types of species-area curves. Global Ecology and Biogeography, 2003, 12(6): 441-447.
[29] Connor E F, McCoy E D. Statistics and biology of the species-area relationship. American Naturalist, 1979, 113: 791-833.
[30] Gleason H A. Species and area. Ecology, 1925, 6: 66-74.
[31] Huston M A. Biological Diversity: The Coexistence of Species on Changing[M]. Cambridge: Cambridge University Press, 1994: 142-143.
[32] Wang C T, Wang Q J, Long R J, et al . Changes in plant species diversity and productivity along an elevation gradient in an alpine meadow. Acta Phytoecologica Sinica, 2004, 28(2): 240-245.
[33] 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.
[34] Luo L M, Miao Y J, Wu J S, et al . Variation in biodiversity of montane shrub grassland communities along an altitudinal gradient in a Lhasa River basin valley. Acta Prataculturae Sinica, 2014, 23(6): 320-326.
[35] Ma K M, Ye W H, Sang W G, et al . Study on plant community diversity in Donglingshan Moutain, Beijing, China: Ⅹ. β diversity and fractal analysis on transect on different scales. Acta Ecology Sinica, 1997, 7(6): 626-634.
[36] Tang Z Y, Fang J Y, Zhang L. Patterns of woody plant species diversity along environmental gradients on Mt. Taibai, Qinling Mountains. Biodiversity Science, 2004, 12(1): 115-122.
[37] Xu P B, Deng J M, Zhao C M, et al . Study on grassland community characteristics and species diversity along altitudinal gradients in the Gahai wetland, Gansu province. Acta Prataculturae Sinica, 2012, 21(2): 219-226.
[38] Qiao X J, Tang Z Y, Mmat A N W E, et al . Study on species-area relationships in the southern and northern slopes of the Tianshan Mountains. Arid Zone Research, 2011, 28(1): 54-59.
[39] Jiang J, Zhang C Y, Zhao X H. Plant species-area relationship in a 42-hm 2 research plot of coniferous and board-leaved mixed forest in Jiaohe, Jilin Province, China. Chinese Journal of Plant Ecology, 2012, 36(1): 30-38.
[40] Bai Y F, Xu Z X, Li D X. Study on α diversity of four Stipa communities in Inner Mongolia Plateau. Biodiversity Science, 2000, 8(4): 353-360.
[41] Chen H, Li Y Q, Zheng S W, et al . Determination of species-area relationships and minimum sampling area for the shrub communities in arid valley in the upper reach of the Minjiang River. Acta Ecology Sinica, 2007, 27(5): 1818-1825.
[42] Weiher E. The combined effects of scale and productivity on species richness. Journal of Ecology, 1999, 87: 1005-1011.
[43] Wang W Y, Wang Q J, Wang H C. The effect of land management on plant community composition, species diversity, and productivity of alpine Kobersia steppe meadow. Ecological Research, 2006, 21(2): 181-187.
[44] 陈圣宾, 欧阳志云, 徐卫华, 等. Beta多样性研究进展. 生物多样性, 2010, 18(4): 323-335.
[45] 梁继业, 于春堂, 杨晓晖. 改进的Modified Whittaker:一种多尺度的嵌套式植物多样性取样方法. 水土保持研究, 2007, 14: 226-230.
[46] 张大勇, 王刚, 赵松岭. 甘南亚高山草甸弃耕地植物群落演替的数量研究Ⅰ.演替先锋群落的特征分析. 中国草地, 1988, 6: 14-18.
[47] 汪诗平, 李永宏, 王艳芬, 等. 不同放牧率对内蒙古冷蒿草原植物多样性的影响. 植物学报, 2001, 43(1): 89-96.
[48] 唐志尧, 乔秀娟, 方精云. 生物群落种-面积关系. 生物多样性, 2009, 17(6): 549-559.
[49] 刘灿然, 马克平, 于顺利, 等. 北京东灵山地区植物群落多样性研究Ⅶ.几种类型植物群落临界抽样面积的确定. 生态学报, 1998, 18(1): 15-23.
[50] 王国平, 汪诗平. 羊草草原植被监测方法的比较研究. 草地学报, 2003, 11(4): 283-288.
[51] 张蕊, 陈军强, 侯尧宸, 等. 亚高山草甸植物物种数与取样面积的关系. 生态学杂志, 2013, 32(9): 2268-2274.
[52] 赵好信. 西藏草地退化现状,成因及改良对策. 西藏科技, 2007, 2: 48-51.
[53] 孙鸿烈, 郑度, 姚檀栋, 等. 青藏高原国家生态安全屏障保护与建设. 地理学报, 2012, 67(1): 3-12.
[54] 孟凡栋, 王常顺, 张振华, 等. 西藏高原高寒草地群落植物多样性和地上生物量监测方法的比较研究. 西北植物学报, 2013, 33(9): 1923-1929.
[55] 董世魁, 汤琳, 王学霞, 等. 青藏高原高寒草地植物多样性测定的最小样地面积. 生物多样性, 2013, 21(6): 651-657.
[56] 张戈丽, 欧阳华, 周才平, 等. 近50年来气候变化对西藏"一江两河"地区农业气候热量资源的影响. 资源科学, 2010, 32(10): 1943-1954.
[57] 武建双, 李晓佳, 沈振西, 等. 藏北高寒草地样带物种多样性沿降水梯度的分布格局. 草业学报, 2012, 21(3): 17-25.
[58] 冯建孟, 王襄平, 徐成东, 等. 玉龙雪山植物物种多样性和群落结构沿海拔梯度的分布格局. 山地学报, 2006, 24(1): 110-116.
[59] 高贤明, 马克平, 黄建辉, 等. 北京东灵山地区植物群落多样性的研究Ⅺ.山地草甸U多样性. 生态学报, 1998, 18(1): 24-32.
[60] 张立敏, 高鑫, 董坤, 等. 生物群落 β 多样性量化水平及其评价方法. 云南农业大学学报, 2014, 29(4): 578-585.
[61] 王长庭, 王启基, 龙瑞军, 等. 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.
[62] 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.
[63] 罗黎鸣, 苗彦军, 武建双, 等. 拉萨河谷山地灌丛草地物种多样性随海拔升高的变化特征. 草业学报, 2014, 23(6): 320-326.
[64] 马克明, 叶万辉, 桑卫国, 等. 北京东灵山地区植物群落多样性研究Ⅹ.不同尺度下群落样带的 β 多样性及分形分析. 生态学报, 1997, 7(6): 626-634.
[65] 唐志尧, 方精云, 张玲. 秦岭太白山木本植物物种多样性的梯度格局及环境解释. 生物多样性, 2004, 12(1): 115-122.
[66] 徐鹏彬, 邓建明, 赵长明, 等. 甘肃尕海湿地不同海拔草地群落组分及物种多样性研究. 草业学报, 2012, 21(2): 219-226.
[67] 乔秀娟, 唐志尧, 安尼瓦尔·买买提, 等. 天山南北坡植物种-面积关系. 干旱区研究, 2011, 28(1): 54-59.
[68] 姜俊, 张春雨, 赵秀海. 吉林蛟河42 hm 2 针阔混交林样地植物种-面积关系. 植物生态学报, 2012, 36(1): 30-38.
[69] 白永飞, 许志信, 李德新. 内蒙古高原针茅草原群落 α 多样性研究. 生物多样性, 2000, 8(4): 353-360.
[70] 陈泓, 黎燕琼, 郑绍伟, 等. 岷江上游干旱河谷灌丛群落种-面积曲线的拟合及最小面积确定. 生态学报, 2007, 27(5): 1818-1825.