植物研究 ›› 2017, Vol. 37 ›› Issue (6): 807-815.doi: 10.7525/j.issn.1673-5102.2017.06.002
唐丽丽1, 陈国平1, 冯小梅2, 赵铁建2, 石福臣1
收稿日期:
2017-04-29
出版日期:
2017-11-15
发布日期:
2017-11-25
通讯作者:
石福臣
E-mail:fcshi@nankai.edu.cn
作者简介:
唐丽丽(1989-),女,博士研究生,主要从事植物资源与植物生态学研究。
基金资助:
TANG Li-Li1, CHEN Guo-Ping1, FENG Xiao-Mei2, ZHAO Tie-Jian2, SHI Fu-Chen1
Received:
2017-04-29
Online:
2017-11-15
Published:
2017-11-25
Supported by:
摘要: 群落构建机制对解释植物物种共存、多样性的维持与发展至关重要。本文以燕山山脉东麓的植物群落为研究对象,野外调查了374个植物样方(20 m×30 m)。通过多元回归树、植物群落亲缘关系指数、高斯核函数密度估计等研究,重点探究了植物群落构建的机制。研究结果表明,燕山东麓的植物群落可划分为以荆条(Vitex negundo var.heterophylla)、槲栎(Quercus aliena)、蒙古栎(Quercus mongolica)、栓皮栎(Quercus variabilis)和白蜡树(Fraxinus chinensis)为优势的5个群系。植物最大树高这一功能性状表现出了较强的系统发育信号,此区域植物功能性状保守性较强。荆条灌丛、槲栎、蒙古栎群系的群落构建过程以环境过滤为主导,栓皮栎群系的群落构建过程以负密度制约为主导,白蜡树群落的构建机制有由环境过滤向负密度制约过渡的趋势。另外,本文引用高斯核密度分布估计对亲缘关系指数的分布进行估计,直观、真实地反映了亲缘关系指数的个体值及整体趋势,为探讨群落构建的生态位机制和中性理论间的争论提供更直接的证据。
中图分类号:
唐丽丽, 陈国平, 冯小梅, 赵铁建, 石福臣. 基于系统发育的燕山东麓植物群落的构建机制[J]. 植物研究, 2017, 37(6): 807-815.
TANG Li-Li, CHEN Guo-Ping, FENG Xiao-Mei, ZHAO Tie-Jian, SHI Fu-Chen. Community Assembly Rules of the East of Yanshan Mountain Based on Phylogeny[J]. Bulletin of Botanical Research, 2017, 37(6): 807-815.
1. Cavender-bares J,Kozak K H,Fine P V A,et al. The merging of community ecology and phylogenetic biology[J]. Ecology Letters,2009,12(7):693-715. 2. Diamond J M. Assembly of species communities[M].//Cody M L,Diamond J M. Ecology and evolution of communities. Cambridge:Harvard University Press,1975. 3. Weiher E,Keddy P. Ecological assembly rules:perspectives,advances,retreats[M]. Cambridge:Cambridge University Press,1999. 4. Hubbell S P. The unified neutral theory of biodiversity and biogeography[M]. Princeton,Oxford:Princeton University Press,2001. 5. Bazzaz F A. Habitat selection in plants[J]. The American Naturalist,1991,137:S116-S130. 6. Tilman D. Resource competition and community structure[M]. Princeton:Princeton University Press,1982. 7. Webb C O,Ackerly D D,Mcpeek M A,et al. Phylogenies and community ecology[J]. Annual Review of Ecology & Systematics,2002,33:475-505. 8. Cavender-bares J,Ackerly D D,Baum D A,et al. Phylogenetic overdispersion in Floridian oak communities[J]. The American Naturalist,2004,163(6):823-843. 9. Gillespie R. Community assembly through adaptive radiation in Hawaiian spiders[J]. Science,2004,303(5656):356-359. 10. Fine P V A,Miller Z J,Mesones I,et al. The growth-defense trade-off and habitat specialization by plants in Amazonian forests[J]. Ecology,2006,87(sp7):S150-S162. 11. Strauss S Y,Webb C O,Salamin N. Exotic taxa less related to native species are more invasive[J]. Proceedings of the National Academy of Sciences of the United States of America,2006,103(15):5841-5845. 12. Davies J T,Meiri S,Barraclough T G,et al. Species co-existence and character divergence across carnivores[J]. Ecology Letters,2007,10(2):146-152. 13. Kraft N J B,Cornwell W K,Webb C O,et al. Trait evolution,community assembly,and the phylogenetic structure of ecological communities[J]. The American Naturalist,2007,170(2):271-283. 14. Vamosi S M,Heard S B,Vamosi J C,et al. Emerging patterns in the comparative analysis of phylogenetic community structure[J]. Molecular Ecology,2009,18(4):572-592. 15. Mcpeek M A. The macroevolutionary consequences of ecological differences among species[J]. Palaeontology,2007,50(1):111-129. 16. Blomberg S P,Garland JR T,Ives A R. Testing for phylogenetic signal in comparative data:behavioral traits are more labile[J]. Evolution,2003,57(4):717-745. 17. 曹科,饶米德,余建中,等. 古田山木本植物功能性状的系统发育信号及其对群落结构的影响[J]. 生物多样性,2013,21(5):564-571. Cao K,Rao M D,Yu J Z,et al. The phylogenetic signal of functional traits and their effects on community structure in an evergreen broad-leaved forest[J]. Biodiversity Science,2013,21(5):564-571. 18. 宫骁. 基于群落系统发育对沿坡向梯度上亚高寒草甸群落构建的分析[D]. 甘肃:兰州大学,2016. Gong X. The research of community assembly along a slope aspect gradient in an alpine meadow based on community phylogeny[D]. Gansu:Lanzhou University,2016. 19. Cavender-bares J,Pahlich A. Molecular,morphological,and ecological niche differentiation of sympatric sister oak species,Quercus virginiana and Q. geminata(Fagaceae)[J]. American Journal of Botany,2009,96(9):1690-1702. 20. 牛红玉,王峥峰,练琚愉,等. 群落构建研究的新进展:进化和生态相结合的群落谱系结构研究[J]. 生物多样性,2011,19(3):275-283. Niu H Y,Wang Z F,Lian J Y,et al. New progress in community assembly:community phylogenetic structure combining evolution and ecology[J]. Biodiversity Science,2011,19(3):275-283. 21. 丛明旸,石会平,张小锟,等. 八仙山国家级自然保护区典型森林群落结构及物种多样性研究[J]. 南开大学学报:自然科学版,2013,46(4):44-52. Cong M Y,Shi H P,Zhang X K,et al. Analyses on community structure and species diversity of typical forest in Baxianshan national natural reserve[J]. Acta Scientiarum Naturalium Universitatis Nankaiensis,2013,46(4):44-52. 22. 王天罡. 天津八仙山自然保护区植物多样性及其保护研究[D]. 北京:北京林业大学,2007. Wang T G. Studies on plant diversity and conservation in Tianjin Baxianshan nature reserve[D]. Beijing:Beijing Forestry University,2007. 23. 陈国平,俎丽红,高张莹,等. 八仙山不同立地落叶阔叶林凋落物养分特征及土壤肥力评价研究[J]. 植物研究,2016,36(6):878-885. Chen G P,Zu L H,Gao Z Y,et al. The characteristics of forest floor nutrients and soil fertility assessment for deciduous broad-leaved forest with different site conditions[J]. Bulletin of Botanical Research,2016,36(6):878-885. 24. 陈国平,程珊珊,丛明旸,等. 三种阔叶林凋落物对下层土壤养分的影响[J]. 生态学杂志,2014,33(4):874-879. Chen G P,Cheng S S,Cong M Y,et al. Effects of litter decomposition on soil nutrients in three broad-leaved forests[J]. Chinese Journal of Ecology,2014,33(4):874-879. 25. 陈国平. 天津典型森林群落和湿地群落对土壤生态特征的影响[D]. 天津:南开大学,2014. Chen G P. Effects of typical forest communities and wetland communities on soil ecological characteristics in Tianjin[D]. Tianjin:Nankai University,2014. 26. 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[J]. 生物多样性,2009,17(6):533-548. Fang J Y,Wang X P,Shen Z H,et al. Methods and protocols for plant community inventory[J]. Biodiversity Science,2009,17(6):533-548. 27. De'ath G. Multivariate Regression Trees:a new technique for modeling species-environment relationships[J]. Ecology,2002,83(4):1105-1117. 28. 赖江山,米湘成,任海保,等. 基于多元回归树的常绿阔叶林群丛数量分类——以古田山24公顷森林样地为例[J]. 植物生态学报,2010,34(7):761-769. Lai J S,Mi X C,Ren H B,et al. Numerical classification of associations in subtropical evergreen broad-leaved forest based on multivariate regression trees-a case study of 24 hm2 Gutianshan forest plot in China[J]. Chinese Journal of Plant Ecology,2010,34(7):761-769. 29. 黄甫昭,王斌,丁涛,等. 弄岗北热带喀斯特季节性雨林群丛数量分类及与环境的关系[J]. 生物多样性,2014,22(2):157-166. Huang P Z,Wang B,Ding T,et al. Numerical classification of associations in a northern tropical karst seasonal rain forest and the relationships of these associations with environmental factors[J]. Biodiversity Science,2014,22(2):157-166. 30. Webb C O,Donoghue M J. Phylomatic:tree assembly for applied phylogenetics[J]. Molecular Ecology Notes,2005,5(1):181-183. 31. Bremer B,Bremer K,Chase M W,et al. An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants:APG Ⅲ[J]. Botanical Journal of the Linnean Society,2003,141(4):399-436. 32. Zanne A E,Tank D C,Cornwell W K,et al. Three keys to the radiation of angiosperms into freezing environments[J]. Nature,2014,506(7486):89-92. 33. Webb C O,Ackerly D D,Kembel S W. Phylocom:software for the analysis of phylogenetic community structure and trait evolution[J]. Bioinformatics,2008,24(18):2098-2100. 34. Kress W J,Erickson D L,Jones F A,et al. Plant DNA barcodes and a community phylogeny of a tropical forest dynamics plot in Panama[J]. Proceedings of the National Academy of Sciences of the United States of America,2009,106(44):18621-18626. 35. Swenson N G. The assembly of tropical tree communities-the advances and shortcomings of phylogenetic and functional trait analyses[J]. Ecography,2013,36(3):264-276. 36. Zhang R,Liu T,Zhang J L,et al. Spatial and environmental determinants of plant species diversity in a temperate desert[J]. Journal of Plant Ecology,2016,9(2):124-131. 37. Arieira J,Penha J,Da Cunha C N,et al. Ontogenetic shifts in habitat-association of tree species in a neotropical wetland[J]. Plant and Soil,2016,404(1):219-236. 38. Obolewski K,Gotkiewicz W,Strzelczak A,et al. Influence of anthropogenic transformations of river bed on plant and macrozoobenthos communities[J]. Environmental Monitoring and Assessment,2011,173(1-4):747-763. 39. Sommer B,Froend R. Phreatophytic vegetation responses to groundwater depth in a drying Mediterranean-type landscape[J]. Journal of Vegetation Science,2014,25(4):1045-1055. 40. Gapare W J,Ivkovic M,Liepe K J,et al. Drivers of genotype by environment interaction in radiata pine as indicated by multivariate regression trees[J]. Forest Ecology and Management,2015,353:21-29. 41. 陈云,王海亮,韩军旺,等. 小秦岭森林群落数量分类、排序及多样性垂直格局[J]. 生态学报,2014,34(8):2068-2075. Chen Y,Wang H L,Han J W,et al. Numerical classification,ordination and species diversity along elevation gradients of the forest community in Xiaoqinling[J]. Acta Ecologica Sinica,2014,34(8):2068-2075. 42. 张荣,刘彤. 古尔班通古特沙漠南部植物多样性及群落分类[J]. 生态学报,2012,32(19):6056-6066. Zhang R,Liu T. Plant species diversity and community classification in the southern Gurbantunggut Desert[J]. Acta Ecologica Sinica,2012,32(19):6056-6066. 43. Gastauer M,Meira-neto J A. Interactions,Environmental sorting and chance:phylostructure of a tropical forest assembly[J]. Folia Geobotanica,2014,49(3):443-459. 44. Piwczyński M,Puchałka R,Ulrich W. Influence of tree plantations on the phylogenetic structure of understorey plant communities[J]. Forest Ecology and Management,2016,376:231-237. 45. Liu X H,Zhu X X,Niu Y,et al. Phylogenetic clustering and over-dispersion for alpine plants along elevational gradient in the Hengduan Mountains Region,southwest China[J]. Journal of Systematics and Evolution,2014,52(3):280-288. 46. Freilich M A,Connolly S R. Phylogenetic community structure when competition and environmental filtering determine abundances[J]. Global Ecology and Biogeography,2015,24(12):1390-1400. 47. Martins C A,Roque F O,Santos B A,et al. Correction:what shapes the phylogenetic structure of anuran communities in a seasonal environment? the influence of determinism at regional scale to stochasticity or antagonistic forces at local scale[J]. PLoS One,2016,11(3):e0151734. 48. Brunbjerg A K,Cavender-bares J,Eiserhardt W L,et al. Multi-scale phylogenetic structure in coastal dune plant communities across the globe[J]. Journal of Plant Ecology,2014,7(2):101-114. 49. 童鑫. 从种群遗传和群落组成的空间结构研究群落维持机制[D]. 上海:华东师范大学,2015. Tong X. Exploring community assembly through the lens of spatial structure:from population genetics to community composition[D]. Shanghai:East China Normal University,2015. 50. Tilman D,Wedin D,Knops J. Productivity and sustainability influenced by biodiversity in grassland ecosystems[J]. Nature,1996,379(6567):718-720. |
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