外来植物入侵对生态系统碳循环影响的研究概述

doi:10.16258/j.cnki.1674-5906.2023.07.015

生态环境学报 ›› 2023, Vol. 32 ›› Issue (7): 1325-1332.DOI: 10.16258/j.cnki.1674-5906.2023.07.015

外来植物入侵对生态系统碳循环影响的研究概述

倪广艳()

中国科学院退化生态系统与植被恢复重点实验室/中国科学院华南植物园，广东广州 510650

收稿日期:2023-02-13 出版日期:2023-07-18 发布日期:2023-09-27
作者简介:倪广艳（1978年生），女，副研究员，博士，从事入侵植物生理生态学研究。E-mail: guangyan.ni@scbg.ac.cn
基金资助:
国家重点研发计划(2021YFC3100403);国家自然科学基金项目(31971498);广东省自然科学基金项目(2022A1515011831)

Effects of Exotic Plant Invasions on Terrestrial Ecosystems Carbon Cycling

NI Guangyan()

Key Laboratory of Vegetation Restoration and Management of Degraded Ecosystems/South China Botanical Garden, Chinese Academy of Sciences, Guangzhou 510650, P. R. China

Received:2023-02-13 Online:2023-07-18 Published:2023-09-27

摘要/Abstract

摘要：

外来植物入侵改变陆地生态系统的植被覆盖与组成，降低生态系统内物种丰富度和多样性，影响系统内碳循环过程，进而影响基于植被组成估算生态系统碳储量结果的准确性。近年来，不少学者展开了植物入侵对生态系统碳循环的影响研究，发现入侵阶段、被入侵生态系统的环境因素及群落组成等均影响生态系统内碳循环过程及碳储量；然而，对于被入侵生态系统的“碳源汇”功能认定目前仍存在较大争议，其中最不确定的为生态系统地下部分。文章综述了国内外关于植物入侵影响生态系统碳循环研究的最新进展，并就被入侵生态系统地上和地下碳循环过程的改变系统阐述了入侵引起的碳源、汇变化；同时，以地下生态过程为核心，从气候因素、植物个体特征及其与周围生物的牧食关系等方面阐述了植物入侵影响地下碳过程的机理。总体上，气候因素可在大区域范围内影响植被更替的速度与物种多样性的发展方向，但不能解释入侵在气候环境一致的特定区域内所引起的差异性影响；入侵植物因叶片光合优势往往会向生态系统输入更多有机碳，当其以凋落物和根系分泌物等形式向系统外输出时则受物质组成、分解速率及土壤环境等多因素的影响；土壤生物既是土壤有机碳的重要组分，也是有机碳向土壤输入与输出的调节者，通过改变有机碳的净通量来调节碳源、汇功能，这可能是造成入侵植物碳源、汇争议的重要原因之一。最后，文章就植物入侵影响生态系统碳循环的关键环节，结合全球变化背景下的学科发展和入侵防控需求，提出若干未来亟需深入研究的科学问题。

关键词: 外来植物入侵, 植被覆盖, 生态系统碳循环, 土壤碳循环, 植物光合优势特征, 土壤生物

Abstract:

Invasive alien species greatly change the forest composition and coverage, and reduce the species richness and diversity therein, which have profoundly altered the terrestrial carbon cycling processes and subsequently influenced the accuracy of carbon calculation that is theoretically based on the terrestrial forest coverage. In recent decades, many scientists have put efforts on the carbon cycle changes in invaded ecosystems and showed that the invasion stages, environmental factors and species compositions in communities influence the processes of carbon cycling. However, whether plant invasions serve as a carbon sink or source function is still obscure, and the main uncertainty comes from the underground ecosystem. In the present paper, we reviewed the recent studies on the effects of exotic plant invasions upon ecosystem carbon cycling. With an emphasis on the underground carbon cycling processes, we analyzed the influences of environment parameters, plant physiological characters, and the relationships between plants and surrounding soil biota. Generally, climate parameters may affect the speed and direction of forest coverage substitution, but are insufficient for explaining the inconsistences resulted from different invasion species at a local scale or even from the same species in the same study. Invasive plants are able to assimilate and install more carbon into ecosystems because of the photosynthesis priority, while the carbon output, usually in the form of root exudates and debris, would depend on the substance composition and degradation rate, as well as soil properties. Soil biota, as an important component of underground carbon, modulates both carbon input and output in ecosystems, and the net flux determines the carbon sink or source function, offering an important rational explanation for the uncertainty. In the end, we raised several research prospects regarding to the key processes of terrestrial carbon cycling, by considering the disciplinary development in the context of global change and the requirement to control invasive alien species.

Key words: exotic plant invasions, forest coverage, ecosystem carbon cycling, underground carbon cycling, priority characters in photosynthesis, soil biota

中图分类号:

Q948
X171.1

倪广艳. 外来植物入侵对生态系统碳循环影响的研究概述[J]. 生态环境学报, 2023, 32(7): 1325-1332.

NI Guangyan. Effects of Exotic Plant Invasions on Terrestrial Ecosystems Carbon Cycling[J]. Ecology and Environment, 2023, 32(7): 1325-1332.

参考文献 75

[1]	BRADLEY B A, HOUGHTON R A, MUSTARD J F, et al., 2006. Invasive grass reduces aboveground carbon stocks in shrublands of the Western US[J]. Global Change Biology, 12(10): 1815-1822. DOI URL
[2]	BRADLEY B A, WILCOVE D S, OPPENHEIMER M, 2010. Climate change increases risk of plant invasion in the Eastern United States[J]. Biological Invasions, 12(6): 1855-1872. DOI URL
[3]	CAI H Y, LU H F, TIAN Y, et al., 2020. Effects of invasive plants on the health of forest ecosystems on small tropical coral islands[J]. Ecological Indicators, 117(Part 2): 106656. DOI URL
[4]	CALLAWAY R M, THELEN G C, RODRIGUEZ A, et al., 2004. Soil biota and exotic plant invasion[J]. Nature, 427(6976): 731-733. DOI
[5]	CHEN B M, PENG S L, NI G Y, 2009. Effects of the invasive plant Mikania micrantha H.B.K. on soil nitrogen availability through allelopathy in South China[J]. Biological Invasions, 11: 1291-1299. DOI URL
[6]	CRAIG M E, LOVKO N, FLORY S L, et al., 2019. Impacts of an invasive grass on soil organic matter pools vary across a tree-mycorrhizal gradient[J]. Biogeochemistry, 144(2): 149-164. DOI
[7]	CRAIG M, PEARSON S M, FRATERRIGO J, 2015. Grass invasion effects on forest carbon depend on landscape-level land use patterns[J]. Ecology, 96(8): 2265-2279. DOI URL
[8]	D’ANTONIO C M, VITOUSEK P M, 1992. Biological invasions by exotic grasses, the grass/fire cycle, and global change[J]. Annual Review of Ecology, Systematics, 23: 63-87. DOI URL
[9]	DAEHLER C C, 2003. Performance comparisons of co-occurring native and alien invasive plants:implications for conservation and restoration[J]. Annual Review of Ecological Evolution and Systematics, 34(1): 183-211.
[10]	DAWSON W M, SCHRAMA A, AUSTIN A. et al., 2016. Identifying the role of soil microbes in plant invasions[J]. Journal of Ecology, 104(5): 1211-1218. DOI URL
[11]	DRENOVSKY R E, BATTEN K M, 2007. Invasion by Aegilops triuncialis (barb goatgrass) slows carbon and nutrient cycling in a serpentine grassland[J]. Biological Invasions, 9: 107-116. DOI URL
[12]	EHRENFELD J, 2003. Effects of exotic plant invasions on soil nutrient cycling processes[J]. Ecosystems, 6(6): 503-523. DOI URL
[13]	EHRENFELD J, JOAN G, 2010. Ecosystem consequences of biological invasions[J]. Annual Review of Ecology, Evolution, and Systematics, 41(1): 59-80. DOI URL
[14]	FENG Y L, LI Y P, WANG R F, et al., 2011. A quicker return energy-use strategy by populations of a subtropical invader in the non-native range: A potential mechanism for the evolution of increased competitive ability[J]. Journal of Ecology, 99(5): 1116-1123. DOI URL
[15]	GAO G F, LI H, SHI Y, et al., 2022. Continental-scale plant invasions reshuffle the soil microbiome of blue carbon ecosystems[J]. Global Change Biology, 28(14): 4423-4438. DOI URL
[16]	HE Y H, ZHOU X H, CHENG W S, et al., 2019. Linking improvement of soil structure to soil carbon storage following invasion by a C4 plant Spartina alterniflora[J]. Ecosystem, 22(4): 859-872. DOI
[17]	HOOK B K, OLSON B E, WRAITH J M, 2004. Effects of the invasive forb Centaurea maculosa on grassland carbon and nitrogen pools in Montana, USA[J]. Ecosystems, 7(6): 686-694.
[18]	HOU Y P, PENG S L, CHEN B M, et al., 2011. Inhibition of an invasive plant (Mikania micrantha H.B.K.) by soils of three different forests in lower subtropical China[J]. Biological Invasions, 13: 381-391. DOI URL
[19]	HUGHES R F, ARCHER S R, ASNER G P, et al., 2006. Changes in aboveground primary production and carbon and nitrogen pools accompanying woody plant encroachment in a temperate savanna[J]. Global Change Biology, 12(9): 1733-1747. DOI URL
[20]	JACKSON R B, BANNER J L, JOBBÁGY E G, et al., 2002. Ecosystem carbon loss with woody plant invasion of grasslands[J]. Nature, 418(6898): 623-626. DOI URL
[21]	KOURTEV P S, EHRENFELD J G, HÄGGBLOM M, 2002. Exotic plant species alter the microbial community structure and function in the soil[J]. Ecology, 83(11): 3152-3166. DOI URL
[22]	KOUTIKA L S, VANDERHOEVEN S, CHAPUIS-LARDY L, et al., 2007. Assessment of changes in soil organic matter after invasion by exotic plant species[J]. Biology and Fertility of Soils, 44(2): 331-341. DOI URL
[23]	LEISHMAN M R, HASLEHURST T, ARES A, et al., 2007. Leaf trait relationships of native and invasive plants: community- and global-scale comparisons[J]. New Phytologist, 176(3): 635-643. DOI PMID
[24]	LEISHMAN M R, THOMSON V P, COOKE J, 2010. Native and exotic invasive plants have fundamentally similar carbon capture strategies[J]. Journal of Ecology, 98(1): 28-42. DOI URL
[25]	LI W H, ZHANG C B, JIANG H B, et al., 2006. Changes in soil microbial community associated with invasion of the exotic weed, Mikania micrantha H.B.K[J]. Plant and Soil, 281: 309-324. DOI URL
[26]	LI W H, ZHANG C B, GAO G J, et al., 2007. Relationship between Mikania micrantha invasion and soil microbial biomass, respiration and functional diversity[J]. Plant and Soil, 296(1-2): 197-207. DOI URL
[27]	LIAO C Z, LUO Y Q, JIANG L F, et al., 2007. Invasion of Spartina alterniflora enhanced ecosystem carbon and nitrogen stocks in the Yangtze Estuary China[J]. Ecosystem, 10(8): 1351-1361. DOI URL
[28]	LIAO C Z, PENG R L, LUO Y Q, et al., 2008. Altered ecosystem carbon and nitrogen cycles by plant invasion: A meta analysis[J]. New Phytologist, 177(3): 706-714. DOI URL
[29]	LITTON C M, SANDQUIST D R, Cordell S, 2006. Effects of non-native grass invasion on aboveground carbon pools and tree population structure in a tropical dry forest of Hawaii[J]. Forest Ecology and Management, 231(1-3): 105-113. DOI URL
[30]	LITTON C M, SANDQUIST D R, CORDELL S, 2008. A non-native invasive grass increases soil carbon flux in a Hawaiian tropical dry forest[J]. Global Change Biology, 14(4): 726-739. DOI URL
[31]	LIU B, YAN J, LI W H, et al., 2020. Mikania micrantha genome provides insights into the molecular mechanism of rapid growth. Nature Communication, 11: 340. DOI
[32]	NASTO M K, MCLEOD M L, BULLINGTON L, et al., 2022. The effect of plant invasion on soil microbial carbon-use efficiency in semi-arid grasslands of the Rocky Mountain[J]. Journal of Ecology, 110(2): 479-493. DOI URL
[33]	NI G Y, SONG L Y, ZHANG J L, et al., 2006. Effects of root extracts of Mikania micrantha H.B.K. on soil microbial community[J]. Allelopathy Journal, 17(2): 247-254.
[34]	NI G Y, ZHAO P, HUANG Q Q, et al., 2020. Mikania micrantha invasion enhances the carbon (C) transfer from plant to soil and mediates the soil C utilization through altering microbial community[J]. Science of the Total Environment, 711: 35020.
[35]	NI M, DEANE D C, LI S P, et al., 2021. Invasion success and impacts depend on different characteristics in non-native plants[J]. Diversity and Distributions, 27(7): 1194-1207. DOI URL
[36]	NORRIS M D, BLAIR J M, JPHNSON L C, 2001. Land cover change in eastern Kansas: litter dynamics of closed-canopy eastern redcedar forests in tallgrass prairie[J]. Canadian Journal of Botany, 79(2): 214-222. DOI URL
[37]	OGLE S M, OJIMA D, REINERS W A, 2004. Modeling the impact of exotic annual brome grasses on soil organic carbon storage in a northern mixed grass prairie[J]. Biological Invasions, 6(3): 365-377. DOI URL
[38]	PATTISON R R, GOLDSTEIN G, ARES A, 1998. Growth, biomass allocation and photosynthesis of invasive and native Hawaiian rain-forest species[J]. Oecologia, 117(4): 449-459. DOI URL
[39]	PELTZER D A, ALLEN R B, LOVETT G M, et al., 2010. Effects of biological invasions on forest carbon sequestration[J]. Global Change Biology, 16(2): 732-746. DOI URL
[40]	PORAZINSKA D L, BARDGETT R D, BLAAUW M B, et al., 2003. Relationships at the aboveground- belowground interface: plants, soil biota, and soil processes[J]. Ecological Monographs, 73(3): 377-395. DOI URL
[41]	QIAO H M, LIU W W, ZHANG Y H, et al., 2019. Genetic admixture accelerates invasion via provisioning rapid adaptive evolution[J]. Molecular Ecology, 28(17): 4012-4027. DOI PMID
[42]	ROGERS C, MCCARTY J P, 2000. Climate change and ecosystems of the mid-Atlantic region[J]. Climate Research, 14(3): 235-244. DOI URL
[43]	SAMPAIO J A G, REIS C R G, CUNHA-LIGNON M, et al., 2021. Plant invasion affects vegetation structure and sediment nitrogen stocks in subtropical mangroves[J]. Marine Environmental Research, 172: 105506. DOI URL
[44]	SHEN X J, LIU Y W, LIU B H, et al., 2022. Effect of shrub encroachment on land surface temperature in semi-arid areas of temperate regions of the Northern Hemisphere[J]. Agricultural and Forest Meteorology, 320: 108943. DOI URL
[45]	SUN Y, ZÜST T, SILESTRO D, et al., 2022. Climate warming can reduce biocontrol efficacy and promote plant invasion due to both genetic and transient metabolomic changes[J]. Ecology Letters, 25(6): 1387-1400. DOI PMID
[46]	TORRES N, HERRERA I, FAJARDO L, et al., 2021. Meta-analysis of the impact of plant invasions on soil microbial communities[J]. BMC Ecology and Evolution, 21: 172. DOI
[47]	VALÉRY L, BOUCHARD V, LEFEUVRE J C, 2004. Impact of the invasive native species Elymus athericus on carbon pools in a salt marsh[J]. Wetlands, 24(2): 268-276. DOI URL
[48]	VILÀ M, ESPINAR J, HEJDA M, et al., 2011. Ecological impacts of invasive alien plants: A meta analysis of their effects on species, communities and ecosystems[J]. Ecology Letters, 14(7): 702-708. DOI URL
[49]	VINTON M A, BURKE I C, 1995. Interactions between individual plant species and soil nutrient status in shortgrass steppe[J]. Ecology, 76(4): 1116-1133. DOI URL
[50]	VITOUSEK P M, WALKER L R, 1989. Biological invasion by Myrica faya in Hawaii-plant demography, nitrogen fixation, ecosystem effects[J]. Ecological Monographs, 59(3): 247-265. DOI URL
[51]	YU Y L, CHENG H Y, WANG S, et al., 2022. Drought may be beneficial to the competitive advantage of Amaranthus spinosus[J]. Journal of Plant Ecology, 15(3): 494-508. DOI URL
[52]	WEI H, XU J L, QUAN G M, et al., 2017. Invasion effects of Chromolaena odorata on soil carbon and nitrogen fractions in a tropical savamma[J]. Ecosphere, 8: e01831. DOI URL
[53]	WILCUT J W, TRUELOVE B, DAVIS D E, et al., 1988. Temperature factors limiting the spread of Cogongrass (Imperata cylindrica) and Torpedograss (Panicum repens)[J]. Weed Science, 36(1): 49-55. DOI URL
[54]	WINDHAM L, Weis J S, Weis P, 2004. Metal dynamics of plant litter of Spartina alterniflora and Phragmites australis in metal-contaminated salt marshes. Part 1: patterns of decomposition and metal uptake[J]. Environmental Toxicology and Chemistry, 23(6): 1520-1528. DOI URL
[55]	WINDHAM L, EHRENFELD J G, 2003. Net impact of a plant invasion on nitrogen-cycling processes within a brackish tidal marsh[J]. Ecological Applications, 13(4): 883-896. DOI URL
[56]	WINDHAM L, LATHROP R G, 1999. Effects of Phragmites australis (common reed) invasion on aboveground biomass and soil properties in brackish tidal marsh of the Mullica river, New Jersey[J]. Estuaries, 22: 927-935. DOI URL
[57]	WOLKOVICH E M, LIPSON D A, VIRGINIA R A, et al., 2010. Grass invasion causes rapid increases in ecosystem carbon and nitrogen storage in a semiarid shrubland[J]. Global Change Biology, 16(4): 1351-1365. DOI URL
[58]	YANG B, CUI M M, DU Z Z, et al., 2022. Influence of multiple global change drivers on plant invasions: additive effects are uncommon[J]. Frontiers in Plant Science, 13: 1020621. DOI URL
[59]	YANG R M, 2019a. Interacting effects of plant invasion, climate, and soils on soil organic carbon storage in coastal wetlands[J]. Journal of Geophysical Research: Biogeosciences, 124(8): 2554-2564. DOI URL
[60]	YANG R M, 2019b. Mechanisms of soil organic carbon storage to Spartina alterniflora invasion and climate change[J]. Science of the Total Environment, 690: 7-15. DOI URL
[61]	ZHANG G L, BAI J H, TEBBE C C, et al., 2022. Plant invasion reconstructs soil microbial assembly and functionality in coastal salt marshes[J]. Molecular Ecology, 31(17): 4478-4494. DOI PMID
[62]	ZHAO M X, LU X F, ZHAO H X, et al., 2019. Agertina adenophora invasions are associated with microbially mediated differences in biogeochemical cycles[J]. Science of the Total Environment, 677: 47-56. DOI URL
[63]	ZHOU G Y, XU S, CIAIS P, et al., 2019. Climate and litter C/N ratio constrain soil organic carbon accumulation[J]. National Science Review, 6(4):746-757. DOI
[64]	陈慧丽, 李玉娟, 李博, 等, 2005. 外来植物入侵对土壤生物多样性和生态系统过程的影响[J]. 生物多样性, 13(6): 555-565. DOI
	CHEN H L, LI Y J, LI B, et al., 2005. Impacts of exotic plant invasions on soil biodiversity and ecosystem processes[J]. Diversity Science, 13(6): 555-565.
[65]	陈蕾伊, 沈海花, 方精云, 2014. 灌丛化草原: 一种新的植被景观[J]. 自然杂志, 36(6): 391-396.
	CHEN L Y, SHEN H H, FANG J Y, 2014. Shrub-encroached grassland: A new vegetation type[J]. Chinese Journal of Nature, 36(6): 391-396.
[66]	冯玉龙, 廖志勇, 张茹, 等, 2009. 外来入侵植物对环境梯度和天敌逃逸的适应进化[J]. 生物多样性, 17(4): 340-240.
	FENG Y L, LIAO Z Y, ZHANG R, et al., 2009. Adaptive evolution in response to environmental gradients and enemy release in invasive alien plant species[J]. Diversity Science, 17(4): 340-240.
[67]	贺金生, 王政权, 方精云, 2004. 全球变化的地下生态学: 问题与展望[J]. 科学通报, 49(13): 1226-1233.
	HE J S, WANG Z Q, FANG J Y, 2004. Belowground ecology under global change: problems and perspectives[J]. Chinese Science Bulletin, 49(13): 1226-1233. DOI URL
[68]	刘宁, 付卫东, 张国良, 等, 2014. 黄顶菊入侵对不同生境地表土壤动物群落的影响[J]. 生态学杂志, 33(1): 176-183.
	LIU N, FU W D, ZHANG G L, et al., 2014. Impacts of Flaveria bidentis invasion on ground-dwelling soil animal community in different habitats[J]. Chinese Journal of Ecology, 33(1): 176-183.
[69]	刘艳杰, 黄伟, 杨强, 等, 2022. 近十年植物入侵生态学重要研究进展[J]. 生物多样性, 30(10): 272-288.
	LIU Y J, HUANG W, YANG Q, et al., 2022. Research advances of plant invasion ecology over the past 10 years[J]. Biodiversity Science, 30(10): 272-288.
[70]	陆建忠, 袭伟, 陈家宽, 等, 2005. 入侵种加拿大一枝黄花对土壤特性的影响[J]. 生物多样性, 13(4): 347-356.
	LU J Z, QIU W, CHEN J K, 2005. Impacts of invasive species on soil properties: Canadian goldenrod (Solidago canadensis) as a case study[J]. Diversity Science, 13(4):347-356.
[71]	王伯荪, 廖文波, 昝启杰, 等, 2003. 薇甘菊Mikania micrantha在中国的传播[J]. 中山大学学报(自然科学版), 42(2): 47-54.
	WANG B S, LIAO W B, ZHAN Q J, 2003. The Spreads of Mikania micrantha in China[J]. Acta Scientiarum Naturalium Universitatis Sunyatseni, 42(2): 47-54.
[72]	王晋萍, 董丽佳, 桑卫国, 2012. 不同氮素水平下入侵种豚草与本地种黄花蒿、蒙古蒿的竞争关系[J]. 生物多样性, 20(1): 3-11. DOI
	WANG J P, DONG L J, SANG W G, 2012. Effects of different nitrogen regimes on competition between Ambrosia artemisiifolia, an invasive species, and two native species, Artemisia annua and Artemisia mongolica[J]. Biodiversity Science, 20(1): 3-11. DOI URL
[73]	闫宗平, 仝川, 2008. 外来植物入侵对陆地生态系统地下碳循环及碳库的影响[J]. 生态学报, 28(9): 4440-4450.
	YAN Z P, TONG C, 2008. Impacts of exotic plant invasions on terrestrial ecosystem below-ground carbon cycling and carbon pools[J]. Acta Ecologica Sinica, 28(9): 4440-4450.
[74]	张祥霖, 石盛莉, 潘根兴, 等, 2008. 互花米草入侵福建漳江口红树林湿地土壤生态化学变化[J]. 地球科学进展, 23(9): 974-980.
	ZHANG X L, SHI S L, PAN G X, et al., 2008. Changes in eco-chemical properties of a mangrove wetland under Spartina invasion from Zhangjiangkou, Fujian, China[J]. Advances in Earth Science, 23(9): 974-980.
[75]	张耀鸿, 张富存, 周晓冬, 等, 2011. 互花米草对苏北滨海湿地表土有机碳更新的影响[J]. 中国环境科学, 31(2): 271-276.
	ZHANG Y H, ZHANG F C, ZHOU X D, et al., 2011. Effects of plant invasion along a Spartina alterniflora chronosequence on organic carbon dynamics in coastal wetland in north Jiangsu[J]. China Environmental Science, 31(2): 271-276.

外来植物入侵对生态系统碳循环影响的研究概述

Effects of Exotic Plant Invasions on Terrestrial Ecosystems Carbon Cycling

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[4]	王瑞璠, 魏倪彬, 张仓皓, 鲍甜甜, 刘健, 余坤勇, 王帆. 南方丘陵区林下植被覆盖度无人机多角度遥感测量[J]. 生态环境学报, 2021, 30(12): 2294-2302.