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Impact of the invasive plant Solidago gigantea on soil nematodes in a semi-natural grassland and a temperate broadleaved mixed forest

  • A. Čerevková (a1), D. Miklisová (a1), L. Bobuľská (a2) and M. Renčo (a1)


Relationships between alien plant species and their aboveground effects have been relatively well studied, but little is known about the effects of invasive plants on belowground faunal communities. Nematodes are abundant, ubiquitous and diverse soil biota, and alterations of their community compositions can illustrate changes in belowground ecosystems. In 2016 and 2017, we determined the response of species diversity, community composition and trophic composition of the soil nematode communities to invasion by the alien plant Solidago gigantea in two ecosystems, forest and grassland, where invasion takes place. Nematode abundance was higher and number of identified nematode species was lower at invaded than uninvaded sites, indicated by lower species diversity, regardless of ecosystem. Herbivorous nematodes were the most affected trophic group. Herbivore abundance was higher at invaded than uninvaded sites and in grassland than forest. The herbivorous species Boleodorus thylactus, Geocenamus sp., Helicotylenchus spp., Paratylenchus bukowinensis, Pratylenchoides crenicauda and Rotylenchus robustus were more abundant at the invaded sites. Abundances of nematodes in the other tropic groups were limited or not affected. The invasion did not significantly affect the ecological and functional indices, except for the Channel Index in 2016. Differences were observed in values of Enrichment Index (indicator of resource availability), Channel Index (indicator of ascendant bacterial/fungal decomposition channel) and Basal Index (indicator of depleted-perturbed soil food webs) between grassland and forests. We can thus conclude that invasion by S. gigantea significantly alters nematode community indicators (abundance, species diversity and specific trophic groups); however, this effect seems to be significantly influenced by the type of ecosystem where invasion takes place.


Corresponding author

Author for correspondence: A. Čerevková, E-mail:;


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Andrássy, I (2005) Free-living nematodes of Hungary Nematoda errantia, Volume I. Budapest, Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences.
Andrássy, I (2007) Free-living nematodes of Hungary Nematoda errantia, Volume II. Budapest, Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences.
Andrássy, I (2009) Free-living nematodes of Hungary Nematoda errantia, Volume III. Budapest, Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences.
Baranová, B, Manko, P and Jászay, T (2014) Differences in surface-dwelling beetles of grasslands invaded and non-invaded by goldenrods (Solidago canadensis, S. gigantea) with special reference to Carabidae. Journal of Insect Conservation 18, 623635.
Belnap, J, Phillips, SL, Sherrod, SK and Moldenke, A (2005) Soil biota can change after exotic plant invasion: does this affect ecosystem processes? Ecology 86, 30073017.
Berkelmans, R, Ferris, H, Tenuta, M and van Bruggen, AHC (2003) Effects of long term crop management on nematode trophic levels other than plant feeders disappear after 1 year of disruptive soil management Applied Soil Ecology 23, 223235.
Bongers, T (1990) The maturity index, an ecological measure of environmental disturbance based on nematode species composition. Oecologia 83, 1419.
Bongers, T and Bongers, M (1998) Functional diversity of nematodes. Applied Soil Ecology 10, 239251.
Bongers, T and Ferris, H (1999) Nematode community structure as a bioindicator in environmental monitoring. Trends in Ecology & Evolution 14, 224228.
Brzeski, MW (1998) Nematodes of Tylenchida in Poland and temperate Europe. Warszawa, Museum of Institute of Zoology, Polish Academy of Sciences.
Cairns, J, McCormick, PV and Niederlehner, BR (1993) A proposed framework for developing indicators of ecosystem health. Hydrobiologica 236, 144.
Chapuis-Lardy, L, Vanderhoeven, S, Dassonville, N, Koutika, LS and Meerts, P (2006) Effect of the exotic invasive plant Solidago gigantea on soil phosphorus status. Biology and Fertility of Soils 42, 481489.
Chen, H, Li, B, Fang, Ch, Chen, J and Wu, J (2007) Exotic plant influences soil nematode communities through litter input. Soil Biology & Biochemistry 39, 17821793.
Cobb, NA (1918) Estimating the nematode population of the soil. Agric Tech Circ Bur Pl Ind US Dep Agric No 1.
De Deyn, GB, Raaijmakers, CE, Van Ruijven, J, Berendse, F and Van Der Putten, WH (2004) Plant species identity and diversity effects on different trophic levels of nematodes in the soil food web. Oikos 106, 576586.
De Goede, RGM and Bongers, T (1994) Nematode community structure in relation to soil and vegetation characteristics. Applied Soil Ecology 1, 2944.
De Goede, RGM, Georgieva, BC, Verschoor, BC and Kamerman, J (1993) Changes in nematode community structure in a primary succession of blown-out areas in a drift sand landscape. Fundamental & Applied Nematology 16, 501513.
De Groot, M, Kleijn, D and Joganc, N (2007) Species groups occupying different trophic levels respond differently to the invasion of semi-natural vegetation by Solidago canadensis. Biological Conservation 136, 612617.
Ehrenfeld, JG (2003) Effects of exotic plant invasions on soil nutrient cycling processes. Ecosystems 6, 503523.
Ehrenfeld, JG and Scott, N (2001) Invasive species and the soil: effects on organisms and ecosystem processes. Ecological Applications 11, 12591260.
Ferris, H and Bongers, T (2006) Nematode indicators of organic enrichment. Journal of Nematology 38, 312.
Ferris, H, Bongers, T and de Goede, RGM (2001) A framework for soil food web diagnostics, extension of the nematode faunal analysis concept. Applied Soil Ecology 18, 1329.
Ferris, H, Venette, RC and Scow, KM (2004) Soil management to enhance bacterivore and fungivore nematode populations and their nitrogen mineralisation function. Applied Soil Ecology 25, 1935.
Fitoussi, N, Pen-Mouratov, S and Steinberger, Y (2016) Soil free-living nematodes as bio-indicators for assaying the invasive effect of the alien plant Heterotheca subaxillaris in a coastal dune ecosystem. Applied Soil Ecology 102, 19.
Gaggini, L, Rusterholz, HP and Baur, B (2018) The invasive plant Impatiens glandulifera affects soil fungal diversity and the bacterial community in forests. Applied Soil Ecology 124, 335343.
Geraert, E (2008) The Tylenchidae of the world Identification of the family Tylenchidae (Nematoda). Gent, Academia Press.
Geraert, E (2010) The Criconematidae of the world Identification of the family Criconematidae (Nematoda). Gent, Academia Press.
Herr, C, Chapuis-Lardy, L, Dassonville, N, Vanderhoeven, S and Meerts, P (2007) Seasonal effect of the exotic invasive plant Solidago gigantea on soil pH and P fractions. Journal of Plant Nutrition and Soil Science 170, 729738.
Klironomos, JN (2002) Feedback with soil biota contributes to plant rarity and invasiveness in communities. Nature 417, 6770.
Korthals, GW, De Goede, RGM, Kammenga, JE and Bongers, T (1996) The maturity index as an instrument for risk assessment of soil pollution. pp. 8594 in Van Straalen, NM and Krivolutsky, DA (Eds) Bioindicator system for soil pollution. Dordrecht, The Netherlands, Kluwer Academic Publishers.
Lenda, M, Witek, M, Skórka, P, Moroń, D and Wojciechowski, M (2013) Invasive alien plants affect grassland ant communities, colony size and foraging behaviour. Biological Invasions 15, 24032414.
Liang, WJ, Li, FP, Li, Q and Zhang, WD (2007) Temporal dynamics of soil nematode community structure under invasive Ambrosia trifida and native Chenopodium serotinum. Helminthologia 44, 2933.
Liao, M, Xie, XM, Peng, Y, Chai, JJ and Chen, N (2013) Characteristics of soil microbial community functional and structure diversity with coverage of Solidago canadensis L. Journal of Central South University of Technology 20, 749756.
Loof, PAA (1999) Nematoda, Adenophorea (Dorylaimida). Heidelberg, Berlin, Spektrum Akademischer Verlag.
Miklós, L (2002) Landscape atlas of the Slovak Republic. Banská Bystrica, Ministry of Environment of the Slovak Republic, Slovak Environmental Agency.
Moroń, D, Lenda, M, Skórka, P, Szentgyörgyi, H, Settele, J and Woyciechowski, M (2009) Wild pollinator communities are negatively affected by invasion of alien goldenrods in grassland landscapes. Biological Conservation 142, 13221332.
Neher, DA, Wu, J, Barbercheck, ME and Anas, O (2005) Ecosystem type affects interpretation of soil nematode community measures. Applied Soil Ecology 30, 4764.
Quist, CW, Vervoort, MTW, Van Megen, H, Gort, G, Bakker, J, Van der Putten, WH and Helder, J (2014) Selective alteration of soil food web components by invasive giant goldenrod Solidago gigantea in two distinct habitat types. Oikos 123, 837845.
Renčo, M and Baležentiené, L (2015) An analysis of soil free-living and plant-parasitic nematode communities in three habitats invaded by Heracleum sosnowskyi in central Lithuania Biological Invasions 17, 10251039.
Renčo, M, Kornobis, FW, Domaradzki, K, Jakubska-Busse, A, Jurová, J and Homolová, Z (2019) How does an invasive Heracleum sosnowskyi affect soil nematode communities in natural conditions? Nematology 21, 7189.
Scharfy, D, Eggenschwiler, H, Olde Venterink, H, Edwards, PJ and Gusewell, S (2009) The invasive alien plant species Solidago gigantea alters ecosystem properties across habitats with differing fertility. Journal of Vegetation Science 20, 10721085.
Scharfy, D, Güsewell, S, Gessner, MO and Venterink, HO (2010) Invasion of Solidago gigantea in contrasting experimental plant communities: effects on soil microbes, nutrients and plant- soil feedbacks. Journal of Ecology 98, 13791388.
Shannon, CE and Weaver, W (1949) The mathematical theory of communication. Urbana, University of Illinois Press.
Siddiqi, MR (2000) Tylenchida: Parasites of Plants and Insects. 2nd edn. Wallingford, CAB International.
Sieriebriennikov, B, Ferris, H and de Goede, RGM (2014) NINJA: an automated calculation system for nematode-based biological monitoring. European Journal of Soil Biology 61, 9093.
Southey, JF (1986) Laboratory methods for work with plant and soil nematodes. London, Her Majesty's Stationery Office, 202 pp.
StatSoft, Inc (2013) STATISTICA (data analysis software system), version 12.0.
Sterzyńska, M, Shrubovych, J and Nicia, P (2017) Impact of plant invasion (Solidago gigantea L.) on soil mesofauna in a riparian wet meadows. Pedobiologia – Journal of Soil Ecology 64, 17.
Ter Braak, CJF and Šmilauer, P (2012) CANOCO reference manual and user's guide, software for ordination, version 50 Microcomputer Power. Ithaca, Biometris.
Tisdale, SL, Nelson, WL and Beaton, JD (1985) Soil and fertilizer potassium. pp. 249291 in Tisdale, SL, Nelson, WL and Beaton, JD (Eds) Soil fertility and fertilizers. 4th edn. New York, MacMillan PubI. Co.
Van Bezooijen, J (2006) Methods and techniques for nematology. Wageningen, Wageningen University.
Vanderhoeven, S, Dassonville, N, Chapuis-Lardy, L, Hayez, M and Meerts, P (2006) Impact of the invasive alien plant Solidago gigantea on primary productivity, plant nutrient content and soil mineral nutrient concentrations. Plant and Soil 286(1–2), 259268.
Virginia, RA, Jarell, WM, Whitford, WG and Freckman, DW (1992) Soil biota and soil properties in the surface rooting zone of mesquite (Prosopis glandulosa) in historical and recently desertified Chihuahuan Desert habitats. Biology and Fertility of Soils 14, 9098.
Wardle, DA, Bardgett, RD, Klironomos, JN, Setälä, H, van der Putten, WH and Wall, DH (2004). Ecological linkages between aboveground and belowground biota. Science 304, 16291633.
Wasilewska, L (1997) Soil invertebrates as bioindicators, with special reference to soil inhabiting nematodes. Russian Journal of Nematology 5, 113126.
Weber, E (1998) The dynamics of plant invasions: a case study of three exotic goldenrod species (Solidago L.) in Europe. Journal of Biogeography 25, 147154.
Weber, E and Jakobs, G (2005) Biological flora of central Europe: Solidago gigantea Aiton. Flora – Morphology, Distribution, Functional Ecology of Plants 200, 109118.
Yeates, GW (1999) Effects of plants on nematode community structure. Annual Review of Phytopathology 37, 127149.
Yeates, GW and Williams, PA (2001) Influence of three invasive weeds and site factors on soil microfauna in New Zealand. Pedobiologia 45, 367383.
Yeates, GW, Bongers, T, de Goede, RGM, Freckman, DW and Georgieva, SS (1993) Feeding habits in soil nematode families and genera, outline for soil ecologists. Journal of Nematology 25, 315331.
Zhang, CB, Wang, J, Qian, BY and Li, WH (2009) Effects of the invader Solidago canadensis on soil properties. Applied Soil Ecology 43, 163169.
Zhang, P, Neher, DA, Li, B and Wu, J (2018) The impacts of above-and belowground plant input on soil microbiota: invasive Spartina alterniflora versus native Phragmites australis. Ecosystems 21, 469481.


Impact of the invasive plant Solidago gigantea on soil nematodes in a semi-natural grassland and a temperate broadleaved mixed forest

  • A. Čerevková (a1), D. Miklisová (a1), L. Bobuľská (a2) and M. Renčo (a1)


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