This work is licensed under the Creative Commons Attribution 4.0 International License.
AbgrallC., ForeyE., MignotL. and ChauvatM.2018. Invasion by Fallopia japonica alters soil food webs through secondary metabolites. Soil Biology and Biochemistry127:100–9.10.1016/j.soilbio.2018.09.016Search in Google Scholar
AguileraA. G., AlpertP., DukesJ. S. and HarringtonR.2010. Impacts of the invasive plant Fallopia japonica (Houtt.) on plant communities and ecosystem processes. Biological Invasions12:1243–52.10.1007/s10530-009-9543-zSearch in Google Scholar
AlefK. and NannipieriP.1995. Methods in applied soil microbiology and biochemistryAcademic Press, London.Search in Google Scholar
AndrássyI.2005. Free-living nematodes of Hungary Nematoda errantia Vol. I, Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences, Budapest.Search in Google Scholar
AndrássyI.2007. Free-living nematodes of Hungary Nematoda errantia Vol. II, Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences, Budapest.Search in Google Scholar
AndrássyI.2009. Free-living nematodes of Hungary Nematoda errantia Vol. III, Hungarian Natural History Museum and Systematic Zoology Research Group of the Hungarian Academy of Sciences, Budapest.Search in Google Scholar
BaileyJ. P. and ConollyA. P.2000. Prize-winners to pariahs – a history of Japanese knotweed s.l. (Polygonaceae) in the British Isles. Watsonia23:93–110.Search in Google Scholar
BaranováB., MankoP. and JászayT.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 Conservation18:623–35.10.1007/s10841-014-9666-0Search in Google Scholar
BardonC., PiolaF., BellvertF., HaicharF. Z., ComteG., MeiffrenG., PommierT., PuijalonS., TsafackN. and PolyF.2014. Evidence for biological denitrification inhibition (BDI) by plant secondary metabolites. New Phytologist204:620–30.10.1111/nph.1294425059468Search in Google Scholar
BeerlingD. J. and DawahH. A.1993. Abundance and diversity of invertebrates with Fallopia japonica (Houtt. Ronse Decraene) and Impatiens glandulifera (Royle): two alien species in the British Isles. Enthomologist112:127–39.Search in Google Scholar
BeerlingD. J., BaileyJ. P. and ConollyA. P.1994. Fallopia japonica (Houtt.) Ronse Decraene. Journal of Ecology82:959–79.Search in Google Scholar
BerkelmansR., FerrisH., TenutaM. and van BruggenA. H. C.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 Ecology23:223–35.10.1016/S0929-1393(03)00047-7Search in Google Scholar
BiedermanL. A. and BouttonT. W.2009. Biodiversity and trophic structure of soil nematode communities are altered following woody plant invasion of grassland. Soil Biology and Biochemistry41:1943–50.10.1016/j.soilbio.2009.06.019Search in Google Scholar
BongersT.1990. The maturity index, an ecological measure of environmental disturbance based on nematode species composition. Oecologia83:14–19.10.1007/BF0032462728313236Search in Google Scholar
BrzeskiM. W.1998. Nematodes of Tylenchida in Poland and temperate Europe. Museum of Institute of Zoology, Polish Academy of Sciences, Warszawa.Search in Google Scholar
ČerevkováA., MiklisováD., BobuľskáL. and RenčoM.2019. Impact of the invasive plant Solidago gigantea on soil nematodes in a semi-natural grassland and a temperate broadleaved mixed forest. Journal of Helminthology1–14, available at:https://doi.org/10.1017/S0022149X19000324..Search in Google Scholar
CesarzS., ReichP. B., ScheuS., RuessL., SchaeferM. and EisenhauerN.2015. Nematode functional guilds, not trophic groups, reflect shifts in soil food webs and processes in response to interacting global change factors. Pedobiologia58:23–32.10.1016/j.pedobi.2015.01.001Search in Google Scholar
CoatsV. C. and RumphoM. E.2014. The rhizosphere microbiota of plant invaders: an overview of recent advances in the microbiomics of invasive plants. Frontiers in Microbiology5:368.10.3389/fmicb.2014.00368410784425101069Search in Google Scholar
ChmuraD., Tokarska-GuzikB., NowakT., WoźniakG., BzdęgaK., KoszelaK. and GancarekM.2015. The influence of invasive Fallopia taxa on resident plant species in two river valleys (southern Poland). Acta Societatis Botanicorum Poloniae84:23–33.10.5586/asbp.2015.008Search in Google Scholar
CiobanuM., PopoviciI., ZhaoJ. and StoicaI.2015. Patterns of relative magnitudes of soil energy channels and their relationships with environmental factors in different ecosystems in Romania. Scientific Reports5:17606.10.1038/srep17606466495826620189Search in Google Scholar
CobbN. A.1918. Estimating the nematode population of the soil. Bulletin of the Bureau of Plant Industry, Agriculture and Technology. Circular 1. U.S. Department of Agriculture, Washington.Search in Google Scholar
DassonvilleN., VanderhoevenS., GruberW. and MeertsP.2007. Invasion by Fallopia japonica increases topsoil mineral nutrient concentration. Ecoscience14:230–40.10.2980/1195-6860(2007)14[230:IBFJIT]2.0.CO;2Search in Google Scholar
DassonvilleN., DomkeS., HerpignyB., PolyF. and MeertsP. J.2010. Impact of Fallopia spp. on ecosystem functioning: Nitrogen and organic matter cycling and implicated soil biota. Pp.19–22inSegersH. and BranquartE. eds. Science Facing Aliens, Proceedings of a scientific meeting on Invasive Alien Species. Belgian Biodiversity Platform,Brussels.Search in Google Scholar
DassonvilleN., GuillaumaudN., PiolaF., MeertsP. and PolyF.2011. Niche construction by the invasive Asian knotweeds (species complex Fallopia): impact on activity, abundance and community structure of denitrifies and nitrifies. Biological Invasions13:1115–33.10.1007/s10530-011-9954-5Search in Google Scholar
De DeynG. B., RaaijmakersC. E., Van RuijvenJ., BerendseF. and Van der PuttenW. H.2004. Plant species identity and diversity effects on different trophic levels of nematodes in the soil food web. Oikos106:576–86.10.1111/j.0030-1299.2004.13265.xSearch in Google Scholar
DommangetF., EvetteA., SpiegelbergerT., GalletC., PacéM., ImberM. and NavasM. L.2014. Differential allelopathic effects of Japanese knotweed on willow and cottonwood cuttings used in riverbank restoration techniques. Journal of Environmental Management132:71–8.10.1016/j.jenvman.2013.10.024Search in Google Scholar
FerrisH., BongersT. and de GoedeR. G. M.2001. A framework for soil food web diagnostics, extension of the nematode faunal analysis concept. Applied Soil Ecology18:13–29.10.1016/S0929-1393(01)00152-4Search in Google Scholar
GeraertE.2008. The Tylenchidae of the world identification of the family Tylenchidae (Nematoda)Academia Press, Ghent.Search in Google Scholar
GeraertE.2010. The Criconematidae of the world identification of the family Criconematidae (Nematoda)Academia Press, Ghent.Search in Google Scholar
GerberE., KrebsC., MurrellC., MorettiM., RocklinR. and SchaffnerU.2008. Exotic invasive knotweeds (Fallopia spp.) negatively affect native plant and invertebrate assemblages in European riparian habitats. Biological Conservation141:646–54.Search in Google Scholar
GrejtovskýA.1991. Effect of soil improvers measures the enzymatic activity of heavy alluvial soil. Rostlinná Výroba37:289–95, (In Slovak).Search in Google Scholar
IslamK. R. and WeilR. R.1998. Microwave irradiation of soil for routine measurement of microbial biomass carbon. Biology and Fertility of Soils27:408–16.10.1007/s003740050451Search in Google Scholar
KabatT. J., StewartG. B. and PullinA. S.2006. Are Japanese knotweed (Fallopia japonica) control and eradication interventions effective?CEE review 05-015, University of Birmingham, Birmingham..Search in Google Scholar
KimY. S., HwangC. S. and ShinD. H.2005. Volatile constituents from the leaves of Polygonum cuspidatum S. et Z. and their anti-bacterial activities. Food Microbiology22:139–44.Search in Google Scholar
KumagaH., KawaiY., SawanoR., KuriharaH., YamazakiK. and InoueN.2005. Antimicrobial substances from rhizomes of the giant knotweed Polygonum sachalinense against the fish pathogen Photobacterium danselae subsp; piscida. Zeitschrift für Naturforschung C. Journal of Biosciences60:39–44.10.1515/znc-2005-1-208Search in Google Scholar
LavoieC.2017. The impact of invasive knotweed species (Reynoutria spp.) on the environment: review and research perspectives. Biological Invasions19:2319–37.Search in Google Scholar
LendaM., WitekM., SkórkaP., MorońD. and WojciechowskiM.2013. Invasive alien plants affect grassland ant communities, colony size and foraging behaviour. Biological Invasions15:2403–14.10.1007/s10530-013-0461-8Search in Google Scholar
LevineJ. M., VilàM., D’AntonioC. M., DukesJ. S., GrigulisK. and LavorelS.2003. Mechanisms underlying the impacts of exotic plant invasions. Proceedings of the Royal Society of London B270:775–81.10.1098/rspb.2003.2327169131112737654Search in Google Scholar
LoweS., BrowneM., BoudjelasS. and De PoorterM.2000. 100 of the world’s worst invasive alien species a selection from the global invasive species database12, Invasive Species Specialist Group, Auckland.Search in Google Scholar
LoofP. A. A.1999. Nematoda, Adenophorea (Dorylaimida)Spektrum Akademischer Verlag, Heidelberg and Berlin.Search in Google Scholar
McCuneB. and GraceJ. B.2002. Analysis of ecological communitiesMjM Software Design, Gleneden Beach. Oregon, USA.Search in Google Scholar
McCuneB. and MeffordM. J.2011. PC-ORD multivariate analysis of ecological data version 6.0 MjM softwareGleneden Beach. Oregon, USA.Search in Google Scholar
MiklósL.2002. Landscape atlas of the Slovak Republic Ministry of Environment of the Slovak RepublicSlovak Environmental Agency, Banská Bystrica.Search in Google Scholar
MinchevaT., BarniE., VareseG. C., BrusaG., CeraboliniB. and SiniscalcoC.2014, Litter quality, decomposition rates and saprotrophic mycoflora in Fallopia japonica (Houtt. Ronse Decraene and in adjacent native grassland vegetation. Acta Oecologica54:29–35.Search in Google Scholar
MorońD., LendaM., SkórkaP., SzentgyörgyiH., SetteleJ. and WoyciechowskiM.2009. Wild pollinator communities are negatively affected by invasion of alien goldenrods in grassland landscapes. Biological Conservation142:1322–32.10.1016/j.biocon.2008.12.036Search in Google Scholar
QuistC. W., VervoortM. T. W., Van MegenH., GortG., BakkerJ., Van der PuttenW. H. and HelderJ.2014. Selective alteration of soil food web components by invasive giant goldenrod Solidago gigantea in two distinct habitat types. Oikos123:837–45.10.1111/oik.01067Search in Google Scholar
RahmonovO., CzylokA., OrczewskaA., MajgierL. and ParuselT.2014. Chemical composition of the leaves of Reynoutria japonica Houtt. and soil features in polluted areas. Central European Journal of Biology9:320–30.Search in Google Scholar
RenčoM. and BaležentienéL.2011. An analysis of soil free-living and plant-parasitic nematode communities in three habitats invaded by Heracleum sosnowskyi in central Lithuania. Biological Invasions17:1025–39.10.1007/s10530-014-0773-3Search in Google Scholar
RenčoM.KornobisF.W., DomaradzkiK., Jakubska-BusseA., JurováJ. and HomolováZ.2019. How does an invasive Heracleum sosnowskyi affect soil nematode communities in natural conditions? Nematology: International Journal of Fundamental and Applied Nematological Research21:71–89.10.1163/15685411-00003196Search in Google Scholar
RitzK., BlackH. I. J., CampbellC. D., HarrisJ. A. and WoodC.2009. Selecting biological indicators for monitoring soils: a framework for balancing scientific and technical opinion to assist policy development. Ecological Indicators9:1212–21.10.1016/j.ecolind.2009.02.009Search in Google Scholar
SabováM. and ValockáB.1980. Parasitic nematodes of cereals in Slovak Republic. Agriculture26:278–85.Search in Google Scholar
ScharfyD., GüsewellS., GessnerM. O. and Olde VenterinkH.2010. Invasion of Solidago gigantea in contrasting experimental plant communities: effects on soil microbes, nutrients and plant-soil feedbacks. Journal of Ecology98:1379–88.10.1111/j.1365-2745.2010.01722.xSearch in Google Scholar
SchinnerF. and VonmersiW.1990. Xylanase-activity, CM-cellulase-activity and invertase activity in soil – an improved method. Soil Biology and Biochemistry22:511–15.10.1016/0038-0717(90)90187-5Search in Google Scholar
ShannonC. E. and WeaverW.1949. The mathematical theory of communicationUniversity of Illinois Press, Urbana, IL.Search in Google Scholar
SiddiqiM. R.2000. Tylenchida, parasites of plants and insects2nd ed., CABI Publishing, Wallingford.10.1079/9780851992020.0000Search in Google Scholar
SieriebriennikovB., FerrisH. and de GoedeR. G. M.2014. NINJA: an automated calculation system for nematode-based biological monitoring. European Journal of Soil Biology61:90–3.10.1016/j.ejsobi.2014.02.004Search in Google Scholar
SołtysiakJ. and BrejT.2014. Invasion of Fallopia genus plants in urban environment. Polish Journal of Environmental Studies23:449–58.Search in Google Scholar
SoutheyJ. F.1986. Laboratory methods for work with plant and soil nematodesHer Majesty’s Stationery Office, London.Search in Google Scholar
StatSoft, Inc2013. STATISTICA (data analysis software system). version 12.0..Search in Google Scholar
StefanowiczA. M., StanekM., NobisM. and ZubekS.2016. Species-specific effects of plant invasions on activity, biomass, and composition of soil microbial communities. Biology and Fertility of Soils52:841–52.10.1007/s00374-016-1122-8Search in Google Scholar
StefanowiczA. M., StanekM., NobisM. and ZubekS.2017. Few effects of invasive plants Reynoutria japonica, Rudbeckia laciniata and Solidago gigantea on soil physical and chemical properties. Science of the Total Environment574:938–46.10.1016/j.scitotenv.2016.09.12027665453Search in Google Scholar
StefanowiczA. M., StanekM., MajewskaM. L., NobisM. and ZubekS.2019. Invasive plant species identity affects soil microbial communities in a mesocosm experiment. Applied Soil Ecology136:168–77.10.1016/j.apsoil.2019.01.004Search in Google Scholar
SterzyńskaM., ShrubovychJ. and NiciaP.2017. Impact of plant invasion (Solidago gigantea L.) on soil mesofauna in a riparian wet meadows. Pedobiologia64:1–7.Search in Google Scholar
StollP., GatzschK., RusterholzH. P. and BaurB.2012. Response of plant and gastropod species to knotweed invasion. Basic and Applied Ecology13:232–40.10.1016/j.baae.2012.03.004Search in Google Scholar
SuseelaV., AlpertP., NakatsuC. H., ArmstrongA. and TharayilN.2016. Plant-soil interactions regulate the identity of soil carbon in invaded ecosystems, implication for legacy effects. Functional Ecology30:1227–38.10.1111/1365-2435.12591Search in Google Scholar
Ter BraakC. J. F. and ŠmilauerP.2012. CANOCO reference manual and user’s guide, software for ordination. version 50 Microcomputer Power, Biometris, Ithaca, NY.Search in Google Scholar
Van BezooijenJ.2006. Methods and techniques for nematologyWageningen University, Wageningen.Search in Google Scholar
ViketoftM., PalmborgC., SohleniusB., Huss-DanellK. and BengtssonJ.2005. Plant species effects on soil nematode communities in experimental grasslands. Applied Soil Ecology30:90–103.10.1016/j.apsoil.2005.02.007Search in Google Scholar
WasilewskaL.1997. Soil invertebrates as bioindicators, with special reference to soil inhabiting nematodes. Russian Journal of Nematology5:113–26.Search in Google Scholar
YeatesG. W.1999. Effects of plants on nematode community structure. Annual Review of Phytopathology37:127–49.10.1146/annurev.phyto.37.1.12711701819Search in Google Scholar
YeatesG. W., FerrisH., MoensT. and van der PuttenW. H.2009. The role of nematodes in Ecosystems. Pp. 19–22inWilsonM. J. and Kakouli-DuarteT. eds. Nematodes as environmental indicatorsCABI, Wallingford.10.1079/9781845933852.0001Search in Google Scholar
YeatesG. W., BongersT., de GoedeR. G. M., FreckmanD. W. and GeorgievaS. S.1993. Feeding habits in soil nematode families and genera, outline for soil ecologists. Journal of Nematology25:315–31.May 11 19-24.Search in Google Scholar