Abstract
Context
Intensive agricultural management practices and landscape homogenisation are the main drivers of biodiversity loss in agricultural landscapes. Agricultural fields are regularly disturbed and provide unstable habitats due to crop management regimes. This may lead to movement of arthropods into neighbouring non-arable habitats, as natural and semi-natural habitats provide suitable overwintering sites.
Objectives
Here we assessed the effect of landscape composition and configuration on the overwintering spider and carabid fauna of grassy field margins and hedgerows.
Methods
We sampled ground-dwelling arthropods at field edges of different types (grassy field margin and hedgerows), landscape composition (diverse and simple) and configuration (mosaic and large-scale agricultural landscapes).
Results
We detected larger spiders in hedgerows than in grassy field margins and in complex landscapes rather than in simple landscapes. We found a significant effect of interaction between landscape composition and edge type on ballooning propensity of spiders. Agrobiont carabids were more abundant in field edges of compositionally simple and large-scale agricultural landscapes. Furthermore, we showed an effect of interaction between landscape composition and edge type on agrobiont spiders. We collected larger carabids in grassy field margins than in hedgerows and carabids were smaller in simple landscapes than in diverse landscapes. The spider community was affected by edge type, and landscape composition had a significant effect on the carabid community.
Conclusions
Small-scale agricultural landscapes may have higher overall densities of ground-dwelling spiders and carabids than large scale landscapes due to the relatively high edge density and the higher quantity of available overwintering sites.
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References
Bartón K (2015) Package MuMIn. R Package version 1.15. 1. R Foundation for Statistical Computing, Vienna
Batáry P, Gallé R, Riesch F, Fischer C, Dormann CF, Mußhoff O, Császár P, Fusarol S, Gayer C, Happe AK, Kurucz K, Molnár D, Rösch V, Wietzke A, Tscharntke T (2017) The former iron curtain still drives biodiversity-profit trade-offs in German agriculture. Nat Ecol Evol 1:1279–1284
Batáry P, Holzschuh A, Orci KM, Samu F, Tscharntke T (2012) Responses of plant, insect and spider biodiversity to local and landscape scale management intensity in cereal crops and grasslands. Agr Ecosyst Environ 146:130–136
Baudry J, Bunce RGH, Burel F (2000) Hedgerows: an international perspective on their origin, function and management. J Environ Manag 60:7–22
Bell JR, Bohan DA, Shaw EM, Weyman GS (2005) Ballooning dispersal using silk: world fauna, phylogenies, genetics and models. Bull Entomol Res 95:69–114
Bianchi FJJA, Booij CJH, Tscharntke T (2006) Sustainable pest regulation in agricultural landscapes: a review on landscape composition, biodiversity and natural pest control. Proc R Soc Lond B 273:1715–1727
Bianchi FJJA, van der Werf W (2003) The effect of the area and configuration of hibernation sites on the control of aphids by Coccinella septempunctata (Coleoptera: Coccinellidae) in agricultural landscapes: a simulation study. Environ Entomol 32:1290–1304
Birkhofer C, Entling M, Lubin Y (2013) Agroecology trait composition, spatial relationships, trophic interactions. In: Penney D (ed) Spider research in the 21st century: trends & perspectives. Siri Scientific Press, New York, pp 200–229
Blandenier G (2009) Ballooning of spiders (Araneae) in Switzerland: general results from an eleven-year survey. Bull Br Arachnol Soc 14:308–316
Blitzer EJ, Dormann CF, Holzschuh A, Klein A-M, Rand TA, Tscharntke T (2012) Spillover of functionally important organisms between managed and natural habitats. Agric Ecosyst Environ 146:34–43
Bonte D, Vandenbroecke N, Lens L, Maelfait JP (2003) Low propensity for aerial dispersal in specialist spiders from fragmented landscapes. Proc R Soc Lond B 270:1601–1607
Buchar J, Ruzicka V (2002) Catalogue of spiders of the Czech Republic. Peres, Prague
Buddle CM, Higgins S, Rypstra AL (2004) Ground-dwelling spider assemblages inhabiting riparian forests and hedgerows in an agricultural landscape. Am Midl Nat 151:15–26
Burnham KP, Anderson DR (2003) Model selection and multimodel inference: a practical information-theoretic approach. Springer, Berlin, p 488
Chaplin-Kramer R, O’Rourke ME, Blitzer EJ, Kremen C (2011) A meta-analysis of crop pest and natural enemy response to landscape complexity. Ecol Lett 14:922–932
Concepción ED, Díaz M, Baquero RA (2008) Effects of landscape complexity on the ecological effectiveness of agri-environment schemes. Landscape Ecol 23:135–148
Cordeau S, Petit S, Reboud X, Chauvel B (2012) Sown grass strips harbour high weed diversity but decrease weed richness in adjacent crops. Weed Res 52:88–97
Drapela T, Moser D, Zaller JG, Frank T (2008) Spider assemblages in winter oilseed rape affected by landscape and site factors. Ecography 31:254–262
Duflot R, Aviron S, Ernoult A, Fahrig L, Burel F (2015) Reconsidering the role of ‘semi-natural habitat’ in agricultural landscape biodiversity: a case study. Ecol Res 30:75–83
Dufrene M, Legendre P (1997) Species assemblages and indicator species: the need for a flexible asymmetrical approach. Ecol Monogr 67:345–367
Entling W, Schmidt-Entling MH, Bacher S, Brandl R, Nentwig W (2010) Body size-climate relationships of European spiders. J Biogeogr 37:477–485
Entling MH, Stämpfli K, Ovaskainen O (2011) Increased propensity for aerial dispersal in disturbed habitats due to intraspecific variation and species turnover. Oikos 120:1099–1109
ESRI (2012) ArcGIS 10.1. ESRI (Environmental Systems Resource Institute), Redlands
Fahrig L, Baudry J, Brotons L, Burel FG, Crist TO, Fuller RJ, Sirami C, Siriwardena GM, Martin JL (2011) Functional landscape heterogeneity and animal biodiversity in agricultural landscapes. Ecol Lett 14:101–112
Ferrante M, González E, Lövei GL (2017) Predators do not spill over from forest fragments to maize fields in a landscape mosaic in central Argentina. Ecol Evol 7:7699–7707
Fischer C, Schlinkert H, Ludwig M, Holzschuh A, Gallé R, Tscharntke T, Batáry P (2013) The impact of hedge-forest connectivity and microhabitat conditions on spider and carabid beetle assemblages in agricultural landscapes. J Insect Conserv 17:1027–1038
Freude H, Harde KW, Müller-Motzfeld G, Lohse GA, Klausnitzer B (2004) Die Käfer Mitteleuropas, Adephaga 1. Carabidae Laufkäfer. Spektrum akademischer Verlag, Munich, pp 1–521
Geiger F, Wäckers FL, Bianchi FJJA (2009) Hibernation of predatory arthropods in semi-natural habitats. Biocontrol 54:529–535
González E, Salvo A, Defagó MT, Valladares G (2016) A moveable feast: insects moving at the forest-crop interface are affected by crop phenology and the amount of forest in the landscape. PLoS ONE 11:e0158836
Hendrickx F, Maelfait JP, Desender K, Aviron S, Bailey D, Diekotter T, Lens L, Schweiger O, Speelmans M, Vandomme V, Bugter R (2009) Pervasive effects of dispersal limitation on within-and among-community species richness in agricultural landscapes. Glob Ecol Biogeogr 18:607–616
Hendrickx F, Maelfait JP, Van Wingerden W, Schweiger O, Speelmans M, Aviron S, Augenstein I, Billeter R, Bailey D, Bukacek R, Burel F, Diekötter T, Dirksen J, Herzog F, Liira J, Roubalova M, Vandomme V, Bugter R (2007) How landscape structure, land-use intensity and habitat diversity affect components of total arthropod diversity in agricultural landscapes. J Appl Ecol 44:340–351
Holland JM, Bianchi FJJA, Entling MH, Moonen A-C, Smith BM, Jeanneret P (2016) Structure, function and management of semi-natural habitats for conservation biological control: a review of European studies. Pest Manag Sci 72:1638–1651
Holland JM, Birkett T, Southway S (2009) Contrasting the farm-scale spatiotemporal dynamics of boundary and field overwintering predatory beetles in arable crops. Biocontrol 54:19–33
Homburg K, Homburg N, Schaefer F, Schuldt A, Assmann T (2014) Carabids.org-a dynamic online database of ground beetle species traits (Coleoptera, Carabidae). Insect Conserv Divers 7:195–205
Hurka K (1996) Carabidae of the Czech and Slovak Republics. Kabourek, Zlin, pp 1–565
Kalushkov P, Blagoev G, Deltshev C (2008) Biodiversity of epigeic spiders in genetically modified (Bt) and conventional (non-Bt) potato fields in Bulgaria. Acta Zool Bulg 60:61–69
Kuznetsova A, Brockhoff PB, Christensen RHB (2015) Package ‘lmerTest’. R package version, 2-0. R Foundation for Statistical Computing, Vienna
Landis DA, Wratten SD, Gurr GM (2000) Habitat management to conserve natural enemies of arthropod pests in agriculture. Ann Rev Entomol 45:175–201
Lang S, Tiede D (2003) vLATE Extension für ArcGIS—vektorbasiertes Tool zur quantitativen Landschaftsstrukturanalyse, ESRI Anwenderkonferenz 2003 Innsbruck. CDROM
Le Viol I, Julliard R, Kerbiriou C, de Redon L, Carnino N, Machon N, Porcher E (2008) Plant and spider communities benefit differently from the presence of planted hedgerows in highway verges. Biol Conserv 101:1581–1590
Legendre P, Gallagher ED (2001) Ecologically meaningful transformations for ordination of species data. Oecologia 129:271–280
Lóczy D (ed) (2015) Landscapes and landforms of Hungary. Springer, Leverkusen, pp 1–294
Madeira F, Tscharntke T, Elek Z, Kormann UG, Pons X, Rösch V, Samu F, Scherber C, Batáry P (2016) Spillover of arthropods from cropland to protected calcareous grassland–the neighbouring habitat matters. Agric Ecosyst Environ 235:127–133
Makra L, Matyasovszky I, Páldy A, Deák ÁJ (2012) The influence of extreme high and low temperatures and precipitation totals on pollen seasons of Ambrosia, Poaceae and Populus in Szeged, southern Hungary. Grana 51:215–227
Mansion-Vaquié A, Ferrante M, Cook SM, Pell JK, Lövei GL (2017) Manipulating field margins to increase predation intensity in fields of winter wheat (Triticum aestivum). J Appl Entomol 141:600–611
Marshall EJP, Moonen AC (2002) Field margins in northern Europe: their functions and interactions with agriculture. Agric Ecosyst Environ 89:5–21
Marshall EJP, West TM, Kleijn D (2006) Impacts of an agri-environment field margin prescription on the flora and fauna of arable farmland in different landscapes. Agric Ecosyst Environ 113:36–44
Martin TJ, Major RE (2001) Changes in wolf spider (Araneae) assemblages across woodland-pasture boundaries in the central wheat-belt of New South Wales, Australia. Austral Ecol 26:264–274
Moretti M, Dias AT, Bello F, Altermatt F, Chown SL, Azcárate FM, Bell JR, Fournier B, Hedde M, Hortal J, Ibanez S, Öckinger E, Sousa JP, Ellers J, Matty PB (2017) Handbook of protocols for standardized measurement of terrestrial invertebrate functional traits. Funct Ecol 31:558–567
Nentwig W, Blick T, Gloor D, Hänggi A, Kropf C (2017) Spiders of Europe. www.araneae.unibe.ch. Accessed 09 Oct 2017
Noordijk J, Raemakers IP, Schaffers AP, Sykora KV (2009) Arthropod richness in roadside verges in the Netherlands. Terr Arthropod Rev 2:63–76
Nyffeler M, Sunderland KD (2003) Composition, abundance and pest control potential of spider communities in agroecosystems: a comparison of European and US studies. Agric Ecosyst Environ 95:579–612
Öberg S, Ekbom B, Bommarco R (2007) Influence of habitat type and surrounding landscape on spider diversity in Swedish agroecosystems. Agric Ecosyst Environ 122:211–219
Opatovsky I, Lubin Y (2012) Coping with abrupt decline in habitat quality: effects of harvest on spider abundance and movement. Acta Oecol 41:14–19
Pfiffner L, Luka H (2000) Overwintering of arthropods in soils of arable fields and adjacent semi-natural habitats. Agric Ecosyst Environ 78:215–222
Pluess T, Opatovsky I, Gavish-Regev E, Lubin Y, Schmidt-Entling MH (2010) Non-crop habitats in the landscape enhance spider diversity in wheat fields of a desert agroecosystem. Agric Ecosyst Environ 137:68–74
Purtauf T, Roschewitz I, Dauber J, Thies C, Tscharntke T, Wolters V (2005) Landscape context of organic and conventional farms: influences on carabid beetle diversity. Agric Ecosyst Environ 108:165–174
Ramsden MW, Menéndez R, Leather SR, Wäckers F (2015) Optimizing field margins for biocontrol services: the relative role of aphid abundance, annual floral resources, and overwinter habitat in enhancing aphid natural enemies. Agric Ecosys Environ 199:94–104
Rand TA, Tylianakis JM, Tscharntke T (2006) Spillover edge effects: the dispersal of agriculturally subsidized insect natural enemies into adjacent natural habitats. Ecol Lett 9:603–614
Ricotta C, Moretti M (2011) CWM and Rao’s quadratic diversity: a unified framework for functional ecology. Oecologia 167:181–188
Roberts DW (2012) Package ‘‘labdsv.’’ http://cran.r-project.org/web/packages/labdsv/labdsv.pdf. Accessed 23 Aug 2017
Rundlöf M, Nilsson H, Smith HG (2008) Interacting effects of farming practice and landscape context on bumble bees. Biol Conserv 141:417–426
Sala OE, Chapin FS, Armesto JJ, Berlow E, Bloomfield J, Dirzo R, HuberSanwald E, Huenneke LF, Jackson RB, Kinzig A, Leemans R, Lodge DM, Mooney HA, Oesterheld M, Poff NL, Sykes MT, Walker BH, Walker M, Wall DH (2000) Global biodiversity scenarios for the year 2100. Science 287:1770–1774
Samu F, Cs Szinetár (2002) On the nature of agrobiont spiders. J Arachnol 30:389–402
Sarthou JP, Badoz A, Vaissière B, Chevallier A, Rusch A (2014) Local more than landscape parameters structure natural enemy communities during their overwintering in semi-natural habitats. Agric Ecosyst Environ 194:17–28
Schaffers AP, Raemakers IP, Sýkora KV (2012) Successful overwintering of arthropods in roadside verges. J Insect Conserv 16:511–522
Schellhorn NA, Bianchi FJJA, Hsu CL (2014) Movement of entomophagous arthropods in agricultural landscapes: links to pest suppression. Annu Rev Entomol 59:559–581
Schirmel J, Blindow I, Buchholz S (2012) Life-history trait and functional diversity patterns of ground beetles and spiders along a coastal heathland successional gradient. Basic Appl Ecol 13:606–614
Schirmel J, Thiele J, Entling MH, Buchholz S (2016) Trait composition and functional diversity of spiders and carabids in linear landscape elements. Agric Ecosyst Environ 235:318–328
Schmidt MH, Thies C, Nentwig W, Tscharntke T (2008) Contrasting responses of arable spiders to the landscape matrix at different spatial scales. J Biogeogr 35:157–166
Southwood TRE (1977) Habitat, the templet for ecological strategies? J Anim Ecol 46:337–365
Symondson WOC, Sunderland KD, Greenstone MH (2002) Can generalist predators be effective biocontrol agents? Annu Rev Entomol 47:561–594
Szilassi P, Bata T, Szabó S, Czúcz B, Molnár Z (2017) The link between landscape pattern and vegetation naturalness on a regional scale. Ecol Indic 81:252–259
Thorbek P, Bilde T (2004) Reduced numbers of generalist arthropod predators after crop management. J Appl Ecol 41:526–538
Tscharntke T, Tylianakis JM, Rand TA, Didham RK, Fahrig L, Batáry P, Bengtsson J, Clough Y, Crist TO, Dormann CF, Ewers RM, Fründ J, Holt RD, Holzschuh A, Klein AM, Kleijn D, Kremen C, Landis DA, Laurance W, Lindenmayer D, Scherber C, Sodhi N, Steffan-Dewenter I, Thies C, van der Putten WH, Westphal C (2012) Landscape moderation of biodiversity patterns and processes—eight hypotheses. Biol Rev 87:661–685
Turner MG, Gardner MH (2015) Landscape ecology in theory and practice pattern and process. Springer, New York, pp 1–482
Wamser S, Dauber J, Birkhofer K, Wolters V (2011) Delayed colonisation of arable fields by spring breeding ground beetles (Coleoptera: Carabidae) in landscapes with a high availability of hibernation sites. Agric Ecosyst Environ 144:235–240
Way JM (1977) Roadside verges and conservation in Britain: a review. Biol Conserv 12:65–74
Werling BP, Gratton C (2008) Influence of field margins and landscape context on ground beetle diversity in Wisconsin (USA) potato fields. Agric Ecosyst Environ 128:104–108
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This work was supported by the Hungarian National Research, Development and Innovation Office (Grant Id: NKFI-FK-124579).
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Gallé, R., Császár, P., Makra, T. et al. Small-scale agricultural landscapes promote spider and ground beetle densities by offering suitable overwintering sites. Landscape Ecol 33, 1435–1446 (2018). https://doi.org/10.1007/s10980-018-0677-1
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DOI: https://doi.org/10.1007/s10980-018-0677-1