Comparison of spatial dispersion of epigeic fauna between alluvial forests in an agrarian and Dunajské luhy protected landscape area, southern Slovakia

Avtaeva, T., Petrovičová, K., Langraf, V., Brygadyrenko, V., 2021a: Potential bioclimatic ranges of crop pests Zabrus tenebrioides and Harpalus rufipes during climate change conditions. Diversity, 13:559. Search in Google Scholar

Avtaeva, T. A., Sukhodolskaya, R. A., Brygadyrenko, V. V., 2021b: Modeling the bioclimatic range of Pterostichus melanarius (Coleoptera, Carabidae) in conditions of global climate change. Biosystems Diversity, 29:140–150. Search in Google Scholar

Boháč, J., Jahnova, Z., 2015: Land Use Changes and Landscape Degradation in Central and Eastern Europe in the Last Decades: Epigeic Invertebrates as Bioindicators of Landscape Changes. In: Armon, R., Hänninen, O. (eds): Environmental Indicators. Dordrecht, Springer, p. 395–420. Search in Google Scholar

Bote, P. J., Romero, A. J., 2012: Epigeic soil arthropod abundance under different agricultural land uses. Spanish Journal of Agricultural Research, 10:55–61. Search in Google Scholar

Briones, M. J. I., Schmidt., O., 2017: Conventional tillage decreases the abundance and biomass of earthworms and alters theircommunity structure in a global meta-analysis. Global Change Biology, 23:4396–4419. Search in Google Scholar

Brygadyrenko, V. V., 2015a: Community structure of litter invertebrates of forest belt ecosystems in the Ukrainian steppe zone. International Journal of Environmental Research, 9:1183–1192. Search in Google Scholar

Brygadyrenko, V. V., 2015b: Influence of tree crown density and density of the herbaceous layer on the structure of litter macrofauna of deciduous forests of Ukraine’s steppe zone. Visnyk of Dnipropetrovsk University Biology ecology, 23:134–148. Search in Google Scholar

Brygadyrenko, V. V., Nazimov, S. S., 2015c: Trophic relations of Opatrum sabulosum (Coleoptera, Tenebrionidae) with leaves of cultivated and uncultivated species of herbaceous plants under laboratory conditions. Zookeys, 481:57–68. Search in Google Scholar

Faly, L. I., Kolombar, T. M., Prokopenko, E. V., Pakhomov, O. Y., Brygadyrenko, V. V., 2017: Structure of litter macrofauna communities in poplar plantations in an urban ecosystem in Ukraine. Biosystems Diversity, 25:29–38. Search in Google Scholar

Fusser, M. S, Pfister, S. C., Entling, M. H., Schirmel, J., 2017: Effects of field margin type and landscape composition on predatory carabids and slugs in wheat fields. Agriculture, Ecosystems & Environment, 247:182–188. Search in Google Scholar

Gordienko, T., Sukhodolskaya, R. A., 2022: Patterns of seasonal population dynamics of soil macrofauna in meadow phytocenoses in the Volga-Kama reserve. MOJ Ecology & Environmental Sciences, 7:174–176. Search in Google Scholar

Guo, X., Bian, Z., Wang, S., Wang, Q., Zhang, Y., Zhou. et al., 2020: Prediction of the spatial distribution of soil arthropods using a random forest model: A case study in Changtu County, Northeast China. Agriculture, Ecosystems & Environment, 292:106818. Search in Google Scholar

Haddaway, N. R., Brown, C., Eales, J., Eggers, S., Josefsson, J., Kronvang, B. et al., 2018: The multifunctional roles of vegetated strips around and within agricultural fields. Environmental Evidence, 7:14. Search in Google Scholar

Klimaszewski, J., Brunke, A., Work, T., Venier, L., 2018: Rove beetles (Coleoptera, Staphylinidae) as bioindicators of change in boreal forests and their biological control services in agroecosystems: Canadian case studies. In: Betz, O., Irmler, U., Klimaszewski, J. (eds): Biology of rove beetles – life history, evolution, ecology and distribution. Springer, p. 161–181. Search in Google Scholar

Kolesnikova, A., Lapteva, E., Degteva, S., Taskaeva, A., Kudrin, A., Vinogradova, Y. et al., 2016: Biodiversity of foodplain soils in the European north-east of Russia. In: Bucur, D. (eds): River basin management. London, IntechOpen, p. 271–294. Search in Google Scholar

Kozak, V. M., Romanenko, E. R., Brygadyrenko, V. V., 2020: Influence of herbicides, insecticides and fungicides on food consumption and body weight of Rossiulus kessleri (Diplopoda, Julidae). Biosystems Diversity, 28:272–280. Search in Google Scholar

Langraf, V., David, S., Babosová, R., Petrovičová, K., Schlarmannová, J., 2020: Change of ellipsoid biovolume (EV) of ground beetles (Coleoptera, Carabidae) along an urban–suburban–rural gradient of Central Slovakia. Diversity, 12:475. Search in Google Scholar

Lavelle, P., Mathieu, J., Spain, A., Brown, G., Fragoso, C., Lapied, E. et al., 2022: Soil macroinvertebrate communities: A world-wide assessment. Global Ecology and Biogeography, 31:1261–1276. Search in Google Scholar

Lenoir, L., Lennartsson, T., 2010: Effects of timing of grazing on arthropod communities in semi-natural grasslands. Journal of Insect Science, 10:1–24. Search in Google Scholar

Litavský, J., Stašiov, S., Svitok, M., Michalková, E., Majzlan, O., Žarnovičan, H. et al., 2018: Epigean communities of harvestmen (Opiliones) in Pannonian Basin floodplain forests: An interaction with environmental parameters. Biologia, 73:753–763. Search in Google Scholar

Litavský, J., Majzlan, O., Stašiov, S., Svitok, M., Fedor, P., 2021: The associations between ground beetle (Coleoptera: Carabidae) communities and environmental condition in floodplain forests in the Pannonian Basin. European Journal of Entomology, 118:14–23. Search in Google Scholar

Porhajašová, J., Babošová, M., Noskovič, J., Ondrišík, P., 2018: Long-term developments and biodiversity in carabid and staphylinid (Coleoptera: Carabidae and Staphylinidae) fauna during the application of organic fertilizers under agroecosystem conditions. Polish Journal of Environmental Studies, 27:2229–2235. Search in Google Scholar

Porhajašová, J., Babošová, M., 2022: Impact of arable farming management on the biodiversity of Carabidae (Coleoptera). Saudi Journal of Biological Sciences, 29:103371. Search in Google Scholar

Potapov, A. M., Sun, X., Barnes, A. D., Briones, M. J., Brown, G. G., Cameron, E. K. et al., 2022: Global monitoring of soil animal communities using a common methodology. Soil Organisms, 94:55–68. Search in Google Scholar

Putchkov, A. V., Brygadyrenko, V. V., 2022: Rare species of ground beetles (Coleoptera, Carabidae) of Dnipropetrovsk Region (Ukraine). Biosystems Diversity, 30:310–337. Search in Google Scholar

Raven, P. H., Wagner, D. L., 2021: Agricultural intensification and climate change are rapidly decreasing insect biodiversity. Proceedings of the National Academy of Sciences of the United States of America, 118:e2002548117. Search in Google Scholar

Schierwater, B., DeSalle, R., 2021: Invertebrate zoology: A tree of life approach. London, CRC Press, 644 p. Search in Google Scholar

Skłodowski, J., 2014: Consequence of the transformation of a primeval forest into a managed forest for carabid beetles (Coleoptera: Carabidae) a case study from Bialowieza (Poland). European Journal of Entomology, 111: 639–648. Search in Google Scholar

Stašiov, S., Michalková, E., Lukáčik, I., Čiliak, M., 2017: Harvestmen (Opiliones) communities in an arboretum: Influence of tree species. Biologia, 72:184–193. Search in Google Scholar

Stašiov, S., Litavský, J., Majzlan, O., Svitok, M., Fedor, P., 2021: Influence of selected environmental parameters on rove beetle (Coleoptera: Staphylinidae) communities in Central European floodplain forests. Wet-lands, 41:115. Search in Google Scholar

R version 4.1.3 2020. The R Foundation for Statistical Computing. Search in Google Scholar

Ter Braak, C. J. F., Šmilauer, P., 2012: Canoco reference manual and user’s guide: Software for ordination, vers. 5.0. Microcomputer Power, Ithaca, New York. 496 p. Search in Google Scholar