Abstract
The exponential increase of mobile telephony has led to a pronounced increase in electromagnetic fields in the environment that may affect pollinator communities and threaten pollination as a key ecosystem service. Previous studies conducted on model species under laboratory conditions have shown negative effects of electromagnetic radiation (EMR) on reproductive success, development, and navigation of insects. However, the potential effects that widespread mobile telecommunication antennas have on wild pollinator communities outside the laboratory microcosm are still unknown. Here we studied the effects of EMR from telecommunication antennas on key wild pollinator groups (wild bees, hoverflies, bee flies, remaining flies, beetles, butterflies, and wasps). We measured EMR at 4 distances (50, 100, 200 and 400 m) from 10 antennas (5 on Limnos Island and 5 on Lesvos Island, eastern Mediterranean, Greece), and correlated EMR values with insect abundance and richness (the latter only for wild bees and hoverflies). All pollinator groups except butterflies were affected by EMR. In both islands, beetle, wasp, and hoverfly abundance decreased with EMR, whereas the abundance of underground-nesting wild bees and bee flies unexpectedly increased with EMR. The effect of EMR on the abundance of remaining flies differed between islands. With respect to species richness, EMR only tended to have a negative effect on hoverflies in Limnos. As EMR affected the abundance of several insect guilds negatively, and changed the composition of wild pollinators in natural habitats, it might also have additional ecological and economic impacts on the maintenance of wild plant diversity, crop production and human welfare.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aguilar R, Ashworth L, Galetto L, Aizen M (2006) Plant reproductive susceptibility to habitat fragmentation: review and synthesis through a meta-analysis. Ecol Lett 9:968–980
Ashman T-L, Knight TM, Steets JA, Amarasekare P, Burd M, Campbell DR, Dudash MR, Johnston MO, Mazer SJ, Mitchell RJ, Morgan MT, Wilson WG (2004) Pollen limitation of plant reproduction: ecological and evolutionary causes and consequences. Ecology 85:2408–2421
Atli E, Ünlü H (2006) The effects of microwave frequency electromagnetic fields on the development of Drosophila melanogaster. Int J Radiat Biol 82:435–441
Atli E, Ünlü H (2007) The effects of microwave frequency electromagnetic fields on the fecundity of Drosophila melanogaster. Turkish J Biol 31:1–5
Balanis C (2005) Antenna theory: analysis and design, 3rd edn. Wiley, New York
Balmori A (2015) Anthropogenic radiofrequency electromagnetic fields as an emerging threat to wildlife orientation. Sci Total Environ 518–519:58–60
Barton K (2014) MuMIn: Multi-model inference. R package version 1.10.0. Retrieved May 14, 2014, from http://cran.r-project.org/package=MuMIn
Biesmeijer JC, Roberts SPM, Reemer M, Ohlemüller R, Edwards M, Peeters T, Schaffers AP, Potts SG, Kleukers R, Thomas CD, Settele J, Kunin WE (2006) Parallel declines in pollinators and insect-pollinated plants in Britain and the Netherlands. Science 313:351–354
Bjørnstad ON, Falck W (2001) Non-parametric spatial covariance functions: estimation and testing. Environ Ecol Stat 8:53–70
Burkle LA, Marlin JC, Knight TM (2013) Plant-pollinator interactions over 120 years: loss of species, co-occurrence and function. Science 339:1611–1615
Cammaerts M-C, Johansson O (2014) Ants can be used as bio-indicators to reveal biological effects of electromagnetic waves from some wireless apparatus. Electromagn Biol Med 33:282–288
Cammaerts M-C, De Doncker P, Patris X, Bellens F, Rachidi Z, Cammaerts D (2012) GSM 900 MHz radiation inhibits ants’ association between food sites and encountered cues. Electromagn Biol Med 31:151–165
Cammaerts M-C, Vandenbosch GAE, Volski V (2014) Effect of short-term GSM radiation at representative levels in society on a biological model: the ant Myrmica sabuleti. J Insect Behav 27:514–526
Chavdoula ED, Panagopoulus DJ, Margaritis LH (2010) Comparison of biological effects between continuous and intermittent exposure to GSM-900-MHz mobile phone radiation: detection of apoptotic cell-death features. Mutat Res 700:51–61
Chittka L, Thomson JD (2001) Cognitive ecology of pollination. Cambridge University Press, Cambridge
Cucurachi S, Tamis WLM, Vijver MG, Peijnenburg WJGM, Bolte JFB, de Snoo GR (2013) A review of the ecological effects of radiofrequency electromagnetic fields (RF-EMF). Environ Int 51:116–140
Dasdag S, Akdag MZ, Aksen F, Bashan M, Buyukbayram H (2004) Does 900 MHZ GSM mobile phone exposure affect rat brain? Electromagn Biol Med 23(3):201–214
Favre D (2011) Mobile phone-induced honeybee worker piping. Apidologie 42:270–279
Flüge S (2004) EMR-TS PC Transfer Set Narda Safety Test Solutions GmbH. BN 2244/90.36. Version 1.02 ff. http://www.narda-sts.us/software/Narda_EMR.zip
Gallai N, Salles JM, Settele J, Vaissière BE (2009) Economic valuation of the vulnerability of world agriculture confronted with pollinator decline. Ecol Econ 68:810–821
Goldsmith A (2005) Wireless communications. Cambridge University Press, Cambridge
Goulson D, Lye GC, Darvill B (2008) Decline and conservation of bumble bees. Annu Rev Entomol 53:191–208
Harst W, Kuhn J, Stever H (2006) Can electromagnetic exposure cause a change in behaviour? Studying possible non-thermal influences on honeybees—an approach within the framework of educational informatics. Acta Syst IIAS Int J 6(1):1–6
Hegland SJ, Nielsen A, Lázaro A, Bjerknes AL, Totland Ø (2009) How does climate warming affect plant–pollinator interactions? Ecol Lett 12:184–195
Kearns C, Inouye D, Waser N (1998) Endangered mutualisms: the conservation of plant–pollinator interactions. Annu Rev Ecol Syst 29:83–112
Kirschvink JL, Walker MM, Diebel C (2001) Magnetite-based magnetoreception. Curr Opin Neurobiol 11:462–467
Klein AM, Vaissière BE, Cane JH, Dewenter IS, Cunningham SA, Kremen C, Tscharntke T (2007) Importance of pollinators in changing landscapes for world crops. Proc R Soc Lond B Biol Sci 274:303–313
Kremen C, Williams NM, Aizen MA, Gemmill-Herren B, LeBuhn G, Minckley R, Packer L, Potts SG, Roulston T, Steffan-Dewenter I, Vázquez DP, Winfree R, Adams L, Crone EE, Greenleaf SS, Keitt TH, Klein AM, Regetz J, Ricketts TH (2007) Pollination and other ecosystem services produced by mobile organisms: a conceptual framework for the effects of land-use change. Ecol Lett 10:299–314
Lázaro A, Tscheulin T, Devalez J, Nakas G, Petanidou T (2016) Effects of grazing intensity on pollinator abundance and diversity, and on pollination services. Ecol Entom. doi:10.1111/een.12310
Lever JJ, van Nes EH, Scheffer M, Bascompte J (2014) The sudden collapse of pollinator communities. Ecol Lett 17:350–359
Löscher W, Käs G (1998) Behavioural abnormalities in a dairy cow herd near a TV and radio transmitting antenna. Prakt Tierarzt 79:437
Marks TA, Ratke CC, English WO (1995) Stray voltage and developmental, reproductive and other toxicology problems in dogs, cats and cows—a discussion. Vet Hum Toxicol 37:163–172
Maskey D, Kim M, Aryal B, Pradhan J, Choi I-Y, Park K-S, Son T, Hong S-Y, Kim SB, Kim HG, Kim MJ (2010) Effect of 835 MHz radiofrequency radiation exposure on calcium binding proteins in the hippocampus of the mouse brain. Brain Res 1313:232–241
Maskey D, Kim H-J, Kim HG, Kim MJ (2012) Calcium-binding proteins and GFAP immunoreactivity alterations in murine hippocampus after 1 month of exposure to 835 MHz radiofrequency at SAR values of 1.6 and 4.0 W/kg. Neurosci Lett 506:292–296
Michener CD (2007) The bees of the world, 2nd edn. John Hopkins University Press, Baltimore
Minckley R, Packer L, Potts SG, Roulston T, Steffan-Dewenter I, Vázquez DP, Winfree R, Adams L, Crone EE, Greenleaf SS, Keitt TH, Klein A-M, Regetz J, Ricketts TH (2007) Pollination and other ecosystem services produced by mobile organisms: a conceptual framework for the effects of land-use change. Ecol Lett 10:299–314
Müller A (2015) Palaearctic osmiine bees. ETH Zürich. http://blogs.ethz.ch/osmiini
Narayanan SN, Kumar RS, Karun KM, Nayak SB, Bhat PG (2015) Possible cause for altered spatial cognition of prepubescent rats exposed to chronic radiofrequency electromagnetic radiation. Metab Brain Dis 30(5):1193–1206
Nielsen A, Steffan-Dewenter I, Westphal C, Messinger O, Potts SG, Roberts SPM, Settele J, Szentgyorgyi H, Vaissière BE, Vaitis M, Woyciechowski M, Bazos I, Biesmeijer JC, Bommarco R, Kunin WE, Tscheulin T, Lamborn E, Petanidou T (2011) Assessing bee species richness in two Mediterranean communities: importance of habitat type and sampling techniques. Ecol Res 26:969–983
Panagopoulos DJ, Margaritis LH (2010) The effect of exposure duration on the biological activity of mobile telephony radiation. Mutat Res 699:17–22
Panagopoulos DJ, Karabarbounis A, Margaritis LH (2004) Effect of GSM 900-MHz mobile phone radiation on the reproductive capacity of Drosophila melanogaster. Electromagn Biol Med 23:29–43
Panagopoulos DJ, Chavdoula ED, Nezis IP, Margaritis LH (2007) Cell death induced by GSM 900-MHz and DCS 1800-MHz mobile telephony radiation. Mutat Res 626:69–78
Panagopoulos DJ, Chavdoula ED, Margaritis LH (2010) Bioeffects of mobile telephony radiation in relation to its intensity or distance from the antenna. Int J Radiat Biol 86:345–357
Pauw A (2007) Collapse of a pollination web in small conservation areas. Ecology 88:1759–1769
Petanidou T, Ellis WN (1993) Pollinating fauna of a phryganic ecosystem: composition and diversity. Biodiv Lett 1:9–22
Petanidou T, Ståhls G, Vujić A, Olesen JM, Rojo S, Thrasyvoulou A, Sgardelis S, Kallimanis AS, Kokkini S, Tscheulin T (2013) Investigating plant–pollinator relationships in the Aegean: the approaches of the project POL-AEGIS (The Pollinators of the Aegean Archipelago: Diversity and Threats). J Apicult Res 52:106–117
Potts SG, Petanidou T, Roberts S, O’Toole C, Hulbert A, Willmer P (2006) Plant-pollinator biodiversity and pollination services in a complex Mediterranean landscape. Biol Conserv 129:519–529
Potts SG, Biesmeijer JC, Kremen C, Neumann P, Schweiger O, Kunin WE (2010) Global pollinator declines: trends, impacts and drivers. Trends Ecol Evol 25:345–353
R Development Core Team (2008) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0. http://www.R-project.org
Sahib SS (2011) Impact of mobile phones on the density of honeybees. J Public Adm Policy Res 3:131–137
Sahin A, Aslan A, Bas O, Ikinci A, Özyilmaz C, Sönmez OF, Çolakoglu OE (2015) Deleterious impacts of a 900-MHz electromagnetic field on hippocampal pyramidal neurons of 8-week-old Sprague Dawley male rats. Brain Res 1624:232–238
Sharma VP, Kumar NR (2010) Changes in honeybee behaviour and biology under the influence of cellphone radiations. Curr Sci 98:1376–1378
Tscheulin T, Spyropoulos A, Petanidou T (2010) Impacts of mobile phone masts on the abundance of pollinators. In: 5th Conference of the Hellenic Ecological Society, Patras, p 201
Vácha, M, Půžová T, Kvíčalová M (2009) Radio-frequency magnetic fields disrupt magnetoreception in American cockroach. J Exp Biol 212:3473–3477
Válková T, Vácha M (2012) How do honeybees use their magnetic compas? Can they see the North? Bull Entomol Res 102:461–467
Vijver MG, Bolte JFB, Evans TR, Tamis WLM, Peijnenburg WJGM, Musters CJM, de Snoo GR (2013) Investigating short-term exposure to electromagnetic fields on reproductive capacity of invertebrates in the field situation. Electromagn Biol Med 33(1):21–28
Wajnberg E, Acosta-Avalos D, Alves OC, de Oliviera JF, Srygley RB, Esquivel DM (2010) Magnetoreception in eusocial insects: an update. J R Soc Interface 7:S207–S225
Warnke U (2009) Bees, birds and mankind: destroying nature by ‘Electrosmog’ effects of wireless communication technologies. A Brochure series by the competence initiative for the protection of humanity, environment and democracy, Kempten, 1st edn, November 2007, ISBN: 978-3-00-023124-7, English edn, March 2009, pp 14–33
Weisbrot D, Lin H, Ye L, Blank M, Goodman R (2003) Effects of mobile phone radiation on reproduction and development in Drosophila melanogaster. J Cell Biochem 89:48–55
Westphal C, Bommarco R, Carre G, Lamborn E, Morison N, Petanidou T, Potts SG, Roberts SPM, Szentgyorgyi H, Tscheulin T, Vaissière BE, Woyciechowski M, Biesmeijer JC, Kunin WE, Settele J, Steffan-Dewenter I (2008) Measuring bee biodiversity in different European habitats and biogeographical regions. Ecol Monogr 78:653–671
Yeates DK, Greathead DJ (1997) The evolutionary pattern of host use in the Bombyliidae (Diptera): a diverse family of parasitoid flies. Biol J Linn Soc 60:149–185
Zuur AF, Ieno EN, Walker NJ, Saveliev AA, Smith GM (2009) Mixed effects models and extensions in ecology with R. Springer, New York
Zuur AF, Hilbe JM, Ieno EN (2013) Beginner’s guide to GLM and GLMM with R. Highland Statistics, Newburgh
Acknowledgments
The research has been co-financed by the European Union (European Social Fund—ESF) and Greek national funds through the Operational Program “Education and Lifelong Learning” of the National Strategic Reference Framework (NSRF)—Research Funding Program: THALES: Investing in knowledge society through the European Social Fund. We would like to thank W. Arens, H. Dathe, J. Dils, A. Ebmer, M. Kuhlmann, V. Mizerakis, A. Mueller, A. Pauly, C. Praz, M. Quaranta, S. Risch, W. Schedl, E. Scheuchl, M. Schwarz, M. Terzo and A. Vujic for insect identification.
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Lázaro, A., Chroni, A., Tscheulin, T. et al. Electromagnetic radiation of mobile telecommunication antennas affects the abundance and composition of wild pollinators. J Insect Conserv 20, 315–324 (2016). https://doi.org/10.1007/s10841-016-9868-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10841-016-9868-8